| 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 | 一种热管式散热器及其生产工艺 | CN201610607841.8 | 2016-07-29 | CN106028764A | 2016-10-12 | 姚国富 |
| 本发明公开了一种热管式散热器,包括热管,所述热管外侧均匀覆盖有翅片,所述翅片上设有通孔,所述热管底部连通有导流管。该热管式散热器及其生产工艺,具有结构设计合理、散热效率高,操作简单、安全实用等优点,同时能大幅度提高散热器的使用寿命,可以普遍推广使用。 | ||||||
| 2 | 通过铸造结合在热交换器中的多孔金属体 | CN200880112655.0 | 2008-10-08 | CN101836051A | 2010-09-15 | K·于博; J·伯凯尔; P·蒂森; J·范佩特盖姆; F·格伦 |
| 本发明涉及一种用于中央供暖锅炉的共铸热交换器元件,所述热交换器元件基本上由铝制成,所述热交换器元件带有围绕载水通道的壁,并且带有封闭燃烧器可以连接到的至少一个废气道的至少一个壁,围绕所述至少一个废气道的至少一个壁被水冷却,原因在于它也形成所述载水通道的边界,而水冷却壁之一带有在各自废气道中延伸的扩大热交换表面的销柱和/或翼片并且也带有扩大热交换表面的其他金属多孔结构。 | ||||||
| 3 | 一种铸铝复合金属换热装置及其制作方法 | CN201611107012.X | 2016-12-06 | CN106500525A | 2017-03-15 | 王亮添; 林特耀; 何卫国; 刘闪闪; 刘峰 |
| 本发明公开了一种铸铝复合金属换热装置,包括导热管和与导热管连接的框架,所述框架包括外框和与外框固定连接的散热肋片,所述散热肋片的两侧分别连接相邻的导热管管壁。本发明涉及换热装置领域,将散热肋片设置于外框上,散热肋片与外框直接接触,外框可以为散热肋片传递导热,增加导热面积,换热效果更佳。散热肋片的两侧分别连接相邻的导热管管壁,同一散热肋片可同时为相邻两段导热管增加换热面积,缩小了换热器的整体体积。使用时,多个铸铝复合金属换热装置并排组装构成换热器,散热肋片与换热管之间构成连续起伏的面,使得换热介质流经时多次形成湍流或涡流,从而使换热管和散热肋片的表面不易结垢。 | ||||||
| 4 | 制造冷却元件的方法及一种冷却元件 | CN98809847.4 | 1998-08-03 | CN1112977C | 2003-07-02 | M·斯马伦; E·米蒂南 |
| 一种用来制造电源电子部件冷却元件和其他电器装置冷却设备的方法,其中熔融金属被浇入一闭合铸型,该闭合铸型包括一芯部(10)和一铸型部分,并让熔融金属凝固,在此之后从铸型取出完工的铸件。借助于把一些薄板(5)彼此紧靠地压紧在一起从而在所述薄板之间保留空气间隙的方法装配一个由多块薄板(5)组成的插入物组件(2),所述薄板(5)用至少基本上与浇铸材料相符的一种材料制成。加工插入物组件(2),使它能配装到芯部(10)内的一个凹槽(11)中,而且组件(2)的至少一个加工表面在芯部(10)和插入物组件之间形成一个紧密连接,而且,在闭合铸型之前将插入物组件(2)定位在芯部凹槽(11)中,借此一旦铸型被充填,组件就被固定在铸件上。 | ||||||
| 5 | 制造冷却元件的方法及一种冷却元件 | CN98809847.4 | 1998-08-03 | CN1273543A | 2000-11-15 | M·斯马伦; E·米蒂南 |
| 一种用来制造电源电子部件冷却元件和其他电器装置冷却设备的方法,其中熔融金属被浇入一闭合铸型,该闭合铸型包括一芯部(10)和一铸型部分,并让熔融金属凝固,在此之后从铸型取出完工的铸件。借助于把一些薄板(5)彼此紧靠地压紧在一起从而在所述薄板之间保留空气间隙的方法装配一个由多块薄板(5)组成的插入物组件(2),所述薄板(5)用至少基本上与浇铸材料相符的一种材料制成。加工插入物组件(20),使它能配装到芯部(10)内的一个凹槽(11)中,而且组件(2)的至少一个加工表面在芯部(10)和插入物组件之间形成一个紧密连接,而且,在闭合铸型之前将插入物组件(2)定位在芯部凹槽(11)中,借此一旦铸型被充填,组件就被固定在铸件上。 | ||||||
| 6 | 带有管的散热器的分配和收集头以及制造方法 | CN200980159248.X | 2009-05-12 | CN102428337B | 2014-10-22 | 卡诺·佩利佐拉 |
| 本发明公开了用于带有管的散热器的分配和收集头(2,4),其具有配备有管状插件(22)的内导管(20)。该头的主体是压铸铝合金制成的;该插件是钢制成的。另外,该管利用莫氏圆锥形状的管末端通过受迫连接而连接至该头。 | ||||||
| 7 | 热交换器元件及其制造方法和包含该元件的供暖锅炉 | CN200880112655.0 | 2008-10-08 | CN101836051B | 2013-07-31 | K·于博; J·伯凯尔; P·蒂森; J·范佩特盖姆; F·格伦 |
| 本发明涉及一种用于中央供暖锅炉的共铸热交换器元件,所述热交换器元件基本上由铝制成,所述热交换器元件带有围绕载水通道的壁,并且带有封闭燃烧器可以连接到的至少一个废气道的至少一个壁,围绕所述至少一个废气道的至少一个壁被水冷却,原因在于它也形成所述载水通道的边界,而水冷却壁之一带有在各自废气道中延伸的扩大热交换表面的销柱和/或翼片并且也带有扩大热交换表面的其他金属多孔结构。 | ||||||
| 8 | 带有管的散热器的分配和收集头以及制造方法 | CN200980159248.X | 2009-05-12 | CN102428337A | 2012-04-25 | 卡诺·佩利佐拉 |
| 本发明公开了用于带有管的散热器的分配和收集头(2,4),其具有配备有管状插件(22)的内导管(20)。该头的主体是压铸铝合金制成的;该插件是钢制成的。另外,该管利用莫氏圆锥形状的管末端通过受迫连接而连接至该头。 | ||||||
| 9 | JPH0128667B2 - | JP6435582 | 1982-04-16 | JPH0128667B2 | 1989-06-05 | KAWAHARA MASUMI; IGARASHI SHINJI |
| 10 | JPS5636358B2 - | JP13191575 | 1975-10-31 | JPS5636358B2 | 1981-08-24 | |
