| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 液体加热器和液体加热方法 | CN200980134691.1 | 2009-08-31 | CN102138045B | 2015-11-25 | 内田稔; 丸山刚 |
| 一种在短时间内将过硫酸溶液等流体加热至高温的液体加热器。所述液体加热器包括:流道构件,该流道构件由能被近红外线穿过的材料构成,并形成能流过液体的流道厚度在10mm以下的流道(4);以及近红外线加热器(7、8),该近红外线加热器(7、8)配置在该流道的相对的流道面中至少一方的外侧以对所述流道内的所述液体进行加热。利用近红外线将流过所述流道的液体瞬间均匀地加热。作为优选在流道(4)内部还包括限制流道容量的隔板(6)。通过减小加热器内的流道容积且增大加热器内的流速,从而缩短加热器内的滞留时间,并尽可能较大地维持传热面积,即使传热面温度的设定温度较低也能将被加热液体在很短的时间内升温至高温。 | ||||||
| 2 | 液体加热单元、具有该单元的液处理装置和液处理方法 | CN201110264261.0 | 2011-09-01 | CN102401465A | 2012-04-04 | 西田俊彦; 江岛和善; 中山寿一 |
| 本发明提供一种液体加热单元、具有该单元的液处理装置和液处理方法。液体加热单元、具有该液体加热单元的液处理装置、液处理方法能够对内部的液体由于放射光的透过而被加热的液体存储槽或者导管的温度进行监视。本发明公开了一种液体加热单元,其包括:灯加热器,其放射出放射光;圆筒构件,其具有能够供上述灯加热器在内部空间中贯穿的圆筒形状,并由可透过上述放射光的材料形成;液体流通部,其沿着上述圆筒构件的外周部配置,并利用上述放射光来加热流过内部的液体;反射板,其从外侧覆盖上述液体流通部,并反射上述放射光;第1温度传感器,其安装在上述反射板的外部。 | ||||||
| 3 | 灯及加热装置 | CN200980111851.0 | 2009-03-27 | CN101983537A | 2011-03-02 | 前田则行; 岩原健吾 |
| 提供一种构造简单且可以有效地防止密封部过热的灯及加热装置。灯(1)具有:管部(11),容纳了具有线圈部(14)的灯丝(13);密封部(12),密封连接于上述灯丝(13)末端的金属箔(16);及过热防止部(30),覆盖上述管部(11)的外表面(11a)的一部分。 | ||||||
| 4 | 液体加热单元、具有该单元的液处理装置和液处理方法 | CN201110264261.0 | 2011-09-01 | CN102401465B | 2014-09-24 | 西田俊彦; 江岛和善; 中山寿一 |
| 本发明提供一种液体加热单元、具有该单元的液处理装置和液处理方法。液体加热单元、具有该液体加热单元的液处理装置、液处理方法能够对内部的液体由于放射光的透过而被加热的液体存储槽或者导管的温度进行监视。本发明公开了一种液体加热单元,其包括:灯加热器,其放射出放射光;圆筒构件,其具有能够供上述灯加热器在内部空间中贯穿的圆筒形状,并由可透过上述放射光的材料形成;液体流通部,其沿着上述圆筒构件的外周部配置,并利用上述放射光来加热流过内部的液体;反射板,其从外侧覆盖上述液体流通部,并反射上述放射光;第1温度传感器,其安装在上述反射板的外部。 | ||||||
| 5 | 液体加热器和液体加热方法 | CN200980134691.1 | 2009-08-31 | CN102138045A | 2011-07-27 | 内田稔; 丸山刚 |
| 一种在短时间内将过硫酸溶液等流体加热至高温的液体加热器。所述液体加热器包括:流道构件,该流道构件由能被近红外线穿过的材料构成,并形成能流过液体的流道厚度在10mm以下的流道(4);以及近红外线加热器(7、8),该近红外线加热器(7、8)配置在该流道的相对的流道面中至少一方的外侧以对所述流道内的所述液体进行加热。利用近红外线将流过所述流道的液体瞬间均匀地加热。作为优选在流道(4)内部还包括限制流道容量的隔板(6)。通过减小加热器内的流道容积且增大加热器内的流速,从而缩短加热器内的滞留时间,并尽可能较大地维持传热面积,即使传热面温度的设定温度较低也能将被加热液体在很短的时间内升温至高温。 | ||||||
| 6 | 飲料又は食品調製マシンのための体積加熱装置 | JP2016522419 | 2014-06-23 | JP2016527671A | 2016-09-08 | ミン チュアン ファン,; ペーター フォッケンフーバー,; ロバート メデック, |
| 本発明は、放射源であり、電磁放射線を放出し、放射源を少なくとも部分的に囲む液体にエネルギーを伝達するように設計された放射源と、液体導管と、放射スペクトルの電磁放射線に対して本質的に透過性であり、放射源を液体から電気的に分離するように設計された分離手段とを含む、飲料調製マシンのための体積加熱装置を提供する。【選択図】図22 | ||||||
| 7 | INTEGRATED LIGHT AND HEAT ARRANGEMENT OF LOW PROFILE LIGHT-EMITTING DIODE FIXTURE | US15486797 | 2017-04-13 | US20170299167A1 | 2017-10-19 | Hongyi CAI |
| According to aspects of the embodiments, an integrated light and heat arrangement of low profile light-emitting diode (LED) fixture to harness both the light and the heat generated by the LEDs is described. New system architectures and example form factors are provided for the development of new LED fixtures for integrative lighting and heating arrangement to increase their overall luminaire system efficiency. The integrative lighting and heating arrangement of the LED fixture in low profile design can minimize interference of harvesting the heat from LEDs with their light output. The heat which would otherwise be wasted from LEDs is harvested for the purpose of heating up some nearby body, such as a body of air, or a component, or a lens to accomplish some benefits, including, for example, reduction in overall energy uses for space heating, cooling, and lighting and associated cost, and melting snow and de-icing on outdoor LED fixtures for safety and security. | ||||||
| 8 | Heating device using photodetector to detect temperature and method for protecting the same | US14159595 | 2014-01-21 | US09377214B2 | 2016-06-28 | Helge Jacob Krystad; Yueh-Ying Lee; Ying-Chiao Chang |
