Product Description
Product Description
Hollow shaft rotary actuators
KAH series hollow shaft rotary actuators
Main features
1.KAH series hollow shaft rotary actuator provides large-torque and high-precision rotary actuation. With integrated design, processing and assembly technique, it is provided with high precision speed reducer, framework torque motor, hollow shaft high resolution absolute encoder, brake and intelligent sensor.
2.It provides high torque output and torque density, for example, the torque of KAH-40 rotary actuator can reach 800N·m.
3.The positioning precision of rotary actuator is within 30 Arc sec.
4.An internal through hole is set to facilitate threading wires, gas pipe and laser beams and simplify system structure.
5.Dozens of product models are provided to meet diversified needs, and the products with 220 VAC, 110 VAC and 48 VAC voltages are available.
6.The high protection grade (IP67) makes the product applicable to severe working environment.
8.It can be used by matching with KDE series EtherCAT bus servo drives to realize ultra-low vibration controland reliable and stable operation. It provides an integrated drive control solution.
Applications
The products have been widely used in such fields as electronic and semiconductor equipment, precision machine tool, factory automation systems, precision laser processing device, LED equipment, detection device, medical apparatus and instruments, robot and special mechanical arm, printing machinery, spray painting equipment, glass processing equipment, precision measuring instrument and other fields.
Model
Specifications
KAH-20 encoder Specification parameter | |||||||
Series | KAH-20 | ||||||
Model KAH-20 | 20A | 20B | 20C | 20D | 20E | ||
Deceleration ratio | 1:51 | 1:81 | 1:101 | 1:121 | 1:161 | ||
Maximum torque starting &stopping(N·M) | 69 | 91 | 102 | 108 | 113 | ||
Instantaneous maximum torque(N·M) | 42 | 58 | 61 | 61 | 61 | ||
AC voltage 220VAC | Maximum speed | RPM | 119.6 | 75.3 | 60.4 | 50.4 | 37.9 |
Rated speed | RPM | 60.8 | 38.3 | 30.7 | 25.6 | 19.3 | |
Maximum current | Arms | 4.53 | 3.89 | 3.41 | 2.78 | 2.21 | |
Rated current | Arms | 2.12 | 1.85 | 1.56 | 1.3 | 0.98 | |
Torque constant | N·M/Arms | 19.81 | 31.35 | 39.10 | 46.92 | 62.24 | |
Motor phase resistance | Ohms | 2.135 | |||||
Motor phase inductance | mH | 3.869 | |||||
Motor Back EMF | Vrms/kRPM | 30.66 | |||||
AC voltage 1100VAC | Maximum speed | RPM | 100 | 63.0 | 50.5 | 42.1 | 31.7 |
Rated speed | RPM | 60.8 | 38.3 | 30.7 | 25.6 | 19.3 | |
Maximum current | Arms | 9.49 | 7.87 | 7.08 | 6.25 | 4.91 | |
Rated current | Arms | 4.28 | 3.72 | 3.14 | 2.62 | 1.97 | |
Torque constant | N·M/Arms | 9.82 | 15.61 | 19.45 | 23.32 | 31.04 | |
Motor phase resistance | Ohms | 1.036 | |||||
Motor phase inductance | mH | 1.684 | |||||
Motor Back EMF | Vrms/kRPM | 14.79 | |||||
AC voltage 480VAC | Maximum speed | RPM | 78.4 | 49.4 | 39.6 | 33.1 | 24.8 |
Rated speed | RPM | 60.8 | 38.3 | 30.7 | 25.6 | 19.3 | |
Maximum current | Arms | 17.89 | 18.86 | 13.33 | 11.79 | 9.27 | |
Rated current | Arms | 10.88 | 12.03 | 7.97 | 6.66 | 5.03 | |
Torque constant | N·M/Arms | 3.86 | 4.82 | 7.65 | 9.16 | 12.19 | |
Motor phase resistance | Ohms | 0.262 | |||||
Motor phase inductance | mH | 0.313 | |||||
Motor Back EMF | Vrms/kRPM | 7.98 | |||||
Absolute Encoder | Encoder Type | Hollow absolute multiturn encoders ,Single-loop 19,22or24, multiturn16 | |||||
Encoder resolution Motor(1time)rotation | 219(524,288),222(4,194.304)or224(16777216) | ||||||
Motor multiple rotation counter | 215(65.536) | ||||||
Incremental | Encoder resolution | Hollow incremental encoder,40000impulse/rpm(4 time signal) | |||||
encoder | Output shaft resolution | pulse/rev | 2040000 | 3240000 | 4040000 | 4840000 | 6440000 |
uniderection positioning accuracy | Arc Sec | 60 | 40 | 40 | 40 | 40 | |
Bidirectional positioning accuracy | Arc Min | 2 | 1.5 | 1 | 1 | 1 | |
Overturning stiffness | ×104 N·m /rad | 22.5 | 27.3 | ||||
Torsional stiffness | ×104 N·m /rad | 1.8 | 2.3 | ||||
Moment of inertia | without Brake | Kg*m2 | 0.19 | 0.57 | 0.86 | 1.23 | 2.18 |
with Brake | Kg*m2 | 0.22 | 0.63 | 0.95 | 1.35 | 2.35 | |
Weight | without Brake | Kg | 2.2 | ||||
with Brake | Kg | 2.5 | |||||
Motor Grade | 16 | ||||||
Motor insulation | Heat resistance grade :F(155ºC) | ||||||
Insulation resistance:above200MΩ(DC500V) | |||||||
Dielectric Strength:AC1500V/1min | |||||||
Protection grade | Fully closed self cooling type(IP65/IP67 degree) |
Photos
/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | Motor, Machinery |
---|---|
Hardness: | Hardened Tooth Surface |
Installation: | Vertical Type |
Samples: |
US$ 3000/Piece
1 Piece(Min.Order) | Order Sample |
---|
Customization: |
Available
|
|
---|
.shipping-cost-tm .tm-status-off{background: none;padding:0;color: #1470cc}
Shipping Cost:
Estimated freight per unit. |
about shipping cost and estimated delivery time. |
---|
Payment Method: |
|
---|---|
Initial Payment Full Payment |
Currency: | US$ |
---|
Return&refunds: | You can apply for a refund up to 30 days after receipt of the products. |
---|
Are there common issues or challenges associated with servo motor systems, and how can they be addressed?
Servo motor systems are widely used in various applications, but they can encounter common issues or challenges that affect their performance and reliability. Let’s explore some of these issues and discuss potential solutions:
1. Positioning and Tracking Errors:
One common challenge in servo motor systems is positioning and tracking errors. These errors can occur due to factors such as mechanical backlash, encoder resolution limitations, or disturbances in the system. To address this issue, careful calibration and tuning of the servo control system are necessary. This includes adjusting feedback gains, implementing feedback filtering techniques, and utilizing advanced control algorithms to improve the system’s accuracy and minimize errors. Additionally, employing high-resolution encoders and backlash compensation mechanisms can help enhance the positioning and tracking performance.
2. Vibration and Resonance:
Vibration and resonance can impact the performance of servo motor systems, leading to reduced accuracy and stability. These issues can arise from mechanical resonances within the system or external disturbances. To mitigate vibration and resonance problems, it is crucial to analyze the system’s dynamics and identify critical resonant frequencies. Implementing vibration dampening techniques such as mechanical isolation, using vibration-absorbing materials, or employing active vibration control methods can help minimize the effect of vibrations and improve the system’s performance.
3. Overheating and Thermal Management:
Servo motors can generate heat during operation, and inadequate thermal management can lead to overheating and potential performance degradation. To address this issue, proper cooling and thermal management techniques should be employed. This may involve using heat sinks, fans, or liquid cooling systems to dissipate heat efficiently. Ensuring adequate ventilation and airflow around the motor and avoiding excessive current or overloading can also help prevent overheating. Monitoring the motor’s temperature and implementing temperature protection mechanisms can further safeguard the motor from thermal damage.
4. Electrical Noise and Interference:
Electrical noise and interference can affect the performance and reliability of servo motor systems. These issues can arise from electromagnetic interference (EMI) or radio frequency interference (RFI) from nearby equipment or electrical sources. To mitigate electrical noise, proper shielding and grounding techniques should be employed. Using shielded cables, ferrite cores, and grounding the motor and control system can help minimize the impact of noise and interference. Additionally, employing filtering techniques and surge protection devices can further improve system robustness against electrical disturbances.
5. System Integration and Compatibility:
Integrating a servo motor system into a larger control system or automation setup can present challenges in terms of compatibility and communication. Ensuring proper compatibility between the servo motor and the control system is crucial. This involves selecting appropriate communication protocols, such as EtherCAT or Modbus, and ensuring compatibility with the control signals and interfaces. Employing standardized communication interfaces and protocols can facilitate seamless integration and interoperability. Additionally, thorough testing and verification of the system’s compatibility before deployment can help identify and address any integration issues.
6. Maintenance and Service:
Maintenance and service requirements are important considerations for servo motor systems. Regular maintenance, including lubrication, inspection, and cleaning, can help prevent issues related to wear and tear. Following manufacturer-recommended maintenance schedules and procedures is essential to ensure the longevity and optimal performance of the motor. In case of any malfunctions or failures, having access to technical support from the manufacturer or trained service personnel can help diagnose and address problems effectively.
By being aware of these common issues and challenges associated with servo motor systems and implementing appropriate solutions, it is possible to enhance the performance, reliability, and lifespan of the servo motor system. Regular monitoring, proactive maintenance, and continuous improvement can contribute to optimizing the overall operation and efficiency of the system.
Are there different types of servo motors, and how do they differ?
Yes, there are different types of servo motors available, each with its own characteristics and applications. The variations among servo motors can be attributed to factors such as construction, control mechanisms, power requirements, and performance specifications. Let’s explore some of the common types of servo motors and how they differ:
1. DC Servo Motors:
DC servo motors are widely used in various applications. They consist of a DC motor combined with a feedback control system. The control system typically includes a position or velocity feedback sensor, such as an encoder or a resolver. DC servo motors offer good speed and torque control and are often employed in robotics, automation, and hobbyist projects. They can be operated with a separate motor driver or integrated into servo motor units with built-in control electronics.
2. AC Servo Motors:
AC servo motors are designed for high-performance applications that require precise control and fast response times. They are typically three-phase motors and are driven by sinusoidal AC waveforms. AC servo motors often incorporate advanced control algorithms and feedback systems to achieve accurate position, velocity, and torque control. These motors are commonly used in industrial automation, CNC machines, robotics, and other applications that demand high precision and dynamic performance.
3. Brushed Servo Motors:
Brushed servo motors feature a traditional brushed DC motor design. They consist of a rotor with a commutator and carbon brushes that make physical contact with the commutator. The brushes provide electrical connections, allowing the motor’s magnetic field to interact with the rotor’s windings. Brushed servo motors are known for their simplicity and cost-effectiveness. However, they may require more maintenance due to brush wear, and they generally have lower efficiency and shorter lifespan compared to brushless servo motors.
4. Brushless Servo Motors:
Brushless servo motors, also known as brushless DC (BLDC) motors, offer several advantages over brushed motors. They eliminate the need for brushes and commutators, resulting in improved reliability, higher efficiency, and longer lifespan. Brushless servo motors rely on electronic commutation, typically using Hall effect sensors or encoder feedback for accurate rotor position detection. These motors are widely used in robotics, industrial automation, aerospace, and other applications that require high-performance motion control with minimal maintenance.
5. Linear Servo Motors:
Linear servo motors are designed to provide linear motion instead of rotational motion. They consist of a primary part (stator) and a secondary part (slider or forcer) that interact magnetically to generate linear motion. Linear servo motors offer advantages such as high speed, high acceleration, and precise positioning along a linear axis. They find applications in various industries, including semiconductor manufacturing, packaging, printing, and machine tools.
6. Micro Servo Motors:
Micro servo motors are small-sized servo motors often used in applications with limited space and low power requirements. They are commonly found in hobbyist projects, model airplanes, remote-controlled vehicles, and small robotic systems. Micro servo motors are lightweight, compact, and offer reasonable precision and control for their size.
These are some of the different types of servo motors available, each catering to specific applications and requirements. The choice of servo motor type depends on factors such as the desired performance, accuracy, power requirements, environmental conditions, and cost considerations. Understanding the differences between servo motor types is essential for selecting the most suitable motor for a particular application.
What is a servo motor, and how does it function in automation systems?
A servo motor is a type of motor specifically designed for precise control of angular or linear position, velocity, and acceleration. It is widely used in various automation systems where accurate motion control is required. Let’s explore the concept of servo motors and how they function in automation systems:
A servo motor consists of a motor, a position feedback device (such as an encoder or resolver), and a control system. The control system receives input signals, typically in the form of electrical pulses or analog signals, indicating the desired position or speed. Based on these signals and the feedback from the position sensor, the control system adjusts the motor’s operation to achieve the desired motion.
The functioning of a servo motor in an automation system involves the following steps:
- Signal Input: The automation system provides a control signal to the servo motor, indicating the desired position, speed, or other motion parameters. This signal can be generated by a human operator, a computer, a programmable logic controller (PLC), or other control devices.
- Feedback System: The servo motor incorporates a position feedback device, such as an encoder or resolver, which continuously monitors the motor’s actual position. This feedback information is sent back to the control system, allowing it to compare the actual position with the desired position specified by the input signal.
- Control System: The control system, typically housed within the servo motor or an external servo drive, receives the input signal and the feedback from the position sensor. It processes this information and generates the appropriate control signals to the motor.
- Motor Operation: Based on the control signals received from the control system, the servo motor adjusts its operation to achieve the desired motion. The control system varies the motor’s voltage, current, or frequency to control the motor’s speed, torque, or position accurately.
- Closed-Loop Control: Servo motors operate in a closed-loop control system. The feedback information from the position sensor allows the control system to continuously monitor and adjust the motor’s operation to minimize any deviation between the desired position and the actual position. This closed-loop control mechanism provides high accuracy, repeatability, and responsiveness in motion control applications.
One of the key advantages of servo motors in automation systems is their ability to provide precise and dynamic motion control. They can rapidly accelerate, decelerate, and change direction with high accuracy, allowing for intricate and complex movements. Servo motors are widely used in applications such as robotics, CNC machines, printing presses, packaging equipment, and automated manufacturing systems.
In summary, a servo motor is a specialized motor that enables accurate control of position, velocity, and acceleration in automation systems. Through the combination of a control system and a position feedback device, servo motors can precisely adjust their operation to achieve the desired motion. Their closed-loop control mechanism and high responsiveness make them an essential component in various applications requiring precise and dynamic motion control.
editor by CX 2024-03-11
China Custom Omron R88m-1L1K530t-BS2 PLC R88m1l1K530t-BS2 AC Servo Motor with Good quality
Product Description
HangZhou CHINAMFG Electronics Co., Ltd. is a B2B and B2C online shopping mall specializing in the industrial control electrical and electronic components industry.
In order to facilitate buyers to be able to purchase globally
We are not only an industrial control electrical and electronic retailer, but also a wholesale company. We do not have a complete list of our online stores.
If you need to purchase in bulk, please contact us for a better quote.
We hope to win your trust through reliable and competitive services.
Our aim is customer satisfaction is our biggest aim !!!!
