201116795 六、發明說明: 【發明所屬之技術領域】 本發明係關於使用卫作流體之相變來傳輸熱之熱傳輸器 件、其製造方法及包括其之電子裝置。 【先前技術】 一直以來,使用平坦熱管作為冷卻諸如中央處理單元 (CPU)之熱源之器件。諸如水之工作流體容納於熱管中。 工作流體之相變及回流傳輪熱,藉此冷卻熱源。 牛例而。,曰本專利特許公開申請案第號 揭π-種包括-容器之平坦熱管。在該容器中設置有用於 使-工作流體回流之一毛細結構(wick)。藉由壓製一摺疊 過複數次之帶狀筛孔來獲得該毛細結構。結果,製造出具 有極好毛細管力之毛細結構(專利文件k0014段、圖i 等)。 【發明内容】 寸▼地iL在不斷地開發具有較高效能之電子裝置及其 類似:。連同此較高效能,$自電子裝置及其類似者之熱 產生!正在i曰力σ。因此’需要具有較高熱傳輸效能之熱傳 輸器件…抑制製造費用,需要在短時間内以高產量製 k此種具有較尚效能之熱傳輸器件。 :\上所提及之情形’需要提供-種具有較高熱傳輸 效能且能夠在短時間內乂肖 于間内以良好可加工性製造之熱傳輸器 ^其製造方法及包括其之電子裝置。 據本發月之f施例,提供一種熱傳輸器件,其包括 149451.doc 201116795 一工作流體、一毛細管部件及一容器。 該工作流體藉由執行—相變來傳輸熱。 該毛細管部件將_主& @ 毛、,田g力鈿加至該工作流體。爷 管部件包括具有一第一尺+ — ^毛、,,田 具有不同於該第一尺寸之一第_ ^ 丨件及 網部件。該第二筛網部件經 弟—轉 夾住。 使付。亥第一師網部件被 該容器容納該工作流體及該毛細管部件。201116795 VI. Description of the Invention: [Technical Field] The present invention relates to a heat transfer device for transferring heat using a phase change of a servo fluid, a method of manufacturing the same, and an electronic device including the same. [Prior Art] A flat heat pipe has been used as a device for cooling a heat source such as a central processing unit (CPU). A working fluid such as water is contained in the heat pipe. The phase change of the working fluid and the return heat of the transfer wheel thereby cooling the heat source. The cow is a case. Japanese Patent Application Laid-Open No. Hei---------------------------------------- A wick for recirculating the working fluid is provided in the container. The capillary structure is obtained by pressing a ribbon mesh that has been folded over a plurality of times. As a result, a capillary structure having excellent capillary force is produced (patent document k0014, Fig. i, etc.). SUMMARY OF THE INVENTION The iL is constantly developing electronic devices with higher performance and the like: Together with this higher performance, the heat from the electronics and its likes is generated! I am working on σ. Therefore, there is a need for a heat transfer device having a high heat transfer performance ... suppressing the manufacturing cost, and it is required to produce such a heat transfer device with high efficiency in a short period of time. The situation mentioned in the above is required to provide a heat transfer device having a high heat transfer efficiency and capable of being manufactured with good processability in a short time. The manufacturing method thereof and the electronic device including the same. According to this embodiment of the present invention, a heat transfer device is provided which includes a working fluid, a capillary member and a container, 149451.doc 201116795. The working fluid transfers heat by performing a phase change. The capillary member adds _main & @毛,,田力 force to the working fluid. The trunk member includes a first dimension + - ^ hair, and the field has a different size than the first dimension and the mesh member. The second screen member is clamped by the younger brother. Make it pay. The first division net component is housed by the container with the working fluid and the capillary member.
在該熱傳輸器件中,蕻ώ搞a , X 肖由適當地組合篩孔尺寸彼此不同 的…師網部件及該第二筛網部件,工作流體 效率可得到改良。舉例而言,在將複數個筛網層專: 該容器中的情況下,必須定位該等筛網部件。然而= 實施例之熱傳輸器件中,該第一筛網部件被夹在該第二筛 網部件之間’且因此,此種定位並非必要的,結果為形成 該熱傳輸器件時之可加工性得到改良。結果,有可能在短 時間内以良好可加工枓制;主目 q “具有向的熱傳輸效能之熱傳輸 益件。 一該第-筛網部件可具有一末端部分。在此情況下,該第 一篩網部件可經摺疊以覆蓋該末端部分。 藉由編織導線來形成該第一筛網部件及該第二筛網部 件。該等導線可插人筛網部件之末端部分中。舉例而言, 在該容器係藉由接合複數個部件而形成的情況下,害怕延 伸之導線可能進入該複數個部件之接合區域中,此可造成 自接合區域之茂漏。然而’在此實施例之熱傳輸器件中, 149451.doc 201116795 ==部件經摺疊以便覆蓋該第-部件之末端部分。 μ第—4網部件之摺疊部分沿著該接合 藉此使得可能防止導線進入該接合區 s ^㈣ 器件之製造產量可得到改良。 -果’熱傳輸 =一=部件可具有一對彼此相對之末端部分。在此 月在钱^二筛網部件可經摺疊以覆蓋該對末端部分。 器件中,該第二筛網部件經指疊,以便覆蓋 件之該對彼此相對之末端部分。以此方式, 間二網部件之方式被適當設定,結果為可在短時 件。、了加工性製造具有高的熱傳輸效能之熱傳輸器 該第一尺寸可小於該第二尺寸。 的=!器件可進-步包括呈-液相之工作流趙所通過 相"道及呈-氣相之工作流趙所通過的一氣相流 在此情況下,該容器 厚度之-厚Μ 有4於耗細管部件之一 /子!的一内部空間。 網部件。2田S部件可包括該第—篩網部件及該第二篩 部件充當該氣相流道。相流道,且該第二篩網 在°玄熱傳輸盗件中,由於該容器之該内部空間之厚声盘 該毛細管部件之厘谇知m 1 I工間之与度與 ^ ^ " S,故將該毛細管部件設置於該容 益之整個内部空間令。 到改良心此結構’該容器之对久性可得 '。,有可能防止該容器歸因於一由該容器 14945l.doc 201116795 之内部之溫度的增加所產生之内部壓力而變形。另外,無 需在該内部空間中設置用於改良該容器之耐久性之另一部 件’結果為可在短時間内以良好可加工性製造該熱傳輸器 件。在此實施例之熱傳輸器件中,具有較小篩孔之第—篩 網部件被設定為液相流道,且具有較大篩孔之第二篩網部 件被設定為氣相流道,此可改良熱傳輸效能。 该第一篩網部件及該第二篩網部件可交替地摺疊以相互 炎住。 在該熱傳輸器件令’該第-篩網部件及該第二篩網部件 經交替摺疊以便相互夹住。提供此種毛細管部件,藉此允 許該毛細管部件更多地佔據該容器之内部此可改良熱傳 輸效率。 部件及一第二部件 弟 該容器可包括彼此接合之 在此情況下’該毛細管部件可容納於該容器中,使得該 第二篩網部件之一摺疊部分沿著該第一部件及該第二部件 之一接合區域安置。 該容器可包括經摺疊且經接入 丄接合以形成該容器之單平板部 件(one plate member)。 