61 |
マイクロ波によって誘発される準瞬間的サーモヒーター |
JP2015535069 |
2012-10-03 |
JP2015534236A |
2015-11-26 |
ヒダルゴ,ディエゴ ホセ コレラ |
サーモヒーターであって:カバー(7)にぴったりと合う、ガラスから成るタンク(1)と、タンク(1)を取り囲むベルト又は支持枠組み(2)によって支持された多数のマグネトロン(3)とを備え、該ベルト又は支持枠組み(2)は、マグネトロンに継続的な支持を提供し、且つタンク(1)の内側に配置されてもよい。マグネトロン(3)の各々は、第1交換体(5)の上に収容され、且つマグネトロン(3)は、更に、主交換体(6)の上に収容される。ソレノイド(8)は、ロッド・サーモスタットと水入口及び水出口とのための支持体と同様に、カバーの上に配置される。混合バルブ(20)はカバーの下方に配置され、カバーを備えたレギュレータ(17)によって接続され、且つソレノイドに接続されたピストン(15)によって動作される。混合バルブは、二重フィルタバルブである。使用される材料の特性のおかげで、以下が達成される:ほぼ瞬間的加熱、エネルギー消費の低減、及びレジオネラのような集団の拡散に対する効果的防護。 |
62 |
蓄熱装置 |
JP2015502310 |
2013-03-26 |
JP2015519530A |
2015-07-09 |
マクドナルド アラン |
改良されたサーマルストアが提供される。このサーマルは、サーマルストアから出力される熱を、ヒータに供給されるエネルギーから切り離す。 |
63 |
Electrical module |
JP2008546000 |
2006-12-15 |
JP2009520330A |
2009-05-21 |
ジョンストン、ジェフリー、ディー.; スタンリー、スティーブン、ジェイ.; スラプ、ガイ、シー.; ソリス、レイ |
複数のエネルギー蓄積コンポーネントがクランプを使用して互いに接続される、電気モジュールが提供される。 一構成では、第1の端子と第2の端子とを含む第1のエネルギー蓄積コンポーネントが、第3の端子と第4の端子とを含む第2のエネルギー蓄積コンポーネントに接続される。 第1のエネルギー蓄積コンポーネントの第1の端子は、凹部を含むクランプを使用して第2のエネルギー蓄積コンポーネントの第3の端子に電気的に接続される。 クランプの凹部は、第1のエネルギー蓄積コンポーネントの第1の端子の少なくとも一部分と第2のエネルギー蓄積コンポーネントの第3の端子の少なくとも一部分を受け入れる。 このクランプは、第1のエネルギー蓄積コンポーネントの第1の端子と第2のエネルギー蓄積コンポーネントの第3の端子とを電気的に接続して、第1のエネルギー蓄積コンポーネントと第2のエネルギー蓄積コンポーネントとをインライン構成で固定する。 |
64 |
Closed-type thermal storage electric multiple underfloor heating device, a method of heating, thermal energy storage method |
JP26198495 |
1995-09-18 |
JP2722380B2 |
1998-03-04 |
YONGU TAIKU CHOI |
|
65 |
Heat storage type double heating device, heating method therefor and method of storing heat energy |
JP26198495 |
1995-09-18 |
JPH0894101A |
1996-04-12 |
YONGU TAIKU CHIYOI |
PROBLEM TO BE SOLVED: To improve the heating efficiency of a double heating device by a method wherein heat energy is stored in the heating device upon initial using while the lower surface of a metallic plate formed matter for a panel is constituted of a curved surface to increase the amount of diffusion as well as the area of diffusion of radiation heat. SOLUTION: Heat energy is produced locally with a high temperature in the upper part of an electric heater 50 through local heating upon the initial using of the same and is radiated against heating devices 1, 2 quickly to store the heat energy within a short period of time. The heat transfer in the horizontal direction is effected quickly through diffusion by the high heat conductivity of metallic plate formed matters 14, 24 for panels 12, 22. The lower surfaces of the metallic plate formed matters 14, 24 are formed of a curved surface to change 60% of the transferred heat energy into diffused and reflected radiation heat as well as reflected heat. Accordingly, the radiation heat and the reflected heat are diffused and reflected whereby the moving direction of energy is formed so as to be a multitude of types and the amount of diffusion as well as the area of diffusion of the radiation heat are increased. Therefore, ideal diffusion and smooth convection can be obtained. According to this method, the heating efficiency of the double heating devices 1, 2 is improved. |
66 |
Accumulator |
JP2104687 |
1987-01-31 |
JPH0760075B2 |
1995-06-28 |
明男 三谷; 山口 広一; 弘次 鹿島 |
|
67 |
Heat storage unit |
JP11029491 |
1991-05-15 |
JPH04227476A |
1992-08-17 |
GOODON ERISU |
PURPOSE: To prevent significant displacement during heat cycle by providing a heat exchanger for heating fluid by touching heat storage bricks having an electric heating means, constructing a chamber of opposed plates arranged at an interval smaller than the side dimension.
