• Guide Width: 60 mm

• Max Load: 40 kg

• Pitch: 95 mm

• Synchronous Wheel Spec: STD5M-19Z

• Recommended Speed: ≤ 2 m/s

• Customized Length: Up to 6 meters

• Input Torque: ≤ 8.5 N·m

• Belt Spec: PU-5M-20 (steel wire)

• Straightness: 0.05 / 300 mm

• Applicable Motors:

  • Stepper Motor: 57/86 (DC/Speed Reducer Set)

  • Servo Motor: 750W (Direct Connection); 200W/400W (DC/Speed Reducer Set)

• Suggested Length Adjustment: Effective stroke + 310 mm (increments of 50 mm, such as 1000 mm, 1050 mm, 1100 mm)

This summary highlights the key technical aspects of the Z60-40 linear motion module. If you require the full data sheet of the technical parameters, please contact us. 

Maximize Efficiency: 

Robotic arms mounted on linear guide rails are transforming industries with their precision, speed, and flexibility. Whether in manufacturing, automation, or material handling, this combination offers incredible benefits. In this short guide, we’ll explore the smartest ways to utilize this powerful technology to optimize your operations.

1. Precision Material Handling

A robotic arm mounted on a linear guide rail ensures smooth and precise movement along multiple axes. This makes it ideal for material handling tasks like sorting, stacking, and transporting components. With accurate positioning, you can improve throughput while reducing errors in the production line.

Tip: Use advanced sensors to enhance the robotic arm’s ability to pick and place items with higher accuracy, reducing the risk of misalignment or damage.

2. Automated Assembly

One of the most common uses for robotic arms mounted on linear guide rails is automated assembly. The robotic arm can move precisely along the rail to pick up parts and assemble them with minimal human intervention. This improves consistency and speeds up the production process.

Tip: For high-precision assembly, integrate vision systems to help the robotic arm correctly align and position components before assembly.

3. CNC Machining and Milling

Linear guide rails offer robust support for robotic arms in CNC machining applications. The arm’s ability to travel along the rail with high accuracy allows for precise movements in tasks like cutting, drilling, or milling materials like metal or plastic.

Tip: Enhance the system’s performance by choosing a high-quality linear guide rail that can withstand the heavy loads and vibrations typically associated with CNC machines.

4. 3D Printing

Robotic arms mounted on linear guide rails are also used in 3D printing systems, where they can move the extruder along the X, Y, and Z axes. This configuration ensures precise layer deposition for high-quality prints in applications ranging from prototypes to end-use parts.

Tip: For large-scale 3D printing, use a longer linear guide rail to increase the reach of the robotic arm and enable faster and more efficient printing.

5. Packaging and Palletizing

In packaging applications, robotic arms mounted on linear guide rails can efficiently move items along conveyors or pick and place products into boxes or onto pallets. Their ability to handle repetitive tasks with minimal error makes them perfect for high-speed packaging lines.

Tip: Combine the robotic arm with a conveyor system to automate packaging and palletizing, reducing labor costs and increasing throughput.

Conclusion:
Using a robotic arm mounted on a linear guide rail allows industries to streamline operations, improve accuracy, and increase efficiency. Whether for material handling, assembly, CNC machining, or packaging, this technology is a game-changer in modern automation. By integrating sensors, vision systems, and high-quality rails, you can optimize your operations and take your production line to the next level.

Stay ahead of the competition by implementing robotic arms on linear guide rails today!