161 |
Circuit interrupter |
US12042726 |
1926-07-03 |
US1699769A |
1929-01-22 |
DAYTON ULREY; CRICHTON LESLIE N |
|
162 |
Electrical cut-out |
US57457322 |
1922-07-12 |
US1678187A |
1928-07-24 |
HENRY ILLINGWORTH WILLIAM |
|
163 |
Fuse |
US2790925 |
1925-05-04 |
US1624322A |
1927-04-12 |
ENGLEMAN CHARLES W |
|
164 |
Protective device for electric circuits |
US53788022 |
1922-02-20 |
US1556134A |
1925-10-06 |
STOEKLE ERWIN R |
|
165 |
Fuse |
US55471422 |
1922-04-18 |
US1531756A |
1925-03-31 |
ROACH LESLIE F; WOLFE MICHAEL F |
|
166 |
Electrical cut-out |
US41491320 |
1920-10-05 |
US1490925A |
1924-04-22 |
HENRY ILLINGWORTH WILLIAM |
|
167 |
Thermally-controlled circuit interrupter |
US46815821 |
1921-05-09 |
US1488952A |
1924-04-01 |
STOEKLE ERWIN R |
|
168 |
Electrical circuit breaker |
US41983420 |
1920-10-27 |
US1488392A |
1924-03-25 |
HENRY ILLINGWORTH WILLIAM |
|
169 |
Thermostat |
US1466070D |
|
US1466070A |
1923-08-28 |
|
|
170 |
Circuit-protective device. |
US17974017 |
1917-07-10 |
US1272090A |
1918-07-09 |
PYLE WILLIAM D |
|
171 |
Circuit-breaker. |
US5894715 |
1915-11-01 |
US1228408A |
1917-06-05 |
CLEAVER FREMONT J |
|
172 |
Electrical protective device. |
US1905240320 |
1905-01-09 |
US838066A |
1906-12-11 |
WHITE CHARLES E |
|
173 |
Device for controlling electrical circuits. |
US1904200130 |
1904-03-26 |
US823295A |
1906-06-12 |
SCHWEITZER EDMUND O |
|
174 |
Mercury safety attachment for electric circuits. |
US1901087867 |
1901-12-31 |
US736127A |
1903-08-11 |
MIES EDUARD |
|
175 |
Stephen dudley field |
US432521D |
|
US432521A |
1890-07-22 |
|
|
176 |
Thermal cut-out |
US310472D |
|
US310472A |
1885-01-06 |
|
|
177 |
PROCEDE DE FERMETURE DE CIRCUIT D'ALIMENTATION ELECTRIQUE D'APPAREIL ELECTRIQUE PLACE DANS UNE CHAMBRE A PRESSION VARIABLE CONTROLEE ET DISPOSITIF ASSOCIE |
EP15726031.6 |
2015-05-18 |
EP3146552A1 |
2017-03-29 |
LINES, Jean-François; CHARGY, Jérémy |
The invention relates to a method for closing an electrical power supply circuit of an electric apparatus (A) located in a chamber (EV) at a controlled variable pressure, characterised in that the electrical power supply circuit comprises an open circuit located in an enclosure which is open to the pressure from the chamber (6) and defined between two electrically conductive terminals of the electrical power supply circuit, the method comprising: heating which provides energy to an element made of electrically conductive material (3) and located in the enclosure (6) which is open to the pressure from the chamber; subliming the element made of electrically conductive material once the element reaches a given temperature, if the pressure conditions in the chamber correspond to the conditions required for operating the electric apparatus in a vacuum; removing vapour particles resulting from the sublimation from the electrically conductive material, and forming a deposit of electrically conductive material between the two electrically conductive terminals, after the vapour particles have been removed. |
178 |
SELF-RECOVERY CURRENT LIMITING FUSE USING DIELECTROPHORETIC FORCE |
EP05770830.7 |
2005-08-10 |
EP1786011B1 |
2008-11-12 |
OHTSUKA, Shinya,
KYUSHU KOGYO DAIGAKU; HIKITA, Masayuki,
KYUSHU KOGYO DAIGAKU |
A self-recovery current limiting fuse protecting a secondary battery having a high rated voltage thanks to its improved breakdown voltage, expanding the application range, shortening the charging time, and realizing maintenance-free. The self-recovery current limiting fuse (1) is made by fluid-dispersing solid conductive particles (3) into a liquid matrix (2) between electrodes (4). A current limiting operation through evaporation/spreading of the solid conductive particles (3) and a conducting state brought about through collection of the solid conductive particles (3) between the electrodes (4) by dielectrophoretic force of the solid conductive particles (3) are realized repeatedly, and a current limiting operation through evaporation/spreading of the solid conductive particles (3) by overcurrent is realized. |
179 |
SELF-RECOVERY CURRENT LIMITING FUSE USING DIELECTROPHORETIC FORCE |
EP05770830 |
2005-08-10 |
EP1786011A4 |
2007-09-05 |
OHTSUKA SHINYA; HIKITA MASAYUKI |
A self-recovery current limiting fuse protecting a secondary battery having a high rated voltage thanks to its improved breakdown voltage, expanding the application range, shortening the charging time, and realizing maintenance-free. The self-recovery current limiting fuse (1) is made by fluid-dispersing solid conductive particles (3) into a liquid matrix (2) between electrodes (4). A current limiting operation through evaporation/spreading of the solid conductive particles (3) and a conducting state brought about through collection of the solid conductive particles (3) between the electrodes (4) by dielectrophoretic force of the solid conductive particles (3) are realized repeatedly, and a current limiting operation through evaporation/spreading of the solid conductive particles (3) by overcurrent is realized. |
180 |
System zur Strombegrenzung |
EP01113783.3 |
2001-06-06 |
EP1164617B1 |
2007-02-28 |
Borchmann, Oliver; Berger, Frank Dr.; Krätzschmar, Andreas; Terhoeven, Peter Dr.-Ing.; Daube, Thomas Dr. |
|