M382704 五、新型說明: 【新型所屬之技術領域】 【先前技術】 按,本創作 '有鑑於傳統熱導 .道空間内流動而 點’遂有相關業 而此種氣液分流 者如中華民國專 工方法」發明專 一中空芯材(如 或熱板内部空間 以區隔出蒸發氣 型態於實際使用 劃設計上,係以 則設為冷凝部, •'化所形成的蒸發 -該冷凝部,而該 全部流道空間流 間縱有區隔形成 法確實達成,因 互推擯、衝突干 而有待再加以改 所指熱導構件係包括 構件内部之蒸發氣體 存在容易相互干擾而 者研發出一種氣液分 結構之習知設計已有 利公告編號第407455 利案所揭’其係於熱 管體、毛細組織等) 區隔形成沿著同一方 體流道與冷凝液流道 經驗中發現’由於此 熱管或熱板之一端為 故當該蒸發部受熱時 氣體,事實上會沿著 冷凝部所冷卻形成的 回該蒸發部;所以, 複數流道’但氣液分 此造成蒸發氣體與冷 擾的問題與缺弊存在 良突破。 熱管以及熱板結構; 與冷凝液係於同一通 影響熱導效率之問題 流之結構空間型態, 多種實施型態,常見 號之「散熱管及其加 管或熱板空間中藉由 的設置,以將該熱管 向延伸的複數流道, ;惟,此種習知結構 種熱管或熱板空間規 蒸發部、相對之另端 ,該端内部工作液汽 該全部流道空間流至 冷凝液’ t會沿著該 該熱管或熱板内部* 流的效果實際上並^ 凝液之間仍然會有^目 ,實有未螓完善之處 是以,針對上述習知熱導構件之氣液分流結 之問題點,如何開發一種更具理想實用性之創级所存在 係相關業者須再努力研發突破之目標及方向。構,實 3 Z/U4 - 有鑑於此, 與設計經驗,針 終得一確具實用 創作人 對上述 性之本 本於多 之目標 創作。 年從事相關產品之製造開發 ,詳加設計與審慎評估後, 【新型内 本創 改良,其 分流結構 致蒸發氣 突破; 本創 構件包括 ,其内部 部,設於 設於扁型 蒸發部之 於蒸發部 中區域; 之間,且 ,設於二 間,藉以 空間;二 間中,藉 創新獨特 導構件導 置中區域 透過該二 發部,藉 昇熱管或 容】 作之主 所欲解 設計上 體與冷 作解決 :一扁 相對界 扁型封 封閉殼 間呈間 與冷凝 二側置 位於中 側置式 隔開該 側置式 以將冷 設計, 熱運作 的中置 側置式 此而能 熱板熱 要目的 決之問 仍舊存 凝液之 問題之 型封閉 定形成 閉毂體 體内部 隔配置 部之間 式冷凝 冷凝液 铡置式 毛細組 凝部所 使本創 上,其 式蒸汽 冷凝液 獲得確 導效能 ’係在 題點, 在氣液 間仍會 技術特 殼體, 有呈真 内部空 &間另 關係; ’且位 液導流 汽導流 導流空 冷凝液 織,容 產生的 作對照 蒸發氣 導流空 導流空 實而有 與品質 提供一種扁型熱導構件結構 係針對習知熱導構件之氣液 分流效果無法確實達成,以 相互干擾之問題畔 π點加以改良 點,主 為扁型 空狀態 間一偏 一偏置 一中置 於扁型 空間, 空間相 間與中 導流空 設於二 冷凝液 先前技 體係透 間流向 間之側 效之氣 之實用 要在於戶斤 熱管或熱 之内部空 置部位; 部位,令 式蒸汽導 封閉殼體 設於蒸發 對二側部 置式蒸汽 間與中置 側置式冷 導引至蒸 術而言, 過位在扁 冷凝部, 置式毛細 液分流效 進步性》 迷扁型熱導 板結構型態 間 一冷凝_ 該冷凝部 流空間, 内部空JPgE 部與冷_ 、’二區嗎 導流空控 式蒸汽_ 凝液導 發部;; 所述扁罢 M封閉奪 其冷凝浴果,诘 蒸發 M382704 【實施方式】 請參閱第1 、2 、3圖所示,係本創作扁型熱導構件 結構改良之較佳實施例,惟此等實施例僅供說明之用,在 專利申請上並不受此結構之限制。所述扁型熱導構件A係 包括下述構成: μM382704 V. New description: [New technology field] [Prior technology] According to this, the creation 'in view of the traditional heat conduction, the flow in the space, and the point of 'there are related industries, and such gas-liquid shunts, such as the Republic of China. The method of the invention is to invent a specific hollow core material (for example, the internal space of the hot plate is separated from the evaporation gas type in the actual use design, and is set as the condensation portion, • the evaporation formed by the formation - the condensation portion, However, the method of forming the separation between the flow channels of the entire flow channel is indeed achieved, and the heat conduction member includes the fact that the evaporation gas inside the member is easily interfered with each other due to mutual pushing and conflicting. The conventional design of gas-liquid substructure has been beneficially disclosed in the No. 407455 case. It is found in the heat pipe body, capillary structure, etc. The interval is formed along the same square flow channel and the condensate flow path. One end of the heat pipe or the hot plate is such that when the evaporation portion is heated, the gas actually flows back along the condensation portion to form the evaporation portion; therefore, the plurality of flow paths 'but the gas and liquid are separated There are good breakthroughs in the problems and shortcomings of evaporation gas and cold disturbance. Heat pipe and hot plate structure; structure space type with the same flow affecting the heat transfer efficiency of the condensate, various implementation types, common number "heat pipe and its pipe or hot plate space by the setting To extend the heat pipe to the plurality of flow channels; however, the conventional structure of the heat pipe or the hot plate space gauge evaporation portion, and the opposite end, the internal working liquid vapor of the end flows to the condensate 't will follow the effect of the heat pipe or the inside of the hot plate*. Actually, there will