1. Low voltage contact resistance
The supply voltage and current will not change the size of the physical contact surface and the oxide and film of the contact surface to evaluate the contact resistance of the contact system. The test is that the larger current is 100mA and the larger open circuit voltage is 20mV.
2. Insulation resistance
When the DC potential is supplied between adjacent contact points or between the metals closest to the contact point, the resistance of the insulating substance is detected.
3. Withstand voltage
When the system voltage suddenly increases or the instantaneous excess potential is generated due to switching, the connector can maintain the voltage that it can bear when it is safe and undamaged.
4. Positive force
The contact system is under normal use conditions, the contact point bears the pressure perpendicular to the contact surface, and the working point of the pogo pin connector exceeds 60gf.
5. Durability
Because the contact surface will wear out during plugging and unplugging, this wear will reduce the mechanical and electrical performance of the connector. Under the set environment, the connector plugging and unplugging is a cycle. The minimum plugging and unplugging that can be undertaken with the pogo pin connector The number of cycles is used to evaluate the durability of the connector, and the plug-in cycle rate that the pogo pin connector can bear can reach tens of thousands of times.
6. Vibration
Evaluate the influence of small changes on the contact surface caused by the action of mechanical force on the electrical characteristics of the contact system. Pogo pin connector 15 minutes 10~500HZ vibration frequency, 1.2mm amplitude, power failure will not exceed 1μsec, contact impedance <100mOhm.
7. Mechanical shock
Detect the mechanical and electrical integrity of the connector. When the connector device acts on an electronic device, it may be subjected to vibration during handling and transportation.
8. Hot and cold shock
Detect the resistance when pogo pin connector is exposed to extremely high temperature and low temperature, or the worst-case shock during storage, transportation and use.
9. Temperature life
When exposed to a high temperature environment where the mechanical properties fail due to temperature changes, evaluate the impact of this environment on electrical stability. High temperature will cause contact oxidation and reduce the positive force of the terminal, which will reduce the electrical performance.