| A heating device includes a housing having a flow channel, a heater disposed in the flow channel, an optical rod, a light guider and a photodetector. The optical rod has a transparent body, a first end portion, and a second end portion located inside the housing. The light guider is provided at the second end portion for guiding lights emitted by the heater toward the first end portion. The photodetector is located around the first end portion and faces the second end portion for indirectly receiving the lights emitted by the heater to the light guider through the transparent body. The temperature of the heater can be measured efficiently and timely by using the photodetector having a high responding speed, such that an overheat or damage of the heater can be prevented by controlling the heater based on the measured temperature. | ||||||
| 9 | HEATING DEVICE USING PHOTODETECTOR TO DETECT TEMPERATURE AND METHOD FOR PROTECTING THE SAME | US14159595 | 2014-01-21 | US20150204581A1 | 2015-07-23 | Helge Jacob KRYSTAD; Yueh-Ying LEE; Ying-Chiao CHANG |
| A heating device includes a housing having a flow channel, a heater disposed in the flow channel, an optical rod, a light guider and a photodetector. The optical rod has a transparent body, a first end portion, and a second end portion located inside the housing. The light guider is provided at the second end portion for guiding lights emitted by the heater toward the first end portion. The photodetector is located around the first end portion and faces the second end portion for indirectly receiving the lights emitted by the heater to the light guider through the transparent body. The temperature of the heater can be measured efficiently and timely by using the photodetector having a high responding speed, such that an overheat or damage of the heater can be prevented by controlling the heater based on the measured temperature. | ||||||
| 10 | LIQUID HEATING APPARATUS AND LIQUID HEATING METHOD | US12737930 | 2009-08-31 | US20110262120A1 | 2011-10-27 | Minoru Uchida; Tsuyoshi Maruyama |
| Provided is a liquid heating apparatus capable of heating fluid such as peroxosulfuric acid solution to high temperature in a short time. The heating apparatus includes: a flow channel member forming a flow channel 4 allowing liquid to flow and having flow channel thickness of 10 mm or smaller, the flow channel member composed of material transmitting near-infrared rays; and a near-infrared heaters 7, 8 placed over the outside of at least one of opposite flow channel surfaces of the flow channel and heating the liquid in the flow channel. The liquid flowing through the flow channel is instantaneously and evenly heated using near-infrared rays. It is preferable that spacers 6 be further provided within the flow channel 4 in order to limit the volume of the flow channel. Since not only the residence time in the heating apparatus can be shortened but the possible largest heat transfer area can be also maintained by decreasing the volume of the flow channel of the heating apparatus and by increasing the flow velocity in the heating apparatus, it is possible to increase the temperature of liquid to be heated to high temperature in a very short time even if the preset temperature of heat transfer surfaces is low. | ||||||
| 11 | LAMP AND HEATING DEVICE | US12933733 | 2009-03-27 | US20110008028A1 | 2011-01-13 | Noriyuki Maeda; Kengo Iwahara |
| Provided are a lamp and a heating device which are capable of effectively preventing a seal portion from being overheated with a simple structure. A lamp includes: a tube portion in which a filament including a coil portion is contained; a seal portion filled with a metal foil connected to an end of the filament; and an overheat preventing portion covering a part of an outer surface of the tube portion. | ||||||
| 12 | Multi-temperature control system and fluid temperature control device applicable to the same system | US388896 | 1999-09-02 | US6148145A | 2000-11-14 | Kanichi Kadotani |