still be a connection between the condensate, and the improvement is that the gas-liquid of the above-mentioned conventional heat-conductive member is The problem of diversion, how to develop a more ideal and practical level of existence, the relevant industry must redouble the goal and direction of research and development breakthrough. Structure, real 3 Z/U4 - In view of this, and design experience, the end of the needle A practical creator has created the goal of the above-mentioned nature. After years of manufacturing and development of related products, after detailed design and careful evaluation, [the new internal innovation, its diversion structure causes evaporation of gas; The innovating member includes an inner portion disposed in a region of the evaporating portion disposed in the flat evaporating portion, and is disposed between the two spaces by the space; and the middle portion of the second portion is guided by the innovative unique guiding member The second hair department, by the heat pipe or the capacity of the main body, is designed to solve the upper body and the cold work solution: a flat opposite boundary flat seal between the closed shell and the condensation side on the middle side of the side separated from the side The arrangement is to form a condensed condensate between the interior of the closed body body and the cold-designed, heat-operated central side-mounted type, which can be used to solve the problem of still condensing liquid. The setting of the capillary group of the condensate makes the steam condensate of the type of the condensate is obtained at the point of the problem, and the technical shell is still present between the gas and the liquid, and there is a relationship between the true internal space and the amp; The liquid-conducting vapor-conducting flow-conducting flow-conducting condensate is woven, and the volume of the air-conducting flow is controlled by the air-conducting air-conducting airflow. The shunting effect can not be achieved, and the problem of mutual interference is improved by π points. The main flat-empty state is biased and placed in a flat space, and the spatial interphase and middle diversion are set in the second condensate. The utility of the prior art system for the side effect of the inter-flow to the inter-flow is mainly due to the heat pipe or the internal vacant part of the heat; the part, the steam-conducting closed casing is arranged in the evaporation side and the side-side steam and the central side. Cold guide to steaming, over-position in the flat condensing section, the placement of the capillary fluid flow-effect progress" condensed between the flat-type heat-conducting plate structure type _ the condensing part flow space, the internal empty JPgE part and cold _ , 'Second Zone Guided Air Control Steam _ Condensate Guide;; The flat stop M closed its condensation bath, 诘 evaporation M382704 【Embodiment】 Please refer to Figures 1, 2, 3, The preferred embodiment of the present invention is a modification of the structure of the flat heat guide member, but the embodiments are for illustrative purposes only and are not limited by the structure in the patent application. The flat type heat conductive member A includes the following composition: μ
