| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 121 | MEMS device having contact and standoff bumps and related methods | US10291107 | 2002-11-08 | US20030116417A1 | 2003-06-26 | Dana Richard DeReus |
| MEMS Device Having Contact and Standoff Bumps and Related Methods. According to one embodiment, a movable MEMS component suspended over a substrate is provided. The component can include a structural layer having a movable electrode separated from a substrate by a gap. The component can also include at least one standoff bump attached to the structural layer and extending into the gap for preventing contact of the movable electrode with conductive material when the component moves. | ||||||
| 122 | Fuse wire switch | US293623 | 1989-01-05 | US4906962A | 1990-03-06 | Frederick A. Duimstra |
| A spring powered switching mechanism in which the energy required to complete switching is stored in a spring (or springs) which are constrained in a "cocked" or stressed condition by a fuse wire. The fuse wire has the characteristic of having a relative flat coefficient of resistivity over a large temperature range. The mechanism is operative to close (or open) electrical circuits permanently upon receipt of the appropriate electrical signal to the "fuse" or "bridge" wire which is caused to break as a result of the receipt of the electrical signal. | ||||||
| 123 | Reticulated electrothermal fluid motor | US558503 | 1983-12-06 | US4583365A | 1986-04-22 | Frank T. John |
| A new electrothermal fluid motor connected to an electrically controlled energy source for uniformly heating a unique reticulated heat exchanger, which together with an expansion fluid fills a chamber, having a mechanical energy output consisting of a jet flow or a change of force, pressure, or motion, has achieved elimination of internal convection and consequent start-up wall losses found in prior art devices, resulting in improved efficiency and response-time reduction. Typically, the heat exchanger has millions of heating elements, interconnected in a network of distorted dodecahedron cells, each with thirty shared heating elements of triangular cross-section, giving a shock resistance of thousands of g's and thousands of degrees centigrade, a void space of about 97%, and an average thermal diffusion distance of about 100 microns. The preferred energy source is electrical resistance heating, but induction, electrostatic, or radiation-absorption heating may be used. For high power applications, a change-of-state liquid is preferred. For example, DuPont Freon 12 will produce a 160% volume change at constant pressure of 0.7 MPa (100 p.s.i.) for a 30.degree. C. temperature change. An example of the invention is a linear differential servomotor with two reticulated electrothermal motors connected to a common output shaft in expansion opposition. The ambient temperature effect cancels, with the output force, velocity, and direction being proportional to the sum of the input energies to the respective motors. Other applications of the inventive principles include hot jet gas emitters, stepping motors, latches, power jacks, printers, acoustical signalling devices, and pistons. | ||||||
| 124 | Method of forming elements of insulating material on a bimetal strip | US676516 | 1976-04-13 | US4069289A | 1978-01-17 | Fritz Krasser; William F. Sell |
| A method of moulding an element of an insulating material, such as a thermosetting plastics material, on a bimetal strip in which the bimetal strip is clamped in an injection mould by narrow clamping jaws disposed on either side of the mould cavity in the longitudinal direction of the bimetal strip. The width of the clamping jaws is such as to enable the remaining portions of bimetal strip to bow freely in response to heat present in the injection mould.The bimetal strips may be processed individually or as a group formed from a blank, the individual bimetal strips in the group being transversely joined to each other. | ||||||
| 125 | Meter relay using photoelectric relay elements controlled by an annular shutter mounted on the meter movement assembly | US36642664 | 1964-05-11 | US3329825A | 1967-07-04 | ENRIGHT JOHN A |
| 126 | Electric relay | US66323757 | 1957-06-03 | US2860209A | 1958-11-11 | HADLEY LESTER J |
| 127 | Electrical control devices | US32290552 | 1952-11-28 | US2809253A | 1957-10-08 | BROEKHUYSEN WILLIAM C |
| 128 | BLADE-TYPE FUSE | EP12839267.7 | 2012-10-12 | EP2768007B1 | 2016-04-27 | KAWAMOTO Arata; NOMURA Syoichi; SHIMOCHI Eiji; NAKAMURA Goro |
| 129 | Thermal trip device of a thermal magnetic circuit breaker having a resistor element, thermal magnetic circuit breaker and switching device for interrupting a current flow and method for protecting an electrical circuit from damage | EP14157175.2 | 2014-02-28 | EP2913836A1 | 2015-09-02 | Flores Silguero, Carlos |
The present invention is directed to a thermal magnetic circuit breaker for protecting an electrical circuit from damage by overload, a thermal trip device and a switching device of the thermal magnetic circuit breaker and a method for protecting an electrical circuit from damage, wherein an electric conductive bimetal element 1 is arranged with its first end 1.1 next to a current conductive element 3 for conducting electrical current and with its second end 1.2 next to a tripping element 20 adapted to trigger an interruption of a current flow. A resistor element 2 is arranged between the bimetal element and the current conductive element in order to redirect the electrical current at least partially via the bimetal element, when an overload occurs. The resistor may be a negative temperature coefficient (NTC) thermistor.