6ES7953-8LG11-0AA0 | 6ES7193-4CA50-0AA0 | D4SL-NSK10-LKH | E2E-X4MD1 2M |
6ES7953-8LG20-0AA0 | 6ES7193-4CK30-0AA0 | D4V-8104SZ-N | E2E-X14MD1 2M |
6ES7953-8LG30-0AA0 | 6ES7193-4JA00-0AA0 | D4V-8104Z-N | E2E-C04S12-WC-B1 2M |
6ES7953-8LG31-0AA0 | 6ES7193-4JA00-0AA0 | D4V-8107Z-N BY OMR | E2E-C04S12-WC-C1 2M |
6ES7953-8LF11-0AA0 | 6ES7193-4DL00-0AA0 | D4V-8108SZ | E2E-C04S12-WC-B1-2 2M |
6ES7953-8LF20-0AA0 | 6ES7193-4DL10-0AA0 | D4V-8108SZ-N | E2E-S05S12-WC-C1 2M |
6ES7953-8LF30-0AA0 | 6ES7193-4DE10-0AA0 | D4V-8108SZ-N | E2E-S05S12-WC-B1 2M |
6ES7953-8LF31-0AA0 | 6ES7193-4CE00-0AA0 | D4V-8108SZ-N BY OMR | E2E-S05S12-WC-C1-2 2M |
6ES7953-8LL20-0AA0 | 6ES7193-4CE10-0AA0 | D4V-8108Z-N | E2E-C03SR8-WC-C1 2M |
6ES7953-8LL31-0AA0 | 6ES7195-7HD80-0XA0 | D4V-8108Z-N BY OMR | E2B-M12KS04-WP-B1 |
6ES7195-7HB00-0XA0 | D4V-8111Z BY OMR | E2B-M12KS04-WP-B2 | |
6ES7131-4BF00-0AA0 | D4V-8112Z | E2B-M12KS04-WP-C1 | |
6ES7134-4MB02-0AB0 | 6ES7131-4BF00 | E2B-M12KS04-WP-C2 | |
6ES7134-4GD00-0AB0 | 6ES7132-4BF00 | E2B-M12LS04-M1-B1 OMS | E2B-S08KS02-MC-B1 OMS |
6ES7135-4GB01-0AB0 | 6ES7134-4GB01 | E2B-M12LS04-M1-B2 OMS | E2B-S08KS02-MC-B2 OMS |
6ES7135-4LB02-0AB0 | 6ES7134-4GB11 | E2B-M12LS04-M1-C1 OMS | E2B-S08KS02-MC-C1 OMS |
6ES7138-4DF01-0AB0 | 6ES7134-4GD00 | E2B-M12LS04-M1-C1 OMS | E2B-S08KS02-MC-C2 OMS |
6ES7138-4DF11-0AB0 | 6ES7135-4GB01 | E2B-S08KN04-WP-B1 2M OMS | E2B-S08KN04-MC-B1 OMS |
6ES7138-4CA01-0AB0 | 6ES7135-4LB02 | E2B-S08KN04-WP-B2 2M OMS | E2B-S08KN04-MC-B2 OMS |
6ES7138-4DA04-0AB0 | 6ES7138-4DA04 | E2B-S08KN04-WP-C1 2M OMS | E2B-M12LN05-M1-C1 OMS |
6ES7138-4CF03-0AB0 | 6ES7138-4CA01 | E2B-S08KN04-WP-C2 2M OMS | E2B-M12LN05-M1-C2 OMS |
6ES7151-3AA23-0AB0 | 6ES7151-3AA23 | E2B-M12KN05-M1-B1 OMS | E2B-M12KS02-M1-B1 OMS |
6ES7972-0BA52-0XA0 | 6ES7151-1AA06 | E2B-M12KN05-M1-B2 OMS | E2B-M12KS02-M1-B2 OMS |
6ES7972-0BA12-0XA0 | 6ES7138-4DF11 | E2B-M12KN05-M1-C1 OMS | E2B-M12KS02-M1-C1 OMS |
6ES7193-4GD20-0AA0 | 6ES7151-1BA02 | E2B-M12KN05-M1-C2 OMS | E2B-M12KS02-M1-C2 OMS |
6ES7134-4MB02-0AB0 | E2B-S08KN02-MC-B1 OMS | E2B-S08KN02-WP-B1 2M OMS | |
6ES7151-3BA23-0AB0 | E2B-S08KN02-MC-B2 OMS | E2B-S08KN02-WP-C1 2M OMS | |
6SL3120-1TE23-0AC0 | 6SL3120-2TE13-0AD0 | E2B-S08KN02-MC-C1 OMS | E2B-S08LN04-MC-B1 OMS |
E2B-S08KN02-MC-C2 OMS | E2B-S08LN04-MC-B2 OMS | ||
GP2501-TC11 | 3G3JZ-A4015 | D2F-F-D | CJ1W-ID261 |
GP2501-TC41-24V | 3G3JZ-A4571 | D2F-L | CJ1W-ID262 |
GP2400-TC41-24V | 3G3JZ-A4037 | D2FW-G271M(D) | CJ1W-MD231 |
GP2401-TC41-24V | 3G3JZ-AB004 | D2FW-G273M | CJ1W-MD233 |
GP2300-LG41-24V | 3G3JZ-AB007 | D2HW-A201D | CJ1W-MD261 |
GP2301-LG41-24V | 3G3JZ-AB007 | D2MQ-1 | CJ1W-MD263 |
GP2300-SC41-24V | 3G3JZ-AB015 | D2MV-01L22-1C3 | CJ1W-MD563 |
GP2301-SC41-24V | 3G3JZ-AB015 | D2VW-5-1M(D)(CHN) | CJ1W-OA201 |
GP2300-TC41-24V | 3G3MX2-A4007-ZV1 | D2VW-5L2-1M(CHN) | CJ1W-OC201 |
GP2301-TC41-24V | 3G3MX2-A4110-ZV1 | D2VW-5L2-1M(D) | CJ1W-OC211 |
3G3MX2-A4150-ZV1 | D2X-C | CJ1W-OD201 | |
GP4301TAD | 3G3MZ-AB015 | D3M-01L2 | CJ1W-OD211 |
GP4301TADW | 3M6006 | D3V-16-3C25 BY OMI | CJ1W-OD212 |
GP4201TAD | 3TB4322-0XB0 | D40A-1C015-F | CJ1W-OD231 |
GP4201TADW | 3Z4S-CA STC-S133P-CS | D40A-1C5 BY OMS | CJ1W-OD232 |
GP4401TAD | 3Z4S-LE SV-1214V | D4A-3101N | CJ1W-OD233 |
GP4401TADW | D4A-4501N | CJ1W-OD261 | |
GM4301TAD | 6571-1030 VS64-CBL-03M | D4A-4501N | CJ1W-OD262 |
GM4201TAD | 61F-G 110/220VAC C | D4A-A00 | CJ1W-OD263 |
GP4501TAD | 61F-G1N AC110/220 | D4A-C00 | CJ1W-IC101 |
GP4501TAA | 61F-G3N AC110/220 | D4A-C00 | CJ1W-II101 |
GP4501TADW | 61F-GP-N AC100 | D4B-2A15N | CJ1W-TER01 |
GP4601TAA | 61F-GP-N AC220 | D4C-1202 | CJ1W-B7A22 |
GP4601TAD | 61F-GP-N AC220 | D4C-1202 | CJ1W-INT01 |
GP4501TMA | 61F-IN AC110/220 | D4C-1224 | CJ1W-IDP01 |
GP4601TMA | 6ES7-216-2BD23-0XB0 | D4C-1302 | CJ1W-CLK23 |
GP4501TMD | 8PFA | D4C-1402 | CJ1W-CRM21 |
GP4601TMD | A165-JRM-1 | D4C-1602 | CJ1W-DRM21 |
A-20GV2-B | D4C-3202 | CJ1W-EIP21 | |
NS5-SQ00B-V2 | A22-01 | D4C-4332 | CJ1W-ETN21 |
NS5-TQ11B-V2 | A22E-M-12 | D4C-6224 | CJ1W-ETN11 |
NS5-SQ11B-V2 | A22Z-EG1 | D4CC-3060 | CJ1W-CLK21-V1 |
NS5-SQ10B-V2 | AP-Z | D4CC-4571 | CJ1W-SCU21-V1 |
NS5-SQ10B-ECV2 | B7AS-T6B6 | D4CC-4060 | CJ1W-SCU31-V1 |
NS8-TV00B-V2 | B7A-T6A1 | D4DS-K1 | CJ1W-SRM21 |
NS8-TV00B-ECV2 | BNL6 | D4DS-K2 | CJ1W-SCU41-V1 |
NS8-TV01B-V2 | BS-1 | D4DS-K2 | CJ2M-MD211 |
NS10-TV00B-V2 | BS-1 | D4DS-K2 | CJ2M-CPU11 |
NS10-TV00B-ECV2 | BS-1 | D4DS-K2 | CJ2M-CPU12 |
NS10-TV01B-V2 | D4DS-K3 | CJ2M-CPU13 | |
NS12-TS01B-V2 | C500-CE403 | D4DS-K3 | CJ2M-CPU14 |
NS12-TS01-V2 | C500-CE404 | D4DS-K3 | CJ2M-CPU15 |
NS12-TS00B-V2 | C500-CE404 | D4DS-K5 | CJ2M-CPU31 |
NS12-TS00-V2 | C500-CE404 | D4DS-K5 | CJ2M-CPU32 |
CDHD-N | D4E-1A10N OKUMA | CJ2M-CPU33 | |
6ES7331-7HF01-0AB0 | CDHD-N1KW | D4E-1A20N | CJ2M-CPU34 |
6ES7331-7KB02-0AB0 | D4E-1A20N | CJ2M-CPU35 | |
6ES7331-7KF02-0AB0 | CMT3155X | D4E-2C10N | CJ1W-PA202 |
6ES7331-7PF01-0AB0 | CP1EB-CPURM01 | D4GL-1AFA-A | CJ1W-PA205R |
6ES7331-7PF11-0AB0 | CP1E-E20SDR-A | D4GS-NK1 | CJ1W-PD571 |
6ES7331-7NF00-0AB0 | CP1E-E30SDR-A | D4JL-2NFA-C5 | CJ1W-PD571 |
6ES7331-7SF00-0AB0 | CP1E-E40SDR-A | D4JL-2NFG-C5 | CJ1W-PA205C |
6ES7331-1KF01-0AB0 | CP1E-E60DR-A | D4JL-2RFA-C6 | CJ1M-CPU11 |
6ES7331-1KF02-0AB0 | CP1E-E60SDR-A | D4JL-4QFA-C6 | CJ1M-CPU12 |
CP1E-N14DR-D | D4JL-4QFA-D6 | CJ1M-CPU13 | |
6ES7332-7ND02-0AB0 | CP1E-N14DT1-A | D4JL-K2 | CJ1M-CPU21 |
6ES7332-5HB01-0AB0 | CP1E-N14DT-D | D4JL-K3 | CJ1M-CPU22 |
6ES7332-5HD01-0AB0 | CP1E-N20DR-A | D4MC-2000 | CJ1M-CPU23 |
6ES7332-5HF00-0AB0 | CP1E-N20DT-A | D4MC-2000 | CJ1W-AD041-V1 |
CP1E-N20DT-D | D4MC-2571 | CJ1W-AD04U | |
6ES7153-1AA03-0XB0 | CP1E-N30DR-A | D4MC-5000 | CJ1W-AD081-V1 |
6ES7153-2BA02-0XB0 | CP1E-N30DR-D -CH | D4MC-5571-N BY OMR | CJ1W-DA571 |
6ES7153-2BA10-0XB0 | CP1E-N30DT-A | D4MC-5040-N | CJ1W-DA041 |
6ES7334-0CE01-0AA0 | CP1E-N30SDT-D | D4N-2120 | CJ1W-DA08C |
6ES7334-0KE00-0AB0 | CP1E-N40DR-A | D4N-2122 | CJ1W-DA08V |
6ES7335-7HG02-0AB0 | CP1E-N40DT1-A | D4N-212G | CJ1W-MAD42 |
6ES7338-4BC01-0AB0 | CP1E-N40DT-A | D4N-212G | CJ1W-PTS15 |
6ES7350-1AH03-0AE0 | CP1E-N40SDR-A | D4N-212G | CJ1W-PTS16 |
CP1E-N60DR-D | D4N-212H | CJ1W-PTS51 | |
6ES7307-1BA01-0AA0 | CP1E-N60DT1-D | D4N-2A2GR | CJ1W-PTS52 |
6ES7307-1EA01-0AA0 | CP1E-N60DT-A | D4N-412G | CJ1W-PH41U |
6ES7307-1KA02-0AA0 | CP1E-N60DT-D | D4N-8B32 | cj1W-NC113 |
CP1H-EX40DT-D | D4NA-412G | cj1W-NC133 | |
6ES7315-2AG10 | CP1H-EX40DT-D | D4NA-412G | cj1W-NC213 |
6ES7315-2AH14-0AB0 | CP1H-EX40DT-D | D4NA-4131 | cj1W-NC233 |
6ES7315-2EH14-0AB0 | CP1H-X40DR-A | D4NL-1DFA-B | cj1W-NC413 |
6GK7343-1CX10-0XE0 | CP1H-X40DR-A | D4NL-1DFA-BS | cj1W-NC433 |
6GK7343-1EX30-0XE0 | CP1H-X40DR-A | D4NL-1FFA-B4S | CJ1W-TC001 |
CP1H-X40DT-D | D4NL-2FFA-BS | CJ1W-TC002 | |
374-2XH01-0AA0 | CP1H-X40DT-D | D4NL-4DFA-BS | CJ1W-TC004 |
6ES7313-6CF03-0AB0 | CP1H-X40DT-D | D4NS-1AF | CJ1W-TC101 |
6ES7314-1AG140AB0 | CP1H-X40DT-D-SC | D4NS-1AF | CJ1W-CT571 |
6ES7317-2EK14-0AB0 | CP1H-X40DT-D-SC | D4NS-1AF | |
CP1H-XA40DR-A | D4NS-1AF | E2E-X2E1 2M | |
6ES7151-1AA02-0AB0 | CP1H-XA40DR-A | D4NS-1BF | E2E-X2F1 2M |
6ES7151-1AA04-0AB0 | CP1H-XA40DR-A | D4NS-1BF | E2E-X2ME1 2M |
6ES7151-1AA05-0AB0 | CP1H-XA40DR-A | D4NS-1CF | E2E-X2D1-N 2M |
6ES7151-1AA06-0AB0 | CP1H-XA40DR-A | D4NS-1CF | E2E-X2D2-N 2M |
6ES7151-1AB02-0AB0 | CP1H-XA40DR-A | D4NS-1CF | E2E-X2D1-U-Z 2M BY OMS |
6ES7151-1AB05-0AB0 | CP1H-XA40DT1-D | D4NS-1CF | E2E-X20MD1 2M OMS |
6ES7151-3BA23-0AB0 | CP1H-XA40DT-D | D4NS-1CF | E2E-X3D1-N 2M |
6ES7151-3AA23-0AB0 | CP1H-XA40DT-D | D4NS-2BF | E2E-X3D2-N 2M |
6ES7151-1BA02-0AB0 | CP1H-XA40DT-D | D4NS-4AF | E2E-X3D1-M1G |
6ES7151-1CA00-0AB0 | CP1H-Y20DT-D | D4NS-4BF | E2E-X5E1 2M |
6ES7151-1CA00-1BL0 | D4NS-4CF | E2E-X5E2 2M | |
6ES7151-1CA00-3BL0 | TM-E15S26-A1 | D4NS-4CF | E2E-X5MF1 5M |
6ES7151-8AB00-0AB0 | 6ES7193-4CA20-0AA0 | D4NS-4DF | E2E-X1R5E1 2M |
6ES7151-8AB01-0AB0 | 6ES7193-4CB20-0AA0 | D4SL-CN3 | E2E-X1R5E2 2M |
6ES7151-8FB00-0AB0 | 6ES7193-4CC20-0AA0 | D4SL-N2FFA-D | E2E-X5ME1 2M |
6ES7151-8FB01-0AB0 | 6ES7193-4CD20-0AA0 | D4SL-N2GFG-D | E2E-X5ME2 2M |
6ES7151-7AA11-0AB0 | 6ES7193-4CG20-0AA0 | D4SL-N2HFA-D | E2E-X7D1-N 2M |
6ES7151-7AA13-0AB0 | 6ES7193-4CA30-0AA0 | D4SL-N2VFA | E2E-X7D1-N 5M |
6ES7151-7AA20-0AB0 | 6ES7193-4CB30-0AA0 | D4SL-N4RFG-D | E2E-X7D2-N 5M |
6ES7151-7AA21-0AB0 | 6ES7193-4CC30-0AA0 | D4SL-NK1S | E2E-X8MD1 2M |
6ES7151-7FA21-0AB0 | 6ES7193-4CD30-0AA0 | D4SL-NK2 | E2E-X18ME1 2M |
6ES7151-3BA60-0AB0 | 6ES7193-4CG30-0AA0 | D4SL-NK2 | E2EM-X8C1 2M |
6ES7193-4CA40-0AA0 | D4SL-NK3 | E2E-X10E1 2M | |
6ES7953-8LJ20-0AA0 | 6ES7193-4CF40-0AA0 | D4SL-NSK10-LK | E2E-X10ME1 2M |
6ES7953-8LJ30-0AA0 | 6ES7193-4CF50-0AA0 | D4SL-NSK10-LK | E2E-X10MF1 2M |
6ES7953-8LJ31-0AA0 | 6ES7193-4CB00-0AA0 | D4SL-NSK10-LKH | E2E-X10D1-N 5M |
Our company specializes in industrial control PLC products, touch screen, relays, power switches, USB accessories, and is 1 of the few quality distributors/agents in China. If you have more needs. Or need more quantity. Or have other questions. Please feel free to contact us. We will give you more favorable First-class service. Let you buy with confidence ——>>Please contact us! |
|||
/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | Industrial |
---|---|
Speed: | High Speed |
Number of Stator: | Single-Phase |
Function: | Control |
Casing Protection: | Open Type |
Number of Poles: | 8 |
Customization: |
Available
|
|
---|
How are servo motors used in CNC machines and other precision machining equipment?
