| 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 | HEIZVORRICHTUNG | EP14730934.8 | 2014-06-18 | EP3011802B1 | 2017-12-20 | HEEPER, Lars; MARQUAS, Karsten; NAGEL, Dirk; STALLEIN, Matthias; STEINKAMP, Michael |
| 122 | FLUID HEATING DEVICE | EP15184394.3 | 2015-09-09 | EP2999308A1 | 2016-03-23 | TONOMURA, Toru; FUJIMOTO, Yasuhiro; KIMURA, Masayoshi |
An object of this invention is to detect breakage of a conductor tube 1 before it happens and to prevent leakage of the heated fluid. More concretely, this invention is a fluid heating device 100 that applies heat to a fluid that flows in the conductor tube 1 of a helical shape by applying induction heat to the conductor tube 1 and that comprises an electrical connecting member 2 that constitutes a short circuit by electrically connecting each of required portions of the conductor tube 1, and a potential measuring instrument 4 that measures a potential of the conductor tube 1.
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| 123 | OIL DIFFUSION PUMP AND VACUUM FILM FORMATION DEVICE | EP13878178.6 | 2013-03-14 | EP2975271A1 | 2016-01-20 | SAISHO, Shinichiro |
Provided is an oil diffusion pump equipped with an oil vapor generator capable of eliminating the problems occurring when a heater wire is used as a heating source for an operating oil. The present invention is a vacuum pump for which an oil vapor generator (70) is arranged within a casing (51) and this oil vapor generator is operated to vaporize an operating oil (8), thereby producing oil vapor and this oil vapor is sprayed from a jet (53, 53a) to exhaust intake air. The oil vapor generator (70) is equipped with: a container (71, 72) in the interior of which oil is stored, with the lower end of the tubular member (71), which comprises a material to be heated, being closed; and induction coil (75) wrapped around the atmosphere-side perimeter of the tubular member (71) (in particular, the case inner wall (71b)) with an insulating material (73) therebetween; and a power supply means that applies a low-frequency alternating current of several tens of Hz to several hundreds of Hz to the induction coil (75). The configuration is such that the tubular member (71) itself is heated when the power supply means is operated and the low-frequency alternating current is applied to the induction coil (75), thereby vaporizing the oil within the container. |
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| 124 | High efficiency water boiling device | EP11152689.3 | 2011-01-31 | EP2420755A3 | 2014-08-27 | Shun-Chi, Yang; Mao, Hsiung Yang; YANG, Tsung-Chuan; FANG, Ming-Wu; CHENG-YEN, Wu |
A water boiling device (10) includes a heat tank unit (14) received in a machine body (12), a high frequency induction heater (16), and a heat pipe unit (18). Heat tank unit (14) includes first and second heating tanks (34, 35) in communication with each other. Outside water (44) can flow into first and second heating tanks (34, 35). The high frequency induction heater (16) includes a heat pipe induction coil (66) and first and second induction coils (60, 62). The heat pipe unit (18) includes first and second heating pipes (72). An upper section (74) of each heating pipe (72) is received in one of heating tanks (34, 35), and a lower section (76) of each heating pipe (72) extends out of heating tanks (34, 35) and is inserted into heat pipe induction coil (66). The first and second heating tanks (34, 35) will heat up to heat the water (44) in the first and second heating tanks (34, 35) when a high frequency current is passed through the heat pipe induction coil (66) and first and second induction coils (60, 62).
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| 125 | Energy-saving water boiler | EP11152671.1 | 2011-01-31 | EP2388534A3 | 2014-08-27 | Shun-Chi, Yang; Mao, Hsiung Yang; YANG, Tsung-Chuan; FANG, Ming-Wu; CHENG-YEN, Wu |
A water boiler (10) includes a water storage tank (12), a heater (16), and a heat pipe unit (18). The water storage tank (12) includes a heating room (34), an outer water storage room (36), and an inner water storage room (40) between and spaced from the heating room (34) and the outer water storage room (36) in a radial direction. Outside water (56) flows from an inlet pipe (54) to the outer water storage room (36), and water (56) in the outer water storage room (36) flows into the inner water storage room (40) and the heating room (34) for storage. The heater (16) includes an induction coil (78). The heat pipe unit (18) includes a plurality of heat-transfer pipes (84). An upper segment (86) of each heat-transfer pipe (84) is arranged in the heating room (34), while a lower segment (88) of each heat-transfer pipe (84) is received in the induction coil (78). When the induction coil (78) turns ON, heat-transfer pipes (84) are heated to heat the water (56) in the heating room (34).
