IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0068261
(2008-02-05)
|
등록번호 |
US-8407980
(2013-04-02)
|
우선권정보 |
DE-10 2007 006 444 (2007-02-05) |
발명자
/ 주소 |
- Friedberger, Alois
- Schulte, Georg
- Mueller, Gerhard
- Telitschkin, Dimitri
- Ziegenhagen, Stefan
|
출원인 / 주소 |
|
대리인 / 주소 |
Greenblum & Bernstein, P.L.C.
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인용정보 |
피인용 횟수 :
0 인용 특허 :
6 |
초록
▼
Microthruster includes a combustion chamber comprising a substrate material, a fuel inlet, and a gas outlet. A first resistance heater is arranged in the combustion chamber. A catalyst is structured and arranged to decompose fuel entering the combustion chamber. First substrate material sections are
Microthruster includes a combustion chamber comprising a substrate material, a fuel inlet, and a gas outlet. A first resistance heater is arranged in the combustion chamber. A catalyst is structured and arranged to decompose fuel entering the combustion chamber. First substrate material sections are heated by the first resistance heater to at least one of a predetermined temperature and a predetermined temperature range.
대표청구항
▼
1. A microthruster comprising: a combustion chamber comprising a substrate material, a fuel inlet, and a gas outlet;a first resistance heater arranged in the combustion chamber;a catalyst structured and arranged to decompose fuel entering the combustion chamber; andfirst substrate material sections
1. A microthruster comprising: a combustion chamber comprising a substrate material, a fuel inlet, and a gas outlet;a first resistance heater arranged in the combustion chamber;a catalyst structured and arranged to decompose fuel entering the combustion chamber; andfirst substrate material sections heated by the first resistance heater to one of a predetermined temperature and a predetermined temperature range. 2. The microthruster of claim 1, further comprising a thrust nozzle adjoining the gas outlet,wherein at least one of:the microthruster is adapted for use as a position adjustment thruster;the combustion chamber is arranged with a structure formed by portions of the substrate material;the first substrate material sections are made from portions of the substrate material;the substrate material comprises an electrically conductive substrate material; andone of: the catalyst comprising the first substrate material sections;the catalyst forming part of the first substrate material sections; andthe catalyst being integrally formed with the first substrate material sections. 3. The microthruster of claim 1, wherein at least one of: the first resistance heater comprises the catalyst itself; andthe first resistance heater is integrally formed with the first substrate material sections. 4. The microthruster of claim 1, wherein at least one of: the first substrate material sections are coated at least partially with a catalyst material; andthe first resistance heater comprises a catalyst layer arranged on the first substrate material sections. 5. The microthruster of claim 1, further comprising an insulating layer arranged at least partially between a catalyst layer and the first substrate material sections. 6. The microthruster of claim 1, wherein the first substrate material sections are arranged in the combustion chamber and have an at least partially porous surface structure. 7. The microthruster of claim 1, further comprising second substrate material sections, and one of: the first substrate material sections being spaced apart by a first spacing and the second substrate material sections are spaced apart by a second different spacing; andthe first substrate material sections being spaced apart by a first spacing and the second substrate material sections are spaced apart by a second larger spacing. 8. The microthruster of claim 1, wherein a volume of the combustion chamber is at least partially defined by a cover layer of the combustion chamber, whereby the cover layer adjoins at least the first substrate material sections. 9. The microthruster of claim 1, wherein one of: the first resistance heater comprises a conductor structure arranged in a meandering configuration; andthe first resistance heater comprises a conductor structure arranged in a meandering configuration and comprising a metal and being arranged on a cover layer. 10. The microthruster of claim 1, wherein the substrate material comprises one of: silicon and silicon carbide (SiC); andsapphire. 11. The microthruster of claim 1, wherein the microthruster is a monergol hydrazine thruster. 12. A thruster comprising a plurality of microthrusters of claim 1. 13. The thruster of claim 12, wherein the plurality of microthrusters are arranged in an array. 14. A method of making the microthruster of claim 1, the method comprising: forming at least one of first and second substrate material sections on a substrate material one of a mechanical, physical or chemical process, the first and second substrate material sections having column-shaped portions which project into an interior of the combustion chamber; coating at least partially the first substrate material sections with the catalyst material; andarranging a cover layer on the substrate material, whereby the cover layer at least partially defines the combustion chamber. 15. The method of claim 14, wherein the substrate material comprises sapphire, wherein the cover layer comprises an SOI substrate having a metal structure, and wherein the metal structure is arranged adjacent at least the first substrate material sections. 16. The method of claim 14, further comprising forming the first substrate material sections with at least a partially porous surface structure before coating with a catalyst material. 17. The method of claim 14, further comprising at least one of applying and forming an insulating layer between the first substrate material sections and the catalyst material. 18. The method of claim 14, further comprising at least one of: electrically connecting at least one of the first substrate material sections and the catalyst material via a metal structure; andelectrically connecting at least one of the first substrate material sections and the catalyst material via a metal structure of a cover layer. 19. The method of claim 14, further comprising connecting together a cover layer and the substrate material via at least one of: direct bonding, eutectic bonding, solder glass adhesive, ceramic adhesive, and soldering. 20. The method of claim 14, further comprising forming a peripheral boundary section in a cover layer by an abrasion process, wherein the peripheral boundary section lies at least partially in an assembly plane, with which the cover layer is connected to the substrate material, whereby a functional area is defined and is set back with respect to the assembly plane. 21. The method of claim 20, further comprising at least one of arranging and forming a layer arrangement in the functional area, the layer arrangement comprising an insulating layer, a metallization layer, and a passivation layer. 