| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 21 | Falling film heat exchanger, absorption chiller system, and ships, offshore structures, underwater structure | JP2011197237 | 2011-09-09 | JP5607006B2 | 2014-10-15 | 拓樹 中村; 雅樹 川瀬 |
| A guide plate 22A, 22B having depressed portions 22 is provided between an array of heat exchanger tubes 21 arranged side by side in a horizontal direction and a next lower array of heat exchanger tubes 21 arranged side by side in the horizontal direction, and is positioned with the lowest parts of the depression portions 22a disposed near crest portions of the respective lower heat exchanger tubes 21. Thus, the guide plate is configured to convey a liquid D flowing down on outer surfaces of the respective upper heat exchanger tubes 21 onto the lower heat exchanger tubes 21 having one-to-one correspondences to the upper heat exchanger tubes 21 even when an inclination in a right-and-left direction of the heat exchanger tubes 21 occurs. Having this configuration, a falling film heat exchanger installed in a ship, an offshore structure, an underwater offshore structure or the like can avoid reduction in heat exchange performance, even when the ship or the like inclines and swings, by substantially evenly distributing and dropping a liquid such as a coolant or absorber onto the crests of the heat exchanger tubes and causing the liquid dropped from the heat exchanger tubes located in an upper array to surely fall onto the heat exchanger tubes located in the next lower array. | ||||||
| 22 | Carbon dioxide separation method and apparatus | JP2011524648 | 2010-07-22 | JP5571085B2 | 2014-08-13 | 恭敏 庄司; 朗 木村; 輝雄 岸本 |
| Provided is a carbon dioxide separation method and a carbon dioxide separation apparatus capable of maintaining a carbon dioxide adsorption capacity for a long term by collecting an amine compound that evaporates during an operation of the apparatus and reloading the amine compound onto a carbon dioxide adsorbent. An amine collector 11 and an amine aqueous solution preparation device 14 are connected to an adsorbent-packed tank 1 packed with a carbon dioxide adsorbent 2. An amine compound that evaporates from the carbon dioxide adsorbent 2 during an operation of the apparatus is collected by the amine collector 11 into the amine aqueous solution preparation device 14. The collected amine compound is reloaded onto the carbon dioxide adsorbent 2 via a supply line 7. | ||||||
| 23 | Falling film type heat exchanger, absorption refrigeration system, ship, offshore structure and underwater structure | JP2011197237 | 2011-09-09 | JP2013057485A | 2013-03-28 | NAKAMURA TAKUKI; KAWASE MASAKI; ITOJIMA AKIRA; JITSUKAWA HIROTAKE |
| PROBLEM TO BE SOLVED: To provide a falling film type heat exchanger that substantially uniformly distributes liquid such as a refrigerant or an absorption liquid and drops the liquid on apexes of heat exchanger tubes in the falling film type heat exchanger, can make the liquid dropped from the heat exchanger tubes located in an upper row surely fall on surfaces of the heat exchanger tubes located in a lower row, and can avoid the lowering of heat exchanging performance even if being mounted to a ship, an offshore structure, an underwater structure or the like and applied with the inclination and the oscillation of the ship or the like, and to provide an absorption refrigeration system, the ship, the offshore structure, the underwater structure.SOLUTION: A guide plate 22A having a recess 22a is arranged between a row of heat exchanger tubes 21 which are aligned in a horizontal direction and a row of the heat exchanger tubes 21 which are aligned in a horizontal direction below the row so that the lowest portion of the recess 22a is located in the vicinity of apex portions of the respective heat exchanger tubes 21 at the lower side, and fluids falling down on external surfaces of the respective heat exchanger tubes 21 at the upper side are transferred to the heat exchanger tubes 21 at the lower side corresponding to the upper-side heat exchanger tubes 21 in a one-on-one manner even if the heat exchanger tubes 21 are inclined in left and right directions. | ||||||
| 24 | Falling film type heat exchanger, absorption refrigeration system, ship, offshore structure and underwater structure | JP2011197227 | 2011-09-09 | JP2013057484A | 2013-03-28 | NAKAMURA TAKUKI; KAWASE MASAKI; ITOJIMA AKIRA; JITSUKAWA HIROTAKE |
| PROBLEM TO BE SOLVED: To provide a falling film type heat exchanger that substantially uniformly distributes liquid such as a refrigerant or an absorption liquid and drops the liquid on apexes of heat exchanger tubes in the falling film type heat exchanger, can make the liquid dropped from the heat exchanger tubes located in an upper row surely fall on surfaces of the heat exchanger tubes located in a lower row, and can avoid the lowering of heat exchanging performance even if being mounted to a ship, an offshore structure, an underwater structure or the like and applied with the inclination and the oscillation of the ship or the like, and to provide an absorption refrigeration system, the ship, the offshore structure, the underwater structure.SOLUTION: In the falling film type heat exchanger 20, a liquid distribution device 10 which distributes the liquid D on the external surfaces of the heat exchanger tubes 21 which are distributed in a wide area is constituted of: a distribution tank 11; a plurality of discharge devices 12 which discharge the liquid D from the distribution tank 11; and a first distribution passage 13 which receives the liquid D from the discharge devices 12. The liquid D is introduced into a region assigned by the first distribution passage 13, and the liquid D is dropped to the heat transfer pipes 21. | ||||||