在此情況下,該毛細營邮丛+ / S邛件可容納於該容器中,使得該In the heat transfer device, the working fluid efficiency can be improved by appropriately combining the mesh member and the second mesh member whose mesh sizes are different from each other. For example, in the case where a plurality of screen layers are specialized: in the container, the screen components must be positioned. However, in the heat transfer device of the embodiment, the first screen member is sandwiched between the second screen members' and thus such positioning is not necessary, and as a result, workability in forming the heat transport device is obtained. Improved. As a result, it is possible to process the product in a short time with good processing; the main item q "the heat transfer benefit having the heat transfer efficiency of the direction. One of the first screen members may have an end portion. In this case, the The first screen member may be folded to cover the end portion. The first screen member and the second screen member are formed by braiding wires. The wires may be inserted into an end portion of the screen member. In the case where the container is formed by joining a plurality of components, it is feared that the extended wire may enter the joint region of the plurality of components, which may cause leakage from the bonding region. However, in this embodiment In the heat transfer device, 149451.doc 201116795 == the part is folded to cover the end portion of the first part. The folded portion of the μ -4 net part along the joint thereby makes it possible to prevent the wire from entering the joint area s ^ (4) The manufacturing yield of the device can be improved. - Fruit 'Heat Transfer = One = The component can have a pair of end portions opposite each other. This month, the wire mesh member can be folded to cover the pair of end portions. In the device, the second screen member is finger-joined so as to cover the pair of end portions opposite to each other. In this manner, the manner of the inter-network member is appropriately set, and as a result, it can be processed in a short time. The first size of the heat transfer device having high heat transfer performance can be smaller than the second size. The device can further include a flow-through process in the phase-by-phase and gas-phase. In this case, the thickness of the container - thick Μ has an internal space of one of the thin tube parts / the mesh part. The net part. The 2 field S part can include the first - the screen member and the second screen member act as the gas phase flow path, the phase flow channel, and the second screen is in the thick heat transfer thief, the thick sound plate of the inner space of the container之 谇 know the degree of m 1 I work and ^ ^ " S, so the capillary part is placed in the entire internal space of the benefit. To improve the structure of this structure 'the durability of the container is available' It is possible to prevent the container from being attributed to a container by the 14945l.doc 201116795 The internal pressure generated by the increase in the internal temperature is deformed. In addition, there is no need to provide another member for improving the durability of the container in the internal space. As a result, the heat can be manufactured with good workability in a short time. A transfer device. In the heat transfer device of this embodiment, the first screen member having a smaller mesh opening is set as the liquid phase flow path, and the second mesh member having the larger mesh opening is set to the gas phase flow The first screen member and the second screen member are alternately folded to inflate each other. The heat transfer device causes the first screen member and the second screen The components are alternately folded to clamp each other. Such a capillary member is provided, thereby allowing the capillary member to more occupy the interior of the container, which improves heat transfer efficiency. a component and a second component, the container may include a joint with each other in which case the capillary member may be received in the container such that one of the second screen members is folded along the first member and the second One of the components is placed in the joint area. The container can include a one plate member that is folded and joined via an access jaw to form the container. In this case, the capillary bark + / S component can be accommodated in the container, so that
第二自|網部件之一摺疊部分、VL宜—T 且丨刀,口者該平板部件之一接合區域 安置。 < 在該熱傳輸器件中,由於嗲 、X奋益係精由摺疊該單平板部 件而形成,故可減少組件之赵 … 又數目且可卽約費用。另外,若 S亥谷器由複數個部件構成,則 則該專部件之預定定位準確度 149451.doc 201116795 為必要的。對比而言,在 、 在此實施例中,高定位準减译廿& 必要的。此外,該第_茲 確又並非 乂弟—靖網部件之摺疊部 部件之接合區域安置,社罢系,口者該平板 、-〇果為有可能防止該 — 及該第二篩網部件之導綠 師肩#件 μ; 料板料之接合區域中。 根據本發明之另一實域中 括一工你★触 種熱傳輸器件,其包 作&體 '-毛細管部件及—容器。 該工作流體藉由執行一相變來傳輸熱。 該毛細管部件將—毛細管力施加至該 細管部件包括具有配置在一第—^Llt且该毛 網邱杜《曰+ 方向上之師孔之一第一篩 、.周。卩件及具有配置在不 茲如 第—方向之一第二方向上之 師孔之一第二篩網部件〇 後 ^ °亥第一篩網部件經摺疊,使得該 苐—篩網部件被夾住。 且便付3 該容器容納該工作流體及該毛細管部件。 在該熱傳輸器件中,藉由谪卷从4 α 的^ # 藉由適虽地組合筛孔尺寸彼此不同 效率可得到改良。 師心件’工作流體之熱傳輸 之方本發月之另f施例’提供—種製造-熱傳輸器件 餘綱/該方法包括藉由摺疊一第二篩網部件以使-第-自f ’"II部件被夾住且霜荖#苗 成用认 A覆錢第卩件之-末端部分來形 熱傳輸器件之一毛細管部件。該第-筛網部件具 &寸之H ^•該第二I網部件具有不同於該 第一尺寸之一第二尺寸之一篩孔。 ^毛細管部件置放於構成該熱傳輸器件之—容器之一 #件上,使得該第二篩網部件之一指疊部分沿著該第 149451.doc 201116795 一部件之一接合區域安置。 :由將構《容器之―第二部件接合至該第-部件之該 妾口區域來形成容納該毛細管部件之該容器。 根據本發明之另—. 