| Image | Part Number | Description / PDF | Quantity | Rfq |
|---|---|---|---|---|
 |
Woodhead - Molex |
TOOL EXTRACTION |
209240 |
|
 |
Woodhead - Molex |
TOOL HAND EXTRACTION MINI-FIT JR |
3228 |
|
 |
Woodhead - Molex |
INSERTION TOOL ZQSFP+ 1X1 |
12 |
|
 |
Woodhead - Molex |
INSERTION TOOL FOR CONTACT |
0 |
|
 |
Woodhead - Molex |
PRESS-IN TOOL INSERTION |
21 |
|
 |
Woodhead - Molex |
EXTRACTION TOOL FOR MULTICAT |
45 |
|
 |
Woodhead - Molex |
PRESS IN TOOL 3PR X 10COLUMN BCP |
3 |
|
 |
Woodhead - Molex |
EXTRACT TOOL CTX280 TERM |
215 |
|
 |
Woodhead - Molex |
EXTRACTION TOOL, ML-XT |
1580 |
|
 |
Woodhead - Molex |
HAND TOOL SUPER SABRE SERIES |
410 |
|
 |
Woodhead - Molex |
TOOL HOLDER 72MM VHDM BACKPLANE |
1 |
|
 |
Woodhead - Molex |
TOOL EXTRACTOR .093 AND HCS-125 |
5 |
|
 |
Woodhead - Molex |
INSERT TOOL 4X8 IMPEL BP 1.9MM |
11 |
|
 |
Woodhead - Molex |
PRESS-IN TOOL LPH SIGNAL |
1 |
|
 |
Woodhead - Molex |
EXTRACTION TOOL FOR CP-6.5 |
1020 |
|
 |
Woodhead - Molex |
TANGLESS EXTRACTOR TOOL |
11 |
|
 |
Woodhead - Molex |
IMPACT 4X10 85OHM BP INSERT TOOL |
1 |
|
 |
Woodhead - Molex |
PRESS-IN TOOL LPH |
0 |
|
 |
Woodhead - Molex |
TERMINAL EXTRACT - MINI FIT TPA |
10295 |
|
 |
Woodhead - Molex |
STD VHDM 8X10 MALE PRESS |
1 |
|
Insertion/Extraction tools are precision mechanical devices designed to automate the installation (insertion) and removal (extraction) of components in industrial processes. These tools integrate with robotic systems, CNC machines, and manual workflows to enhance efficiency, accuracy, and safety. They play a critical role in sectors requiring high repeatability and minimal human intervention, such as electronics manufacturing, automotive assembly, and medical device production.
| Type | Functional Features | Application Examples |
|---|---|---|
| Manual Insertion Tools | Handheld devices with ergonomic design for controlled force application | Prototyping, small-scale electronics assembly |
| Pneumatic Extractors | Compressed air-driven mechanisms for rapid component removal | Automotive engine component disassembly |
| Electric Insertion Systems | Motorized linear/rotary actuators with torque control | PCB connector installation, battery pack assembly |
| Automated Robotic End-effectors | Multi-axis grippers with vision system integration | High-speed semiconductor packaging lines |
A typical system comprises: - Mechanical Frame: Aluminum/steel alloy housing for structural integrity - Actuation System: Servo motors/pneumatic cylinders for motion control - Sensing Array: Force-torque sensors and proximity detectors - Tool Interface: Quick-change couplers with ISO standard compliance - Control Module: PLC-based unit with programmable parameters
| Parameter | Importance | Typical Range |
|---|---|---|
| Insertion Force | Determines material compatibility and joint integrity | 5-500N |
| Positioning Accuracy | Ensures proper alignment in precision applications | 0.01-0.1mm |
| Cycle Life | Indicates durability for high-volume production | 1M-10M operations |
| Environmental Resistance | Defines operational suitability in harsh conditions | IP54-IP67 |
Primary Industries: - Electronics Manufacturing: IC socket insertion, heat sink installation - Medical Equipment: Surgical instrument sterilization tray handling - Automotive Production: Transmission component assembly - Aerospace: Composite panel fastening systems - Consumer Goods: Battery insertion in mobile devices
| Manufacturer | Key Product | Technical Highlights |
|---|---|---|
| Coval MecWeld | Electromagnetic Insertion Tool | Patented shock absorption, 0.02mm repeatability |
| Atlas Copco | QX Series Electric Extractor | Smart torque feedback, 300rpm max speed |
| OnRobot | MULTI Mount End-effector | Quick-swap modular design for collaborative robots |
Key Considerations: 1. Match insertion force requirements with material specifications 2. Verify compatibility with existing automation infrastructure 3. Evaluate environmental operating conditions (temperature, dust/water exposure) 4. Calculate total cost of ownership including maintenance intervals 5. Prioritize programmability for adaptive manufacturing needs
Future developments include: - Integration with AI-powered predictive maintenance systems - Adoption of digital twins for virtual process optimization - Miniaturization for micro-electronics assembly applications - Expansion of cobot-compatible tooling solutions - Increased adoption of energy-efficient piezoelectric actuators