| 25 | 二酸化炭素分離方法及び装置 | JP2011524648 | 2010-07-22 | JPWO2011013332A1 | 2013-01-07 | 庄司 恭敏; 恭敏 庄司; 朗 木村; 輝雄 岸本 |
| 稼働中に蒸散するアミン化合物を回収して二酸化炭素吸着材に再担持することにより、二酸化炭素吸着能を長期間維持し得る二酸化炭素分離方法及び装置を提供する。二酸化炭素吸着材2を充填した吸着材充填槽1にアミン回収装置11とアミン水溶液調合装置14とを接続し、稼働中に二酸化炭素吸着材2から蒸散したアミン化合物をアミン回収装置11によりアミン水溶液調合装置14に回収し、回収したアミン化合物を供給ライン7を介して二酸化炭素吸着材2に再担持させる。 | ||||||
| 26 | JPH0456920B2 - | JP50415184 | 1984-11-12 | JPH0456920B2 | 1992-09-09 | JABU ARUBAATO |
| 27 | System for transferring fluid to second pressure region fromfirst pressure region and returning it to first pressure region | JP6876187 | 1987-03-23 | JPS62237084A | 1987-10-17 | YORUGU HAASU |
| 28 | Marine fluid controller | JP9500482 | 1982-06-04 | JPS584693A | 1983-01-11 | DEBITSUDO MAATEIN HAARERU |
| 29 | JPS5024357B1 - | JP1839564 | 1964-04-01 | JPS5024357B1 | 1975-08-14 | |
| 30 | Heat reclamation and temperature control for submersible vehicles that utilize fuel cells | US14319091 | 2014-06-30 | US09716284B2 | 2017-07-25 | Michael J Marich; Joshua M Mermelstein; Michael Webber |
| Embodiments described herein provide for heat reclamation and temperature control of a SOFC for a submersible vehicle. The vehicle includes a SOFC, a hot box that surrounds the SOFC, a cooling loop, and a Stirling engine. The cooling loop has a heat exchanger and a coolant pump. The heat exchanger thermally couples the cooling loop to the water. The Stirling engine has a first end thermally coupled to an interior of the hot box and a second end thermally coupled to the cooling loop. The coolant pump modifies a rate of heat removal from the second end of the Stirling engine based on a pump control signal. A thermal management controller monitors a temperature of a cathode outlet of the SOFC, and modifies the pump control signal to maintain the temperature of the cathode outlet within a temperature range. | ||||||
| 31 | Underwater vehicle provided with heat exchanger | US14596935 | 2015-01-14 | US09505478B2 | 2016-11-29 | Mauro Peselli |
| An electric battery for the propulsion of vehicles in an underwater environment, comprising a cylindrical tubular casing defining a main chamber housing an anhydrous electrolyte; intake members to transfer a flow of water from the marine environment to the main chamber, to form, following execution of a water-intake command, a liquid electrolyte; a plurality of electrochemical cells housed in the tubular casing; a heat exchanger receiving as input electrolyte taken from the main chamber and an outlet communicating with an inlet of the electrochemical cells. The heat exchanger is provided in the cylindrical tubular portion and comprises at least one channel made in an inner wall of the cylindrical tubular portion, and extending along a helical path coaxial to the axis of the tubular portion. | ||||||
| 32 | Variable speed drive for subsea applications | US14645706 | 2015-03-12 | US09496798B2 | 2016-11-15 | Ove Boe |
| A Variable Speed Drive (1) for subsea installations (20), subsea vessels or subsea vehicles, as well as to a corresponding subsea installation (20), subsea vessel or subsea vehicle, has an alternating current/alternating current converter (2) having a current-controlled capacitor-less direct current link (7). | ||||||
| 33 | SUBMARINE STRUCTURE | US15066176 | 2016-03-10 | US20160264224A1 | 2016-09-15 | Chen-Hsin LIN |
| A submarine structure provides a submarine in which the interior thereof is formed with an accommodation space and an electricity storing chamber connected to the accommodation space and having a battery and a power set having a propeller, and includes: at least one pipe, having the interior installed with at least one cable; at least one floating member, connected to another end of the at least one pipe; at least one energy supplier, disposed and in the floating member or the accommodation space and located at a relatively higher location inside the floating member or the accommodation space; and at least one control board, installed in the accommodation space of the submarine or the floating member, wherein the control board is connected to the energy supplier through the cable of the at least one pipe for providing power and maintaining communication and control. | ||||||
| 34 | Natural Gas Transport Vessel | US14480014 | 2014-09-08 | US20160068243A1 | 2016-03-10 | Jesse R. Cheatham, III; Tom Driscoll; Alexander Galt Hyde; Roderick A. Hyde; Muriel Y. Ishikawa; Jordin T. Kare; Nathan P. Myhrvold; Tony S. Pan; Robert C. Petroski; David R. Smith; Clarence T. Tegreene; Nicholas W. Touran; Yaroslav A. Urzhumov; Charles Whitmer; Lowell L. Wood, JR.; Victoria Y.H. Wood |