CONSTITUTION: The heat exchanger 7 touches heat storage bricks 8 surrounded by heat insulating panel wherein the bricks 8 are heated by a heating coil 13 and charged electrically during off-peak period. The heat exchanger 7 comprises identical chambers 17, 18, 19 consisting of opposed pan-type plates welded along flanges constituting the rims of the pan. Depressions in each plate abut corresponding depressions in an opposing plate. Each chamber is coupled with upper and lower header pipes, respectively. Consequently, a large area is available for contact with the bricks and each side thereof does not displace significantly during heat cycle.
COPYRIGHT: (C)1992,JPO |
68 |
JPH0251105B2 - |
JP2021484 |
1984-02-06 |
JPH0251105B2 |
1990-11-06 |
UNO HIROSHI; YAMASHITA KAZUO; ISHII TAKAHITO; HAYASHI TAKESHI; ISHII KAZUNORI |
|
69 |
JPS4835332A - |
JP8520072 |
1972-08-25 |
JPS4835332A |
1973-05-24 |
|
|
70 |
System and method for adaptively controlling the charging time of a storage heater |
US15312825 |
2015-05-26 |
US10072874B2 |
2018-09-11 |
Alan McDonald; Damian Shields |
Provided is a method for adaptively controlling the charging time of a storage heater, comprising: determining a stored energy requirement of the heater; determining a background heat requirement of the heater; determining a daily energy requirement (DER) based on the stored energy requirement and the background heat requirement; and determining a daily run time (DRT) at a predetermined time to calculate the charging time for a following period of time based on the daily energy requirement (DER). |
71 |
INDUCTION HEATING MODULE AND WATER PURIFIER HAVING THE SAME |
US15473707 |
2017-03-30 |
US20170321931A1 |
2017-11-09 |
Kobong CHOI; Yonghyun KIM; Jewook JEON |
A water purifier includes a working coil, a hot water tank that faces toward the working coil and is spaced apart from the working coil by a gap to heat a liquid passing through an inner space of the hot water tank by an induction of the working coil, a bracket that is coupled to the hot water tank, the working coil being located between the hot water tank and the bracket, and a spacer that is located between the working coil and the hot water tank to thereby define the gap between the working coil and the hot water tank. |
72 |
Caloric Water Heater Appliance |
US15141874 |
2016-04-29 |
US20170314814A1 |
2017-11-02 |
Michael Alexander Benedict; David G. Beers |
A water heater appliance includes a first heat exchanger that is coupled to a tank. The water heater appliance also includes a caloric heat pump system that is configured for heating liquid within the tank via the first heat exchanger. The caloric heat pump system includes a plurality of caloric material stages. A field generator is positioned such that the caloric material stages are moved in and out of a field of the field generator during operation of the caloric heat pump system. |
73 |
Liquid Heating Appliance |
US15500311 |
2015-07-28 |
US20170306798A1 |
2017-10-26 |
Piers St John Spencer Cave |
A liquid heating appliance for heating water or other liquids, suitably to a target temperature of from 55° C. to around boiling point, includes a primary heat chamber or body (heat source chamber) that is thermally insulated and which in use contains a high thermal density heat storing liquid or solid; and a secondary chamber alongside the primary chamber through which a liquid to be heated is passed in use. The appliance has a heat transfer feature to selectively transfer thermal energy from the heat-storing liquid or solid to the liquid to be heated in the secondary chamber. The secondary chamber is preferably a conduit through which the liquid to be heated is able to flow and the thus heated liquid can be delivered to a tap as hot water for a range of uses. Water may also be heated for a central heating system for space heating. |
74 |
SYSTEM AND METHOD FOR ADAPTIVELY CONTROLLING THE CHARGING TIME OF A STORAGE HEATER |
US15312825 |
2015-05-26 |
US20170130992A1 |
2017-05-11 |
Alan McDonald; Damian Shields |
Provided is a method for adaptively controlling the charging time of a storage heater, comprising: determining a stored energy requirement of the heater; determining a background heat requirement of the heater; determining a daily energy requirement (DER) based on the stored energy requirement and the background heat requirement; and determining a daily run time (DRT) at a predetermined time to calculate the charging time for a following period of time based on the daily energy requirement (DER). |