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| 126 | High efficiency water boiling device | EP11152689.3 | 2011-01-31 | EP2420755A2 | 2012-02-22 | Shun-Chi, Yang; Mao, Hsiung Yang; YANG, Tsung-Chuan; FANG, Ming-Wu; CHENG-YEN, Wu |
A water boiling device (10) includes a heat tank unit (14) received in a machine body (12), a high frequency induction heater (16), and a heat pipe unit (18). Heat tank unit (14) includes first and second heating tanks (34, 35) in communication with each other. Outside water (44) can flow into first and second heating tanks (34, 35). The high frequency induction heater (16) includes a heat pipe induction coil (66) and first and second induction coils (60, 62). The heat pipe unit (18) includes first and second heating pipes (72). An upper section (74) of each heating pipe (72) is received in one of heating tanks (34, 35), and a lower section (76) of each heating pipe (72) extends out of heating tanks (34, 35) and is inserted into heat pipe induction coil (66). The first and second heating tanks (34, 35) will heat up to heat the water (44) in the first and second heating tanks (34, 35) when a high frequency current is passed through the heat pipe induction coil (66) and first and second induction coils (60, 62).
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| 127 | COOKING APPARATUS AND METHOD OF CONTROLLING THE SAME | US15774799 | 2016-10-31 | US20180328589A1 | 2018-11-15 | Seung Wook SUH; Jae Moon LEE |
| A cooking device and a control method thereof is provided which heating a curved area to a higher temperature than a flat area of a cooking area where food is cooked. A cooking apparatus includes a cooking unit having one side in which a first cooking region and a second cooking region distinguished from the first cooking region are provided; a heating unit configured to heat the cooking unit; and a controller configured to control the heating unit to heat the first cooking region to a first temperature and to heat the second cooking region to a second temperature different from the first temperature. | ||||||
| 128 | METHOD FOR HEATING WATER IN A MACHINE FOR MAKING AND DISPENSING DRINKS | US15970254 | 2018-05-03 | US20180249860A1 | 2018-09-06 | Carlo DOGLIONI MAJER |
| A method for heating water in a machine for making and dispensing beverages, the machine having a device with at least one heating metallic duct and a winding of electromagnetic induction. The device is part of a heating and feeding assembly wherein, by a logical unit, a method is carried out which, for every beverage type the machine can dispense, the temperature of heated water is brought to a specific temperature value that can be selected by the user. | ||||||
| 129 | Method for managing the heating of water in a tank of a water heater | US14910959 | 2014-07-31 | US10060650B2 | 2018-08-28 | Jean-Yves Gaspard |
| The invention relates to a method for managing the heating of water in a tank of a water heater which comprises a device for electrically heating the water in the tank, characterized in that it comprises, when a water heating phase is actuated: activation of heating by the heating device, determination of a variation of the temperature in the tank over time and determination of at least one water filling state in the tank according to the variation over time. | ||||||
| 130 | INDUCTION HEATER AND VAPORIZER | US15786261 | 2017-10-17 | US20180180367A1 | 2018-06-28 | Robert FOLK; Adrian LACHANCE |
| A method and apparatus for induction heating or vaporization of water, oil, or other fluids. An induction heater system includes a ferrous heat tube, an induction coil extending around the ferrous heat tube, an induction drive, and a controller to regulate the operation of the induction drive or a fluid supply or both, to heat or vaporize the fluid. | ||||||
| 131 | Oil diffusion pump and vacuum film formation device | US14774403 | 2013-03-14 | US09933159B2 | 2018-04-03 | Shinichiro Saisho |