| A fluid temperature control device is improved to be simpler in structure, less in fluid temperature non-uniformity, and able to heat a fluid having a small light absorbability. The fluid temperature control device has a cylindrical inner vessel (20), a cylindrical outer vessel (22) surrounding the inner vessel (20), and a heating lamp (25) inserted into the inner vessel (20). Metal fins (28a) and (28b) are provided on the inner and outer circumferential surfaces of the inner vessel (20). A working fluid is passed through the inner space (21) between the inner vessel (20) and the heating lamp (25) and a cooling liquid is passed through the outer space (23) between the inner vessel (20) and the outer vessel (22). Infrared rays from the heating lamp (25) heat the working fluid, and the cooling liquid cools the working fluid. This device is applicable to, for instance, temperature control of plural process chambers of semiconductor processing apparatus. A plurality of the temperature control devices are arranged in the vicinity of the semiconductor processing apparatus. Each of the devices is assigned to each of plural portions of the process chambers and provides the temperature-controlled fluid exclusively to each portion. | ||||||
| 13 | Liquid heating unit, liquid processing apparatus including the same, and liquid processing method | JP2010204053 | 2010-09-13 | JP2012057904A | 2012-03-22 | NISHIDA TOSHIHIKO; EJIMA KAZUYOSHI; NAKAYAMA JUICHI |
| PROBLEM TO BE SOLVED: To provide a liquid heating unit capable of monitoring the temperature of a liquid storage tank or pipe in which liquid is heated by permeation of radiated light, to provide a liquid processing apparatus including the same, and to provide a liquid processing method.SOLUTION: The liquid heating unit includes a lamp heater radiating light, a cylindrical member having a cylindrical shape allowing the lamp heater to be inserted in its internal space, and made of a material permeating the radiated light, a liquid conduction section disposed along an outer periphery of the cylindrical member and heating the liquid flowing therein by the radiated light, a reflection plate covering the liquid conduction section from the outside, and reflecting the radiated light, and a first temperature sensor attached to an outer surface of the reflection plate. | ||||||
| 14 | Liquid heater and liquid heating method | JP2008223396 | 2008-09-01 | JP2010060147A | 2010-03-18 | UCHIDA MINORU; MARUYAMA TAKESHI |
| PROBLEM TO BE SOLVED: To provide a liquid heater capable of quickly heating a fluid such as a sulfuric peroxide solution to high temperatures. SOLUTION: The liquid heater includes a flow channel member composed of a material transmitting near infrared rays and forming a flow channel 4 of a thickness of 10 mm or less through which a liquid flows, and near-infrared heaters 7, 8 disposed outside of at least one of the opposing flow channel faces of the flow channel and heating the liquid inside of the flow channel. The liquid flowing through the flow channel is instantly and uniformly heated by means of the near-infrared rays. A spacer 6 for restricting a capacity of the flow channel is preferably disposed inside of the flow channel 4. By reducing a volume of the flow channel inside of the heater and by increasing a flow velocity in the heater, a retention time inside of the heater can be reduced while keeping a heat transfer area as much as possible, thus the heated liquid can be heated to high temperatures in a short time even when a set temperature of a heat transfer face is low. COPYRIGHT: (C)2010,JPO&INPIT | ||||||
| 15 | Lamp and heater | JP2008090785 | 2008-03-31 | JP2009243760A | 2009-10-22 | MAEDA NORIYUKI; IWAHARA KENGO |