一扁型封閉设體10 ’本實施例係為一扁型熱板結構型 態,該扁型封閉殼體10内部相對界定形成有一真空狀態之 内部空間11 ;本實施例所揭扁型封閉殼體1〇係由一上蓋板 1〇1以及一下蓋板102相對組靠結合呈封閉狀所構成者; 一蒸發部20,係設於該扁型封閉殼體1〇内部空間u之 一偏置部位,所述蒸發部20係藉以對位於預定之熱源目標 物(如CPU ),以令該蒸發部2〇之工作液因受熱而蒸發^ 氣體型態; ·»-冷凝 置部位, ,所述冷 一中置 之間,且 當該蒸發 體係經由 二側置 30之間; 二區隔 置式蒸汽 空間50與 二側置 空間50中 部20 ;所 構成者: 其中, 口卩 ου , 令該冷 凝部30 式蒸汽 位於該 部20之 該中置 式冷凝 部60, 導流空 中置式 式毛細 ,藉以 述側置 燒結體 該中置 設於該扁型封閉殼體1〇内部空間之一另 凝部與該蒸發部20之間呈間隔配置關 係藉以聚集冷凝液; 導流空間40,設於該蒸發部2〇與冷凝部 扁型封閉殼體10内部空間u的置中區域 工作液受熱蒸發為氣體型態時,其2發 式蒸汽導流空間40到達該冷凝部30 了 X 液導流空間50,設於該蒸發部20與冷凝 側:式冷凝液導流空間5〇與該 s ^ β藉以隔開該側置式冷凝液導 蒸汽導流空間4〇 ; 組織70,係宠埒仏# _ , ;該—側置式冷凝液導 將該冷凝部30所连;^认Α 守 Ί^ 的冷凝液導引至蒸 、綑铲、Γ 為边任其中一種型態 ,周體條狀體、管體。 式蒸汽導流空間4〇夕吞^ Α 间4ϋ之截面積係大於該側 5 MJ82704 如第 CPU )而 ’其蒸發 而到達該 會因冷卻 透過該二 流空間50 發而形成 達到氣液 式蒸汽導 凝液導流 );而其 毛細組織 該中置式 無任何反 脹方向逆 另如 結構型態 差異點, 之型態, 7圖所示, 令該蒸發部 氣體W1會 冷凝部30, 而凝結轉變 側置式毛細 而回到該蒸 一個氣、液 分流之導引 流空間40流 空間50呈偏 冷凝液W2 70的輸導往 蒸汽導流空 向導流作用 衝的可能性 第8圖所示 ,其與前述 僅在於其扁 至於其它結 當該蒸 20之工 經由該 而該蒸 成冷凝 組織70 發部20 相變循 效果, 至該冷 置型態 也會順 二側置 間40中 ,故冷 ,幾乎 扁型熱 扁型熱 型封閉 構設計 發部20對位於熱源目標 作液受熱而蒸發為氣體 中置式蒸汽導流空間40 發氣體W1到達冷凝部 液W2 ,而所述冷凝液 導引經過該二側置式冷 ,使得冷凝液W2重新 環過程;所以,本創作 其蒸發氣體W1僅能從 凝部30 (往:因該二側 ,且容置有侧置式毛細 勢由該冷凝部30透過二 式冷凝液導流空間5〇流 不具毛細組織,對冷凝 凝液W2朝該蒸發部2〇 是不存在的。 導構件A2 ’其係為—扁 板結構型態之扁型熱導 威體10B為一管體壓設 均相同於前揭,即不寶 物(如 型態時 之導引 30後, W2將 凝液導 受熱蒸 可確實 該中置 置式冷 組織70 側置式 動,且 液W2 之熱膨 型熱管 構件A 成扁狀 述。 功效說明: 本創作功效增進之事實如下 所揭「扁型熱導構件結構改良 閉殼體 '蒸發部、冷凝部、中置式蒸气』处所述扁型封 冷凝液導流空間、區隔部、側置式^细组間、側置式 構組成型態設計,使本創作對照【_姑你^釗新獨特結 構而言,使得扁型熱導構件導熱運作1,立】所提習知結 過位在扁型封閉殼體置中區域的中置式莩發氣體係透 ”,、’飞導流空間流向 7 M382704 .【圖式簡單說明】 • 第1圖:本創作扁型熱導 第2圖:本創作扁型熱導 第3圖:本創作扁型熱導 第4圖:本創作之區隔部 第5圖:本創作之支撐補 第6圖:本創作之支撐補 -第7圖:本創作導熱運作 第8圖:本創作扁型熱導 ®【主要元件符號說明】 扁型熱導構件 扁型封閉殼體 内部空間 上蓋板 下蓋板 蒸發部 冷凝部 中置式蒸汽導流空間 •側置式冷凝液導流空間 -區隔部 側置式毛細組織 第一曲折延伸部 第二曲折延伸部 支撐補強定位構件 蒸發氣體 冷凝液 較佳實施例之組合立體圖。 較佳實施例之分解立體圖。 較佳實施例之組合剖視圖。 另一實施例圖。 位構件型態另一實施例圖。 位構件另一實施例圖。 動示意圖。 另一實施例之局部剖視圖。 2A flat type sealing body 10' is a flat type hot plate structure type, and the inside of the flat type closed casing 10 is oppositely defined to form a vacuum space internal space 11; the flat type closed casing disclosed in this embodiment The body 1 is composed of an upper cover plate 1〇1 and a lower cover plate 102 which are combined in a closed shape; an evaporation portion 20 is disposed in one of the inner spaces of the flat closed casing 1 a portion where the evaporation portion 20 is located opposite to a predetermined heat source target (such as a CPU) to cause the working liquid of the evaporation portion 2 to evaporate due to heat; -»-condensing portion, Between the cold and the middle, and when the evaporation system is between the two sides 30; the two compartments of the vapor space 50 and the two side spaces 50 of the middle 20; the constituents: wherein, the mouth 卩 υ, the condensation The portion 30 type steam is located in the center-mounted condensing portion 60 of the portion 20, and the air-flowing type is wicked, and the side-side sintered body is disposed in one of the inner spaces of the flat closed casing 1 The evaporation portions 20 are arranged in a spaced relationship to form a poly The condensate; the flow guiding space 40 is disposed in the central portion of the evaporation space 2 and the inner space u of the condensing portion of the flat closed casing 10, and the working fluid is heated and evaporated into a gas type, and the two-stage steam guiding space 40 Arriving at the condensing portion 30, the X liquid guiding space 50 is disposed on the evaporation portion 20 and the condensation side: the condensate guiding space 5 〇 and the s ^ β are separated by the side condensing liquid guiding steam guiding space 4组织; organization 70, is the favorite # _ , ; the side-mounted condensate guide is connected to the condensation portion 30; ^ Α Ί 的 的 condensate is guided to the steam, bundle shovel, Γ for the side A type, a body strip, a tube body. The cross-sectional area of the steam diversion space 4 〇 ^ Α ϋ 大于 大于 大于 大于 5 5 5 5 5 M M M M M M M M M M M M M M M M M M M M M M M M M M M M M M M M M M M M M M Condensate diversion); and