TE Connectivity NEXT GENERATION GI CONNECTOR Series Crimp Contact, 22 AWG Min, 28 AWG Max
- RS Stock No.:
- 123-3909
- Mfr. Part No.:
- 5-1971794-1
- Brand:
- TE Connectivity
Bulk discount available
Subtotal (1 pack of 10 units)*
£2.80
(exc. VAT)
£3.40
(inc. VAT)
FREE delivery for orders over £60.00
Temporarily out of stock
- Shipping from 02 October 2026
Need more? Click ‘Check delivery dates’ to find extra stock and lead times.
Units | Per unit | Per Pack* |
|---|---|---|
| 10 - 240 | £0.28 | £2.80 |
| 250 - 490 | £0.213 | £2.13 |
| 500 - 990 | £0.182 | £1.82 |
| 1000 - 2490 | £0.151 | £1.51 |
| 2500 + | £0.137 | £1.37 |
*price indicative
- RS Stock No.:
- 123-3909
- Mfr. Part No.:
- 5-1971794-1
- Brand:
- TE Connectivity
Specifications
Technical Reference
Legislation and Compliance
Product Details
Find similar products by selecting one or more attributes.
Select all | Attribute | Value |
|---|---|---|
| Brand | TE Connectivity | |
| Product Type | Crimp Contact | |
| For Use With | Grace Inertia Connector 2.5 | |
| Current | 5A | |
| Series | NEXT GENERATION GI CONNECTOR | |
| Minimum Wire Size AWG | 22AWG | |
| Maximum Wire Size AWG | 28AWG | |
| Maximum Contact Resistance | 20mΩ | |
| Minimum Operating Temperature | -30°C | |
| Maximum Operating Temperature | 105°C | |
| Standards/Approvals | No | |
| Length | 13mm | |
| Select all | ||
|---|---|---|
Brand TE Connectivity | ||
Product Type Crimp Contact | ||
For Use With Grace Inertia Connector 2.5 | ||
Current 5A | ||
Series NEXT GENERATION GI CONNECTOR | ||
Minimum Wire Size AWG 22AWG | ||
Maximum Wire Size AWG 28AWG | ||
Maximum Contact Resistance 20mΩ | ||
Minimum Operating Temperature -30°C | ||
Maximum Operating Temperature 105°C | ||
Standards/Approvals No | ||
Length 13mm | ||
TE Connectivity Grace Inertia 2.5 Mark II TPA (Terminal Position Assurance)
TPA (Terminal Position Assurance) for use with Grace Inertia 2.5 Mark II TPA plug housings. The TPA ensures that the contacts are securely seated in the connector housing and help prevent contact back-out due to vibration shock or pulling forces.