| 11 | ヒートシンクの製造方法 | JP2017073806 | 2017-04-03 | JP2018176166A | 2018-11-15 | 三浦 光博; 永川 悠太 |
| 【課題】熱放射性樹脂被膜を形成するために基材を別途加熱する必要がなく生産性に優れ、かつ、基材の表面に形成する熱放射性樹脂被膜の膜厚を均一にすること。 【解決手段】本発明の一態様に係るヒートシンクの製造方法は、基材の表面に熱放射性樹脂被膜が形成されたヒートシンクの製造方法であって、基材をダイカスト鋳造した後、ダイカスト用金型から基材を取り出すステップと、ダイカスト用金型から取り出した基材の余熱を用いて、基材の表面に熱放射性樹脂被膜を形成するステップと、を備えている。熱放射性樹脂被膜を形成するステップにおいて、基材の表面に熱放射性樹脂フィルムを貼り付けることによって、基材の表面に熱放射性樹脂被膜を形成する。 【選択図】図2 |
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| 12 | Manufacturing method and the cooling element of the cooling element | JP2000509547 | 1998-08-03 | JP2001514976A | 2001-09-18 | ミーティネン エルッキ; スマレン マッティ |
| (57)【要約】 電力用の電子部品および他の電気器具のための冷却要素の製造方法であって、中央部分(10)および溶融金属を固化させることができる鋳型部分を具える閉鎖した鋳型へ溶融金属を注型し、この溶融金属を固化しうるようにした後、完成した鋳造品を鋳型より取り外す。 インサートパッケージ(2)は、少なくとも鋳造材料と一致する材料より作られた層板(5)を、この複数の層板(5)を、それらの間に空気用の溝を残すように相互に隣接して配置し、これら層板を押し嵌めすることにより組み立てる。 このインサートパッケージ(2)は、中央部分(10)の溝(11)に嵌り込むように加工され、またパッケージ(2)の少なくとも一つの加工された表面が、中央部分(10)とパッケージ(2)との間の密封された結合を形成する。 またインサートパッケージ(2)は鋳型を閉鎖する前に中央部分の溝(11)内に配置され、それによって、一旦鋳型が充填されると、鋳造品に固定される。 | ||||||
| 13 | JPS6242699B2 - | JP7741778 | 1978-06-28 | JPS6242699B2 | 1987-09-09 | HAYASHI MASAKATSU; TANAKA TAKEO; NATORI TATSUO; AIZAWA TATSUSHI; KOJIMA SHIGERU; CHIAKI TAKAO |
| 14 | Production of heat exchanger | JP7741778 | 1978-06-28 | JPS555152A | 1980-01-16 | HAYASHI MASAKATSU; TANAKA TAKEO; NATORI TATSUO; AIZAWA TATSUSHI; KOJIMA SHIGERU; CHIAKI TAKAO |
| PURPOSE:To obtain the heat exchangers of superior heat tansfer characteristics, lightness in weight and small sizes by using the casting molds using the specific resins as a pattern and integrally forming fin plates and porous metals around the zigzag pipe by the special method in producing the heat exchangers. CONSTITUTION:With resins having continous cavities such as foamed urethane or the like as a pattern, casting mold material such as of plaster slurry is filled in the abovementioned cavities and the resins are removed by heating or the like, whereby split film casting molds 6, 7 are formed. The casting molds 6, 7 are incorporated to a heat transfer pipe 1 having beforehand molded to zigzag form in the lengthwise direction of the plural pipes 1 by leaving a clearance 9. Molten metal such as copper or other is filled through vacuum or pressure operation into the holes of the casting molds 6, 7 and the clearances 9. After the metal has solidified, the casting molds are removed. This yields the heat exchanger integrally molded with the fin blocks 2 having the heat transfer pipe 1, fin plates 3, and three-dimensional continuous spaces 4. The fin plates 3 improve the coupling and heat transfer and reception between the blocks 2 and heat transfer pipe 1. It is also possible to perform the removal of the foregoing resin patterns after incorporation to the heat transfer pipe 1. | ||||||