Servo motors play a crucial role in CNC (Computer Numerical Control) machines and other precision machining equipment. They provide precise and dynamic control over the movement of various axes, enabling high-accuracy positioning, rapid speed changes, and smooth motion profiles. Here’s a detailed explanation of how servo motors are used in CNC machines and precision machining equipment:
1. Axis Control:
CNC machines typically have multiple axes, such as X, Y, and Z for linear movements, as well as rotary axes for rotational movements. Servo motors are employed to drive each axis, converting electrical signals from the CNC controller into mechanical motion. The position, velocity, and acceleration of the servo motors are precisely controlled to achieve accurate and repeatable positioning of the machine’s tool or workpiece.
2. Feedback and Closed-Loop Control:
Servo motors in CNC machines are equipped with feedback devices, such as encoders or resolvers, to provide real-time information about the motor’s actual position. This feedback is used in a closed-loop control system, where the CNC controller continuously compares the desired position with the actual position and adjusts the motor’s control signals accordingly. This closed-loop control ensures accurate positioning and compensates for any errors, such as mechanical backlash or load variations.
3. Rapid and Precise Speed Changes:
Servo motors offer excellent dynamic response, allowing CNC machines to achieve rapid and precise speed changes during machining operations. By adjusting the control signals to the servo motors, the CNC controller can smoothly accelerate or decelerate the machine’s axes, resulting in efficient machining processes and reduced cycle times.
4. Contouring and Path Tracing:
CNC machines often perform complex machining tasks, such as contouring or following intricate paths. Servo motors enable precise path tracing by accurately controlling the position and velocity of the machine’s tool along the programmed path. This capability is crucial for producing intricate shapes, smooth curves, and intricate details with high precision.
5. Spindle Control:
In addition to axis control, servo motors are also used to control the spindle in CNC machines. The spindle motor, typically a servo motor, rotates the cutting tool or workpiece at the desired speed. Servo control ensures precise speed and torque control, allowing for optimal cutting conditions and surface finish quality.
6. Tool Changers and Automatic Tool Compensation:
CNC machines often feature automatic tool changers to switch between different cutting tools during machining operations. Servo motors are utilized to precisely position the tool changer mechanism, enabling quick and accurate tool changes. Additionally, servo motors can be used for automatic tool compensation, adjusting the tool’s position or orientation to compensate for wear, tool length variations, or tool offsets.
7. Synchronized Motion and Multi-Axis Coordination:
Servo motors enable synchronized motion and coordination between multiple axes in CNC machines. By precisely controlling the servo motors on different axes, complex machining operations involving simultaneous movements can be achieved. This capability is vital for tasks such as 3D contouring, thread cutting, and multi-axis machining.
In summary, servo motors are integral components of CNC machines and precision machining equipment. They provide accurate and dynamic control over the machine’s axes, enabling high-precision positioning, rapid speed changes, contouring, spindle control, tool changers, and multi-axis coordination. The combination of servo motor technology and CNC control systems allows for precise, efficient, and versatile machining operations in various industries.
Are there different types of servo motors, and how do they differ?
Yes, there are different types of servo motors available, each with its own characteristics and applications. The variations among servo motors can be attributed to factors such as construction, control mechanisms, power requirements, and performance specifications. Let’s explore some of the common types of servo motors and how they differ:
1. DC Servo Motors:
DC servo motors are widely used in various applications. They consist of a DC motor combined with a feedback control system. The control system typically includes a position or velocity feedback sensor, such as an encoder or a resolver. DC servo motors offer good speed and torque control and are often employed in robotics, automation, and hobbyist projects. They can be operated with a separate motor driver or integrated into servo motor units with built-in control electronics.
2. AC Servo Motors:
AC servo motors are designed for high-performance applications that require precise control and fast response times. They are typically three-phase motors and are driven by sinusoidal AC waveforms. AC servo motors often incorporate advanced control algorithms and feedback systems to achieve accurate position, velocity, and torque control. These motors are commonly used in industrial automation, CNC machines, robotics, and other applications that demand high precision and dynamic performance.
3. Brushed Servo Motors:
Brushed servo motors feature a traditional brushed DC motor design. They consist of a rotor with a commutator and carbon brushes that make physical contact with the commutator. The brushes provide electrical connections, allowing the motor’s magnetic field to interact with the rotor’s windings. Brushed servo motors are known for their simplicity and cost-effectiveness. However, they may require more maintenance due to brush wear, and they generally have lower efficiency and shorter lifespan compared to brushless servo motors.
4. Brushless Servo Motors:
Brushless servo motors, also known as brushless DC (BLDC) motors, offer several advantages over brushed motors. They eliminate the need for brushes and commutators, resulting in improved reliability, higher efficiency, and longer lifespan. Brushless servo motors rely on electronic commutation, typically using Hall effect sensors or encoder feedback for accurate rotor position detection. These motors are widely used in robotics, industrial automation, aerospace, and other applications that require high-performance motion control with minimal maintenance.
5. Linear Servo Motors:
Linear servo motors are designed to provide linear motion instead of rotational motion. They consist of a primary part (stator) and a secondary part (slider or forcer) that interact magnetically to generate linear motion. Linear servo motors offer advantages such as high speed, high acceleration, and precise positioning along a linear axis. They find applications in various industries, including semiconductor manufacturing, packaging, printing, and machine tools.
6. Micro Servo Motors:
Micro servo motors are small-sized servo motors often used in applications with limited space and low power requirements. They are commonly found in hobbyist projects, model airplanes, remote-controlled vehicles, and small robotic systems. Micro servo motors are lightweight, compact, and offer reasonable precision and control for their size.
These are some of the different types of servo motors available, each catering to specific applications and requirements. The choice of servo motor type depends on factors such as the desired performance, accuracy, power requirements, environmental conditions, and cost considerations. Understanding the differences between servo motor types is essential for selecting the most suitable motor for a particular application.
Can servo motors be used in robotics, and if so, how are they implemented?
Yes, servo motors are commonly used in robotics due to their precise control capabilities and suitability for a wide range of robotic applications. When implementing servo motors in robotics, several factors need to be considered. Here’s an overview of how servo motors are used and implemented in robotics:
1. Joint Actuation:
Servo motors are often used to actuate the joints of robotic systems. Each joint in a robot typically requires a motor to control its movement. Servo motors provide the necessary torque and angular control to accurately position the joint. They can rotate between specific angles, allowing the robot to achieve the desired configuration and perform precise movements.
2. Position Control:
Servo motors excel at position control, which is essential for robotics applications. They can accurately maintain a specific position and respond quickly to control signals. By incorporating servo motors in robotic joints, precise positioning control can be achieved, enabling the robot to perform tasks with accuracy and repeatability.
3. Closed-Loop Control:
Implementing servo motors in robotics involves utilizing closed-loop control systems. Feedback sensors, such as encoders or resolvers, are attached to the servo motors to provide real-time feedback on the motor’s position. This feedback is used to continuously adjust the motor’s behavior and ensure accurate positioning. Closed-loop control allows the robot to compensate for any errors or disturbances and maintain precise control over its movements.
4. Control Architecture:
In robotics, servo motors are typically controlled using a combination of hardware and software. The control architecture encompasses the control algorithms, microcontrollers or embedded systems, and communication interfaces. The control system receives input signals, such as desired joint positions or trajectories, and generates control signals to drive the servo motors. The control algorithms, such as PID control, are used to calculate the appropriate adjustments based on the feedback information from the sensors.
5. Kinematics and Dynamics:
When implementing servo motors in robotics, the kinematics and dynamics of the robot must be considered. The kinematics deals with the study of the robot’s motion and position, while the dynamics focuses on the forces and torques involved in the robot’s movement. Servo motors need to be properly sized and selected based on the robot’s kinematic and dynamic requirements to ensure optimal performance and stability.
6. Integration and Programming:
Servo motors in robotics need to be integrated into the overall robot system. This involves mechanical mounting and coupling the motors to the robot’s joints, connecting the feedback sensors, and integrating the control system. Additionally, programming or configuring the control software is necessary to define the desired movements and control parameters for the servo motors. This programming can be done using robot-specific programming languages or software frameworks.
By utilizing servo motors in robotics and implementing them effectively, robots can achieve precise and controlled movements. Servo motors enable accurate positioning, fast response times, and closed-loop control, resulting in robots that can perform tasks with high accuracy, repeatability, and versatility. Whether it’s a humanoid robot, industrial manipulator, or collaborative robot (cobot), servo motors play a vital role in their actuation and control.
editor by CX 2024-03-10
China manufacturer St Series 380V Permanent-Magnet AC Synchronous Servo Motor vacuum pump diy
Product Description
product/zwuaLhprXkWO/China-Yvf-Series-Frequency-Control-Three-Phase-Asynchronous-Motors-H80-355mm-.html
Xihu (West Lake) Dis. Xihu (West Lake) Dis.i Motor Co.,Ltd which was founded in 1969, is national appointed as chief factory for small and medium-size motor by machinery ministry. It has 50 years history of producing electric Motor.In November 2 square meter’s workshop,8200 square meter’s technology Research building, 23 assembly lines and 2300 sets of producing Machines, and motor testing center (10000KW).The main electric motors for technical research are high-efficiency motor with energy saving, VFD motor, large-size motor and special motor. The company has 1200 staff and workers in total, there are 130 engineers who work on scientific, technical research and test development, Which build “ZheJiang technical center”, “ZheJiang Electrical Engineering Center “. The company passes ISO9001:2008, ISO14001:2004, GB/T28001.
Main products: high-efficiency motor (YE3 80-355, YE2 56-355), High-efficiency high voltage motor (YX/YXKK/YXKS series H355-800),compact high voltage motor (YX2 H355-560), VFD motor (YVF2 series H80-450),high voltage VFD motor, low voltage rotor motor (YR series H315-355),YR/YRKK high voltage rotor motor, high-efficiency explosion-proof motor (YB3 series H80-355),TDMK series large-size synchronous motor (specified for mine mill), high voltage explosion-proof motor (YB2 H355-560), Y2 series low voltage big power motor, permanent magnet synchronous motor, YE4 series super premium efficiency motor, special motor for car and other special motors for customers. YE3,JHM,YVF2, YE2 series motors pass “CCC” certificates; YE2, YE3 series high-efficiency motors get “CE” certificates; YE3 premium efficiency motor, CXYT permanent magnet synchronous motor, S18/25 get National energy-saving certificates.
In year 2016, the company achieved sales revenue RMB 1.52 billion Yuan, incoming tax RMB 60 million yuan, net profit RMB 10.171 million yuan, and top 3 comprehensive strength in field of small-medium electric motors in China.
Rated voltage | 220v.380v |
Rated power | 5.5~110kW |
Rated torque | 35~480Nm |
Rated speed | 1000~3000rpm |
The above is The Default Parameters, If you have any other special requirements, you can contact us for Customization.
Q: Are you a factory or trading company?
A: HangZhou XIHU (WEST LAKE) DIS.I is a factory that has been focusing on motors and accessories for more than 50 years.
Q: What about the warranty?
A: We offer 12 month warranty period as the quality guarantee.
Q: Can you do OEM?
A: Yes , we offer OEM.
Q: How about your service?
A: We have pre-sale service, in-sale service and after-sale service.What we pursue is long-term cooperation,
so our principle is customer first.
Q: What are your terms of delivery?
A: Generally we ship in FOB term, but we couldoffer the solution for CNF, CIF and DDP, which all based on your
requirement.
Q: What’s the delivery time?
A: 10 to 30 days after receiving your payment in advance. /* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | Industrial |
---|---|
Speed: | Constant Speed |
Number of Stator: | Three-Phase |
Function: | Driving, Control |
Casing Protection: | Open Type |
Number of Poles: | 4 |
Customization: |
Available
|
|
---|
How does the cost of servo motors vary based on their specifications and features?
The cost of servo motors can vary significantly based on their specifications and features. Several factors influence the price of servo motors, and understanding these factors can help in selecting the most cost-effective option for a specific application. Let’s explore in detail how the cost of servo motors can vary:
1. Power Rating:
One of the primary factors affecting the cost of a servo motor is its power rating, which is typically measured in watts or kilowatts. Higher power-rated servo motors generally cost more than lower-rated ones due to the increased materials and manufacturing required to handle higher power levels. The power rating of a servo motor is determined by the torque and speed requirements of the application. Higher torque and speed capabilities often correspond to higher costs.
2. Torque and Speed:
The torque and speed capabilities of a servo motor directly impact its cost. Servo motors designed for high torque and high-speed applications tend to be more expensive due to the need for robust construction, specialized materials, and advanced control electronics. Motors with higher torque and speed ratings often require more powerful magnets, larger windings, and higher precision components, contributing to the increase in cost.
3. Frame Size:
The physical size or frame size of a servo motor also plays a role in determining its cost. Servo motors come in various frame sizes, such as NEMA (National Electrical Manufacturers Association) standard sizes in North America. Larger frame sizes generally command higher prices due to the increased materials and manufacturing complexity required to build larger motors. Smaller frame sizes, on the other hand, may be more cost-effective but may have limitations in terms of torque and speed capabilities.
4. Feedback Mechanism:
The feedback mechanism used in a servo motor affects its cost. Servo motors typically employ encoders or resolvers to provide feedback on the rotor position. Higher-resolution encoders or more advanced feedback technologies can increase the cost of the motor. For example, servo motors with absolute encoders, which provide position information even after power loss, tend to be more expensive than those with incremental encoders.
5. Control Features and Technology:
The control features and technology incorporated into a servo motor can influence its cost. Advanced servo motors may offer features such as built-in controllers, fieldbus communication interfaces, advanced motion control algorithms, or integrated safety functions. These additional features contribute to the cost of the motor but can provide added value and convenience in certain applications. Standard servo motors with basic control functionality may be more cost-effective for simpler applications.
6. Brand and Reputation:
The brand and reputation of the servo motor manufacturer can impact its cost. Established and reputable brands often command higher prices due to factors such as quality assurance, reliability, technical support, and extensive product warranties. While motors from less-known or generic brands may be more affordable, they may not offer the same level of performance, reliability, or long-term support.
7. Customization and Application-Specific Requirements:
If a servo motor needs to meet specific customization or application-specific requirements, such as specialized mounting options, environmental sealing, or compliance with industry standards, the cost may increase. Customization often involves additional engineering, design, and manufacturing efforts, which can lead to higher prices compared to off-the-shelf servo motors.
It’s important to note that the cost of a servo motor is not the sole indicator of its quality or suitability for a particular application. It is essential to carefully evaluate the motor’s specifications, features, and performance characteristics in relation to the application requirements to make an informed decision.
In summary, the cost of servo motors varies based on factors such as power rating, torque and speed capabilities, frame size, feedback mechanism, control features and technology, brand reputation, and customization requirements. By considering these factors and comparing different options, it is possible to select a servo motor that strikes the right balance between performance and cost-effectiveness for a specific application.
Can you explain the concept of torque and speed in relation to servo motors?
Torque and speed are two essential parameters in understanding the performance characteristics of servo motors. Let’s explore these concepts in relation to servo motors:
Torque:
Torque refers to the rotational force produced by a servo motor. It determines the motor’s ability to generate rotational motion and overcome resistance or load. Torque is typically measured in units of force multiplied by distance, such as Nm (Newton-meter) or oz-in (ounce-inch).
The torque output of a servo motor is crucial in applications where the motor needs to move or control a load. The motor must provide enough torque to overcome the resistance or friction in the system and maintain the desired position or motion. Higher torque allows the motor to handle heavier loads or more challenging operating conditions.
It is important to note that the torque characteristics of a servo motor may vary depending on the speed or position of the motor. Manufacturers often provide torque-speed curves or torque-position curves, which illustrate the motor’s torque capabilities at different operating points. Understanding these curves helps in selecting a servo motor that can deliver the required torque for a specific application.
