Product Description
CHINAMFG CHINAMFG 90K55-87134X AC SERVO MOTOR YV100II AXIS-X MOTOR CHINAMFG DENKI P50B5711DXS07 AXIS-X
Part Number: 90K55-87134X
Model :P50B5711DXS07
Applicable models: YV100II
Product Tags: 90K55-87134X
P50B5711DXS07
We can supply zhe following prodcuts of motor:
YAMAHA MOTOR
90K55-87134X AC SERVO MOTOR YV100II
90K55-8A134Y AC SERVO MOTOR YV100II
90K55-4W032W AC SERVO MOTOR YV100II
90K55-4W035R AC SERVO MOTOR YV100II
90K55-4W034Z AC SERVO MOTOR YV100II
90K52-87174X AC SERVO MOTOR YV100X
90K52-8A174Y AC SERVO MOTOR YV100X
90K50-4W072W AC SERVO MOTOR YV100X
90K50-4W074R AC SERVO MOTOR YV100X
90K55-4W074R AC SERVO MOTOR YV100X
90K50-4W074Z AC SERVO MOTOR YV100X
90K55-4W074Z AC SERVO MOTOR YV100X
KM0-M666J-00X100II
KM1-M665H-00X100II
KV8-M665U-00X100X
KV8-M666H-00X100X
YAMAHA FILTER:
YAMAHA YSM20 FILTER
YAMAHA YG12 FILTER KHY-M7154-C0X
YAMAHA YV88 FILTER KH5-M7182-C0X
YAMAHA YV88 FILTER KH5-M718-C0X
YAMAHA YV100 FILTER K46-M8527-C0X
YAMAHA YV100 FILTER K46-M8527-C0X
YAMAHA SHAFT
KM9-M7107-00XSHFT, HEAD ASSYYV100II
KM9-M7106-00XSHAFT HEAD ASSY YV100II
KV8-M713S-A0X STD.SHAFT2,SPARE YV100X
KV8-M712S-A0X STD.SHAFT1,SPARE YV100X
KV8-M711S-A0X FNC SHAFT,SPARE YV100X
KGB-M711S-A0X FNC SHAFT,SPARE YV100XG
KGB-M712S-A0X STD.SHAFT1,SPARE YV100XG
KGT-M712S-A0X STD. SHAFT 1, SPAREYG200X
YAMAHA VAVLE
KM1-M7163-20X A571E1-37W
KM1-M7163-21X A571E1-54W
KM1-M7163-30X A571E1-44W
KGA-M7111-H0X A041E1-48W 88X
KM5-M7174-11X AME05-E2-PSL-13W
KV7-M7111-B0X A041E1-11-48W
KM1-M7162-20X A571E1-35W
KV8-M7162-20X A571E1-55W
KV8-M7162-10X A040-4E1-56W
KM1-M7162-11X A040-4E1-54W
KU0-M3410-41X A571E1-32W
KGA-M37P1-00X G571HE1-5W
KV5-M7121-L0XA040-4E1-50W
KV5-M7121-R0XA040-4E1-50W
KH2-M7101-00XA040-4E1-3W YTF Head
KGA-M7111-G0X A571E1-59W VALVE Blow valve
KV8-M7535-01X VALVE
KGB-M7163-A0X 37W+44W+13W
KV8-M7163-A0X 37W+44W+13W
YAMAHH CYLIDER
KG7-M9165-00X PDAS6*30
KH5-M9176-00X PDAS6*30
KG7-M9166-00X PBDA10*30
K98-M9283-00X BDAS16*25-259W
KG7-M9236-00X CYLINDER JDAD12*5
KV7-M9165-00X PDAS6*40
KV7-M9179-A0X PDAS6*40
KV7-M9237-00X PBSA10*5-W
KV7-M9283-00X YMDA16*35-1W
KM1-M9605-02X CYLINDER, CLAMP
KM1-M9611-02X CYLINDER, U/D
KV8-M7522-01X CYLINDER ASSY
YAMAHA BELT
KM1-M7138-00X CHINAMFG YV100II
KV8-M7137-00X CHINAMFG YV100X
KGB-M7181-00X 100XG
KGB-M7137-00X 100XG
KGT-M7181-00X YG200
KV7-M7176-00X BELT,N AXIS 88X/88XG
KV7-M9129-00X YV100X
KGT-M916T-0XX YG200
KGT-M913J-0XX YG200
KG7-M9129-00X YV100II
KV7-M9140-00X YAMAHA
KM0-M2267-20X CHINAMFG YV100-II CABLE DUCT
KV7-M2267-00X CHINAMFG YV100X CABLE DUCT
KV7-M221A-AOX COVER KUCT ASSY CHINAMFG YV100X
K46-M9174-10X, XIHU (WEST LAKE) DIS. (LWL9), YV100-2
KV7-M9166-00X, XIHU (WEST LAKE) DIS. (LWL9 R80B), YV100X
KM1-M9610-00X XIHU (WEST LAKE) DIS.
