The KK linear module, also known as an industrial robot, is essentially an automated moving device driven by a motor. Its core structure consists of a ball screw and a U-shaped linear guide, ingeniously integrating the ball screw nut and the guide slider into one unit. By combining the smooth guiding performance of the Linear Guide Rail with the efficient transmission advantages of precision ball screw, and matching with the optimized U-shaped rail design, it not only greatly saves installation space but also significantly shortens the assembly time, stably achieving high-precision and high-rigidity operation requirements. The linear motion module adopts a design with two rows of Gothic arcs and a 45° contact angle on the ball rolling surface, which can effectively withstand loads from four directions and is suitable for multi-dimensional coordinated operations on the X, Y, and Z axes.
Ⅰ. Core Product Advantages
•Convenient Installation: With a rational structural design, the installation process is simple and quick.
•Compact and Lightweight: Occupies less space, this precision linear module is easy to integrate, and reduces the overall weight of the equipment.
•Excellent Performance: High operation accuracy and rigidity ensure the work stability of the Linear Modules. •Complete Configuration: Our linear motion modules provide a wide range of supporting components.
•Optimized Design: Meets diverse industrial application requirements.
Ⅱ. Model Selection Guide
1. Consider the Usage Scenario
Stroke Parameters: Determine the effective movement distance.
Space Constraints: Take into account the length, width, and height dimensional constraints of the installation environment.
Installation Methods: Supports various installation forms such as horizontal, vertical, and side-mounted.
Load Characteristics: Clarify the position and weight of the load center of gravity.
Operation Requirements: Plan the lead, running speed, acceleration and deceleration time, and duty cycle.
Environmental Factors: Adapt to special working conditions such as high temperature, vibration, humidity, and corrosion.
2. Define Accuracy Requirements
Positioning Accuracy: Ensure the accuracy of moving to the specified position.
Repeatability Accuracy: Consistent performance in multiple operations.
Motion Parallelism: Requirements for the straightness of the running track.
3. Determine the Application Form
Single-Axis Operation: Meets the movement requirements in a single direction.
Multi-Axis Combination: Two or more axes are interlocked/coordinated to achieve complex movements.
Customized Solutions: Modular combination design according to special requirements.
4. Select the Suitable Drive Motor
Motor Types: Options include AC servo motors and stepper motors.
Braking Function: Built-in or external braking devices.
5. Calculate the Motor Load
Speed Parameters: Meet the maximum running speed requirements of the equipment.
Resolution Setting: Ensure positioning control accuracy.
Torque Calculation: Ensure sufficient driving torque of the motor.
6. Analyze the Operation Status
Acceleration and Deceleration Performance: Evaluate the smoothness of the acceleration and deceleration processes.
Motion Curve: Draw the velocity-time (V-T) operation curve.
7. Select Optional Auxiliary Components
Limit Devices: Limit switches ensure operational safety.
Adapter Components: Adapters connect the module to the equipment.
Protective Components: Telescopic protective sleeves and cable protection tubes enhance protection.
8. Finalize the Plan
Condition Review: Reconfirm the degree of matching between usage requirements and the selected model.
Business Communication: Understand the price and delivery cycle.
Customization Requirements: Special processing and customized functions.
Ⅲ. Typical Application Areas
Widely used in automated inspection equipment, dispensing equipment, surface mount production lines, industrial robotic arms, chip die bonders, flip-chip equipment, automatic drilling machines, etc. At the same time, according to specific customer needs, it can be flexibly combined into an X-Y motion platform to meet diverse industrial production scenarios.