Speed:
Speed refers to the rotational velocity at which a servo motor operates. It indicates how fast the motor can rotate and how quickly it can achieve the desired position or motion. Speed is typically measured in units of revolutions per minute (RPM) or radians per second (rad/s).
The speed of a servo motor is crucial in applications that require rapid movements or high-speed operations. It determines the motor’s responsiveness and the system’s overall performance. Different servo motors have different speed capabilities, and the maximum achievable speed is often specified by the manufacturer.
It is worth noting that the speed of a servo motor may also affect its torque output. Some servo motors exhibit a phenomenon known as “speed-torque curve,” where the motor’s torque decreases as the speed increases. This behavior is influenced by factors such as motor design, winding resistance, and control algorithms. Understanding the speed-torque characteristics of a servo motor is important for selecting a motor that can meet the speed requirements of the application while maintaining sufficient torque.
Overall, torque and speed are interrelated parameters that determine the performance capabilities of a servo motor. The torque capability determines the motor’s ability to handle loads, while the speed capability determines how quickly the motor can achieve the desired motion. When selecting a servo motor, it is essential to consider both the torque and speed requirements of the application to ensure that the motor can deliver the desired performance.
What are the key advantages of using servo motors in industrial applications?
Servo motors offer several key advantages that make them highly beneficial for a wide range of industrial applications. Here are some of the main advantages of using servo motors:
1. Precise Positioning:
Servo motors excel at precise positioning control. They can accurately move to specific angles or positions with high repeatability. This level of precision is crucial in applications where accurate and consistent positioning is required, such as robotics, CNC machining, and assembly lines.
2. High Torque at Various Speeds:
Servo motors are designed to deliver high torque output across a range of speeds. They can generate significant torque even at low speeds, enabling efficient operation in applications that require both high torque and precise control, such as lifting heavy loads or performing intricate movements.
3. Fast Response Times:
Servo motors have fast response times, meaning they can quickly accelerate, decelerate, and change direction in response to control signals. This responsiveness is essential in applications where rapid and dynamic motion control is needed, such as industrial automation, robotics, and production line equipment.
4. Closed-Loop Control:
Servo motors operate in a closed-loop control system, where feedback from position sensors is continuously used to adjust the motor’s behavior. This feedback control mechanism enables accurate tracking of the desired position and compensates for any disturbances or variations that may occur during operation. It enhances the motor’s accuracy, stability, and performance.
5. Wide Range of Sizes and Power Ratings:
Servo motors are available in a wide range of sizes and power ratings, making them suitable for diverse industrial applications. Whether it’s a small motor for precision tasks or a large motor for heavy-duty operations, there are servo motor options to meet various requirements.
6. Energy Efficiency:
Servo motors are designed to be energy-efficient. They typically have high power density, which means they can deliver a significant amount of torque per unit of size and weight. This efficiency helps reduce power consumption, lowers operating costs, and contributes to a greener and more sustainable industrial environment.
7. Flexibility and Adaptability:
Due to their versatility, servo motors can be easily integrated into different systems and applications. They can be combined with various control systems, sensors, and communication protocols to provide seamless integration and compatibility with existing industrial setups. This flexibility allows for customized and scalable solutions tailored to specific industrial requirements.
8. Durability and Reliability:
Servo motors are known for their durability and reliability, even in demanding industrial environments. They are built to withstand harsh conditions such as high temperatures, vibrations, and dust. This robust construction ensures long-term operation and minimizes downtime, contributing to increased productivity and reduced maintenance costs.
In summary, the key advantages of using servo motors in industrial applications include precise positioning, high torque at various speeds, fast response times, closed-loop control for accuracy and stability, a wide range of sizes and power ratings, energy efficiency, flexibility, and durability. These advantages make servo motors highly valuable for industries that require precise motion control, such as robotics, manufacturing, automation, CNC machining, and many others.
editor by CX 2024-03-09
China Best Sales High Performance 100kw 5000rpm AC Servo Motor vacuum pump design
Product Description
Product Description
AC Motor is a device that transforms the electrical energy of alternating current into mechanical energy. The AC Motor is mainly composed of an electromagnet winding or stator winding for generating magnetic field and a rotating armature or rotor. The motor is made by the phenomenon that the electric coil is forced to rotate in the magnetic field. AC motors are divided into 2 types: synchronous alternating current motor and induction motor.
The stator windings of three-phase AC motors are basically 3 coils separated by 120 degrees, which are connected by triangle or star. When three-phase current is applied, a magnetic field is generated in each coil, and the 3 magnetic fields are combined to form a rotating magnetic field.
High voltage ac motors are designed with the application of modern technology resulting in compact machines featuring excellent dynamic properties, meeting the most severe application in areas that include automation and process control.
Besides offering reliability and high performance, which will guarantee long operating periods without requiring any maintenance, the New high voltage ac motors present outstanding operating features, which include:
•Wide speed variation range
•Dimensions as per GB and IEC Standards
•High efficiency
•Low noise level
•High moment of inertia
•High capacity to dynamic loads
•Rugged construction
•High vibration resistance
•Excellent commutation quality
Product Parameters
Product Name | High Performance 100kW 5000rpm AC Servo Motor |
Motor Type | DC Motor,AC Motor,Stepper Motor,Asynchronous Motor ,Synchronous Motor (Electric machinery) |
Rotational Speed |
Low Speed/Constant Speed/High Speed/Variable Speed |
Stator Phase Number |
Three-Phase/Single-Phase |
Standard Features | •NEMA Premium Efficiency Level according to NEMA Y •Three-phase, 50, 60 Hz •Voltage: 3000 to 11000 V •Rated output: up to 12500 kw •Number of poles: 2 ,4,6,8,10 or 12poles •Frame sizes: 450 mm to 630mm •Cast aluminium squirrel cage for rotor •Degree of protection: IP23 to IP54(Totally enclosed) •Class insulation F with class (120ºC) temperature rise •Grease nipples for frame 450 to 630MM •Continuous Duty (S1) •With thermal protection PTC140 ºC or PT100 •Larger diameter shafts for the highest overhung load ratings in the industry •Oversized roller bearings for maximum load capacity •Other optional features under request |
AC Motor | AC Motors can operate in high temperature, flammable and other environments, and do not need to clean the dirt of carbon brushes regularly, but it is difficult to control the speed, because it is necessary to control the frequency of AC motors (or use induction motors, increase internal resistance, reduce the motor speed at the same AC frequency. Speed, control the voltage will only affect the torque of the motor. The voltage of the general civil motor has 2 kinds, such as 110V and 220V, and there are 380V or 440V in industrial application. |
Application | AC Motors have higher working efficiency, no smoke, odor, no pollution to the environment, and less noise. Because of its series of advantages, it is widely used in industrial and agricultural production, transportation, national defense, commercial and household appliances, medical appliances and other fields. For Example: •Compressor •Rubber mixer •Fans and Pumps •Air brower •Coal mill and rolling mill •Crushers •Conveyor belts •Centrifugal machines •Lathe •Hoist |
/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | Industrial |
---|---|
Operating Speed: | High Speed |
Number of Stator: | Three-Phase |
Species: | Yjs Series |
Rotor Structure: | Winding Type |
Casing Protection: | Explosion-Proof Type |
Customization: |
Available
|
|
---|
What role does the controller play in the overall performance of a servo motor?
The controller plays a crucial role in the overall performance of a servo motor system. It is responsible for monitoring and regulating the motor’s operation to achieve the desired motion and maintain system stability. Let’s explore in detail the role of the controller in the performance of a servo motor:
1. Motion Control:
The controller is responsible for generating precise control signals that dictate the motor’s speed, torque, and position. It receives input commands from the user or higher-level control system and translates them into appropriate control signals for the servo motor. By accurately controlling the motor’s motion, the controller enables precise positioning, smooth acceleration and deceleration, and the ability to follow complex trajectories. The controller’s effectiveness in generating accurate and responsive control signals directly impacts the motor’s motion control capabilities.
2. Feedback Control:
The controller utilizes feedback from position sensors, such as encoders, to monitor the motor’s actual position, speed, and other parameters. It compares the desired motion profile with the actual motor behavior and continuously adjusts the control signals to minimize any deviations or errors. This closed-loop feedback control mechanism allows the controller to compensate for disturbances, variations in load conditions, and other factors that may affect the motor’s performance. By continuously monitoring and adjusting the control signals based on feedback, the controller helps maintain accurate and stable motor operation.
3. PID Control:
Many servo motor controllers employ Proportional-Integral-Derivative (PID) control algorithms to regulate the motor’s behavior. PID control calculates control signals based on the error between the desired setpoint and the actual motor response. The proportional term responds to the present error, the integral term accounts for accumulated past errors, and the derivative term considers the rate of change of the error. By tuning the PID parameters, the controller can achieve optimal performance in terms of response time, stability, and steady-state accuracy. Properly configured and tuned PID control greatly influences the servo motor’s ability to follow commands accurately and efficiently.
4. Trajectory Planning:
In applications requiring complex motion profiles or trajectories, the controller plays a vital role in trajectory planning. It determines the optimal path and speed profile for the motor to follow, taking into account constraints such as acceleration limits, jerk limits, and mechanical limitations. The controller generates the required control signals to achieve the desired trajectory, ensuring smooth and precise motion. Effective trajectory planning by the controller enhances the motor’s performance in applications that involve intricate or high-speed movements.
5. System Monitoring and Protection:
The controller monitors various parameters of the servo motor system, including temperature, current, voltage, and other diagnostic information. It incorporates protective measures to prevent damage or excessive stress on the motor. The controller can implement safety features such as overcurrent protection, over-temperature protection, and fault detection mechanisms. By actively monitoring and safeguarding the motor and the system, the controller helps prevent failures, prolongs the motor’s lifespan, and ensures safe and reliable operation.
6. Communication and Integration:
The controller facilitates communication and integration with other components or systems within the overall automation setup. It may support various communication protocols, such as Ethernet, CAN bus, or fieldbus protocols, enabling seamless integration with higher-level control systems, human-machine interfaces (HMIs), or other peripheral devices. The controller’s ability to efficiently exchange data and commands with other system components allows for coordinated and synchronized operation, enhancing the overall performance and functionality of the servo motor system.
In summary, the controller plays a vital role in the overall performance of a servo motor system. It enables precise motion control, utilizes feedback for closed-loop control, implements PID control algorithms, plans complex trajectories, monitors system parameters, and facilitates communication and integration. The controller’s capabilities and effectiveness directly impact the motor’s performance in terms of accuracy, responsiveness, stability, and overall system efficiency.
Can you explain the concept of torque and speed in relation to servo motors?
Torque and speed are two essential parameters in understanding the performance characteristics of servo motors. Let’s explore these concepts in relation to servo motors:
Torque:
Torque refers to the rotational force produced by a servo motor. It determines the motor’s ability to generate rotational motion and overcome resistance or load. Torque is typically measured in units of force multiplied by distance, such as Nm (Newton-meter) or oz-in (ounce-inch).
The torque output of a servo motor is crucial in applications where the motor needs to move or control a load. The motor must provide enough torque to overcome the resistance or friction in the system and maintain the desired position or motion. Higher torque allows the motor to handle heavier loads or more challenging operating conditions.
It is important to note that the torque characteristics of a servo motor may vary depending on the speed or position of the motor. Manufacturers often provide torque-speed curves or torque-position curves, which illustrate the motor’s torque capabilities at different operating points. Understanding these curves helps in selecting a servo motor that can deliver the required torque for a specific application.
Speed:
Speed refers to the rotational velocity at which a servo motor operates. It indicates how fast the motor can rotate and how quickly it can achieve the desired position or motion. Speed is typically measured in units of revolutions per minute (RPM) or radians per second (rad/s).
The speed of a servo motor is crucial in applications that require rapid movements or high-speed operations. It determines the motor’s responsiveness and the system’s overall performance. Different servo motors have different speed capabilities, and the maximum achievable speed is often specified by the manufacturer.
It is worth noting that the speed of a servo motor may also affect its torque output. Some servo motors exhibit a phenomenon known as “speed-torque curve,” where the motor’s torque decreases as the speed increases. This behavior is influenced by factors such as motor design, winding resistance, and control algorithms. Understanding the speed-torque characteristics of a servo motor is important for selecting a motor that can meet the speed requirements of the application while maintaining sufficient torque.
Overall, torque and speed are interrelated parameters that determine the performance capabilities of a servo motor. The torque capability determines the motor’s ability to handle loads, while the speed capability determines how quickly the motor can achieve the desired motion. When selecting a servo motor, it is essential to consider both the torque and speed requirements of the application to ensure that the motor can deliver the desired performance.
What is a servo motor, and how does it function in automation systems?
A servo motor is a type of motor specifically designed for precise control of angular or linear position, velocity, and acceleration. It is widely used in various automation systems where accurate motion control is required. Let’s explore the concept of servo motors and how they function in automation systems:
A servo motor consists of a motor, a position feedback device (such as an encoder or resolver), and a control system. The control system receives input signals, typically in the form of electrical pulses or analog signals, indicating the desired position or speed. Based on these signals and the feedback from the position sensor, the control system adjusts the motor’s operation to achieve the desired motion.
The functioning of a servo motor in an automation system involves the following steps:
- Signal Input: The automation system provides a control signal to the servo motor, indicating the desired position, speed, or other motion parameters. This signal can be generated by a human operator, a computer, a programmable logic controller (PLC), or other control devices.
- Feedback System: The servo motor incorporates a position feedback device, such as an encoder or resolver, which continuously monitors the motor’s actual position. This feedback information is sent back to the control system, allowing it to compare the actual position with the desired position specified by the input signal.
- Control System: The control system, typically housed within the servo motor or an external servo drive, receives the input signal and the feedback from the position sensor. It processes this information and generates the appropriate control signals to the motor.
- Motor Operation: Based on the control signals received from the control system, the servo motor adjusts its operation to achieve the desired motion. The control system varies the motor’s voltage, current, or frequency to control the motor’s speed, torque, or position accurately.
- Closed-Loop Control: Servo motors operate in a closed-loop control system. The feedback information from the position sensor allows the control system to continuously monitor and adjust the motor’s operation to minimize any deviation between the desired position and the actual position. This closed-loop control mechanism provides high accuracy, repeatability, and responsiveness in motion control applications.
One of the key advantages of servo motors in automation systems is their ability to provide precise and dynamic motion control. They can rapidly accelerate, decelerate, and change direction with high accuracy, allowing for intricate and complex movements. Servo motors are widely used in applications such as robotics, CNC machines, printing presses, packaging equipment, and automated manufacturing systems.
In summary, a servo motor is a specialized motor that enables accurate control of position, velocity, and acceleration in automation systems. Through the combination of a control system and a position feedback device, servo motors can precisely adjust their operation to achieve the desired motion. Their closed-loop control mechanism and high responsiveness make them an essential component in various applications requiring precise and dynamic motion control.
editor by CX 2024-03-07
China Custom High Torque 1500rpm AC 7.5kw 380V Servo Motor for 180mm Flange wholesaler
Product Description
Product Description:
H series permanent magnet synchronous motor is a high efficiency and energy saving motor independently developed and produced by Hui Xunjun. It uses permanent magnet material to generate magnetic field, which has high efficiency, reliable operation, small size, light weight, energy saving and environmental protection, and low noise. It can be matched with servo drive, and realize precise walking and reversing through cooperative motion between servo drive and servo drive, realizing fast response, high stability and high precision control in the whole motion control process. According to the customer’s own characteristics can quickly provide professional customized services. Widely used in machine tools, textile, rewinding, air compressor, fan pump and other industries.
Name plate:
180 series specifications:
Product Feature:
Technical Specification:
Scope of application:
DIMENSION:(UNIT:MM)
Factory outline:
/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | Industrial |
---|---|
Function: | Driving |
Casing Protection: | Protection Type |
Number of Poles: | 4 |
Starting Mode: | Direct on-line Starting |
Certification: | ISO9001 |
Customization: |
Available
|
|
---|
How are servo motors used in CNC machines and other precision machining equipment?
Servo motors play a crucial role in CNC (Computer Numerical Control) machines and other precision machining equipment. They provide precise and dynamic control over the movement of various axes, enabling high-accuracy positioning, rapid speed changes, and smooth motion profiles. Here’s a detailed explanation of how servo motors are used in CNC machines and precision machining equipment:
1. Axis Control:
CNC machines typically have multiple axes, such as X, Y, and Z for linear movements, as well as rotary axes for rotational movements. Servo motors are employed to drive each axis, converting electrical signals from the CNC controller into mechanical motion. The position, velocity, and acceleration of the servo motors are precisely controlled to achieve accurate and repeatable positioning of the machine’s tool or workpiece.