KV8-M71WC-00X (M4-50mm)
KV8-M71WF-00X (M4-75mm)
KV8-M71WG-00X (M4-70mm)
KM1-M4592-11X YAMAHAVAC SENSOR BOARD ASSY
YAMAHA O-RING
9571-22J015/KV8-M71Y5-00X PACKING(MYA-12)
9571-22J002/KM1-M7141-0X PACKING(MYA-10a)
9571-22J003/KM1-M7140-00X PACKING(MYA-6)
9571-22J006 KM1-M7107-00X PACKING(L57165)
9571-22J001/KG2-M7181-00X PACKING(MYA-4)
95710-01J125 O-RING K65-M257M-00X
9571-17J013 O-RING
9571-171J003 O-RING
9571-171J008 O-RING K46-M8527-D0X
9571-171J571 O-RING
9571-171J0007 O-RING/ KM1-M7186-00X
YAMAHA MOTOR
90K55-87134X AC SERVO MOTOR YV100II
90K55-8A134Y AC SERVO MOTOR YV100II
90K55-4W032W AC SERVO MOTOR YV100II
90K55-4W035R AC SERVO MOTOR YV100II
90K55-4W034Z AC SERVO MOTOR YV100II
90K52-87174X AC SERVO MOTOR YV100X
90K52-8A174Y AC SERVO MOTOR YV100X
90K50-4W072W AC SERVO MOTOR YV100X
90K50-4W074R AC SERVO MOTOR YV100X
90K55-4W074R AC SERVO MOTOR YV100X
90K50-4W074Z AC SERVO MOTOR YV100X
90K55-4W074Z AC SERVO MOTOR YV100X
KM0-M666J-00X100II
KM1-M665H-00X100II
KV8-M665U-00X100X
KV8-M666H-00X100X
YAMAHA CAMERA
KV7-M7210-00X CCD CAMERA YV100X MOVE CAM
KGA-M7210-00X CCD CAMERA YV100XG MOVE CAM
KG9-M7210-10X CCD CAMERA YV100II MOVE CAM
KV8-M7310-00X L CAMERA ASSYYV100II
KG9-M7210-10X CCD CAMERA YV100II SINGLE CAM
KV8-M73A0-30X MULTI CAM.SUB ASSY YV100X
KV8-M7310-00X L CAMERA ASSYYAMAHA CCD
KV8-M73A0-30X MULTI CAM.SUB ASSYYAMAHA CCD
KV7-M7600-00XFIDUCIAL LIGHT ASSYYAMAHA
KV7-M66F6-00X C.cable assy 7.7M
KV7-M66F2-00X C.cable assy 7.7M
KV7-M66F4-00XC.cable assy 1.7M
YAMAHA SENSOR
KV7-M654F-00X SENSOR 3E2S-Q22
KV7-M654G-00X SENSOR 4 E2S-Q22B
KV7-M653F-A0X SENSOR 3E2S-Q22B
KV8-M653H-00X SENSOR 5 ASSY 1 E2S
KV8-M7160-00X SENSOR HEAD ASSY 7383
KGT-M654J-A0X SENSOR HEAD ASSY 7832
KGB-M653A-00X SENSOR HEAD ASSY 7383
KGB-M653F-10X SENSOR, 3 ASSY E2S-Q22B
KV7-M653A-00X SENSOR,1 ASSY 1 L=600 E2S-Q22B
KV7-M653E-00X SENSOR,2 ASSY 1 L=600 E2S-Q22B
KV7-M653A-20X SENSOR,1 ASSY 1 L=300 E2S-Q22B
KV7-M653E-10X SENSOR,2 ASSY 1 L=300 E2S-Q22B
KH2-M655E-00X SENSOR,1-2 E2S-Q22B
KV7-M653A-20X SENSOR 1 ASSY:L=300 E2S-Q22B
KM0-M655F-10X SENSOR,1-3 7232
KH4-M655F-20X SENSOR 1-3 2 7233
KU0-M655F-20X SENSOR,1-3 7234
KH5-M655A-02X FIBER
/* 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
Transport Package: | Carton |
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Specification: | 0.1MM |
Trademark: | YAMAHA |
Origin: | China&Japen |
Customization: |
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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.
How does the accuracy of a servo motor impact the precision of a system it operates in?
The accuracy of a servo motor has a significant impact on the precision of the system in which it operates. Here’s how the accuracy of a servo motor influences the precision of the system:
1. Positioning Control:
The accuracy of a servo motor directly affects the precision of positioning control in a system. A servo motor with high accuracy can accurately and consistently reach and maintain the desired position. This precision in positioning control is crucial in applications where precise movements, such as in robotics or manufacturing processes, are required. If the servo motor lacks accuracy, it may introduce position errors, leading to reduced precision in the system’s overall operation.
