Technical Data Sheet of the Double Lathe Positioner RRRobotica TRN/300 with Three Controlled Axes

Brand: RRRobotica
Model: TRN/300
Type: Double Lathe Positioner with Three Controlled Axes
Condition: Used
Price: On request

1. General Description

The RRRobotica TRN/300 double lathe positioner is a highly specialized device designed for automation and precision in the positioning of work pieces during turning operations. This model is equipped with three controlled axes, allowing complex movements and precise manipulation of work pieces. It is ideal for applications in high-precision industrial and manufacturing environments.

2. Main Components

• Structure and Base: Built with a solid and resistant base, typically made of steel to ensure stability and reduce vibrations. The structure is designed to support heavy loads and maintain accuracy during operation.
• Controlled Axes: Three controlled axes allow precise movements of the piece. These axes are usually motorized and equipped with sensors to control position and speed.
  • X axis: Horizontal movement along the longitudinal axis.
  • Y axis: Vertical or lateral movement.
  • Z axis: Movement towards or away from the piece.
• Positioning Stations: Two independent stations for positioning the pieces. Each station has a load capacity of up to 300 kg.
• Control System: An electronic control unit manages the axis movements and positioning operations. Includes software for scheduling and monitoring operations.

3. Technical Characteristics

• Uncle between the Tips: 1500 mm
• Maximum capacity per station: 300 kg
• Controlled Axes: Three controlled axes (X, Y, Z)
• Dimensions and Weight: Detailed dimensions and weight specifications should be checked with the supplier or the user manual. The machine is designed to be robust and suitable for heavy loads.
• Precision: The machine offers high precision in movements and positioning thanks to advanced control systems.

4. Formulas and Parameters of Optimal Use

• Load Capacity (C): Determined by the structural resistance and the axle motors. The optimal load capacity must be respected to avoid damage to the machine.

• Positioning Accuracy (P): Can be calculated based on the resolution of the control system. General formula:
  P=DNP = \frac{D}{N}
  $P$ $=$ N D ​Where

  • DD $D$ = Total distance traveled by the axis in mm
  • NN $N$ = Number of position increments

• Movement Speed ​​(v): The movement speed of the axes must be adjusted according to the material and type of operation. Formula for linear velocity:
  v=DTv = \frac{D}{T}
  $v$ $=$ T D ​Where

  • DD $D$ = Distance traveled in mm
  • TT $T$ = Time taken in seconds

5. Workable Materials

The positioner can be used with a wide range of materials, provided they are compatible with the load capacities and specifications of the machine. Common materials include:

• Metals: Steel, aluminium, brass, copper.
• Plastics: Various types of plastics, including thermoplastics and thermosets.
• Composites: Fiber-reinforced composite materials, such as CFRP (Carbon Fiber Reinforced Plastic).

6. Maintenance

• Lubrication: Regularly check lubrication points and apply lubricant to ensure smooth operation of axles and moving components.
• Cleaning: Clean the machine regularly to remove dust and debris. Contaminants can affect accuracy and function.
• Component Inspection: Check cables, motors and sensors for any signs of wear or malfunction. Make repairs or replacements if necessary.
• Calibration: Perform periodic calibration of the axes to maintain the precision of the movements.

7. Verification of used cars

• Functionality: Test the positioner to ensure that all three axes are operational and that the control system is functioning properly.
• Condition of Components: Inspect the frame and components for signs of wear or damage. Check the status of the motors and sensors.
• Documentation: Check the availability and completeness of the use and maintenance manual. This document is essential for correct operation and maintenance of the machine.

8. Sectors of Use

• Manufacturing Industry: Used for precision machining and positioning of work pieces in lathes and other machine tools.
• Automotive Sector: Used for the processing of automotive components that require high precision.
• Aerospace Sector: For the production of aeronautical parts and components that require high precision and reliability.

9. Why Buy Used

• Lower Cost: Purchasing a used positioner allows you to get a high quality machine at a lower cost than a new one.
• Reliability: Used positioners, if well maintained, can continue to provide excellent performance and durability.
• Immediate Availability: Purchasing a used machine can reduce waiting times and ensure immediate availability.

Note: For further details and to arrange a viewing or test drive of the machine, please contact the seller.