2. Feedback and Closed-Loop Control:
Servo motors in CNC machines are equipped with feedback devices, such as encoders or resolvers, to provide real-time information about the motor’s actual position. This feedback is used in a closed-loop control system, where the CNC controller continuously compares the desired position with the actual position and adjusts the motor’s control signals accordingly. This closed-loop control ensures accurate positioning and compensates for any errors, such as mechanical backlash or load variations.
3. Rapid and Precise Speed Changes:
Servo motors offer excellent dynamic response, allowing CNC machines to achieve rapid and precise speed changes during machining operations. By adjusting the control signals to the servo motors, the CNC controller can smoothly accelerate or decelerate the machine’s axes, resulting in efficient machining processes and reduced cycle times.
4. Contouring and Path Tracing:
CNC machines often perform complex machining tasks, such as contouring or following intricate paths. Servo motors enable precise path tracing by accurately controlling the position and velocity of the machine’s tool along the programmed path. This capability is crucial for producing intricate shapes, smooth curves, and intricate details with high precision.
5. Spindle Control:
In addition to axis control, servo motors are also used to control the spindle in CNC machines. The spindle motor, typically a servo motor, rotates the cutting tool or workpiece at the desired speed. Servo control ensures precise speed and torque control, allowing for optimal cutting conditions and surface finish quality.
6. Tool Changers and Automatic Tool Compensation:
CNC machines often feature automatic tool changers to switch between different cutting tools during machining operations. Servo motors are utilized to precisely position the tool changer mechanism, enabling quick and accurate tool changes. Additionally, servo motors can be used for automatic tool compensation, adjusting the tool’s position or orientation to compensate for wear, tool length variations, or tool offsets.
7. Synchronized Motion and Multi-Axis Coordination:
Servo motors enable synchronized motion and coordination between multiple axes in CNC machines. By precisely controlling the servo motors on different axes, complex machining operations involving simultaneous movements can be achieved. This capability is vital for tasks such as 3D contouring, thread cutting, and multi-axis machining.
In summary, servo motors are integral components of CNC machines and precision machining equipment. They provide accurate and dynamic control over the machine’s axes, enabling high-precision positioning, rapid speed changes, contouring, spindle control, tool changers, and multi-axis coordination. The combination of servo motor technology and CNC control systems allows for precise, efficient, and versatile machining operations in various industries.
Are there different types of servo motors, and how do they differ?
Yes, there are different types of servo motors available, each with its own characteristics and applications. The variations among servo motors can be attributed to factors such as construction, control mechanisms, power requirements, and performance specifications. Let’s explore some of the common types of servo motors and how they differ:
1. DC Servo Motors:
DC servo motors are widely used in various applications. They consist of a DC motor combined with a feedback control system. The control system typically includes a position or velocity feedback sensor, such as an encoder or a resolver. DC servo motors offer good speed and torque control and are often employed in robotics, automation, and hobbyist projects. They can be operated with a separate motor driver or integrated into servo motor units with built-in control electronics.
2. AC Servo Motors:
AC servo motors are designed for high-performance applications that require precise control and fast response times. They are typically three-phase motors and are driven by sinusoidal AC waveforms. AC servo motors often incorporate advanced control algorithms and feedback systems to achieve accurate position, velocity, and torque control. These motors are commonly used in industrial automation, CNC machines, robotics, and other applications that demand high precision and dynamic performance.
3. Brushed Servo Motors:
Brushed servo motors feature a traditional brushed DC motor design. They consist of a rotor with a commutator and carbon brushes that make physical contact with the commutator. The brushes provide electrical connections, allowing the motor’s magnetic field to interact with the rotor’s windings. Brushed servo motors are known for their simplicity and cost-effectiveness. However, they may require more maintenance due to brush wear, and they generally have lower efficiency and shorter lifespan compared to brushless servo motors.
4. Brushless Servo Motors:
Brushless servo motors, also known as brushless DC (BLDC) motors, offer several advantages over brushed motors. They eliminate the need for brushes and commutators, resulting in improved reliability, higher efficiency, and longer lifespan. Brushless servo motors rely on electronic commutation, typically using Hall effect sensors or encoder feedback for accurate rotor position detection. These motors are widely used in robotics, industrial automation, aerospace, and other applications that require high-performance motion control with minimal maintenance.
5. Linear Servo Motors:
Linear servo motors are designed to provide linear motion instead of rotational motion. They consist of a primary part (stator) and a secondary part (slider or forcer) that interact magnetically to generate linear motion. Linear servo motors offer advantages such as high speed, high acceleration, and precise positioning along a linear axis. They find applications in various industries, including semiconductor manufacturing, packaging, printing, and machine tools.
6. Micro Servo Motors:
Micro servo motors are small-sized servo motors often used in applications with limited space and low power requirements. They are commonly found in hobbyist projects, model airplanes, remote-controlled vehicles, and small robotic systems. Micro servo motors are lightweight, compact, and offer reasonable precision and control for their size.
These are some of the different types of servo motors available, each catering to specific applications and requirements. The choice of servo motor type depends on factors such as the desired performance, accuracy, power requirements, environmental conditions, and cost considerations. Understanding the differences between servo motor types is essential for selecting the most suitable motor for a particular application.
How does feedback control work in a servo motor system?
In a servo motor system, feedback control plays a crucial role in achieving precise control over the motor’s position, speed, and acceleration. The feedback control loop consists of several components that work together to continuously monitor and adjust the motor’s behavior based on the desired and actual position information. Here’s an overview of how feedback control works in a servo motor system:
1. Position Reference:
The servo motor system starts with a position reference or a desired position. This can be specified by a user or a control system, depending on the application requirements. The position reference represents the target position that the servo motor needs to reach and maintain.
2. Feedback Sensor:
A feedback sensor, such as an encoder or resolver, is attached to the servo motor’s shaft. The purpose of the feedback sensor is to continuously measure the motor’s actual position and provide feedback to the control system. The sensor generates signals that indicate the motor’s current position, allowing the control system to compare it with the desired position.
3. Control System:
The control system receives the position reference and the feedback signals from the sensor. It processes this information to determine the motor’s current position error, which is the difference between the desired position and the actual position. The control system calculates the required adjustments to minimize this position error and bring the motor closer to the desired position.
4. Controller:
The controller is a key component of the feedback control loop. It receives the position error from the control system and generates control signals that govern the motor’s behavior. The controller adjusts the motor’s inputs, such as voltage or current, based on the position error and control algorithm. The control algorithm can be implemented using various techniques, such as proportional-integral-derivative (PID) control, which adjusts the motor’s inputs based on the current error, the integral of past errors, and the rate of change of errors.
5. Motor Drive:
The control signals generated by the controller are sent to the motor drive unit, which amplifies and converts these signals into appropriate voltage or current levels. The motor drive unit provides the necessary power and control signals to the servo motor to initiate the desired motion. The drive unit adjusts the motor’s inputs based on the control signals to achieve the desired position, speed, and acceleration specified by the control system.
6. Motor Response:
As the motor receives the adjusted inputs from the motor drive, it starts to rotate and move towards the desired position. The motor’s response is continually monitored by the feedback sensor, which measures the actual position in real-time.
7. Feedback Comparison:
The feedback sensor compares the actual position with the desired position. If there is any deviation, the sensor generates feedback signals reflecting the discrepancy between the desired and actual positions. These signals are fed back to the control system, allowing it to recalculate the position error and generate updated control signals to further adjust the motor’s behavior.
This feedback loop continues to operate in a continuous cycle, with the control system adjusting the motor’s inputs based on the feedback information. As a result, the servo motor can accurately track and maintain the desired position, compensating for any disturbances or variations that may occur during operation.
In summary, feedback control in a servo motor system involves continuously comparing the desired position with the actual position using a feedback sensor. The control system processes this position error and generates control signals, which are converted and amplified by the motor drive unit to drive the motor. The motor’s response is monitored by the feedback sensor, and any discrepancies are fed back to the control system, enabling it to make further adjustments. This closed-loop control mechanism ensures precise positioning and accurate control of the servo motor.
editor by CX 2024-03-07
China supplier Servo Motor Set 400 750 1000W 10n. M 3600rpm AC Servo Motor with Servo Drive vacuum pump belt
Product Description
Product Description
HangZhou K-Easy Automation Co.,Limited is a professional manufacturer, specialize in R&D And production of AC drives. We have built up a comprehensive product family. Frequency inverters’ power covers the range from 0.4 to 630kW, and voltage range is between 220V and 480V. More than inverters are running smoothly 300, 000 units at different industrial sites.
-
The response frequency is up to 1.5KHz, which is especially suitable for applications requiring high-speed response;
-
Driver menu, control interface, parameter modification and writing operation are consistent with CHINAMFG A5 series servo driver;
-
The encoder interface of A-type servo driver is consistent with CHINAMFG A5 series servo driver, and it can directly operate with CHINAMFG A5 and A6 servo motors;
-
The driver can directly drive the direct drive motor, and can support up to 23 bit absolute encoder;
-
It is provided with electronic cam special machine and internal position special machine;
-
The driver is currently used in automation equipment such as manipulator, loading and unloading, winding machine, die-cutting machine, 3C processing, fine carving, textile, SCARA robot, tensile machine, capping machine, labeling machine, etc.
Product Parameters
Performance | K-Drive |
---|---|
Applicable motors | Asynchronous /synchronous motors |
Starting torque | 0.5Hz, 180% (sensor-less vector control) 0Hz, 200% (closed-loop vector control) |
Speed adjustable range | 1:200 (SVC), 1:1000 (VC) |
Ambient temperature (no derating required) | -10-50ºC (for most of the models) |
Rated input voltage | 208VAC-480VAC |
Communication | Modbus RTU//ASCII Profibus-DP, CANopen, etc. |
Position control (fixed length, or angular positioning) | √ |
Field weakening control | √ |
Autotune online | Online & Offline |
Short-time ramp-up | No trip |
Customized features (software and/or hardware) | Procurable with rich experience |
Product Features
Company Profile
/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | High-performance Transducer, Three Phase Transducer, General Transducer, Single-phase Transducer, High Frequency Converter Transducer |
---|---|
Output Type: | Triple |
Principle of Work: | Vector Control Transducer |
Switch Mode: | High Carrier Frequency PWM Control |
Main Circuit Type: | Voltage |
Voltage of Power Supply: | Low Voltage Variable-Frequency Drive |
Samples: |
US$ 78/Piece
1 Piece(Min.Order) | |
---|
Customization: |
Available
|
|
---|
Are there common issues or challenges associated with servo motor systems, and how can they be addressed?
Servo motor systems are widely used in various applications, but they can encounter common issues or challenges that affect their performance and reliability. Let’s explore some of these issues and discuss potential solutions:
1. Positioning and Tracking Errors:
One common challenge in servo motor systems is positioning and tracking errors. These errors can occur due to factors such as mechanical backlash, encoder resolution limitations, or disturbances in the system. To address this issue, careful calibration and tuning of the servo control system are necessary. This includes adjusting feedback gains, implementing feedback filtering techniques, and utilizing advanced control algorithms to improve the system’s accuracy and minimize errors. Additionally, employing high-resolution encoders and backlash compensation mechanisms can help enhance the positioning and tracking performance.
2. Vibration and Resonance:
Vibration and resonance can impact the performance of servo motor systems, leading to reduced accuracy and stability. These issues can arise from mechanical resonances within the system or external disturbances. To mitigate vibration and resonance problems, it is crucial to analyze the system’s dynamics and identify critical resonant frequencies. Implementing vibration dampening techniques such as mechanical isolation, using vibration-absorbing materials, or employing active vibration control methods can help minimize the effect of vibrations and improve the system’s performance.
3. Overheating and Thermal Management:
Servo motors can generate heat during operation, and inadequate thermal management can lead to overheating and potential performance degradation. To address this issue, proper cooling and thermal management techniques should be employed. This may involve using heat sinks, fans, or liquid cooling systems to dissipate heat efficiently. Ensuring adequate ventilation and airflow around the motor and avoiding excessive current or overloading can also help prevent overheating. Monitoring the motor’s temperature and implementing temperature protection mechanisms can further safeguard the motor from thermal damage.
4. Electrical Noise and Interference:
Electrical noise and interference can affect the performance and reliability of servo motor systems. These issues can arise from electromagnetic interference (EMI) or radio frequency interference (RFI) from nearby equipment or electrical sources. To mitigate electrical noise, proper shielding and grounding techniques should be employed. Using shielded cables, ferrite cores, and grounding the motor and control system can help minimize the impact of noise and interference. Additionally, employing filtering techniques and surge protection devices can further improve system robustness against electrical disturbances.
5. System Integration and Compatibility:
Integrating a servo motor system into a larger control system or automation setup can present challenges in terms of compatibility and communication. Ensuring proper compatibility between the servo motor and the control system is crucial. This involves selecting appropriate communication protocols, such as EtherCAT or Modbus, and ensuring compatibility with the control signals and interfaces. Employing standardized communication interfaces and protocols can facilitate seamless integration and interoperability. Additionally, thorough testing and verification of the system’s compatibility before deployment can help identify and address any integration issues.
6. Maintenance and Service:
Maintenance and service requirements are important considerations for servo motor systems. Regular maintenance, including lubrication, inspection, and cleaning, can help prevent issues related to wear and tear. Following manufacturer-recommended maintenance schedules and procedures is essential to ensure the longevity and optimal performance of the motor. In case of any malfunctions or failures, having access to technical support from the manufacturer or trained service personnel can help diagnose and address problems effectively.
By being aware of these common issues and challenges associated with servo motor systems and implementing appropriate solutions, it is possible to enhance the performance, reliability, and lifespan of the servo motor system. Regular monitoring, proactive maintenance, and continuous improvement can contribute to optimizing the overall operation and efficiency of the system.
What factors should be considered when selecting a servo motor for a specific application?
When selecting a servo motor for a specific application, several factors need to be considered. These factors help ensure that the chosen servo motor meets the requirements and performs optimally in the intended application. Here are some key factors to consider:
1. Torque and Power Requirements:
One of the primary considerations is the torque and power requirements of the application. The servo motor should be able to generate sufficient torque to handle the load and overcome any resistance or friction in the system. Additionally, the power rating of the motor should match the power supply available in the application. It is essential to evaluate the torque-speed characteristics of the servo motor to ensure it can deliver the required performance.
2. Speed and Acceleration:
The required speed and acceleration capabilities of the servo motor should align with the application’s needs. Different applications have varying speed and acceleration requirements, and the servo motor should be able to meet these demands. It is crucial to consider both the maximum speed that the motor can achieve and the time it takes to accelerate or decelerate to specific speeds. Evaluating the servo motor’s speed-torque characteristics and acceleration capabilities is necessary for selecting the right motor.
3. Positioning Accuracy and Repeatability:
The desired positioning accuracy and repeatability of the application play a significant role in servo motor selection. If precise positioning is crucial, a servo motor with high accuracy and low positioning errors should be chosen. The feedback mechanism, such as encoders or resolvers, should provide the required resolution to achieve the desired accuracy. Repeatability, the ability to consistently reach the same position, should also be considered, especially in applications where repetitive movements are necessary.
4. Environmental Conditions:
The environmental conditions in which the servo motor will operate should be taken into account. Factors such as temperature extremes, humidity, dust, and vibration can affect the motor’s performance and lifespan. In harsh environments, it may be necessary to choose a servo motor with appropriate protection ratings, such as IP (Ingress Protection) ratings, to ensure reliable operation and longevity.
5. Control System Compatibility:
The compatibility of the servo motor with the control system used in the application is crucial. The motor should be compatible with the control signals and communication protocols employed in the system. This includes considerations such as voltage compatibility, control signal types (analog, digital, pulse), and communication interfaces (such as Ethernet, CAN, or Modbus). Ensuring compatibility will facilitate seamless integration and efficient control of the servo motor within the application.
6. Size and Weight Constraints:
The physical size and weight limitations of the application should be considered when selecting a servo motor. The motor’s dimensions should fit within the available space, and its weight should not exceed the application’s weight capacity. Compact and lightweight servo motors may be preferred in applications where space is limited or weight is a critical factor.
7. Cost Considerations:
The cost of the servo motor and its overall value for the application should be evaluated. It is essential to consider the initial purchase cost as well as the long-term maintenance and operational costs. While cost is a factor, it should not be the sole determining factor, as compromising on quality or performance may lead to suboptimal results.