之方法兮古 Λ ',柃供—種製造一熱傳輪器件 :’该方法包括藉由權疊_第二筛網部件以使—第— 師,.周。卩件被夾住且覆蓋 & 盍^自帛網部件之-對末端部分來 成用於-熱傳輸器件之-毛細管部件。 將:亥毛細管部件置放於構成該熱傳 第一部件上,使得該筮—茲_ A 益之 一部件β Λ 一凋。Η牛之一摺疊部分沿著該第 丨件之一接合區域安置。 藉由將構成該容器之一第_ 接人F敁Λ , 弟—。Ρ件接合至該第一部件之該 =域來形成容納該毛細管部件之該容器。 敎料Γ造方法’可在短時間内以良好可加工性製” 部件及^ ~ 吏用師孔尺寸不同的該第一篩網 =弟師網部件,熱傳輸效能可得到改良。 之古明之另—實施例’提供-種製造-㈣η 之方法,該方法包括藉由衣&熱傳輸"件 筛網部件被爽住且覆蓋:/二師網部件以使-第- 成用於-熱傳㈣之° 師網部件之一末端部分來形 有-第— 尺+ t 細管部件m網部件具 -尺寸之_ m '币孔’ e亥第二篩網部件具有不同於該第 第二尺寸之一筛孔 不 二:=r構成㈣㈣"器之單 板部件之—接件之一财部分沿著該平 14945l.doc .9- 201116795 藉由摺疊該平板部件並將其接合至該接合區域來形成容 納該毛細管部件之該容器。 根據本發明之另一實施例,提供一種電子裝置,其包括 一熱源及一熱傳輸器件。 該熱傳輸器件包括一工作流體、一毛細管部件及一容 器。 該工作流體藉由執行一相變來傳輸熱。 該毛細管部件將一毛細管力施加至該工作流體,且該毛 細管部件包括具有-第—尺寸之—_孔之—第—筛網部件 及具有不同於該第一尺寸之一第二尺寸之一篩孔的一第二 筛網部件m網部件經摺4,使得該第—篩網部件 被爽住。 該容器連接至該熱源,且容納該工作流體及該毛細管部 件。 如上所述,根據本發明之實施例,有可能提供具有高的 熱傳輸效能且能夠在短時間内以良好可加工性製造之熱傳 輸器件、其製造方法及包括其之電子裝置。 依據本發明之最佳模式實施例之以下詳細描述,本發明 之此等及其他目標、特徵及優點將變得更明顯,如隨附圖 式中所說明。 【實施方式】 下文中’將參看圖式來描述本發明之實施例。 <第一實施例> (熱傳輸器件之結構) 149451.doc -10· 201116795 立圖1為展示根據本發明之第一實施例之熱傳輪器件的示 意透視圖。圖2為沿著一短邊方向(沿著圖】之線截取 的熱傳輸器件之橫截面圖。應注意,在用於描述本說明書 之諸圖中,為簡單起見,可使用不同於實際尺寸之尺寸。 一熱傳輸器件100包括具有一矩形薄板形狀之—容器b 容器1係藉由將盤狀之下部平板部件3(第一部件)與平板狀 之上部平板部件4(第二部件)彼此择合而形成。下部平板部 件3具有-凹陷部分2。此日寺,下部平板部件]之凹陷部分2 對應於容器1之内部空間2,。 通常’下部平板部件3及上部平板部件4係由無氧銅、精 銅(tough pitch copper)或一銅合金製成。然而,材料並不 限於彼等材料’且除銅以外之金屬、樹脂或具有一較高熱 導率之另-材料可用作下部平板部件3及上部平板部件 通常’容器1在—長邊方向上之長度被設定成約1〇議至 且合态1在一紐邊方向上之長度被設定成約5 mm至 300 _。此外,通常,容器1之厚度被設定成0.3咖至5 _。 然而’容器1之長度及厚度不限於彼等值且可適當地設 定0 谷為1具有直技為(例如)約〇 · 1 示)。經由該入口 一工作流體注 mm至1 mm之入口(未圖 入至容器1中。通常,該 工作流體係在容器1之内部 流體之實例包括純水 Fluorinert(註冊商標)fc_72 類之混合液體。 經降壓之狀態下注入。該工作 、諸如乙醇之醇類、諸如 之基於氟之液體’及純水與醇 14945J.doc • II · 201116795 如圖2中所*,在熱傳輸 中,設置用於使一毛如焚上 之谷益1之内部空間2, ’” g力作用於該工作流體之丰 件5。毛細管部件 ^體之毛細管部 、上。P +板部件4之間的一 中空體6。Ub f + 门的間隙對應於 毛細管部件5,且一氣相工—液相工作流體主要移動穿過 亦即,毛細管部件二=體主要移動穿過— 田 液相流道5丨’且中空I* 6奋》#· 氣相流道6,。 Y二體6充田一 毛細管部件5由一笫—益Λκη Α 甲‘用βρ件7及一第二篩網部件8構 成。如圖2中所示’第二筛網部件8經摺疊,使得第一筛網 部件7被爽住,藉此形成毛細管部件5。因此,在—除於此 處摺疊第二篩網部件8之卹八η , 之邛分9以外的部分中,第一篩網部 件7及第二篩網部件8層疊。第二篩網部件8之摺疊將在下 文對-製造熱傳輸器件1〇〇之方法之描述中予以詳細描 述0 圖3Α及圖3BJb H網部件7及第二篩網部件8之放大 平面圖。圖3A為第-篩網部件7之放大平面圖,且圖把為 第二篩網部件8之放大平面圖。 如圖3A中所示,第一篩網部件7包括第一導線1〇及第二 導線11。第一導線10在熱傳輸器件i 〇〇之長邊方向上延 伸’且第二導線11在熱傳輸器件1〇〇之短邊方向上延伸。 第一導線10與第二導線11經交替編織,藉此形成具有複數 個篩孔12之第一篩網部件7。 如圖3B中所示’第二篩網部件8包括第一導線13及第二 導線14。第一導線13在熱傳輪器件ι〇〇之長邊方向上延 •12· 149451.doc 201116795 伸,且第二導線14在熱傳輸器件ι〇〇之短邊方向上延伸。 第一導線13與第二導線14經交替編織,藉此形成具有複數 個篩孔1 5之第二篩網部件8。 舉例而言’使用由銅 '磷青銅 '鋁、銀、不鏽鋼、鉬或 其合金製成的細金屬線作為形成第一篩網部件7及第二筛 網部件8之導線。另外,編織第一導線1〇及第二導線丨1之 方式及編織第一導線1 3及第二導線14之方式之實例包括平 織、斜紋織(trill weave)、鎖壓接〇〇ck cHmp)織法或平頭 (flat top)織法。 如圖3A及圖3B中所示,第一篩網部件7之篩孔i2之尺寸 Wi(第一尺寸)被設定成小於第二筛網部件8之篩孔b之尺 切2(第二尺寸)。亦即,在此實施例中,第—篩網部件7 之篩目數大於第二篩網部件8之篩目數。 在此,「篩目數」指代每吋筛網部件之篩孔之數目。因 此’具有較大篩目數之篩網部件具有每讀大數目個綿 孔。亦即,筛網部件之筛孔之尺寸較小。在以下描述中, 將篩目數為100之篩網部件稱為#100篩網部件。 在此實施例中,使用#150第—t帛網部件7及㈣ =件8。然而數之組合並不限於以上實例; α 了使用第-篩網部件7及_第二筛網部件8。 '數之組合可適當地設定在-範圍内,在該範圍中,第 -師網部件7之筛目數大於第二筛網部件8之筛目數。 (普通熱傳輪器件之操作) 圖4為展示作為比較實例給出的熱傳輸器件之示意橫截 14945I.doc 201116795 面圖。圖4展示沿著一長邊 下的橫截面圖。 °截取熱傳輸器件980之情况 熱傳輸器件980包括一容器 ¢. έ Λ ° 在容器981中,設置__ 毛細官部件985及一工 又罝 細管部件985接合至容器州之_下=平如,中所示’毛 一液相流道985,。另外, U件983且充當 〇81 形成於毛細管部件985與容@ 州之-上部平板部件984之間 了- 道986, ^ 卫體986充當一軋相流 987^/部件985具有將具有相同篩目數之三個篩網部件 第-導線(未圖示)及第-導線=自错由交替地編織 ^ ^ ^ 弟一導線(未圖不)而形成。該等第一 導線在熱傳輸器件_之一長邊方向上延伸,且第 在㈣傳輸器件之一短邊方向上延伸。由於堆疊了具有相 同師目數之篩網部件987 ’故篩網部件987之筛孔之尺寸相 同。 如圖4中所示,在熱傳輸器件980之在長邊方向上之一末 端Ρ刀995a中’设置一蒸發區域Ε,且在另一末端部分 995b中’设置—冷凝區域c。使一諸如一 之熱源9的在 下部平板部件983側上與蒸發區域£接觸。 圖5為一熱傳輸器件之冷卻模型圖。呈液相之一工作流 體在蒸發區域E中自熱源999接收熱且在蒸氣壓力差下 蒸發,從而變為氣相。該氣相工作流體通過氣相流道 986,且自蒸發區域E移動至冷凝區域此時,歸因於氣 相洲·道986’之阻力(resistance),氣相工作流體在接收一壓 149451.doc • 14· 201116795 力損失ΔΡν之同時移動至冷凝區域C。 已移動至冷凝區域C之氣相工作流體輻射熱w以冷凝, 且由此自氣相變至液相。此時的蒸氣壓力差由Δρε來表 示。藉由使用毛細管部件985之一毛細管力ΔΡς^ρ作為用以 自冷凝區域C移動至蒸發區域£之一抽吸力,液相工作流體 流過液相流道985,。此時,歸因於液相流道985ι之阻力, 液相工作流體在接收一壓力損失ΔΡ1之同時移動至蒸發區 域Ε 〇 已返回至蒸發區域Ε之液相工作流體藉由再次自熱源999 接收熱而蒸發。藉由重複上述該等操作,來自熱源999之 熱被傳輸。 在熱傳輸器件980中之總壓力損失小於毛細管部件985之 毛細管力APcap的情況下,熱傳輸器件98〇恰當地操作。對 比而言,在熱傳輸器件980中之總壓力損失大於毛細管部 件985之毛細管力^pcap的情況下,熱傳輸器件98〇不操 作且不傳輸熱。當總壓力損失與毛細管力APcap之間存 在平衡時,獲得熱傳輸器件98〇之最大熱傳輸量卩饥以。 因此,當獲得最大熱傳輸量Qmax時之APcap由以下表達 式(1)表述: APcap=APv+APl+APe+APc+APh ⑴ 其中ΔΡν表示氣相工作流體之壓力損失,Δρ1表示液相工作 流體之>£力損失,APe表示歸因於蒸發之壓力差,APc表示 歸因於冷凝之壓力差,且表示歸因於體積力之壓力 差。 I49451.doc 201116795 本文中,最大熱傳輸量Qmax由以下表達式(2)表述:The second self-web member has a folded portion, VL, and a file, and the mouth portion is disposed in a joint region of the plate member. < In the heat transfer device, since the 嗲 and X 奋 乐 are formed by folding the single flat member, the number of components can be reduced and the cost can be reduced. In addition, if the S-Hagner is composed of a plurality of components, the predetermined positioning accuracy of the component is 149451.doc 201116795 is necessary. In contrast, in this embodiment, high-position quasi-subtraction & In addition, the _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ The green guide shoulder #子μ; in the joint area of the material sheet. According to another embodiment of the present invention, a ★ heat-transfer device is packaged as a &body'-capillary