DANAHER MOTION TG10K259-A00X3 46/TG10K259A00X34 6 servo stepper motor driver

DANAHER MOTION TG10K259-A00X3 46/TG10K259A00X34 6 servo stepper motor driver

TG10K259-A00X346 linear device, Movopart M100, ball screw drive, prism guide, 0.05 mm repeatability, non preloading, 3052 mm stroke, 3539 mm total length, single standard slider, 25 mm stroke per axis speed, single axis with keyway

TG10K259-A00X346 linear device, Movopart M100, ball screw drive, prism guide, 0.05 mm repeatability accuracy

No preload, stroke 3052 mm, total length 3539 mm, single standard slider, each axis speed 25 mm, single axis with keyway

Product overview

DANAHER MOTION TG10K259-A00X3 46/TG10K259A00X34 6 servo stepper motor driver is a key device under DANAHER MOTION, specially designed for high-precision motion control scenarios. It integrates advanced electronic technology and precise control algorithms, playing an important role in industrial automation, intelligent manufacturing, and other fields. It can provide precise, stable, and efficient power drive control for various mechanical equipment.

Working principle

Pulse signal reception and processing: This driver works like a sharp "signal receiver", mainly by receiving pulse signals sent by external controllers. When these pulse signals arrive at the driver, the driver will precisely regulate the operation of the motor based on the number, frequency, and direction of the signals. For example, in an automated production line, the controller sends corresponding pulse signals to the driver based on the processing requirements of the product. The driver accurately interprets these signals and then commands the motor to make precise actions. If the motor needs to rotate a specific angle, the controller sends a corresponding number of pulses; To change the direction of motor rotation, it is achieved by changing the direction of the pulse signal.

Current and voltage conversion output: After receiving the pulse signal, the driver quickly converts it into current and voltage signals suitable for motor operation. This process is similar to a precise 'energy conversion station', carefully adjusting the output current and voltage based on the characteristics and operational requirements of the motor. Different types of motors have specific requirements for current and voltage, and this driver can intelligently adapt to ensure that the motor can obtain the appropriate power supply under various working conditions, and operate stably and efficiently.

Performance characteristics

High precision control: In terms of precision control, this driver performs excellently. It can control the positioning accuracy of the motor within a very small range, achieving micrometer level accuracy. In semiconductor manufacturing equipment, the machining accuracy of components is extremely high. With its high-precision control performance, this driver can accurately control the motor movement, ensuring that the equipment achieves precise characterization of chip patterns in processes such as photolithography and etching, and guaranteeing the manufacturing quality of semiconductor chips. This is thanks to its advanced subdivision technology, which can further subdivide the step angle of the motor, making the motor run more smoothly and the positioning more accurate.

Rapid response capability: It has excellent rapid response characteristics. When the external control signal changes, it can react in a very short time and quickly adjust the operating state of the motor. On an automated assembly line, the robotic arm needs to quickly and accurately grasp and place components. The driver can respond to control instructions in a timely manner, allowing the motor to quickly start, stop, or change speed, greatly improving assembly efficiency and reducing production cycles. Its rapid response mechanism is based on optimized circuit design and efficient control algorithms, which can quickly process signals and drive motors to perform actions.

Multiple control modes: To adapt to diverse application scenarios, a rich variety of control modes are provided. Common modes include position control mode, speed control mode, and torque control mode. In CNC machine tools, when machining parts, if precise control of the tool position is required, position control mode can be used; In the material conveying process, if the conveyor belt needs to run at a constant speed, the speed control mode can play a role; In some applications that require overcoming significant resistance, such as driving large machinery, torque control mode can ensure that the motor outputs sufficient torque. Users can flexibly switch control modes according to their actual needs, making the equipment run more in line with production requirements.

High reliability and stability: Reliability and stability factors are fully considered in the design and manufacturing process. High quality electronic components are used, and after strict quality testing and aging testing, they can operate stably in complex industrial environments. It can work normally in harsh environments with high temperature and humidity, as well as in places with strong electromagnetic interference, effectively reducing equipment failure rates and minimizing production interruption losses caused by equipment failures for enterprises. The internal circuit design has good anti-interference ability, which can shield external interference signals and ensure the stable operation of the driver and motor.