2. Repeatability:
Repeatability refers to the ability of a system to consistently achieve the same position or motion repeatedly. The accuracy of a servo motor plays a vital role in achieving high repeatability. A servo motor with high accuracy will consistently return to the same position when commanded to do so. This level of repeatability is essential in applications where consistent and precise movements are necessary, such as in assembly lines or pick-and-place operations. A lack of accuracy in the servo motor can result in variations in position from one cycle to another, reducing the overall precision of the system.
3. Error Compensation:
The accuracy of a servo motor is crucial for error compensation in a system. In many applications, external factors, such as variations in load or environmental conditions, can introduce errors in the system’s operation. An accurate servo motor can help compensate for these errors by precisely adjusting its position or motion based on feedback from sensors. This error compensation capability contributes to maintaining the precision of the system, as the servo motor can continuously adjust to minimize any deviations from the desired position or trajectory.
4. System Stability:
The accuracy of the servo motor also impacts the stability of the system. A servo motor with high accuracy can achieve stable movements and maintain control over the system’s dynamics. It can respond accurately to control signals, preventing overshoot, oscillations, or erratic behaviors that can degrade system precision. On the other hand, a servo motor with lower accuracy may introduce instability or erratic movements, compromising the overall precision of the system.
5. System Calibration and Calibration:
An accurate servo motor simplifies the calibration and fine-tuning process of a system. When a system requires calibration, an accurate servo motor provides a reliable reference point for adjustments. The precise and consistent movements of the servo motor make it easier to calibrate other components or subsystems in the system, ensuring that the entire system operates with the desired precision. If the servo motor lacks accuracy, it can be challenging to calibrate the system effectively, resulting in reduced precision in the system’s operation.
In summary, the accuracy of a servo motor has a direct impact on the precision of the system it operates in. An accurate servo motor enables precise positioning control, high repeatability, effective error compensation, system stability, and simplified calibration processes. These factors collectively contribute to achieving the desired precision in the system’s operation. Therefore, selecting a servo motor with the appropriate level of accuracy is crucial for ensuring the overall precision and performance of the system.
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 2024-01-15