member and container. The working fluid transfers heat by performing a phase change. The capillary member applies a capillary force to the thin tube member including a first screen, a circumference having one of the division holes disposed in the first and second directions. The first screen member is folded after the second screen member of the one of the teacher holes disposed in the second direction of the first direction, such as the second direction, so that the 苐-screen member is clamped live. And the container 3 holds the working fluid and the capillary member. In the heat transfer device, the efficiency can be improved by appropriately combining the mesh sizes of the 4? by the coils. The division of the 'work fluid' is the heat transfer of the working fluid. The other example is provided by the manufacturer-heat transfer device. The method includes folding the second screen component to make the -first-f '" The II part is clamped and the frost 荖#Miaocheng uses the end part of the A-money 卩 来 形 to shape the capillary part of the heat transfer device. The first screen member has <H<>>> the second I mesh member has a screen aperture that is different from one of the second dimensions. The capillary member is placed on one of the containers constituting the heat transfer device such that one of the second screen members is placed along the joint region of one of the members of the 149451.doc 201116795. The container accommodating the capillary member is formed by joining a second member of the container to the mouth region of the first member. According to another aspect of the present invention, the method of manufacturing a heat transfer wheel device is carried out by the method of 'supplied with the second screen member to make the first division. The jaws are clamped and cover the <<>> end-to-end portion to form a capillary member for the -heat transfer device. The Hei capillary member is placed on the first component constituting the heat transfer so that the component β Λ 。 。 。 。 One of the folded portions of the yak is placed along the joint area of one of the first members. By constituting one of the containers, the first person is F敁Λ, brother-. A jaw is coupled to the = field of the first component to form the container that houses the capillary component. The method of manufacturing the material can be made in a short period of time with good processability. The components and the first screen mesh with the different hole sizes of the divisions can be improved. Alternatively - the embodiment provides a method of manufacturing - (iv) η, the method comprising: squeezing and covering by means of a garment & heat transfer & sieving screen component: / One of the end parts of the division (4) is formed with a - part - ruler + t thin tube part m net part - size _ m 'coin hole ' e Hai second screen part has a different from the second size One of the screen holes is different: = r constitutes (4) (4) " the veneer parts of the device - the piece of the piece along the flat 14945l.doc .9 - 201116795 by folding the plate member and joining it to the joint area To form the container for accommodating the capillary member. According to another embodiment of the present invention, an electronic device including a heat source and a heat transfer device is provided. The heat transfer device includes a working fluid, a capillary member, and a container. The working fluid is transmitted by performing a phase change The capillary member applies a capillary force to the working fluid, and the capillary member includes a - mesh member having a - first dimension - and a second dimension different from the first dimension A second screen member m mesh member of a screen is folded 4 such that the first screen member is cooled. The container is coupled to the heat source and houses the working fluid and the capillary member. As described above, According to an embodiment of the present invention, it is possible to provide a heat transfer device having high heat transfer efficiency and capable of being manufactured with good processability in a short time, a method of manufacturing the same, and an electronic device including the same. The above and other objects, features and advantages of the present invention will become more apparent from the aspects of the appended claims. <First Embodiment> (Structure of Heat Transfer Device) 149451.doc -10· 201116795 Figure 1 is a schematic perspective view showing a heat transfer wheel device according to a first embodiment of the present invention Figure 2 is a cross-sectional view of the heat transport device taken along a line in the direction of a short side (along the figure). It should be noted that in the figures used to describe the present specification, for the sake of simplicity, a different