| 15 | PART OF A CONTAINER FOR ELECTRONIC EQUIPMENT, HAVING THE FUNCTION OF A HEAT SINK, AND METHOD FOR MAKING IT | US14550102 | 2014-11-21 | US20150144319A1 | 2015-05-28 | Gianfranco NATALI |
| A part (1) of a container for electronic equipment, having the function of a heat sink, comprises a base (2) having mainly two-dimensional extension parallel with a first plane of extension, and a plurality of dissipation fins (3) fixed to the base (2) and also having mainly two-dimensional extension parallel with one or more second planes of extension which are transversal to the first plane of extension. The part (1) comprises a supporting body (4) and one or more metal inserts (5) irremovably connected to the supporting body (4), each metal insert (5) being constituted of a single piece made by extrusion and comprising a group of fins (3) and a connecting portion (7) connecting the fins (3) of the group to one another and at least partly irremovably embedded in the supporting body (4) by overmolding of the supporting body on the insert (5); the base (2) of the part (1) is constituted of both the supporting body (4) and each connecting portion (7) of the one or more inserts (5). | ||||||
| 16 | Multi component reactive metal penetrators, and their method of manufacture | US11764036 | 2007-06-15 | US08573128B2 | 2013-11-05 | Roger S. Storm; Vladimir Shapovalov; James C. Withers; Raouf Loutfy |
| A penetrator comprising a layered composite of at least one high density metal and at least one reactive metal material such as a reactive metal. | ||||||
| 17 | HEAT-DISSIPATING MODULE AND METHOD FOR MANUFACTURING THE SAME | US13351204 | 2012-01-16 | US20130180688A1 | 2013-07-18 | Chia-Yu Lin; Lei-Lei Liu |
| In a heat-dissipating module and a method for manufacturing the same, a hollow aluminum tube is put on a corresponding heat pipe to form an aluminum-skinned heat pipe. Then, one or more aluminum-skinned heat pipes are disposed in a casting space of a die casting mold. Fins are disposed into the die casting mold. Molten aluminum materials are filled in the casting space of the die casting mold to form a heat-dissipating module. By using a die casting process, molten aluminum materials are used to cover at least one aluminum-skinned heat pipe and connect with the fins, thereby finishing the heat-dissipating module. | ||||||
| 18 | HEAT DISSIPATING FIN, HEAT DISSIPATING DEVICE AND METHOD OF MANUFACTURING THE SAME | US13329313 | 2011-12-18 | US20130153189A1 | 2013-06-20 | Chia-Yu Lin; Yen Tsai |