| A lightweight transport vessel transports compressed natural gas underwater without needing to liquefy the gas for transport. | ||||||
| 35 | UNDERWATER FLOATING BODY AND INSTALLATION METHOD THEREOF | US14771298 | 2013-03-28 | US20160068238A1 | 2016-03-10 | Jun Yan; Yao Zhao; Yu Wang; Hua Shao; Shu Xiong |
| The present invention relates to the technical field of ships, and particularly relates to an underwater floating body and an installation method thereof. The floating body includes sub-cabins and pressure resistant cabins, symmetrically arranged sub-cabins are arranged at the left and right sides of the floating body, the sub-cabins are arranged at the front and back sides of the floating body, the buoyant force provided by the sub-cabins at the front side of the floating body is larger than the buoyant force provided by the sub-cabins at the back side of the floating body. According to the underwater floating body and the installation method thereof provided by the present invention, the underwater floating body can arrive at the working water area at one step, thereby saving a large amount of manpower and material resources. | ||||||
| 36 | Air intake device | US13529586 | 2012-06-21 | US09187162B2 | 2015-11-17 | Vittorio Stella |
| An air intake device for a submarine comprises a first fixed member connected to the submarine hull and a second member which is telescopically movable relative to the first member to rise up with an upper end of it above the water's surface to allow air to be taken in from the atmosphere during navigation of the submarine at periscope depth, the movable member mounting at its upper end a radar device designed to emerge from the water together with the selfsame movable member. | ||||||
| 37 | MANNED SUBMARINE FOR UNDERWATER VIEWING AND EXPERIENCE | US14163977 | 2014-01-24 | US20150210368A1 | 2015-07-30 | HYO JIN LEE |
| A manned submarine for underwater viewing and experience. A viewing window through which an outside view can be seen is disposed above the body of the submarine. The viewing window has an internal space and is open in the lower portion thereof. The propulsion systems provides a propelling force to the body. The ascending and descending system allows the manned submarine to ascend on the water or to descend under the water. The control box disposed at the forecastle of the body controls the operations of the propulsion systems, and the ascending and descending system. The viewing window is disposed above the crew room and is configured to allow water to enter the crew room except the internal space of the viewing window to allow the passengers to breathe underwater and provide a high level of leisure experience in addition to the visual viewing experience. | ||||||
| 38 | Variable Speed Drive for Subsea Applications | US14645706 | 2015-03-12 | US20150188444A1 | 2015-07-02 | Ove Boe |
| A Variable Speed Drive (1) for subsea installations (20), subsea vessels or subsea vehicles, as well as to a corresponding subsea installation (20), subsea vessel or subsea vehicle, has an alternating current/alternating current converter (2) having a current-controlled capacitor-less direct current link (7). | ||||||
| 39 | HIGH SPEED SURFACE CRAFT AND SUBMERSIBLE VEHICLE | US14231887 | 2014-04-01 | US20150068441A1 | 2015-03-12 | Gregory E. Sancoff |
| A submersible vessel comprising: an elongated hull; at least one propeller mounted on a forward end of said hull and adapted to move said hull through water; said at least one propeller being of a size and configuration such that when it is rotated at an appropriate speed, it generates supercavitated water flowing from said at least one propeller and thence along an outer surface of said hull so as to diminish friction on the outer surface of said hull and facilitate high underwater speeds. | ||||||
| 40 | FALLING FILM HEAT EXCHANGER, ABSORPTION REFRIGERATOR SYSTEM, SHIP, OFFSHORE STRUCTURE AND UNDERWATER OFFSHORE STRUCTURE | US14234574 | 2012-08-16 | US20140231058A1 | 2014-08-21 | Takuju Nakamura; Masaki Kawase |
| A guide plate having depressed portions is provided between an array of heat exchanger tubes, herein after “tubes”, arranged horizontally side-by-side and a next lower array of tubes arranged horizontally side-by-side, and is positioned with the lowest parts of the depressed portions near crest portions of respective lower tubes. The guide plate conveys a liquid D on outer surfaces of respective upper tubes onto similarly positioned lower tubes even when the tubes move in a right-and-left direction. A falling film heat exchanger installed in a ship, an offshore structure or the like can avoid reduction in heat exchange performance, even when the ship or the like inclines and swings, by substantially evenly distributing and dropping a liquid onto the crests of the tubes and causing the liquid dropped from the tubes located in an upper array to fall onto the tubes located in the next lower array. | ||||||
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