| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 61 | Water vaporizer with intermediate steam superheating pass | US11939081 | 2007-11-13 | US08171985B2 | 2012-05-08 | Jeroen Valensa; Adam Kimmel; Michael Reinke |
| The present invention provides a water vaporizer including a first flow path connected to a water inlet, a second flow path for receiving superheated water vapor from the first flow path and being connected to a vapor outlet to exhaust the superheated water vapor, and a third flow path extending between an exhaust inlet and an exhaust outlet and being oriented to transfer heat from an exhaust flow to the superheated water vapor. The water vaporizer can also include a first convoluted fin positioned along the second flow path, and a second convoluted fin positioned along the second flow path adjacent to and separated from the first fin to define a gap extending between the first and second fins along a length of the first fin in a direction substantially parallel to the exhaust flow along the third flow path. | ||||||
| 62 | WATER VAPORIZER WITH INTERMEDIATE STEAM SUPERHEATING PASS | US11939081 | 2007-11-13 | US20080295784A1 | 2008-12-04 | Jeroen Valensa; Adam Kimmel; Michael Reinke |
| The present invention provides a water vaporizer including a first flow path connected to a water inlet, a second flow path for receiving superheated water vapor from the first flow path and being connected to a vapor outlet to exhaust the superheated water vapor, and a third flow path extending between an exhaust inlet and an exhaust outlet and being oriented to transfer heat from an exhaust flow to the superheated water vapor. The water vaporizer can also include a first convoluted fin positioned along the second flow path, and a second convoluted fin positioned along the second flow path adjacent to and separated from the first fin to define a gap extending between the first and second fins along a length of the first fin in a direction substantially parallel to the exhaust flow along the third flow path. | ||||||
| 63 | Boiler | US998860 | 1960-02-19 | US3050041A | 1962-08-21 | HALE WILLIAM A |
| 64 | Steam generating apparatus | US34148240 | 1940-06-20 | US2285349A | 1942-06-02 | ANTONI MUSZYNSKI |
| 65 | Steam generator for cloth pressing and steaming devices | US73318834 | 1934-06-30 | US2084282A | 1937-06-15 | HUGO SCHMIDT ALEXANDER |
| 66 | Boiler or the like | US10365126 | 1926-04-21 | US1648988A | 1927-11-15 | KEMPER ALBERT H |
| 67 | Water-heater. | US1911644980 | 1911-08-19 | US1039651A | 1912-09-24 | CULLEN JOHN T JR |
| 68 | Steam-boiler | US559583D | US559583A | 1896-05-05 | ||
| 69 | Wilhelm wirz | US470530D | US470530A | 1892-03-08 | ||
| 70 | Steam feed-cooker | US387525D | US387525A | 1888-08-07 | ||
| 71 | Boiler and feed-steamer | US266495D | US266495A | 1882-10-24 | ||
| 72 | Improvement in feed-water heaters | US205813D | US205813A | 1878-07-09 | ||
| 73 | Improvement in feed-water heaters | US198428D | US198428A | 1877-12-18 | ||
| 74 | Improvement in steam-boilers | US120102D | US120102A | 1871-10-17 | ||
| 75 | Eoyal e | US97766D | US97766A | 1869-12-14 | ||
| 76 | Improvement in steam-boilers | US40118D | US40118A | 1863-09-29 | ||
| 77 | HEAT EXCHANGER FOR STEAM GENERATION FOR A SOLAR-THERMAL POWER PLANT | PCT/EP2010003893 | 2010-06-24 | WO2010149387A3 | 2011-09-29 | STAHLHUT JOERG; HEGNER WOLFGANG; BAND DIRK |
| The invention relates to a heat exchanger for generating a steam flow for a solar-thermal power plant, comprising a casing for accommodating a casing-side fluid, and having pipes extending inside the casing for a pipe-side fluid, wherein the heat is transmitted via the pipes from the pipe-side fluid to the casing-side fluid. The casing-side fluid is water, and the pipe-side fluid is a thermo oil or salt. The invention allows for an increase of the startup gradients and the alternating load gradients, thus increasing the availability of the power plant. Furthermore, a higher operational safety can be achieved. | ||||||
| 78 | METHOD AND DEVICE FOR OPERATING COGENERATION POWER PLANTS | PCT/DE2010000950 | 2010-08-10 | WO2011020463A3 | 2012-05-03 | HERBERTZ HEINZ |
| The invention relates to a method and a device for operating cogeneration power plants, by means of which obtaining electricity from the heat of the engine cooling is enabled and the electricity generation can be continued in the event of a lack of heat removal without emergency cooling. In a rotary engine, which drives a generator to generate electricity, the piston chamber (40) is enclosed by a housing (41), in which hot water from a hot-water tank (26) is circulated at high pressure. Steam is produced in the hot-water tank, said steam acting on a steam turbine (29) connected to a second generator. The exhaust steam of the steam turbine condenses in a warm-water tank (50), which contains a heat exchanger (4) for supplying heat to the residential complex. The hot-water tank and the warm-water tank have a water connection and a level controller for replacing the evaporated water. If there is a lack of heat removal, the exhaust steam is discharged to the atmosphere and the electricity generation in both generators can be continued. The invention is especially suitable for small power plants installed in houses in large numbers, saidsmall power plants replacing dangerous and environmentally harmful large power plants. | ||||||
| 79 | WATER VAPORIZER WITH INTERMEDIATE STEAM SUPERHEATING PASS | PCT/US2008083399 | 2008-11-13 | WO2009064881A2 | 2009-05-22 | VALENSA JEROEN; KIMMEL ADAM; REINKE MICHAEL |
| The present invention provides a water vaporizer including a first flow path connected to a water inlet, a second flow path for receiving superheated water vapor from the first flow path and being connected to a vapor outlet to exhaust the superheated water vapor, and a third flow path extending between an exhaust inlet and an exhaust outlet and being oriented to transfer heat from an exhaust flow to the superheated water vapor. The water vaporizer can also include a first convoluted fin positioned along the second flow path, and a second convoluted fin positioned along the second flow path adjacent to and separated from the first fin to define a gap extending between the first and second fins along a length of the first fin in a direction substantially parallel to the exhaust flow along the third flow path. | ||||||
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