By considering these factors, one can make an informed decision when selecting a servo motor for a specific application. It is recommended to consult with manufacturers or experts in the field to ensure the chosen servo motor meets the application’s requirements and provides reliable and efficient performance.
Can you explain the difference between a servo motor and a regular electric motor?
A servo motor and a regular electric motor are both types of electric motors, but they have distinct differences in terms of design, control, and functionality.
A regular electric motor, also known as an induction motor or a DC motor, is designed to convert electrical energy into mechanical energy. It consists of a rotor, which rotates, and a stator, which surrounds the rotor and generates a rotating magnetic field. The rotor is connected to an output shaft, and when current flows through the motor’s windings, it creates a magnetic field that interacts with the stator’s magnetic field, resulting in rotational motion.
On the other hand, a servo motor is a more specialized type of electric motor that incorporates additional components for precise control of position, speed, and acceleration. It consists of a regular electric motor, a sensor or encoder, and a feedback control system. The sensor or encoder provides feedback on the motor’s current position, and this information is used by the control system to adjust the motor’s behavior.
The key difference between a servo motor and a regular electric motor lies in their control mechanisms. A regular electric motor typically operates at a fixed speed based on the voltage and frequency of the power supply. In contrast, a servo motor can be controlled to rotate to a specific angle or position and maintain that position accurately. The control system continuously monitors the motor’s actual position through the feedback sensor and adjusts the motor’s operation to achieve the desired position or follow a specific trajectory.
Another distinction is the torque output of the motors. Regular electric motors generally provide high torque at low speeds and lower torque at higher speeds. In contrast, servo motors are designed to deliver high torque at both low and high speeds, which makes them suitable for applications that require precise and dynamic motion control.
Furthermore, servo motors often have a more compact and lightweight design compared to regular electric motors. They are commonly used in applications where precise positioning, speed control, and responsiveness are critical, such as robotics, CNC machines, automation systems, and remote-controlled vehicles.
In summary, while both servo motors and regular electric motors are used to convert electrical energy into mechanical energy, servo motors offer enhanced control capabilities, precise positioning, and high torque at various speeds, making them well-suited for applications that require accurate and dynamic motion control.
editor by CX 2024-03-06
China Good quality 0.1kw CHINAMFG Msmd Series AC Servo Motor Minas A5 Msmd012g1V a/c vacuum pump
Product Description
0.1KW CHINAMFG MSMD series AC Servo Motor MINAS A5 MSMD012G1V
We can supply Inverter ,Servo Motor,PLC and HMI at good price, please feel free to contact us!
Product Parameters
Product Name | Servo Motor |
Brand | Panasonic |
Model | M MSMD012G1V |
Series | MINAS A5 |
Warranty | 1 Year |
Application | Industrial Ect |
Technical consulting support | Yes |
Real Picture
Company Profile
ZheJiang CHINAMFG Xing Trading Co.,Ltd is a professional supplier of Inverter,Servo Motor,PLC And HMI with 20 years production experience.
Our main products Inverter,Servo Motor,PLC And HMI are widely applied to the field of industrial automation control.
We guaranteed 100% new brand original, and we have a lot of stock with fast delivery. The technical support and after sale service
is provided and customer’s questions will be responded in the first time.
Main Products:
1. Servo system products
2. Linear motion products
3. Sensor products
4. Frequency converter, PLC,
FAQ
1.Q: How about the warranty ?
A: Aiwell provide 12 months warranty for all the goods from us , and you can refund the goods with any quality problem in 15 days.
2.Q: Other supplier have a better pice than yours.
A: “To create more benefit fir clients”is our belief, if you have a better price , please let Aiwell know , we will try best to meet your price and support you.
3.Q: We have not cooperated before , how can we believe you ?
A: For our first order , you can pay after we prepare the goods.
4.Q: What about shipment ?
A: We have DHL forwarder with competitive price , of course , cutsomers can also use their own freight forwarders.
/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | Industrial |
---|---|
Speed: | Variable Speed |
Number of Stator: | Three-Phase |
Function: | Driving, Control |
Casing Protection: | Closed Type |
Number of Poles: | 4 |
Customization: |
Available
|
|
---|
Are there common issues or challenges associated with servo motor systems, and how can they be addressed?
Servo motor systems are widely used in various applications, but they can encounter common issues or challenges that affect their performance and reliability. Let’s explore some of these issues and discuss potential solutions:
1. Positioning and Tracking Errors:
One common challenge in servo motor systems is positioning and tracking errors. These errors can occur due to factors such as mechanical backlash, encoder resolution limitations, or disturbances in the system. To address this issue, careful calibration and tuning of the servo control system are necessary. This includes adjusting feedback gains, implementing feedback filtering techniques, and utilizing advanced control algorithms to improve the system’s accuracy and minimize errors. Additionally, employing high-resolution encoders and backlash compensation mechanisms can help enhance the positioning and tracking performance.
2. Vibration and Resonance:
Vibration and resonance can impact the performance of servo motor systems, leading to reduced accuracy and stability. These issues can arise from mechanical resonances within the system or external disturbances. To mitigate vibration and resonance problems, it is crucial to analyze the system’s dynamics and identify critical resonant frequencies. Implementing vibration dampening techniques such as mechanical isolation, using vibration-absorbing materials, or employing active vibration control methods can help minimize the effect of vibrations and improve the system’s performance.
3. Overheating and Thermal Management:
Servo motors can generate heat during operation, and inadequate thermal management can lead to overheating and potential performance degradation. To address this issue, proper cooling and thermal management techniques should be employed. This may involve using heat sinks, fans, or liquid cooling systems to dissipate heat efficiently. Ensuring adequate ventilation and airflow around the motor and avoiding excessive current or overloading can also help prevent overheating. Monitoring the motor’s temperature and implementing temperature protection mechanisms can further safeguard the motor from thermal damage.
4. Electrical Noise and Interference:
Electrical noise and interference can affect the performance and reliability of servo motor systems. These issues can arise from electromagnetic interference (EMI) or radio frequency interference (RFI) from nearby equipment or electrical sources. To mitigate electrical noise, proper shielding and grounding techniques should be employed. Using shielded cables, ferrite cores, and grounding the motor and control system can help minimize the impact of noise and interference. Additionally, employing filtering techniques and surge protection devices can further improve system robustness against electrical disturbances.
5. System Integration and Compatibility:
Integrating a servo motor system into a larger control system or automation setup can present challenges in terms of compatibility and communication. Ensuring proper compatibility between the servo motor and the control system is crucial. This involves selecting appropriate communication protocols, such as EtherCAT or Modbus, and ensuring compatibility with the control signals and interfaces. Employing standardized communication interfaces and protocols can facilitate seamless integration and interoperability. Additionally, thorough testing and verification of the system’s compatibility before deployment can help identify and address any integration issues.
6. Maintenance and Service:
Maintenance and service requirements are important considerations for servo motor systems. Regular maintenance, including lubrication, inspection, and cleaning, can help prevent issues related to wear and tear. Following manufacturer-recommended maintenance schedules and procedures is essential to ensure the longevity and optimal performance of the motor. In case of any malfunctions or failures, having access to technical support from the manufacturer or trained service personnel can help diagnose and address problems effectively.
By being aware of these common issues and challenges associated with servo motor systems and implementing appropriate solutions, it is possible to enhance the performance, reliability, and lifespan of the servo motor system. Regular monitoring, proactive maintenance, and continuous improvement can contribute to optimizing the overall operation and efficiency of the system.
What is the significance of closed-loop control in servo motor operation?
Closed-loop control plays a significant role in the operation of servo motors. It involves continuously monitoring and adjusting the motor’s behavior based on feedback from sensors. The significance of closed-loop control in servo motor operation can be understood through the following points:
1. Accuracy and Precision:
Closed-loop control allows servo motors to achieve high levels of accuracy and precision in positioning and motion control. The feedback sensors, such as encoders or resolvers, provide real-time information about the motor’s actual position. This feedback is compared with the desired position, and any deviations are used to adjust the motor’s behavior. By continuously correcting for errors, closed-loop control ensures that the motor accurately reaches and maintains the desired position, resulting in precise control over the motor’s movements.
2. Stability and Repeatability:
Closed-loop control enhances the stability and repeatability of servo motor operation. The feedback information enables the control system to make continuous adjustments to the motor’s inputs, such as voltage or current, in order to minimize position errors. This corrective action helps stabilize the motor’s behavior, reducing oscillations and overshoot. As a result, the motor’s movements become more consistent and repeatable, which is crucial in applications where the same motion needs to be replicated accurately multiple times.
3. Compensation for Disturbances:
One of the key advantages of closed-loop control is its ability to compensate for disturbances or variations that may occur during motor operation. External factors, such as friction, load changes, or variations in the operating environment, can affect the motor’s performance and position accuracy. By continuously monitoring the actual position, closed-loop control can detect and respond to these disturbances, making the necessary adjustments to maintain the desired position. This compensation capability ensures that the motor remains on track despite external influences, leading to more reliable and consistent operation.
4. Improved Response Time:
Closed-loop control significantly improves the response time of servo motors. The feedback sensors provide real-time information about the motor’s actual position, which allows the control system to quickly detect any deviations from the desired position. Based on this feedback, the control system can adjust the motor’s inputs promptly, allowing for rapid corrections and precise control over the motor’s movements. The fast response time of closed-loop control is crucial in applications where dynamic and agile motion control is required, such as robotics or high-speed automation processes.
5. Adaptability to Changing Conditions:
Servo motors with closed-loop control are adaptable to changing conditions. The feedback information allows the control system to dynamically adjust the motor’s behavior based on real-time changes in the operating environment or task requirements. For example, if the load on the motor changes, the control system can respond by adjusting the motor’s inputs to maintain the desired position and compensate for the new load conditions. This adaptability ensures that the motor can perform optimally under varying conditions, enhancing its versatility and applicability in different industrial settings.
In summary, closed-loop control is of significant importance in servo motor operation. It enables servo motors to achieve high levels of accuracy, stability, and repeatability in position and motion control. By continuously monitoring the motor’s actual position and making adjustments based on feedback, closed-loop control compensates for disturbances, enhances response time, and adapts to changing conditions. These capabilities make closed-loop control essential for achieving precise and reliable operation of servo motors in various industrial applications.
Can servo motors be used in robotics, and if so, how are they implemented?
Yes, servo motors are commonly used in robotics due to their precise control capabilities and suitability for a wide range of robotic applications. When implementing servo motors in robotics, several factors need to be considered. Here’s an overview of how servo motors are used and implemented in robotics:
1. Joint Actuation:
Servo motors are often used to actuate the joints of robotic systems. Each joint in a robot typically requires a motor to control its movement. Servo motors provide the necessary torque and angular control to accurately position the joint. They can rotate between specific angles, allowing the robot to achieve the desired configuration and perform precise movements.
2. Position Control:
Servo motors excel at position control, which is essential for robotics applications. They can accurately maintain a specific position and respond quickly to control signals. By incorporating servo motors in robotic joints, precise positioning control can be achieved, enabling the robot to perform tasks with accuracy and repeatability.
3. Closed-Loop Control:
Implementing servo motors in robotics involves utilizing closed-loop control systems. Feedback sensors, such as encoders or resolvers, are attached to the servo motors to provide real-time feedback on the motor’s position. This feedback is used to continuously adjust the motor’s behavior and ensure accurate positioning. Closed-loop control allows the robot to compensate for any errors or disturbances and maintain precise control over its movements.
4. Control Architecture:
In robotics, servo motors are typically controlled using a combination of hardware and software. The control architecture encompasses the control algorithms, microcontrollers or embedded systems, and communication interfaces. The control system receives input signals, such as desired joint positions or trajectories, and generates control signals to drive the servo motors. The control algorithms, such as PID control, are used to calculate the appropriate adjustments based on the feedback information from the sensors.
5. Kinematics and Dynamics:
When implementing servo motors in robotics, the kinematics and dynamics of the robot must be considered. The kinematics deals with the study of the robot’s motion and position, while the dynamics focuses on the forces and torques involved in the robot’s movement. Servo motors need to be properly sized and selected based on the robot’s kinematic and dynamic requirements to ensure optimal performance and stability.
6. Integration and Programming:
Servo motors in robotics need to be integrated into the overall robot system. This involves mechanical mounting and coupling the motors to the robot’s joints, connecting the feedback sensors, and integrating the control system. Additionally, programming or configuring the control software is necessary to define the desired movements and control parameters for the servo motors. This programming can be done using robot-specific programming languages or software frameworks.
By utilizing servo motors in robotics and implementing them effectively, robots can achieve precise and controlled movements. Servo motors enable accurate positioning, fast response times, and closed-loop control, resulting in robots that can perform tasks with high accuracy, repeatability, and versatility. Whether it’s a humanoid robot, industrial manipulator, or collaborative robot (cobot), servo motors play a vital role in their actuation and control.
editor by CX 2024-03-03
China Standard High Torque 219mm 1800W 3000rpm 6nm 18nm 220V AC Servo Motor and Driver with 2500PPR Encoder vacuum pump diy
Product Description
High Torque 219mm 1800W 3000RPM 6NM 18NM 220V Ac Servo Motor And Driver With 2500PPR Encoder
SZGH-11180DC(H) is 1800W servo motor ,optimizing design, compact, beautiful contour, long-term continuous working in rated working mode and economic type
Packing list :
1) SZGH-11180DC(H) 1.8kw servo motor -1pcs
2) SZGH-SD2026E 220v servo driver – 1pcs
3) SZGH1MX-5M 5meter motor cables -1pcs
4) SZGH1EX-5M 5 meter encoder cables -1 pcs
5) Manual -1pcs
Pls tell us at first time when you need :
1) Brake motor
2) 2500PPR encoder
3) long cables
Product Description
Rated Power |
1800W |
Rated torque |
6NM |
Rated Speed | 3000RPM |
Rated Curret |
6A |
Rated Voltage |
220V |
Encoder |
17bit |
Description of Driver
Input Power : Single Three Phase AC220V-15%~+10% SO/60HZ
Control model :
0: Position Control; 1:Speed Control;
2: Torque Control; 3:Position/Speed Control;
4·PositionTorque Control: 5:Speed Torque Control
Protective Function : Over-speed Over-voltage Under-voltage Over-current OverloadEncoder Error/ Control Power Eror/ Position Offset Eror
Driver Load : Less than 3times of rotor inertia
Display : 5 bits LED indicator display 4 Operate keys
Communication : RS485
Position Control : Input Model , Electric Ratio
Product Parameters
Certifications
Packaging & Shipping
1.Industrial packing: plastic bag +foam boxes+ carton +wooden pallets 2.Commercial packing: plastic bag+ foam boxes + carton
3.As the clients requirement
Delivery Detail: Normally ready goods and stock within 2- 5days
Company Profile
HangZhou CHINAMFG Automation CO.,LTD (Formerly known as ‘HangZhou CHINAMFG Automation Co.,Limited(Built in 19 November 2571)’) is 1 of the leading CNC & automatic company in China, specialized in designing projects, marketing, and oversea trading, having extensive experience in CNC package solution, Our focus has been on providing the high quality of Industrial robot arm Lathe CNC system, Milling CNC system, Engraving CNC system, Grinding & router CNC system, Motor & driver, Spindle servo motor & driver, Gear reducer.
SZGH’ products have been in working with a wide variety of CNC machinery and automatic processing equipment with high performance and good precision, stably. We have now established a reliable structure , our experienced engineers and technicians are able to provide professional consultancy and offer you most suitable CNC application solution.
Our strict quality control measures guarantee excellent reliability and high standard of quality. Utilizing advanced CNC machinery to test every product, 100 percent inspection is made before packaging and shipment. Moreover, We also offer flexible lead times to support your business.
We have a large number of customers across Asia, America, the Middle East, Europe, South America, and Africa. Specially we already built own business corporate group in Middle East market.
Our Advantages
After Sales Service
Best & Professional after- sales supports
Our company have very professional engineers teams ;
We can provide the professional after -sales service to our all clients ;
Here is our engineer Mike solved the problems for our customer ;
Best supports !! Quicly reply !!
Buy at ease , use at ease !!!
FAQ
Q: Do you support customized manufacturing?
A: Yes,we can customized manufacturing according to customer’s requirment. We support to OEM your own company display interface
and logo.
Q: How long is your delivery time?
