Injection compression modeling of non-linear positive temperature coefficient circuit protection devices

摘要

Polymeric self-resettable circuit protection devices have been manufactured for many years with an extrusion based process. These devices add negligible resistance to a circuit at normal power operating conditions but increases in resistance by several orders of magnitude at a pre-determined level of power in order to protect the circuit from over- current or over-voltage conditions. After the electrical surge stops, and power returns to a normal level, the resistance of the device drops, and the circuit may resume its normal operation. These devices are used in computers, cell-phones, and other consumer and industrial electronic devices where normal fuses are not convenient or practical. The current manufacturing process extrudes long sheets of 2-mm thick polymer lined with 0.05-mm thick foil on both sides. This foil-polymer-foil structure, called plaque, is punched into 13 mm x 8 mm x 2 mm rectangles, called chips. The chips undergo heat treatment and radioactive cross-linking steps before wire leads are soldered onto them for easy electrical connection to either test or circuit boards. Though effective, this process produces more waste and remains less flexible than an injection-compression (IC) molding process. With this new process, devices are made individually in a multi- cavity mold, skipping the punching and soldering steps. This thesis explores IC molding and its benefits and drawbacks for manufacturing circuit protection devices. IC molded devices were manufactured, tested, and compared to standard devices, produced by the extrusion process, in the areas of physical and electrical performance.