| <P>PROBLEM TO BE SOLVED: To provide a lamp and a heater having a simple structure and capable of effectively preventing overheat of sealing parts. <P>SOLUTION: The lamp 1 is provided with tube parts 11 in which filaments 13 having coil parts 14 are stored; the sealing parts 12 in which metallic foils 16 connected to terminals of the filaments 13 are sealed; and overheating prevention parts 30 covering part of outer surfaces 11a of the pipe parts 11. <P>COPYRIGHT: (C)2010,JPO&INPIT | ||||||
| 16 | 液体加熱器および液体加熱方法 | JP2008223396 | 2008-09-01 | JP5610679B2 | 2014-10-22 | 内田 稔; 内田 稔; 丸山 剛; 剛 丸山 |
| 17 | Liquid heating unit, the liquid processing apparatus comprising the same, and liquid processing method | JP2010204053 | 2010-09-13 | JP5307780B2 | 2013-10-02 | 俊彦 西田; 和善 江嶋; 寿一 中山 |
| Disclosed are a liquid heating unit capable of monitoring the temperature of the liquid storage tank or pipe in which liquid is heated by permeation of the radiated light, a liquid processing apparatus including the same, and a liquid processing method. The liquid heating unit includes: a lamp heater radiating light; a cylindrical member having a cylindrical shape made of material permeating the radiated light configured to insert and penetrate the lamp heater into an internal space; a liquid conduction part placed along an outer periphery of the cylindrical member and configured to heat liquid flowing therein by using the radiated light; a reflection plate covering the liquid conduction part from the outside and reflecting the radiated light; and a first temperature sensor attached to an outer surface of the reflection plate. | ||||||
| 18 | Lamps and heating device | JP2008090785 | 2008-03-31 | JP5132392B2 | 2013-01-30 | 則行 前田; 健吾 岩原 |
| 19 | Heating device | EP15151236.5 | 2015-01-15 | EP3045836A1 | 2016-07-20 | Giannoulis, Stylianos |
The application discloses a heating device comprising: a housing having an opening and surrounding an interior space, a fan arranged in proximity to the housing, a heating element arranged in the housing, and a heat distribution element arranged in the housing and in proximity to the heating element, wherein the heating element is adapted to generate heat, the heat distribution element is adapted to transfer the heat generated by the heating element to air in the interior space, and the fan is adapted to provide a flow of air through the interior space of the housing such that the air is heated and the heated air leaves the housing through the opening.
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| 20 | INFRAROTSTRAHLERMODUL UND VERWENDUNG DESSELBEN | EP13718195.4 | 2013-04-24 | EP2861915A1 | 2015-04-22 | FISCHER, Sylvain; RICHTER, Jörg; KONKIEL, Patrick |
| The invention relates to an infrared radiator module for outputting directed infrared radiation (14) at the front module end thereof and a heated air flow (26), said module comprising: an electric infrared emitter (12) for generating the infrared radiation (14); an infrared reflector (16) enclosing the infrared emitter (12) laterally to align the infrared radiation (14) generated by the infrared emitter (12) in the direction of the front module end; a housing (20) enclosing the infrared reflector (16) laterally; and a fan (24) arranged behind the infrared emitter (12) and the infrared reflector (16) to generate an air flow (26) passing through the housing (20). The invention is characterized in that the infrared emitter (12) and the infrared reflector (16) are combined into a unit (18) that is airtight toward the fan (24) and a gap (22) is arranged between the infrared reflector (16) and the housing (20), which gap is open to the exterior of the module and is connected to the fan (24) in a flow-conducting manner. | ||||||
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