A: Generally it is 3-5 days if the goods are in stock. or it is 5-10 days if the goods are not in stock, it is according to
quantity.10-20 days if customized manufacturing.
Q: Do you provide samples ? is it free or extra ?
A: Yes, we could offer the sample with sample price.
Q: What is your terms of payment ?
A: Payment=1000USD, 70% T/T in advance ,balance before shippment.
If you have another question, pls feel free to contact us as below
/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | Machine Tool |
---|---|
Speed: | Variable Speed |
Number of Stator: | Three-Phase |
Function: | Driving, Control |
Casing Protection: | Explosion-Proof Type |
Number of Poles: | 4 |
Customization: |
Available
|
|
---|
How does the cost of servo motors vary based on their specifications and features?
The cost of servo motors can vary significantly based on their specifications and features. Several factors influence the price of servo motors, and understanding these factors can help in selecting the most cost-effective option for a specific application. Let’s explore in detail how the cost of servo motors can vary:
1. Power Rating:
One of the primary factors affecting the cost of a servo motor is its power rating, which is typically measured in watts or kilowatts. Higher power-rated servo motors generally cost more than lower-rated ones due to the increased materials and manufacturing required to handle higher power levels. The power rating of a servo motor is determined by the torque and speed requirements of the application. Higher torque and speed capabilities often correspond to higher costs.
2. Torque and Speed:
The torque and speed capabilities of a servo motor directly impact its cost. Servo motors designed for high torque and high-speed applications tend to be more expensive due to the need for robust construction, specialized materials, and advanced control electronics. Motors with higher torque and speed ratings often require more powerful magnets, larger windings, and higher precision components, contributing to the increase in cost.
3. Frame Size:
The physical size or frame size of a servo motor also plays a role in determining its cost. Servo motors come in various frame sizes, such as NEMA (National Electrical Manufacturers Association) standard sizes in North America. Larger frame sizes generally command higher prices due to the increased materials and manufacturing complexity required to build larger motors. Smaller frame sizes, on the other hand, may be more cost-effective but may have limitations in terms of torque and speed capabilities.
4. Feedback Mechanism:
The feedback mechanism used in a servo motor affects its cost. Servo motors typically employ encoders or resolvers to provide feedback on the rotor position. Higher-resolution encoders or more advanced feedback technologies can increase the cost of the motor. For example, servo motors with absolute encoders, which provide position information even after power loss, tend to be more expensive than those with incremental encoders.
5. Control Features and Technology:
The control features and technology incorporated into a servo motor can influence its cost. Advanced servo motors may offer features such as built-in controllers, fieldbus communication interfaces, advanced motion control algorithms, or integrated safety functions. These additional features contribute to the cost of the motor but can provide added value and convenience in certain applications. Standard servo motors with basic control functionality may be more cost-effective for simpler applications.
6. Brand and Reputation:
The brand and reputation of the servo motor manufacturer can impact its cost. Established and reputable brands often command higher prices due to factors such as quality assurance, reliability, technical support, and extensive product warranties. While motors from less-known or generic brands may be more affordable, they may not offer the same level of performance, reliability, or long-term support.
7. Customization and Application-Specific Requirements:
If a servo motor needs to meet specific customization or application-specific requirements, such as specialized mounting options, environmental sealing, or compliance with industry standards, the cost may increase. Customization often involves additional engineering, design, and manufacturing efforts, which can lead to higher prices compared to off-the-shelf servo motors.
It’s important to note that the cost of a servo motor is not the sole indicator of its quality or suitability for a particular application. It is essential to carefully evaluate the motor’s specifications, features, and performance characteristics in relation to the application requirements to make an informed decision.
In summary, the cost of servo motors varies based on factors such as power rating, torque and speed capabilities, frame size, feedback mechanism, control features and technology, brand reputation, and customization requirements. By considering these factors and comparing different options, it is possible to select a servo motor that strikes the right balance between performance and cost-effectiveness for a specific application.
What factors should be considered when selecting a servo motor for a specific application?
When selecting a servo motor for a specific application, several factors need to be considered. These factors help ensure that the chosen servo motor meets the requirements and performs optimally in the intended application. Here are some key factors to consider:
1. Torque and Power Requirements:
One of the primary considerations is the torque and power requirements of the application. The servo motor should be able to generate sufficient torque to handle the load and overcome any resistance or friction in the system. Additionally, the power rating of the motor should match the power supply available in the application. It is essential to evaluate the torque-speed characteristics of the servo motor to ensure it can deliver the required performance.
2. Speed and Acceleration:
The required speed and acceleration capabilities of the servo motor should align with the application’s needs. Different applications have varying speed and acceleration requirements, and the servo motor should be able to meet these demands. It is crucial to consider both the maximum speed that the motor can achieve and the time it takes to accelerate or decelerate to specific speeds. Evaluating the servo motor’s speed-torque characteristics and acceleration capabilities is necessary for selecting the right motor.
3. Positioning Accuracy and Repeatability:
The desired positioning accuracy and repeatability of the application play a significant role in servo motor selection. If precise positioning is crucial, a servo motor with high accuracy and low positioning errors should be chosen. The feedback mechanism, such as encoders or resolvers, should provide the required resolution to achieve the desired accuracy. Repeatability, the ability to consistently reach the same position, should also be considered, especially in applications where repetitive movements are necessary.
4. Environmental Conditions:
The environmental conditions in which the servo motor will operate should be taken into account. Factors such as temperature extremes, humidity, dust, and vibration can affect the motor’s performance and lifespan. In harsh environments, it may be necessary to choose a servo motor with appropriate protection ratings, such as IP (Ingress Protection) ratings, to ensure reliable operation and longevity.
5. Control System Compatibility:
The compatibility of the servo motor with the control system used in the application is crucial. The motor should be compatible with the control signals and communication protocols employed in the system. This includes considerations such as voltage compatibility, control signal types (analog, digital, pulse), and communication interfaces (such as Ethernet, CAN, or Modbus). Ensuring compatibility will facilitate seamless integration and efficient control of the servo motor within the application.
6. Size and Weight Constraints:
The physical size and weight limitations of the application should be considered when selecting a servo motor. The motor’s dimensions should fit within the available space, and its weight should not exceed the application’s weight capacity. Compact and lightweight servo motors may be preferred in applications where space is limited or weight is a critical factor.
7. Cost Considerations:
The cost of the servo motor and its overall value for the application should be evaluated. It is essential to consider the initial purchase cost as well as the long-term maintenance and operational costs. While cost is a factor, it should not be the sole determining factor, as compromising on quality or performance may lead to suboptimal results.
By considering these factors, one can make an informed decision when selecting a servo motor for a specific application. It is recommended to consult with manufacturers or experts in the field to ensure the chosen servo motor meets the application’s requirements and provides reliable and efficient performance.
Can you explain the difference between a servo motor and a regular electric motor?
A servo motor and a regular electric motor are both types of electric motors, but they have distinct differences in terms of design, control, and functionality.
A regular electric motor, also known as an induction motor or a DC motor, is designed to convert electrical energy into mechanical energy. It consists of a rotor, which rotates, and a stator, which surrounds the rotor and generates a rotating magnetic field. The rotor is connected to an output shaft, and when current flows through the motor’s windings, it creates a magnetic field that interacts with the stator’s magnetic field, resulting in rotational motion.
On the other hand, a servo motor is a more specialized type of electric motor that incorporates additional components for precise control of position, speed, and acceleration. It consists of a regular electric motor, a sensor or encoder, and a feedback control system. The sensor or encoder provides feedback on the motor’s current position, and this information is used by the control system to adjust the motor’s behavior.
The key difference between a servo motor and a regular electric motor lies in their control mechanisms. A regular electric motor typically operates at a fixed speed based on the voltage and frequency of the power supply. In contrast, a servo motor can be controlled to rotate to a specific angle or position and maintain that position accurately. The control system continuously monitors the motor’s actual position through the feedback sensor and adjusts the motor’s operation to achieve the desired position or follow a specific trajectory.
Another distinction is the torque output of the motors. Regular electric motors generally provide high torque at low speeds and lower torque at higher speeds. In contrast, servo motors are designed to deliver high torque at both low and high speeds, which makes them suitable for applications that require precise and dynamic motion control.
Furthermore, servo motors often have a more compact and lightweight design compared to regular electric motors. They are commonly used in applications where precise positioning, speed control, and responsiveness are critical, such as robotics, CNC machines, automation systems, and remote-controlled vehicles.
In summary, while both servo motors and regular electric motors are used to convert electrical energy into mechanical energy, servo motors offer enhanced control capabilities, precise positioning, and high torque at various speeds, making them well-suited for applications that require accurate and dynamic motion control.
editor by CX 2024-03-01
China wholesaler Servo Motor Encoder Absolute Interface High Cost Performance 48mm External Diameter and 8mm Hole 9mm Hole vacuum pump ac
Product Description
Packaging & Delivery
Package size per unit product
10.00cm * 10.00cm * 10.00cm
Gross weight per unit product
0.100kg
Product Description
ADK-SV48 Series
ASIC devices are used inside, with high reliability, long life and strong anti-interference. The taper shaft design link is not easy to slip, the installation volume is small, the resolution range is wide, no signal adjustment required, with A, B, Z, U, V, W six-channel signal output, and can be connected to standard line drives (26L- S31) RS422, and can provide 12 output signals, compatible with TTL
Model No.:ADK-SV-XXXX
Resolution:MAX 23bit
interface:A,B,Z,U,V,W
External diameter:48mm
Shaft diameter:6,8,10mm
Supply Voltage: 5v,8-29v;
Product Parameters
name | ADK SV48 series servo motor rotary encoder A,B,Z,U,V,W max 23bit replace Omron Kubler Autonics Baumer |
resolute | max 23bit |
Output format | voltage,NPN/PNP,Xihu (West Lake) Dis.ne, |
Supply Voltage | 5v, 8-29v |
external diameter | 48mm |
max turn quantity | 4096 |
shaft diameter | 6,8,10mm |
Protection level | IP54~IP67 |
Work temperature | -20~85ºC |
Certification | ISO9001,ROHS,CE,SGS,BV |
Detailed Photos
Certifications
Company Profile
Idencoder is a professional manufacturer of rotary encoders and has provided various encoder solutions for hundreds of companies at home and abroad. HangZhou CHINAMFG is committed to the development, production and sales of various high-performance industrial rotary encoders.
It has an independent R&D team, with companies and offices in HangZhou, HangZhou, and HangZhou.
Certification:ISO9001,SGS,ROHS,CE,BV and etc.
Recognized as a national high-tech enterprise
Our slogan:make the best encoder in China.
To this end, we invest a lot of money and energy in research and development every year. More than 50 patents have been obtained, covering the software and hardware fields such as incremental encoders, absolute encoders, programmable encoders, servo motor encoders, industrial Ethernet encoders, and cable displacement encoders
Applications
General incremental encoder applied to automation control,measurement,robot,X-Ywork,printing&packing,textile printing and dyeing and etc.high reliable,long service life,strong anti-interference capability. Wide temperature range and IP grade can be customized
Packaging & Shipping
The rotary encoder is packed in standard export packaging or as required by buyers
Delivery Time
Shipped within 7 days after full payment by DHL
FAQ
1) How to select an encoder?
Before ordering encoders, you could clearly know which type of encoder you may need.
There are incremental encoder and absolute encoder, after this, our sale-service department would better work for you.
2) What specifications are requested before order an encoder?
Encoder type—————-solid shaft or hollow shaft encoder
External Diameter———-Min 25mm, MAX 100mm
Shaft Diameter—————Min shaft 3mm, Max shaft 45mm
Phase & Resolution———Min 20ppr, MAX 50000ppr
Circuit Output Mode——-you could choose NPN,PNP,Voltage, Push-pull,Line driver, etc
Power Supply Voltage——DC5V-30V
3) How to choose a right encoder by yourself ?
Exact Specification Description
Check The Installation Dimensions
Contact Supplier to get more details
4) How many pieces to start ?
The MOQ is 20pcs .Less quantity is also ok but the freight is higher.
5) Why choose “Gertech” Brand Encoder?
All encoders are designed and developed by our own engineer team since year 2004,
and most of the electronic component of encoders are imported from overseas market.
Never let our quality down,because quality is our culture.
6) How long is your lead time?
Short lead time—-3 days for samples,7-10days for mass production
7) what is your guarantee policy?
1year warranty and life-long technical support
8)What are the benefit if we become your agency ?
Special prices, Market protection and supporting.
9)What is the process to become Gertech agency?
Please send us enquiry,we will contact you as soon as possible.
10)What is your production capacity?
We produce 5000pcs every week.Now we are building second phrase production line.
exhibition
/* March 10, 2571 17:59:20 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | Industrial |
---|---|
Operating Speed: | Adjust Speed |
Number of Stator: | Can Available |
Species: | Can Available |
Rotor Structure: | Can Available |
Casing Protection: | Closed Type |
Customization: |
Available
|
|
---|
Are there common issues or challenges associated with servo motor systems, and how can they be addressed?
Servo motor systems are widely used in various applications, but they can encounter common issues or challenges that affect their performance and reliability. Let’s explore some of these issues and discuss potential solutions:
1. Positioning and Tracking Errors:
One common challenge in servo motor systems is positioning and tracking errors. These errors can occur due to factors such as mechanical backlash, encoder resolution limitations, or disturbances in the system. To address this issue, careful calibration and tuning of the servo control system are necessary. This includes adjusting feedback gains, implementing feedback filtering techniques, and utilizing advanced control algorithms to improve the system’s accuracy and minimize errors. Additionally, employing high-resolution encoders and backlash compensation mechanisms can help enhance the positioning and tracking performance.
2. Vibration and Resonance:
Vibration and resonance can impact the performance of servo motor systems, leading to reduced accuracy and stability. These issues can arise from mechanical resonances within the system or external disturbances. To mitigate vibration and resonance problems, it is crucial to analyze the system’s dynamics and identify critical resonant frequencies. Implementing vibration dampening techniques such as mechanical isolation, using vibration-absorbing materials, or employing active vibration control methods can help minimize the effect of vibrations and improve the system’s performance.
3. Overheating and Thermal Management:
Servo motors can generate heat during operation, and inadequate thermal management can lead to overheating and potential performance degradation. To address this issue, proper cooling and thermal management techniques should be employed. This may involve using heat sinks, fans, or liquid cooling systems to dissipate heat efficiently. Ensuring adequate ventilation and airflow around the motor and avoiding excessive current or overloading can also help prevent overheating. Monitoring the motor’s temperature and implementing temperature protection mechanisms can further safeguard the motor from thermal damage.
4. Electrical Noise and Interference:
Electrical noise and interference can affect the performance and reliability of servo motor systems. These issues can arise from electromagnetic interference (EMI) or radio frequency interference (RFI) from nearby equipment or electrical sources. To mitigate electrical noise, proper shielding and grounding techniques should be employed. Using shielded cables, ferrite cores, and grounding the motor and control system can help minimize the impact of noise and interference. Additionally, employing filtering techniques and surge protection devices can further improve system robustness against electrical disturbances.
5. System Integration and Compatibility:
Integrating a servo motor system into a larger control system or automation setup can present challenges in terms of compatibility and communication. Ensuring proper compatibility between the servo motor and the control system is crucial. This involves selecting appropriate communication protocols, such as EtherCAT or Modbus, and ensuring compatibility with the control signals and interfaces. Employing standardized communication interfaces and protocols can facilitate seamless integration and interoperability. Additionally, thorough testing and verification of the system’s compatibility before deployment can help identify and address any integration issues.
6. Maintenance and Service:
Maintenance and service requirements are important considerations for servo motor systems. Regular maintenance, including lubrication, inspection, and cleaning, can help prevent issues related to wear and tear. Following manufacturer-recommended maintenance schedules and procedures is essential to ensure the longevity and optimal performance of the motor. In case of any malfunctions or failures, having access to technical support from the manufacturer or trained service personnel can help diagnose and address problems effectively.
By being aware of these common issues and challenges associated with servo motor systems and implementing appropriate solutions, it is possible to enhance the performance, reliability, and lifespan of the servo motor system. Regular monitoring, proactive maintenance, and continuous improvement can contribute to optimizing the overall operation and efficiency of the system.
What factors should be considered when selecting a servo motor for a specific application?
