| Image | Part Number | Description / PDF | Quantity | Rfq |
|---|---|---|---|---|
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Wiha |
PUNCH PIN TAPER 1MM X 120MM |
0 |
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Wiha |
PUNCH PIN TAPER 14MM X 175MM |
0 |
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Wiha |
PUNCH CENTER 3PC SET 4,5 & 6MM |
0 |
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Wiha |
PUNCH PIN TAPER 8PC SET 1MM-8MM |
0 |
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Wiha |
PUNCH PIN TAPER 6MM X 120MM |
0 |
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Wiha |
PUNCH CENTER TAPER 5MM X 120MM |
0 |
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Wiha |
PUNCH PIN 15PC 3MM-20MM IN/POUCH |
0 |
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Wiha |
PUNCH PIN TAPER 14PC SET 1-18MM |
0 |
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Wiha |
PUNCH CENTER TAPER 6MM X 150MM |
0 |
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Wiha |
PUNCH PIN TAPER 9MM X 150MM |
0 |
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Wiha |
PUNCH PIN TAPER 18MM X 200MM |
0 |
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Wiha |
PUNCH PIN TAPER 7MM X 150MM |
0 |
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Wiha |
PUNCH PIN TAPER 3MM X 120MM |
0 |
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Wiha |
PUNCH PIN TAPER 8MM X 150MM |
0 |
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Wiha |
PUNCH CENTER TAPER 5MM X 150MM |
0 |
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Wiha |
PUNCH PIN TAPER 12MM X 150MM |
0 |
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Wiha |
PUNCH PIN TAPER 4MM X 120MM |
0 |
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Wiha |
PUNCH CENTER TAPER 4MM X 120MM |
0 |
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Wiha |
PUNCH PIN TAPER 10MM X 150MM |
0 |
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Wiha |
PUNCH PIN TAPER 16MM X 175MM |
0 |
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ToolsPunches refer to a category of industrial equipment designed for material perforation, forming, or cutting through mechanical force. These tools utilize specialized punch and die sets to create precise holes, shapes, or structural modifications in various materials. As fundamental components in manufacturing and fabrication processes, they enable high-precision, repeatable operations critical to modern industrial production. Their importance spans across sectors requiring mass production capabilities, tight tolerances, and material efficiency optimization.
| Type | Functional Characteristics | Application Examples |
|---|---|---|
| Mechanical Presses | High-speed operation with fixed stroke length, electric motor-driven | Automotive sheet metal forming |
| Hydraulic Presses | Variable pressure control, deep drawing capabilities | Aerospace composite molding |
| Pneumatic Punches | Lightweight, rapid cycle times, adjustable force | Electronics component assembly |
| Laser Punch Combinations | Non-contact precision cutting with hybrid mechanical support | Medical device manufacturing |
Typical construction includes: - Frame: Cast iron/steel structure for vibration damping - Punch Assembly: Hardened tool steel with carbide coatings - Die Set: CNC-machined counter-forming component - Drive System: Servo motors/hydraulic cylinders/pneumatic actuators - Control Unit: PLC-based interface with safety interlocks - Material Handling System: Automated feeders/sensors Advanced models integrate IoT sensors for real-time force monitoring and predictive maintenance.
| Parameter | Importance |
|---|---|
| Punching Force (kN) | Determines material thickness capacity |
| Stroke Length (mm) | Defines working range and material clearance |
| Positioning Accuracy ( m) | Impacts production quality consistency |
| Cycle Rate (SPM) | Directly affects production throughput |
| Energy Consumption (kW/ton) | Operational cost efficiency indicator |
Primary industries include: - Automotive: Body panel perforation, frame forming - Electronics: PCB component mounting holes - Aerospace: Titanium alloy structural components - Renewables: Solar panel mounting bracket fabrication - Medical: Surgical instrument precision shaping
| Manufacturer | Representative Product | Key Features |
|---|---|---|
| Amada | HG Series Hydraulic Press | AI-driven pressure optimization |
| TRUMPF | Turbulaser Punch-Laser System | Combined 3D cutting/forming |
| Bystronic | Xpert Punch Series | Modular tooling system |
| Murata Machinery | LASERValkyrie Multi-axis | Hybrid metal processing |
Key consideration factors: - Material properties (thickness, hardness, ductility) - Production volume requirements - Precision vs. speed trade-offs - Integration with existing automation systems - Maintenance accessibility and tooling costs For example, a 2000kN mechanical press suits high-volume automotive parts, while a 30kN pneumatic punch better serves electronics batch production.
Current development directions: - Smart Manufacturing: AI-powered process optimization - Energy Efficiency: Hybrid servo-hydraulic systems reducing energy use by 40% - Multi-axis Flexibility: 6-degree-of-freedom robotic integration - Material Adaptation: Graphene-coated tooling extending die life - Remote Monitoring: Predictive maintenance via cloud analytics Market growth projected at 6.2% CAGR through 2030, driven by electric vehicle component demand.