Author_Institution :
Dept. of Adv. Technol. & Anal., Square D Co., Cedar Rapids, IA, USA
Abstract :
In most existing low current interruption devices, the current is interrupted using only separating contacts. By adding a ceramic PTC (CPTC) element in parallel with the contacts, 100% of the interruption energy can be converted to heat, eliminating the arc totally. The initial voltage across the contacts must be less than a pre-determined value in order to commutate all of the current to the CPTC. The cold resistance of the CPTC is the main factor in determining the initial voltage across the contacts and the current at which the CPTC trips. Two types of ceramic PTC devices were tested, with cold resistances of 16 and 32 Ω, respectively. In the case of each device, at 300 Vdc and 1.0 A, all of the interruption energy was consumed by the CPTC, At 300 Vdc and 1.5 A, the 16 Ω CPTC successfully absorbed 100% of the interruption energy; however, the 32 Ω CPTC device had a slightly lower performance at 98%. Because of the elimination of arcing, use of the CPTC in low current interruption devices, will result in reduced contact size and increased operation cycles, it will also provide an arcless interruption for application in hazardous conditions
Keywords :
circuit breakers; conducting polymers; contactors; electrical contacts; relays; 1.0 A; 1.5 A; 16 ohm; 300 V; 32 ohm; arcless interruptions; ceramic PTC element; cold resistance; contact size; hazardous conditions; initial voltage; interruption devices; low current power circuits; operation cycles; separating contacts; Ceramics; Conducting materials; Contact resistance; Interrupters; Polymers; Solid state circuits; Superconducting materials; Switches; Temperature; Voltage;