The size of the actual size. A heat transfer device 100 includes a rectangular plate shape - the container b is made by the disk-shaped lower plate member 3 (first member) and the flat upper plate member 4 (second member) The lower plate member 3 has a recessed portion 2. The recessed portion 2 of the temple, the lower plate member, corresponds to the inner space 2 of the container 1. Usually, the lower plate member 3 and the upper plate member 4 It is made of oxygen-free copper, tough pitch copper or a copper alloy. However, the materials are not limited to their materials' and metals other than copper, resins or other materials having a higher thermal conductivity may be used as the lower plate member 3 and the upper plate member, usually 'container 1 in the long-side direction The length is set to about 1 and the length of the closed state 1 in the direction of a rim is set to be about 5 mm to 300 _. Further, usually, the thickness of the container 1 is set to 0.3 coffee to 5 _. However, the length and thickness of the container 1 are not limited to their respective values and may be appropriately set to 0. The valley has a straight line of, for example, approximately 〇 · 1 shown. An inlet of the working fluid is injected through the inlet to the inlet of 1 mm (not shown in the container 1. Typically, the example of the internal fluid of the working fluid system in the container 1 includes a mixed liquid of the pure water Fluorinert (registered trademark) fc_72 type. Injected under reduced pressure. This work, alcohols such as ethanol, such as fluorine-based liquids, and pure water and alcohol 14945J.doc • II · 201116795 as shown in Figure 2, in heat transfer, set up In the internal space 2, '" g force of the glutinous rice 1 is applied to the working fluid abundance 5. The capillary portion of the capillary member body, the upper portion, and a hollow between the P + plate member 4 The gap of the Ub f + gate corresponds to the capillary member 5, and a gas phase-liquid phase working fluid mainly moves through, that is, the capillary member two body mainly moves through the liquid phase flow channel 5丨' Hollow I* 6 Fen"#. Gas phase flow path 6. Y two-body 6 filling field-capillary part 5 consists of a 笫-ΛΛκη Α A ' with a β ρ piece 7 and a second screen part 8 as shown in the figure. 'The second screen member 8 is folded as shown in 2, so that the first screen member 7 is cooled Thereby, the capillary member 5 is formed. Therefore, the first screen member 7 and the second screen member 8 are laminated in a portion other than the portion 9 of the second mesh member 8 in which the second screen member 8 is folded. The folding of the second screen member 8 will be described in detail below in the description of the method of manufacturing the heat transport device 1A. Fig. 3A and Fig. 3BJb are enlarged plan views of the H mesh member 7 and the second screen member 8. Figure 3A is an enlarged plan view of the first screen member 7, and is an enlarged plan view of the second screen member 8. As shown in Figure 3A, the first screen member 7 includes a first wire 1 and a second wire. 11. The first wire 10 extends in the longitudinal direction of the heat transport device i ' and the second wire 11 extends in the short side direction of the heat transport device 1 。. The first wire 10 and the second wire 11 are alternated Weaving, thereby forming a first screen member 7 having a plurality of screen openings 12. As shown in Fig. 3B, the 'second screen member 8 includes a first wire 13 and a second wire 14. The first wire 13 is heat-transmitted The wheel device is extended in the longitudinal direction of the 〇〇 • • 12· 149451.doc 201116795, and the second wire 14 is hot The short direction of the transport device ι extends. The first wire 13 and the second wire 14 are alternately woven, thereby forming a second screen member 8 having a plurality of meshes 15. For example, 'using copper a thin metal wire made of 'phosphor bronze' aluminum, silver, stainless steel, molybdenum or alloy thereof as a wire forming the first mesh member 7 and the second mesh member 8. In addition, the first wire 1 and the second wire are woven Examples of the manner of the first one and the manner of knitting the first wire 13 and the second wire 14 include a plain weave, a trill weave, a lock crimping ck cHmp weave or a flat top weave. As shown in FIGS. 3A and 3B, the dimension Wi (first dimension) of the mesh opening i2 of the first screen member 7 is set to be smaller than the size 2 of the mesh opening b of the second screen member 8 (second size) ). That is, in this embodiment, the mesh number of the first screen member 7 is larger than the mesh number of the second screen member 8. Here, the "mesh number" refers to the number of sieve holes per screen member. Therefore, a