75 |
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. |
76 |
SEMI-INSTANTANEOUS MICROWAVE-INDUCED THERMO HEATER |
US14431117 |
2012-10-03 |
US20150245425A1 |
2015-08-27 |
Diego José Correa Hidalgo |
Thermo heater comprising: a tank (1) made of glass, fitted with a cover (7) and a number of magnetrons (3) supported by a belt or a support framework (2) surrounding the tank (1), which offer the magnetrons continued support and which may be arranged inside the tank (1). Each one of the magnetrons (3) is housed on a primary exchanger (5) and this, in turn, on the main exchanger (6). A solenoid (8) is arranged on the cover, as well as a support for a rod thermostat and the water inlets and outlets. A mixing valve (20) is arranged under the cover, connected by a regulator (17) with a cover and operated by means of a piston (15) connected to the solenoid. The mixing valve is a double filter valve. Thanks to the characteristics of the materials used, the following is achieved: almost instant heating, a reduction of energy consumption and effective protection against the proliferation of colonies such as legionella. |
77 |
Controlling the Heating of Rooms |
US13912247 |
2013-06-07 |
US20140365016A1 |
2014-12-11 |
Michael John Hartley; Anthony David Gair |
In a building, electric storage heaters (204) receive off peak electricity, generate thermal energy and store this thermal energy for later release. Each storage heater has a local control device (201) for controlling thermal energy generated during the reception of the off peak electricity. Each local control device receives a generation schedule from a building control device (207). Each building control device controls many local control devices and transmits information to a central control device (208). The central control device transmits generation schedules to many building control devices. Each schedule is constructed in response to room related data supplied by the local control devices, building related data supplied by the building control devices and regional data supplied to the central control device. |
78 |
Radiant system for heat transfer |
US13013219 |
2011-01-25 |
US08718455B2 |
2014-05-06 |
Gianni Mottola; Maurizio Santin |
A radiant heating system includes a molded agglomeration of inert natural stone waste and a heating element embedded in the agglomeration. The agglomeration contains 45-55% by weight of stone particles having a size from 1 to 5 mm; 30-35% by weight of stone dust having a size from 0.01 mm to 0.5 mm; and 20-25% by weight of a resin having a water-based acrylic component. |
79 |
Radiant System for Heat Transfer |
US13013219 |
2011-01-25 |
US20110182565A1 |
2011-07-28 |
Gianni Mottola; Maurizio Santin |
A radiant heating system includes a molded agglomeration of inert natural stone waste and a heating element embedded in the agglomeration. The agglomeration contains 45-55% by weight of stone particles having a size from 1 to 5 mm; 30-35% by weight of stone dust having a size from 0.01 mm to 0.5 mm; and 20-25% by weight of a resin having a water-based acrylic component. |
80 |
Heat storage type heater and method of controlling input and output of heat of the same |
US10845123 |
2004-05-14 |
US07058292B2 |
2006-06-06 |
Satoshi Hirano |
A method of controlling the input and output of heat to and from a heat-storing material. The method includes the step of externally supplying thermal energy to the heat-storing material capable of being supercooled and filled into a plurality of small containers together with a phase-segregation preventive agent by use of a structure for supplying heat, whereby the heat-storing material is melted. The method also includes the steps of maintaining the heat-storing material in the supercooled state after the emission of sensible heat, and releasing the supercooled state of the heat-storing material by use of a structure for releasing the supercooled state of the heat-storing material, when the release of the stored heat energy is required, whereby the heat at the melting point is generated. |