| A heat dissipating device includes a base and a plurality of heat dissipating fins. Each of the heat dissipating fins includes a heat dissipating portion, a fixing portion and an overflow-proof structure. The fixing portion is fixed in the base. The overflow-proof structure is connected between the heat dissipating portion and the fixing portion. A width of the overflow-proof structure is larger than a width of the heat dissipating portion and larger than a width of the fixing portion. | ||||||
| 19 | METALLIC POROUS BODY INCORPORATED BY CASTING INTO A HEAT EXCHANGER | US12680009 | 2008-10-08 | US20100242863A1 | 2010-09-30 | Karel Hubau; Johannes Beukers; Paul Thijssen; Jan Van Peteghem; Frank Geelen |
| The present invention relates to a co-cast heat exchanger element intended for a central heating boiler, which heat exchanger element is made from substantially aluminum, the heat exchanger element being provided with walls which enclose a water carrying channel, and with at least one wall which encloses at least one flue gas draft to which a burner can be connected, at least one wall which encloses the at least one flue gas draft being water-cooled in that it also forms a boundary of the water-carrying channel, while one of the water-cooled walls is provided with heat exchanging surface enlarging pins and/or fins which extend in the respective flue gas draft and is also provided with other heat exchanging surface enlarging metallic porous structures. | ||||||
| 20 | Radiator shaping device | US09321107 | 1999-05-27 | US06257314B1 | 2001-07-10 | Dah-Chyi Kuo |
| A radiator shaping device comprises a lower mold, an upper mold, and two movable molds. The lower mold is installed with a lower chamber; The upper mold installed with an upper chamber, after the lower mold and the upper mold are engaged, a closing space is formed therewithin. The movable molds having a plurality of inserting plates which serves to insert into the fins at two ends of an aluminum folded radiating piece so as to support the folded radiating piece from the two ends thereof. Then it is further placed into the closing space for separating the space as a lower space and an upper space. Next, aluminum liquid is filled into the filling hole of the upper mold. After cooling, the mold is detached, therefore, a high heat dissipating radiator with a lower plate integrally formed in the lower surface of a folded radiating piece is formed by above components. Especially, by the shaping device of the present invention, the aluminum folded radiating piece and the lower plate can be combined together and have identical property. Thus, the heat conductive glue or other material for adhesion is unnecessary. Thus, heat conduction is more rapid, directly and steadily. The defect of prior art radiator in which glue connection is adapted is overcome by the present invention. | ||||||
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