screen member having a larger mesh number has a large number of boring holes per reading. That is, the mesh size of the screen member is small. In the following description, a screen member having a mesh number of 100 is referred to as a #100 screen member. In this embodiment, the #150 first-t帛 mesh member 7 and (four) = member 8 are used. However, the combination of numbers is not limited to the above example; α uses the first screen member 7 and the second screen member 8. The combination of the numbers can be appropriately set within the range in which the number of meshes of the first mesh member 7 is larger than the mesh number of the second mesh member 8. (Operation of Ordinary Heat Transfer Wheel Device) Fig. 4 is a schematic cross-sectional view showing a heat transfer device as a comparative example 14945I.doc 201116795. Figure 4 shows a cross-sectional view along a long side. °In the case of the heat transfer device 980, the heat transfer device 980 includes a container ¢. έ Λ ° In the container 981, the __ capillary member 985 and the thin tube member 985 are joined to the container state _ lower = flat , shown in the 'hair-liquid phase flow path 985,. In addition, the U-piece 983 and the 〇81 are formed between the capillary member 985 and the upper plate member 984 of the state - 986, ^ The body 986 acts as a rolling phase flow 987^/the component 985 has the same sieve The first wire (not shown) and the first wire = self-error of the three mesh members of the mesh are formed by alternately weaving a wire (not shown). The first wires extend in the longitudinal direction of one of the heat transfer devices and extend in the short side direction of one of the (four) transfer devices. Since the screen members 987' having the same number of divisions are stacked, the screen openings of the screen member 987 are the same in size. As shown in Fig. 4, an evaporation region ’ is disposed in the end Ρ 995a of the heat transfer device 980 in the longitudinal direction, and a condensation region c is disposed in the other end portion 995b. A heat source 9 such as a is brought into contact with the evaporation region on the side of the lower plate member 983. Figure 5 is a cooling model diagram of a heat transfer device. One of the working fluids in the liquid phase receives heat from the heat source 999 in the evaporation zone E and evaporates under the vapor pressure difference, thereby becoming a gas phase. The gas phase working fluid passes through the gas phase flow passage 986 and moves from the evaporation region E to the condensation region. At this time, due to the resistance of the gas phase, the gas phase working fluid receives a pressure of 149451. Doc • 14· 201116795 The force loss ΔΡν moves to the condensation zone C at the same time. The gas phase working fluid that has moved to the condensing zone C radiates heat w to condense, and thereby changes from the gas phase to the liquid phase. The vapor pressure difference at this time is represented by Δρε. The liquid phase working fluid flows through the liquid phase flow path 985 by using a capillary force ΔΡς^ρ of one of the capillary members 985 as a suction force for moving from the condensation region C to the evaporation region. At this time, due to the resistance of the liquid phase flow path 985, the liquid phase working fluid moves to the evaporation region while receiving a pressure loss ΔΡ1, and the liquid phase working fluid that has returned to the evaporation region is received by the self-heating source 999 again. Heat and evaporate. By repeating the above operations, heat from the heat source 999 is transferred. In the case where the total pressure loss in the heat transport device 980 is less than the capillary force APcap of the capillary member 985, the heat transfer device 98 is properly operated. In contrast, in the case where the total pressure loss in the heat transport device 980 is greater than the capillary force of the capillary member 985, the heat transfer device 98 does not operate and does not transfer heat. When there is a balance between the total pressure loss and the capillary force APcap, the maximum heat transfer amount of the heat transfer device 98 is obtained. Therefore, APcap when the maximum heat transfer amount Qmax is obtained is expressed by the following expression (1): APcap=APv+APl+APe+APc+APh (1) where ΔΡν represents the pressure loss of the gas phase working fluid, and Δρ1 represents the liquid phase working fluid > loss of force, APe represents the pressure difference due to evaporation, APc represents the pressure difference due to condensation, and represents the pressure difference due to the volume force. I49451.doc 201116795 In this paper, the maximum heat transfer amount Qmax is expressed by the following expression (2):