its capillary structure has no reverse expansion direction, and is different from the structural type difference point, the type, as shown in Fig. 7, so that the evaporation part gas W1 will condense part 30, and the condensation transformation The side-mounted capillary returns to the steaming gas and the liquid-divided guiding flow space 40. The flow space 50 is the possibility that the transmission of the condensate W2 70 is directed to the steam-conducting flow. The foregoing is only in the case that the flattening of the steaming 20 is caused by the steaming into the condensing structure 70, and the cold-type is also in the side 40. The cold, almost flat heat-type heat-type closed-type design part 20 is heated to the heat source target liquid to evaporate into a gas-incorporated vapor flow guiding space 40, and the gas W1 reaches the condensing liquid W2, and the condensate is guided. After the two side-mounted cold, The condensate W2 is re-circulated; therefore, the evaporation gas W1 of the present invention can only be condensed from the condensing portion 30 (to: due to the two sides, and the side-mounted capillary is accommodated by the condensing portion 30 through the dicondensate diversion The space 5 turbulent flow does not have a capillary structure, and the condensate condensate W2 does not exist toward the evaporation portion 2 导. The guide member A2 ' is a flat plate type thermal conductor 10B which is a tube body pressure The settings are the same as before, that is, no treasures (such as the guide 30 after the type, W2 will be condensed by the condensate and can be steamed to the side of the cold tissue 70 side-mounted, and the hot-expanded heat pipe member of the liquid W2 A is described as a flat. Efficacy Description: The fact that the effect of this creation is enhanced is as follows: The flat-type sealing condensate diversion at the "evaporation part, the condensation part, the middle type vapor" of the flat heat-conducting member structure improved closed casing The space, the partition, the side-mounted type, the side-by-side type, and the side-mounted structure form design, so that this creation contrasts with the new unique structure, so that the heat conduction operation of the flat heat guide member is performed. The knowledge is over-positioned in the middle area of the flat closed casing "Fluid gas system", "flying flow space flow 7 M382704. [Simple diagram] Figure 1: This creation of flat heat guide Figure 2: This creation of flat heat guide Figure 3: This Creating a flat heat guide Figure 4: Section 5 of the creation of this creation: Support for the creation of the sixth picture: Support for this creation - Figure 7: Heat conduction operation of this creation Figure 8: This creation is flat Thermal Conductivity® [Description of Main Components] Flat Heat Conducting Member Flat Closed Housing Internal Space Upper Cover Lower Cover Evaporation Condensation Centralized Steam Diversion Space • Side Condensate Diversion Space - Intersection Side The first tortuous extension of the first type of capillary structure and the second tortuous extension support a combination of the preferred embodiment of the reinforcing positioning member evaporating gas condensate. An exploded perspective view of the preferred embodiment. A cross-sectional view of a combination of preferred embodiments. Another embodiment of the figure. A diagram of another embodiment of a bit member type. Another embodiment of the bit member. Schematic diagram. A partial cross-sectional view of another embodiment. 2
、6 Ο B, 6 Ο B
、8 Ο B 、8 0 C 9, 8 Ο B , 8 0 C 9