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| 130 | BLADE-TYPE FUSE | EP12839267 | 2012-10-12 | EP2768007A4 | 2015-08-05 | KAWAMOTO ARATA; NOMURA SYOICHI; SHIMOCHI EIJI; NAKAMURA GORO |
| 131 | TEMPERATURSCHALTER SOWIE VERFAHREN ZUR JUSTIERUNG EINES TEMPERATURSCHALTERS | EP13750274.6 | 2013-07-30 | EP2880670A1 | 2015-06-10 | Reiter, Werner; Soukup, Peter Klaus; Reithofer, Josef |
| The invention relates to a temperature switch comprising a housing (2), a switching system (3) consisting of a first support (3.1) with a fixed contact (3.2) and a second support (3.3) on which a switch spring (3.4) with a switch contact (3.5) is disposed, and of a switch arrangement (4) which, depending on the temperature, effects a change in the position of the switch contact (3.5). | ||||||
| 132 | HYDROGEN PRODUCING FUEL CARTRIDGE AND METHODS FOR PRODUCING HYDROGEN | EP13764321.9 | 2013-03-11 | EP2827977A1 | 2015-01-28 | HOOD, Peter; WINAND, Henri |
| In aspects of the disclosure, a fuel cartridge wherein the fuel is in a powdered form is admixed with inert materials such as alumina or other ceramics to improve thermal conductivity. Said cartridge having fuel zones, heating zones, and controllers to selectively heat fuel zones and thereby generate hydrogen via decomposition of fuel is disclosed. | ||||||
| 133 | BLADE-TYPE FUSE | EP12839267.7 | 2012-10-12 | EP2768007A1 | 2014-08-20 | KAWAMOTO Arata; NOMURA Syoichi; SHIMOCHI Eiji; NAKAMURA Goro |
In a blade-type fuse (10) according to the present invention one of an upper casing (20) and a lower casing (30) includes a fixing post (30K), the other casing includes a through-hole (20K) through which the fixing post (30K) is passed, and also the flat terminal portion (41) includes a through-hole (40K) through which the fixing post (30K) is passed. The flat terminal portion (41) is formed bilaterally symmetrically about a vertical line passing through a center of the blade-type fuse (10), and vertically symmetrically about a horizontal line passing through the center of the blade-type fuse (10). |
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| 134 | Trilayered beam MEMS switch and related method | EP06118802.5 | 2002-11-08 | EP1717195B1 | 2011-09-14 | Cunningham, Shawn, J.; Tatic-Lucic, Svetlana |
| 135 | Trilayered Beam MEMS device and related methods | EP06118800.9 | 2002-11-08 | EP1717194B1 | 2009-05-27 | Cunningham, Shawn, J.; Tatic-Lucic, Svetlana |
| 136 | MEMS device having a trilayered beam and related methods | EP06116530.4 | 2002-11-08 | EP1721866B1 | 2008-12-10 | Cunningham, Shawn, J.; Dereus, Dana R.; Sett, Subham; Tatic-Lucic, Svetlana |
| 137 | MEMS DEVICE HAVING A TRILAYERED BEAM AND RELATED METHODS | EP02797085.4 | 2002-11-08 | EP1454333B1 | 2007-09-12 | CUNNINGHAM, Shawn, J.; DEREUS, Dana, R.; Sett, Subham; TATIC-LUCIC, Svetlana |
| A movable, trilayered microcomponent (108) suspended over a substrate (102) is provided and includes a first electrically conductive layer (116) patterned to define a movable electrode (114). The first metal layer (116) is separated from the substrate (102) by a gap. The microcomponent (108) further includes a dielectric layer formed (112) on the first metal layer (116) and having an end fixed with respect to the substrate (102). Furthermore, the microcomponent (102) includes a second electrically conductive layer (120) formed on the dielectric layer (112) and patterned to define an electrode interconnect (124) for electrically communicating with the movable electrode (114). | ||||||
| 138 | MEMS device having standoff bumps and folded component | EP06126734.0 | 2002-11-08 | EP1760746A3 | 2007-03-14 | Dereus, Dana, R. |
According to one embodiment, a movable MEMS component suspended over a substrate is provided. The component can include a structural layer having a movable electrode separated from a substrate by a gap. The component can also include at least one standoff bump attached to the structural layer and extending into the gap for preventing contact of the movable electrode with conductive material when the component moves. The structural layer is folded.
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| 139 | MEMS device having contact and standoff bumps and related methods | EP06126731.6 | 2002-11-08 | EP1760036A1 | 2007-03-07 | Dereus, Dana, R. |
According to one embodiment, a movable MEMS component suspended over a substrate is provided. The component can include a structural layer having a movable electrode separated from a substrate by a gap. The component can also include at least one standoff bump attached to the structural layer and extending into the gap for preventing contact of the movable electrode with conductive material when the component moves.
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| 140 | MEMS device having a trilayered beam and related methods | EP06116530.4 | 2002-11-08 | EP1721866A1 | 2006-11-15 | Cunningham, Shawn, J.; Dereus, Dana R.; Sett, Subham; Tatic-Lucic, Svetlana |
MEMS Switch Designs and Related Methods. According to one embodiment, a movable, trilayered microcomponent suspended over a substrate is provided and includes a first electrically conductive layer patterned to define a movable electrode. The first metal layer is separated from the substrate by a gap. The microcomponent further includes a dielectric layer formed on the first metal layer and having an end fixed with respect to the substrate. Furthermore, the microcomponent includes a second electrically conductive layer formed on the dielectric layer and patterned to define an electrode interconnect for electrically communicating with the movable electrode.
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