When selecting a servo motor for a specific application, several factors need to be considered. These factors help ensure that the chosen servo motor meets the requirements and performs optimally in the intended application. Here are some key factors to consider:
1. Torque and Power Requirements:
One of the primary considerations is the torque and power requirements of the application. The servo motor should be able to generate sufficient torque to handle the load and overcome any resistance or friction in the system. Additionally, the power rating of the motor should match the power supply available in the application. It is essential to evaluate the torque-speed characteristics of the servo motor to ensure it can deliver the required performance.
2. Speed and Acceleration:
The required speed and acceleration capabilities of the servo motor should align with the application’s needs. Different applications have varying speed and acceleration requirements, and the servo motor should be able to meet these demands. It is crucial to consider both the maximum speed that the motor can achieve and the time it takes to accelerate or decelerate to specific speeds. Evaluating the servo motor’s speed-torque characteristics and acceleration capabilities is necessary for selecting the right motor.
3. Positioning Accuracy and Repeatability:
The desired positioning accuracy and repeatability of the application play a significant role in servo motor selection. If precise positioning is crucial, a servo motor with high accuracy and low positioning errors should be chosen. The feedback mechanism, such as encoders or resolvers, should provide the required resolution to achieve the desired accuracy. Repeatability, the ability to consistently reach the same position, should also be considered, especially in applications where repetitive movements are necessary.
4. Environmental Conditions:
The environmental conditions in which the servo motor will operate should be taken into account. Factors such as temperature extremes, humidity, dust, and vibration can affect the motor’s performance and lifespan. In harsh environments, it may be necessary to choose a servo motor with appropriate protection ratings, such as IP (Ingress Protection) ratings, to ensure reliable operation and longevity.
5. Control System Compatibility:
The compatibility of the servo motor with the control system used in the application is crucial. The motor should be compatible with the control signals and communication protocols employed in the system. This includes considerations such as voltage compatibility, control signal types (analog, digital, pulse), and communication interfaces (such as Ethernet, CAN, or Modbus). Ensuring compatibility will facilitate seamless integration and efficient control of the servo motor within the application.
6. Size and Weight Constraints:
The physical size and weight limitations of the application should be considered when selecting a servo motor. The motor’s dimensions should fit within the available space, and its weight should not exceed the application’s weight capacity. Compact and lightweight servo motors may be preferred in applications where space is limited or weight is a critical factor.
7. Cost Considerations:
The cost of the servo motor and its overall value for the application should be evaluated. It is essential to consider the initial purchase cost as well as the long-term maintenance and operational costs. While cost is a factor, it should not be the sole determining factor, as compromising on quality or performance may lead to suboptimal results.
By considering these factors, one can make an informed decision when selecting a servo motor for a specific application. It is recommended to consult with manufacturers or experts in the field to ensure the chosen servo motor meets the application’s requirements and provides reliable and efficient performance.
What is a servo motor, and how does it function in automation systems?
A servo motor is a type of motor specifically designed for precise control of angular or linear position, velocity, and acceleration. It is widely used in various automation systems where accurate motion control is required. Let’s explore the concept of servo motors and how they function in automation systems:
A servo motor consists of a motor, a position feedback device (such as an encoder or resolver), and a control system. The control system receives input signals, typically in the form of electrical pulses or analog signals, indicating the desired position or speed. Based on these signals and the feedback from the position sensor, the control system adjusts the motor’s operation to achieve the desired motion.
The functioning of a servo motor in an automation system involves the following steps:
- Signal Input: The automation system provides a control signal to the servo motor, indicating the desired position, speed, or other motion parameters. This signal can be generated by a human operator, a computer, a programmable logic controller (PLC), or other control devices.
- Feedback System: The servo motor incorporates a position feedback device, such as an encoder or resolver, which continuously monitors the motor’s actual position. This feedback information is sent back to the control system, allowing it to compare the actual position with the desired position specified by the input signal.
- Control System: The control system, typically housed within the servo motor or an external servo drive, receives the input signal and the feedback from the position sensor. It processes this information and generates the appropriate control signals to the motor.
- Motor Operation: Based on the control signals received from the control system, the servo motor adjusts its operation to achieve the desired motion. The control system varies the motor’s voltage, current, or frequency to control the motor’s speed, torque, or position accurately.
- Closed-Loop Control: Servo motors operate in a closed-loop control system. The feedback information from the position sensor allows the control system to continuously monitor and adjust the motor’s operation to minimize any deviation between the desired position and the actual position. This closed-loop control mechanism provides high accuracy, repeatability, and responsiveness in motion control applications.
One of the key advantages of servo motors in automation systems is their ability to provide precise and dynamic motion control. They can rapidly accelerate, decelerate, and change direction with high accuracy, allowing for intricate and complex movements. Servo motors are widely used in applications such as robotics, CNC machines, printing presses, packaging equipment, and automated manufacturing systems.
In summary, a servo motor is a specialized motor that enables accurate control of position, velocity, and acceleration in automation systems. Through the combination of a control system and a position feedback device, servo motors can precisely adjust their operation to achieve the desired motion. Their closed-loop control mechanism and high responsiveness make them an essential component in various applications requiring precise and dynamic motion control.
editor by CX 2024-02-26
China Good quality Original Hybrid Servo Motors BLDC Servo Motor in Stovk vacuum pump ac system
Product Description
Original hybrid servo motors bldc servo motor in stock
Servo motor refers to the motor that controls the operation of mechanical components in a servo system. The servo motor can control the speed and position very precisely, converting the voltage signal into torque and speed to drive the control object. Servo motor rotor speed is controlled by the input signal, and can respond quickly, in the automatic control system, used as an executive component, can be received into the motor shaft angular displacement or angular speed output. Servo motors are divided into DC and AC servo motors. Stepper motor and servo motor are both motion control products, but there are some differences in performance and application.
Product Description
Specification
Item |
Value |
Warranty |
1 year |
Place of Origin |
China |
Brand Name |
CHINAMFG |
Model Number |
DS2/DM1 |
Type |
SERVO MOTOR |
Frequency |
50HZ |
Phase |
Single-phase/Three-phase |
AC Voltage |
220V 0.1KW-5.5KW |
Feedback |
Support multi-loop 16bit absolute encoder |
23bit communication single-loop absolute encoder (with battery added, it can function as multi-loop absolute encoder) |
|
Using Temperature |
0-45ºC |
Applications
Servo motor and servo drive systems are widely used in many fields, including machine tools, 3C electronic equipment manufacturing, packaging machinery, textile machinery, plastic machinery, medical equipment, food machinery, rubber machinery, printing machinery, and other industries
Packing & Delivery
Packing Method
Outer packing: Standard export carton with required shipping marks. Inner packing: Waterproof packing with shock absorbing EPE and cardboard surrounded. As per the client’s requirement.
Company Profile
LUNYEE Group is a leading manufacturer for factory automation(FA) products. We are dedicated in power transmission and motion control solutions.
We have a professional technical team, from research and development, design, production, assembly to after-sales one-stop service.
We manufacture power transmission products like servo motor and control kits, AC and DC (brush/ brushless) gear motor, stepping motor, spindle motor, and so on.
We Focus On Customer Satisfaction.
We recognize ourselves as eyes and ears for our customers! One professional QC department is built up to inspect all the manufacture process according to international quality standard and our customers’ special requirement! All the products from CHINAMFG can enjoy a warranty from us. Welcome to contact us for cooperation.
Q&A
Q: Are you trading company or manufacturer?
A: We are the motor manufacturer for 15 years history in China.
Q: How long is the delivery, producing and shipping?
A: Deliver time depends on the quantity you order. We have product in stock will delivery fast. If customized, it usually takes 10-20 working days.
Q: Do you have customized service for your standard goods?
A: Yes, customized service acceptable.
Q: How do you make sure alternator quality?
A: We have our own inspection procedures. Every model we have a standard design and test few models before mass production. Also the CE and ISO standard make production goes well. For production process, random inspection will be arranged and final test to make sure qualified products before shipping.
Q: What is your after-sales services?
A: We would supply the free maintenance within 12 months guarantee. We would supply the professional solutions during using.
/* March 10, 2571 17:59:20 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | Industrial |
---|---|
Speed: | Variable Speed |
Number of Stator: | Three-Phase |
Function: | Driving, Control |
Casing Protection: | Closed Type |
Number of Poles: | 4 |
Samples: |
US$ 280/Piece
1 Piece(Min.Order) | |
---|
Customization: |
Available
|
|
---|
How does the cost of servo motors vary based on their specifications and features?
The cost of servo motors can vary significantly based on their specifications and features. Several factors influence the price of servo motors, and understanding these factors can help in selecting the most cost-effective option for a specific application. Let’s explore in detail how the cost of servo motors can vary:
1. Power Rating:
One of the primary factors affecting the cost of a servo motor is its power rating, which is typically measured in watts or kilowatts. Higher power-rated servo motors generally cost more than lower-rated ones due to the increased materials and manufacturing required to handle higher power levels. The power rating of a servo motor is determined by the torque and speed requirements of the application. Higher torque and speed capabilities often correspond to higher costs.
2. Torque and Speed:
The torque and speed capabilities of a servo motor directly impact its cost. Servo motors designed for high torque and high-speed applications tend to be more expensive due to the need for robust construction, specialized materials, and advanced control electronics. Motors with higher torque and speed ratings often require more powerful magnets, larger windings, and higher precision components, contributing to the increase in cost.
3. Frame Size:
The physical size or frame size of a servo motor also plays a role in determining its cost. Servo motors come in various frame sizes, such as NEMA (National Electrical Manufacturers Association) standard sizes in North America. Larger frame sizes generally command higher prices due to the increased materials and manufacturing complexity required to build larger motors. Smaller frame sizes, on the other hand, may be more cost-effective but may have limitations in terms of torque and speed capabilities.
4. Feedback Mechanism:
The feedback mechanism used in a servo motor affects its cost. Servo motors typically employ encoders or resolvers to provide feedback on the rotor position. Higher-resolution encoders or more advanced feedback technologies can increase the cost of the motor. For example, servo motors with absolute encoders, which provide position information even after power loss, tend to be more expensive than those with incremental encoders.
5. Control Features and Technology:
The control features and technology incorporated into a servo motor can influence its cost. Advanced servo motors may offer features such as built-in controllers, fieldbus communication interfaces, advanced motion control algorithms, or integrated safety functions. These additional features contribute to the cost of the motor but can provide added value and convenience in certain applications. Standard servo motors with basic control functionality may be more cost-effective for simpler applications.
6. Brand and Reputation:
The brand and reputation of the servo motor manufacturer can impact its cost. Established and reputable brands often command higher prices due to factors such as quality assurance, reliability, technical support, and extensive product warranties. While motors from less-known or generic brands may be more affordable, they may not offer the same level of performance, reliability, or long-term support.
7. Customization and Application-Specific Requirements:
If a servo motor needs to meet specific customization or application-specific requirements, such as specialized mounting options, environmental sealing, or compliance with industry standards, the cost may increase. Customization often involves additional engineering, design, and manufacturing efforts, which can lead to higher prices compared to off-the-shelf servo motors.
It’s important to note that the cost of a servo motor is not the sole indicator of its quality or suitability for a particular application. It is essential to carefully evaluate the motor’s specifications, features, and performance characteristics in relation to the application requirements to make an informed decision.
In summary, the cost of servo motors varies based on factors such as power rating, torque and speed capabilities, frame size, feedback mechanism, control features and technology, brand reputation, and customization requirements. By considering these factors and comparing different options, it is possible to select a servo motor that strikes the right balance between performance and cost-effectiveness for a specific application.
What factors should be considered when selecting a servo motor for a specific application?
When selecting a servo motor for a specific application, several factors need to be considered. These factors help ensure that the chosen servo motor meets the requirements and performs optimally in the intended application. Here are some key factors to consider:
1. Torque and Power Requirements:
One of the primary considerations is the torque and power requirements of the application. The servo motor should be able to generate sufficient torque to handle the load and overcome any resistance or friction in the system. Additionally, the power rating of the motor should match the power supply available in the application. It is essential to evaluate the torque-speed characteristics of the servo motor to ensure it can deliver the required performance.
2. Speed and Acceleration:
The required speed and acceleration capabilities of the servo motor should align with the application’s needs. Different applications have varying speed and acceleration requirements, and the servo motor should be able to meet these demands. It is crucial to consider both the maximum speed that the motor can achieve and the time it takes to accelerate or decelerate to specific speeds. Evaluating the servo motor’s speed-torque characteristics and acceleration capabilities is necessary for selecting the right motor.
3. Positioning Accuracy and Repeatability:
The desired positioning accuracy and repeatability of the application play a significant role in servo motor selection. If precise positioning is crucial, a servo motor with high accuracy and low positioning errors should be chosen. The feedback mechanism, such as encoders or resolvers, should provide the required resolution to achieve the desired accuracy. Repeatability, the ability to consistently reach the same position, should also be considered, especially in applications where repetitive movements are necessary.
4. Environmental Conditions:
The environmental conditions in which the servo motor will operate should be taken into account. Factors such as temperature extremes, humidity, dust, and vibration can affect the motor’s performance and lifespan. In harsh environments, it may be necessary to choose a servo motor with appropriate protection ratings, such as IP (Ingress Protection) ratings, to ensure reliable operation and longevity.
5. Control System Compatibility:
The compatibility of the servo motor with the control system used in the application is crucial. The motor should be compatible with the control signals and communication protocols employed in the system. This includes considerations such as voltage compatibility, control signal types (analog, digital, pulse), and communication interfaces (such as Ethernet, CAN, or Modbus). Ensuring compatibility will facilitate seamless integration and efficient control of the servo motor within the application.
6. Size and Weight Constraints:
The physical size and weight limitations of the application should be considered when selecting a servo motor. The motor’s dimensions should fit within the available space, and its weight should not exceed the application’s weight capacity. Compact and lightweight servo motors may be preferred in applications where space is limited or weight is a critical factor.
7. Cost Considerations:
The cost of the servo motor and its overall value for the application should be evaluated. It is essential to consider the initial purchase cost as well as the long-term maintenance and operational costs. While cost is a factor, it should not be the sole determining factor, as compromising on quality or performance may lead to suboptimal results.
By considering these factors, one can make an informed decision when selecting a servo motor for a specific application. It is recommended to consult with manufacturers or experts in the field to ensure the chosen servo motor meets the application’s requirements and provides reliable and efficient performance.
What is a servo motor, and how does it function in automation systems?
A servo motor is a type of motor specifically designed for precise control of angular or linear position, velocity, and acceleration. It is widely used in various automation systems where accurate motion control is required. Let’s explore the concept of servo motors and how they function in automation systems:
A servo motor consists of a motor, a position feedback device (such as an encoder or resolver), and a control system. The control system receives input signals, typically in the form of electrical pulses or analog signals, indicating the desired position or speed. Based on these signals and the feedback from the position sensor, the control system adjusts the motor’s operation to achieve the desired motion.
The functioning of a servo motor in an automation system involves the following steps:
- Signal Input: The automation system provides a control signal to the servo motor, indicating the desired position, speed, or other motion parameters. This signal can be generated by a human operator, a computer, a programmable logic controller (PLC), or other control devices.
- Feedback System: The servo motor incorporates a position feedback device, such as an encoder or resolver, which continuously monitors the motor’s actual position. This feedback information is sent back to the control system, allowing it to compare the actual position with the desired position specified by the input signal.
- Control System: The control system, typically housed within the servo motor or an external servo drive, receives the input signal and the feedback from the position sensor. It processes this information and generates the appropriate control signals to the motor.
- Motor Operation: Based on the control signals received from the control system, the servo motor adjusts its operation to achieve the desired motion. The control system varies the motor’s voltage, current, or frequency to control the motor’s speed, torque, or position accurately.
- Closed-Loop Control: Servo motors operate in a closed-loop control system. The feedback information from the position sensor allows the control system to continuously monitor and adjust the motor’s operation to minimize any deviation between the desired position and the actual position. This closed-loop control mechanism provides high accuracy, repeatability, and responsiveness in motion control applications.
One of the key advantages of servo motors in automation systems is their ability to provide precise and dynamic motion control. They can rapidly accelerate, decelerate, and change direction with high accuracy, allowing for intricate and complex movements. Servo motors are widely used in applications such as robotics, CNC machines, printing presses, packaging equipment, and automated manufacturing systems.
In summary, a servo motor is a specialized motor that enables accurate control of position, velocity, and acceleration in automation systems. Through the combination of a control system and a position feedback device, servo motors can precisely adjust their operation to achieve the desired motion. Their closed-loop control mechanism and high responsiveness make them an essential component in various applications requiring precise and dynamic motion control.
editor by CX 2024-02-26