Qmax=APcap/Rq ... (2) 其中Rq表示每單位熱量(heat amount)之流道阻力。 另外,最大熱傳輸量Qmax由以下表達式(3)表述:Qmax = APcap / Rq (2) where Rq represents the flow resistance per unit heat amount. In addition, the maximum heat transfer amount Qmax is expressed by the following expression (3):
Qmax=APcap*H/Rtotal ... (3) 其中Η表示一潛熱(latent heat)且Rtotal表示總流道阻力。 總流道阻力Rtotal為氣相流道之阻力Rv、液相流道之阻 力R1、蒸發阻力Re、冷凝阻力Rc及歸因於體積力Rb之阻 力之和。因此,基於表達式(3),最大熱傳輸量Qmax—般 隨著毛細管力APcap變大而增加,且最大熱傳輸量Qmax隨 著液體流道之阻力R1變大而減小。 氣相工作流體之壓力損失ΑΡν、液相工作流體之壓力損 失ΔΡ1、歸因於蒸發之壓力差APe、冷凝之壓力差APc及歸 因於體積力Rb之壓力差ΔΡΙι分別由以下表達式(4)至(8)表 述: △Pv=8*pv*Q*L/(7T*pv*rVA4*H) ... (4) △P 卜 pl*Q*L/(K*Aw*pl*H) ... (5) APe=(RT/2^A(l/2)*Q/[ac(H-l/2*RT)*rv*le] ... (6) APc=(RT/2rt)A(l/2)*Q/[ac(H-l/2*RT)*rv*lc] ... (7) APh=(pl-pv)*g*L*sin(p ... (8) 其中μν表示氣相工作流體之黏度係數,μΐ表示液相工作流 體之黏度係數,ρν表示氣相工作流體之密度,pi表示液相 149451.doc •16· 201116795 工作流體之密度’ Q表示埶傳 ‘、,、得輸里,L表示長邊方向上的 熱傳輸器件980之長度,卜表 衣不在長邊方向上的蒸發區域E 之長度,lc表示在長邊方& 太 一 逯方向上的冷凝區域C之長度,Aw表 示筛網部件之橫截面積 _ 表不虱相流道986,之毛細管半 徑,K表示滲透係數,Rγ /㈣数R表不氣體常數,§表示重力加速 度’且φ表示熱傳輪器件 干0相對於一水平線之斜度(在水 平:用:傳輸器件98。的情況下,體積力Rb為0)。 上時1力集中在表達式(4)至⑻中之表達式(4)、(6)及⑺ 現氣相卫作流體之心損失心、歸因於蒸發之 因於冷凝之壓力差紙為氣相流道9⑽之毛 、-田s半徑rv之函數。氣相泣 轧相抓道986之毛細管半徑rv在表達 式(4)、(6)及(7)中作為八 QR., 刀 置。因此,藉由增加氣相流 ^ 6之毛細管半徑rv,二個壓力彳 一 1U &力知失ΔΡν、APe及APc可 >父’結果為最大熱傳輸量Qmax可增加。 對氣相或液相工作流體所移動穿過之流道之毛 、-田g半控r加以描;+、 . 部侔你 以。在使用藉由編織導線而獲得之篩網 表達式(9)表述: r=(W+D)/2 其'中W表示篩網 种。 丨仵之師孔之尺寸,且ϋ表示導線之直 :工作流體之流道的情況下毛 表違式(9)矣π . 「 (9) 為面,舉例而言,在未使用筛網部件或其類似者作Qmax = APcap * H / Rtotal (3) where Η represents a latent heat and Rtotal represents the total flow path resistance. The total flow path resistance Rtotal is the sum of the resistance Rv of the gas phase flow path, the resistance R1 of the liquid phase flow path, the evaporation resistance Re, the condensation resistance Rc, and the resistance due to the volume force Rb. Therefore, based on the expression (3), the maximum heat transfer amount Qmax generally increases as the capillary force APcap becomes larger, and the maximum heat transfer amount Qmax decreases as the resistance R1 of the liquid flow path becomes larger. The pressure loss ΑΡν of the gas phase working fluid, the pressure loss ΔΡ1 of the liquid phase working fluid, the pressure difference APe due to evaporation, the pressure difference APc of condensation, and the pressure difference ΔΡΙι attributed to the volume force Rb are respectively expressed by the following expression (4) ) to (8): △ Pv = 8 * pv * Q * L / (7T * pv * rVA4 * H) ... (4) △ P pl * Q * L / (K * Aw * pl * H ) (5) APe=(RT/2^A(l/2)*Q/[ac(Hl/2*RT)*rv*le] ... (6) APc=(RT/2rt) A(l/2)*Q/[ac(Hl/2*RT)*rv*lc] ... (7) APh=(pl-pv)*g*L*sin(p ... (8) Where μν denotes the viscosity coefficient of the gas phase working fluid, μΐ denotes the viscosity coefficient of the liquid phase working fluid, ρν denotes the density of the gas phase working fluid, pi denotes the liquid phase 149451.doc •16·201116795 The density of the working fluid 'Q denotes a rumor ',,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,, The length of the condensation zone C, Aw represents the cross-sectional area of the screen component _ the surface of the flow channel 986, the capillary radius, K represents the permeability coefficient, Rγ / (four) number R is not gas often The number, § denotes the gravitational acceleration' and φ denotes the slope of the heat transfer device dry 0 relative to a horizontal line (in the horizontal: with: transmission device 98., the volume force Rb is 0). The expressions (4), (6), and (7) in Expressions (4) to (8) are the core loss of the gas-phase fluid, and the pressure difference due to evaporation is the gas phase flow path 9 (10). The function of the radius of the hair, the field s radius rv. The capillary radius rv of the gas phase wetting phase 986 is used as the eight QR. in the expressions (4), (6) and (7). Therefore, by increasing The capillary radius rv of the gas phase flow ^6, the two pressures 彳1U & the force loss ΔΡν, APe and APc can be > the parent's result is that the maximum heat transfer amount Qmax can be increased. For the gas phase or liquid phase working fluid Move through the flow of the hair, - Tian g semi-control r to draw; +, . Department of you. Use the sieve expression obtained by braiding the wire (9): r = (W + D ) / 2 The 'W in the screen indicates the size of the screen mesh. The size of the hole of the division is ,, and ϋ indicates the straightness of the wire: in the case of the flow path of the working fluid, the hair is violated (9) 矣 π. "(9) is , For example, without using a mesh member or the like as