| Provided is an oil diffusion pump equipped with an oil vapor generator capable of eliminating the problems occurring when a heater wire is used as a heating source for an operating oil. The present invention is a vacuum pump for which an oil vapor generator (70) is arranged within a casing (51) and this oil vapor generator is operated to vaporize an operating oil (8), thereby producing oil vapor and this oil vapor is sprayed from a jet (53, 53a) to exhaust intake air. The oil vapor generator (70) is equipped with: a container (71, 72) in the interior of which oil is stored, with the lower end of the tubular member (71), which comprises a material to be heated, being closed; and induction coil (75) wrapped around the atmosphere-side perimeter of the tubular member (71) (in particular, the case inner wall (71b)) with an insulating material (73) therebetween; and a power supply means that applies a low-frequency alternating current of several tens of Hz to several hundreds of Hz to the induction coil (75). The configuration is such that the tubular member (71) itself is heated when the power supply means is operated and the low-frequency alternating current is applied to the induction coil (75), thereby vaporizing the oil within the container. | ||||||
| 132 | Magnetic induction heat engine and heat pipe delivery system and methods of producing and delivering heat | US15051604 | 2016-02-23 | US09544945B2 | 2017-01-10 | Stamatios Hadoulias; Darryl L. Snyder; John C. May |
| A magnetic induction thermal heat unit, capable of producing heat by magnetic field, inducing direct agitation and friction, at the molecular level within a ferrous magnetic or semi-magnetic substrate. The substrate is specifically designed to capitalize on storing the heat generated and then transferring the heat generated to a subsequent device that requires or uses heat as its primary energy source. The system can use both a combination of induction heated substrates that are ferrous or magnetic in various configurations. The substrates can also be joined or bonded to non-magnetic or ferrous materials such as aluminum or copper as a conductive heat path to a heat pipe system where a transfer of thermal energy occurs. Additionally, convective and resultant radiant heat from the magnetic induction system can be directed back into the cumulative total of heat energy produced. The major objective ultimately being able to produce a greater degree of efficiency per given watt of electricity beyond what is currently available with current technology. | ||||||
| 133 | DEVICE AND METHOD FOR HEATING WATER IN A MACHINE FOR MAKING AND DISPENSING DRINKS | US15032641 | 2014-10-28 | US20160287010A1 | 2016-10-06 | CARLO DOGLIONI MAJER |
| A device (1) for heating water in a machine for making and dispensing beverages, comprising at least one heating metallic duct (2) and a winding of electromagnetic induction (3). The device is part of a heating and feeding assembly wherein, by a logical unit, it is possible to carry out a method in which, for every beverage type the machine can dispense, the temperature of heated water is led to a specific temperature value that can be selected by the user. | ||||||
| 134 | MAGNETIC INDUCTION HEAT ENGINE AND HEAT PIPE DELIVERY SYSTEM AND METHODS OF PRODUCING AND DELIVERING HEAT | US15051604 | 2016-02-23 | US20160255681A1 | 2016-09-01 | Stamatios Hadoulias; Darryl L. Snyder; John C. May |
| A magnetic induction thermal heat unit, capable of producing heat by magnetic field, inducing direct agitation and friction, at the molecular level within a ferrous magnetic or semi-magnetic substrate. The substrate is specifically designed to capitalize on storing the heat generated and then transferring the heat generated to a subsequent device that requires or uses heat as its primary energy source. The system can use both a combination of induction heated substrates that are ferrous or magnetic in various configurations. The substrates can also be joined or bonded to non-magnetic or ferrous materials such as aluminum or copper as a conductive heat path to a heat pipe system where a transfer of thermal energy occurs. Additionally, convective and resultant radiant heat from the magnetic induction system can be directed back into the cumulative total of heat energy produced. The major objective ultimately being able to produce a greater degree of efficiency per given watt of electricity beyond what is currently available with current technology. | ||||||
| 135 | Water Heater | US14910945 | 2014-07-31 | US20160195301A1 | 2016-07-07 | Jean-Yves Gaspard |
| Water heater comprising a tank for holding water, the tank being delimited by a peripheral jacket and the wall of a leak-tight sheath immersed in the internal volume of the peripheral jacket, an electric heating device, characterised in that the heating device includes at least one inductor housed in the sheath and at least one load formed by at least a part of the wall of the sheath. | ||||||
| 136 | HEATING DEVICE | US14899185 | 2014-06-18 | US20160157303A1 | 2016-06-02 | Lars HEEPER; Karsten MARQUAS; Dirk NAGEL; Matthias STALLEIN; Michael STEINKAMP |
