Specification
Specification |
RTC-170HR |
RTC-200HR |
RTC-250HR |
RTC-320HR |
|||
Table Diameter | mm |
Ø170 | Ø200 | Ø250 | Ø320 | ||
Center Height(Vertical) | mm | 150 | 165 | 210 | 255 | ||
Table Surface Height(Horizontal) | mm | 180 | 185 | 220 | 240 | ||
Reference Hole Diameter | mm | Ø65H7 | Ø75H7 | Ø110H7 | Ø165H7 | ||
Through Hole Diameter | mm | Ø65H7 | Ø75H7 | Ø110H7 | Ø165H7 | ||
Table Width | mm | 12H7 | 12H7 | 12H7 | 14H7 | ||
Degree of Reference Channel Width | mm |
14h7 | 18h7 | 18h7 | 18h7 | ||
MIN. Increment | deg. |
0.001° | 0.001° | 0.001° | 0.001° | ||
Max. Rotation Speed (Motor 3000 min-1) Values are Determined by the Servo Motor |
|
rpm | 50 | 50 | 50 | 50 | |
Gear Ratio
|
1/60 | 1/60 | 1/60 | 1/60 | |||
Indexing Accuracy | arc-sec | 18 | 18 | 15 | 15 | ||
Repeatability Accuracy | arc-sec | 4 | 4 | 4 | 4 | ||
Servo Motor (Customer's choice) | FANUC | αiF 4 | αiF 4 | αiF 8 | αiF 12 | ||
|
MITSUBISHI | HG104S | HG104S | HG154S | HG204S | ||
|
SIEMENS | 1FK7060 | 1FK7060 | 1FK7063 | 1FK7083 | ||
|
YASKAWA | SGM7G-09A | SGM7G-09A | SGM7G-13A | SGM7G-30A | ||
Clamp System (Pneumatic / Hydraulic) | Kg/cm² | H | H | H | H | ||
Pneumatic / Hydraulic Pressure | Kg.m | 35 | 35 | 35 | 35 | ||
Pneumatic / Hydraulic Clamping Torque | Kg | 36 | 46 | 101 | 123 | ||
MAX. Allowable Load on the Table | Vertical |
|
Kg | 80 | 100 | 125 | 180 |
|
Vertical with Tailstock | Kg | 160 | 200 | 250 | 360 | |
|
Horizontal | Kg | 160 | 200 | 250 | 360 | |
MAX. Allowable Thrust Load on the Table (When clamped) | Allowable Axial Load | Kgf | 1300 | 1612 | 3819 | 5715 | |
|
MAX. Output Torque | Kgf.m | 30 | 54 | 103 | 152 | |
|
Allowable Bending Torque | Kgf.m | 61 | 97 | 226 | 363 | |
MAX. Allowable Moment of Inertia | Kgf.m² | 0.6 | 1.2 | 2 | 4.5 | ||
Net Weight(servo motor excluded) | Kg | 70 | 100 | 170 | 280 |
Feature
These features make Campower's four-axis cam rotary tables highly valuable machining equipment, capable of tackling challenges in processing various complex workpieces while ensuring high efficiency, precision, and reliability. This is particularly crucial for industries that require high-quality machining, such as aviation, automotive, and mold manufacturing.
Drive mode
Unlike the commonly used worm and gear mechanisms in the market, COMPOWER Precision Machinery employs roller cam mechanisms for both the fourth and fifth axes to drive the machine.
Roller cam mechanisms and worm and gear mechanisms are two different mechanical structures, and they differ in terms of stability, rigidity, and wear and tear:
|
Roller Cam Mechanism | Worm and Gear Mechanism |
Stability | Exhibits higher stability. The design of roller cams allows for smoother motion, reducing vibration and instability. |
Lower stability, with potential for vibration and uncertainty, especially under high loads or high-speed conditions. |
---|---|---|
Rigidity | Possesses higher rigidity, providing better resistance to external forces and torque. | Relatively softer, potentially experiencing some deformation when subjected to external forces. |
Wear and Tear | Lower wear and tear, capable of maintaining high precision over extended periods. | May experience wear and tear due to friction on contact surfaces, particularly during prolonged high-frequency use. |
Backlash | Typically achieves zero backlash, offering more accurate motion control. | May have some backlash, affecting precision and the accuracy of motion. |