22. The method of claim 14, further comprising: at least one of arranging and forming a feed line section in a peripheral boundary section, wherein the feed line section is part of the functional area; andfilling a space between the passivation layer and the assembly plane with passivation material. 23. The method of claim 14, further comprising, after a cover layer and the substrate material are connected, filling a feed line section with a filler paste, the filler paste being inserted via a bore in the cover layer or the substrate material in a region of the feed line section. 24. The method of claim 14, further comprising applying an electrically insulating passivation layer to a back of the substrate material, whereby the electrically insulating passivation layer is opened only in an area of the first substrate material sections. 25. The microthruster of claim 1, wherein the substrate material is arranged to form a plurality of columns. 26. The microthruster of claim 1, wherein the substrate material is at least partially porous. 27. The microthruster of claim 1, wherein the substrate material having an adjustable porosity. 28. The microthruster of claim 1, further comprising a thruster nozzle arranged at the gas outlet. 29. A microthruster comprising: a combustion chamber comprising a substrate material, a fuel inlet, and a gas outlet;a first resistance heater arranged in the combustion chamber;a catalyst structured and arranged to decompose fuel entering the combustion chamber;first substrate material sections heated by the first resistance heater to one of a predetermined temperature and a predetermined temperature range; anda second resistance heater arranged in an interior of the combustion chamber between the catalyst and the gas outlet, whereby a gas leaving the catalyst is heated. 30. The microthruster of claim 29, wherein one of: the second resistance heater is arranged on second substrate material sections;the second resistance heater forms part of second substrate material sections; andthe second resistance heater is integrally formed with second substrate material sections. 31. The microthruster of claim 30, wherein one of: at least one of the first and second substrate material sections comprise portions of the substrate material of the combustion chamber and are made by one of a mechanical or chemical process;at least one of the first and second substrate material sections comprise column-shaped portions of the substrate material of the combustion chamber;at least one of the first and second substrate material sections comprise column-shaped portions of the substrate material of the combustion chamber formed on a base of the substrate material; andat least one of the first and second substrate material sections comprise column-shaped portions of the substrate material of the combustion chamber integrally formed with a base of the substrate material. 32. A microthruster comprising: a combustion chamber comprising a substrate material, a fuel inlet, and a gas outlet;a first resistance heater arranged in the combustion chamber;a catalyst structured and arranged to decompose fuel entering the combustion chamber; andfirst substrate material sections heated by the first resistance heater to one of a predetermined temperature and a predetermined temperature range;wherein a volume of the combustion chamber is at least partially defined by a cover layer of the combustion chamber, whereby the cover layer adjoins at least the first substrate material sections, andwherein the cover layer is made from a structured silicon on insulator (SOI) wafer and is bonded via an electrical bonding to at least one of the first resistance heater and the first substrate material sections. 33. A microthruster comprising: a combustion chamber comprising a substrate material, a fuel inlet, and a gas outlet;a first resistance heater arranged in the combustion chamber;a catalyst structured and arranged to decompose fuel entering the combustion chamber;first substrate material sections heated by the first resistance heater to one of a predetermined temperature and a predetermined temperature range;a cover layer having a peripheral boundary section;a functional area surrounded by the peripheral boundary section; anda layer arrangement arranged in the functional area and comprising an insulating layer, a metallization layer and a passivation layer, whereby the layer arrangement does not project beyond an assembly plane. 34. The microthruster of claim 33, further comprising: a feed line section arranged in the peripheral boundary section; andat least one of a passivation material and a filler paste arranged between the passivation layer and the assembly plane. 35. A microthruster comprising: a combustion chamber comprising a substrate material, a fuel inlet, and a gas outlet;a first resistance heater arranged in the combustion chamber;a catalyst structured and arranged to decompose fuel entering the combustion chamber;first substrate material sections heated by the first resistance heater to one of a predetermined temperature and a predetermined temperature range;at least one of a first arrangement for detecting a first resistance of the first resistance heater and a second arrangement for detecting a second resistance of a second resistance heater; anda third arrangement for determining a first temperature from the first resistance and a second temperature from the second resistance. 36. The microthruster of claim 35, further comprising: a temperature sensor arranged outside the combustion chamber and coupled to an arrangement for compensating for a resistance drift of the first resistance and the second resistance. 37. The microthruster of claim 35, further comprising one of: at least one of a third heater and a third resistance heater assigned to the thrust nozzle; andat least one of a third heater and a third resistance heater for heating the thrust nozzle. 38. A microthruster comprising: a combustion chamber comprising a substrate material, a fuel inlet, and a gas outlet;a first resistance heater arranged in the combustion chamber;a catalyst structured and arranged to decompose fuel entering the combustion chamber;first substrate material sections heated by the first resistance heater to one of a predetermined temperature and a predetermined temperature range; andone of: a heater formed on a cover layer comprising a meandering conductor structure; anda heater arranged on a cover layer comprising a meandering conductor structure of a metal or a conductive material. 39. A microthruster comprising: a combustion chamber arranged in a substrate and comprising a fuel inlet and a gas outlet;a first resistance heater arranged in the combustion chamber;a catalyst structured and arranged to decompose fuel entering the combustion chamber; andat least first substrate material sections formed in the substrate and heated by the first resistance heater to one of a predetermined temperature and a predetermined temperature range. 40. The microthruster of claim 39, further comprising a thruster nozzle arranged at the gas outlet.
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