| The invention relates to a heating device comprising a housing having a fluid channel arranged therein with a fluid inlet and a fluid outlet, wherein an element generating an alternating magnetic field is provided in the housing, wherein, furthermore, at least one metallic panel heating element is provided, which is heatable by the alternating magnetic field, wherein the at least one panel heating element is arranged in the fluid channel, wherein the element generating the alternating magnetic field is formed by a coil shaped in hollow-cylindrical fashion, which coil is operable by an AC voltage, wherein the coil is separated in fluidtight fashion from the fluid channel. | ||||||
| 137 | FLUID HEATING DEVICE | US14859007 | 2015-09-18 | US20160088687A1 | 2016-03-24 | Toru Tonomura; Yasuhiro Fujimoto; Masayoshi Kimura |
| An object of this invention is to detect breakage of a conductor tube before it happens and to prevent leakage of the heated fluid. More concretely, this invention is a fluid heating device that applies heat to a fluid that flows in the conductor tube of a helical shape by applying induction heat to the conductor tube and that comprises an electrical connecting member that constitutes a short circuit by electrically connecting each of required portions of the conductor tube, and a potential measuring instrument that measures a potential of the conductor tube. | ||||||
| 138 | Heart-type circulation device | US14236074 | 2013-05-10 | US09254221B2 | 2016-02-09 | Henglai Zhao |
| A heart-type circulation device comprises a power system, a cover plate (16), an elastic plate (5), a pressing contact ring (6), a water inlet (13), a check valve A (9), a self-pressing liquid storage tank (12), a check valve B (10), a water outlet (11), and a pipeline (17). The elastic plate (5) is disposed above the power system, the pressing contact ring (6) is disposed on the periphery of a bottom surface of the elastic plate (5), and the pressing contact ring (6), the elastic plate (5), and the cover plate (16) are fixedly connected in sequence from bottom to top. The water inlet (13) and the water outlet (11) are in communication with each other between the cover plate (16) and the elastic plate (5) via the cover plate (16) respectively. The water inlet (13), the check valve A (9), the self-pressing liquid storage tank (12), the check valve B (10), and the water outlet (11) are connected in sequence via the pipeline (17), wherein the direction of the check valve A (9) is the direction of a fluid flowing to the cover plate (16), and the direction of the check valve B (10) is the direction of the fluid flowing out of the cover plate (16). The space where the whole pipeline (17) is in communication with the self-pressing liquid storage tank (12) is filled up with a liquid. The heart-type circulation device has a simple structure, makes no noise, and has no leakage and a low maintenance rate, and is energy-saving, environment-friendly, green and efficient. | ||||||
| 139 | MAGNETIC FLUID HEATING APPARATUS | US14203644 | 2014-03-11 | US20150264750A1 | 2015-09-17 | JOE WALDNER |
| An apparatus for heating fluid may comprise a housing with an interior, a fluid inlet, and a fluid outlet. A fluid heating assembly in the housing is rotatable and includes a plurality of disks including a conductive material and being spaced from each other to form gaps therebetween. A magnetic assembly may be configured to apply a magnetic field of adjustable intensity to the disks. The magnetic assembly may comprise a plurality of magnetic elements positioned adjacent to the disks and a support structure supporting the magnetic elements proximate to the gaps between the disks. The support structure moves the magnetic elements between a maximum exposure position with respect to the conductive material of the disks in which a relatively greater degree of heating is produced and a minimum exposure position with respect to the conductive material in which a relatively lesser degree of heating is produced. | ||||||
| 140 | MULTI-CHANNEL CONDUIT AND METHOD FOR HEATING A FLUID FOR USE IN HYDRAULIC FRACTURING | US14100807 | 2013-12-09 | US20150159911A1 | 2015-06-11 | ARTHUR H. HOLT |
| System and method directed to the art of heating a fluid for use in a hydraulic fracturing system. A heat tube having a plurality of pipes disposed axially along and substantially near the periphery of a medial portion of the heat tube. The heat tube is heated by induction heaters. | ||||||