局工作流體之、、* $。 F w道且一矩形中空體充當流道的情況下,毛 149451.doc -17- 201116795 細管半徑Γ由以下表達式(ίο)表述: r=ab/(a+b) 其中a表示流道之寬度(短邊 之深度(流道之厚度)。 ... (10) 方向上之長度),且!^表示流道 (熱傳輸器件1 〇 〇之操作) 接下來’將描述根據此實施例之熱傳輸器件剛之操 作。圖6為用於解釋熱傳輸器件之操作的示意橫截面圖。 圖6展不沿著長邊方向截取熱傳輸器件1〇〇之情況下的橫截 面。因此,在圖6中,未展示第二篩網部件8之摺疊部分。 如圖6中所#,在熱傳輸器件1〇〇之在長邊方向上之一末 端部分15a中,設置| …£域E,且在另一末端部分丨% 中’設置冷;疑區域(:。^吏諸如cpu之熱源999在下部平板部 件3側上與蒸發區域£;接觸。熱源999可在上部平板部件續 上與蒸發區域E接觸。 呈液相之一工作流體在蒸發區域E中自熱源999接收熱, 且在蒸氣壓力差她下蒸發,從而變為氣相。氣相工作流 體通過氣相流道6,且自蒸發區域E移動至冷凝區域(:。此 時,歸因於氣相流道6.之阻力,氣相工作流體在接收壓力 損失ΔΡν之同時移動至冷凝區域匸。 已移動至冷凝區域C之氣相工作流體輻射熱评以冷凝, 且由此自氣相變至液相。此時的蒸氣壓力差由Δρβ來表 示。藉由使用毛細管部件5之毛細管力APcap作為用以自冷 凝區域C移動至蒸發區域e之抽吸力,液相工作流體流過液 149451.doc 201116795 相流道5'。此時,歸因於液相流道5'之阻力,液相工作流 體在接收壓力損失API之同時移動至蒸發區域£。 已返回至蒸發區域E之液相工作流體藉由再次自熱源999 接收熱而蒸發。藉由重複上述該等操作,來自熱源999之 熱被傳輸。 此處’注意力集中在根據此實施例之毛細管部件5上。 如上所述,此實施例之毛細管部件5具有第一篩網部件7及 第二篩網部件8層疊在一除於此處摺疊第二篩網部件8之部 分9以外的部分中之結構。 =上所述,基於表達式(3),最大熱傳輪量Qmax隨著毛 細管力ΔΡ^ρ變大而增加,且隨著液相流道之阻力Ri變大 而減小。舉例而言,在使用篩網部件作為毛細管部件的情 況下,藉由增加筛網部件之篩孔之尺寸,液相流道之阻力 可減小°然而’㈣,網部件之筛孔之尺寸增加,則毛細 管力APcap會減小。 一在此實施例中1 -篩網部件7之篩孔12之尺寸Wi被設 疋成小於第二篩網部 藉由具有較大、 2。亦即,雖然 師?之第二篩網部件8來減小液相流道之阻 力R1,但十入告_车 邱件⑴/ APeap由具有較小篩孔之第一筛網The working fluid of the bureau, * $. In the case of the F w road and a rectangular hollow body acting as a flow path, the hair 149451.doc -17- 201116795 thin tube radius 表 is expressed by the following expression (ίο): r=ab/(a+b) where a represents the flow path Width (depth of the short side (thickness of the flow path) ... (10) length in the direction), and !^ denotes the flow path (operation of the heat transfer device 1 )) Next 'will be described according to this embodiment The heat transfer device has just been operated. Fig. 6 is a schematic cross-sectional view for explaining the operation of the heat transport device. Fig. 6 shows a cross section in the case where the heat transporting device 1 is not taken along the long side direction. Therefore, in Fig. 6, the folded portion of the second screen member 8 is not shown. As shown in Fig. 6, in one end portion 15a of the heat transfer device 1 in the longitudinal direction, the field is set to "," and in the other end portion 丨%, the cold portion is set. The heat source 999 such as cpu is in contact with the evaporation zone on the side of the lower plate member 3. The heat source 999 may continue to contact the evaporation zone E in the upper plate member. The working fluid in the liquid phase is in the evaporation zone E. The heat source 999 receives heat and evaporates under a vapor pressure difference to become a gas phase. The gas phase working fluid passes through the gas phase flow path 6 and moves from the evaporation region E to the condensation region (: at this time, due to The resistance of the gas phase flow path 6. The gas phase working fluid moves to the condensing zone 接收 while receiving the pressure loss ΔΡν. The fluorothermal working fluid that has moved to the condensing zone C converges to condense, and thus changes from the gas phase to The liquid phase. The vapor pressure difference at this time is represented by Δρβ. By using the capillary force APcap of the capillary member 5 as the suction force for moving from the condensation region C to the evaporation region e, the liquid phase working fluid flows through the liquid 149451. Doc 201116795 Phase flow path 5'. This Due to the resistance of the liquid phase flow path 5', the liquid phase working fluid moves to the evaporation region while receiving the pressure loss API. The liquid phase working fluid that has returned to the evaporation region E receives heat from the heat source 999 again. Evaporation. By repeating the above operations, heat from the heat source 999 is transmitted. Here, attention is focused on the capillary member 5 according to this embodiment. As described above, the capillary member 5 of this embodiment has the first sieve The mesh member 7 and the second screen member 8 are laminated in a structure other than the portion 9 where the second screen member 8 is folded. Here, based on the expression (3), the maximum heat transfer wheel The amount Qmax increases as the capillary force ΔΡ^ρ becomes larger, and decreases as the resistance Ri of the liquid phase flow path becomes larger. For example, in the case where a screen member is used as the capillary member, the sieve is increased by The size of the mesh hole of the mesh member, the resistance of the liquid phase flow channel can be reduced. However, (4), the size of the mesh hole of the mesh member is increased, and the capillary force APcap is reduced. In this embodiment, the 1 - mesh member The size Wi of the sieve hole 12 of 7 is set to be smaller than The second screen portion has a larger, 2, that is, although the second screen member 8 of the division is used to reduce the resistance R1 of the liquid phase flow path, but the ten entry _ Cheqiu (1) / APeap has First screen of smaller mesh
口 ί5件7來保護。处 J ,、·σ果,工作流體之熱傳輸效率得到改良。 此外,液;{;日τ ^ 乍^體主要通過充當液相流道5,之毛細管 口丨4件5,且翁知τΒ 6。然而〃—作流體主要通過充當氣相流道6,之中空體 部件^詳^些情況Τ’.氣相工作流體移㈣過毛細管 Q之,上部板4側上的第二篩網部件8之該摺疊 H9451.doc 201116795 部分為氣相及液相工作流體所通過之—部分。 若將毛細管部件5看作工作流體之氣相流道,則基於表 達式⑼,毛細管半徑rv由第-_網部件7及第二篩㈣件8 分別之篩孔12及15之尺寸WjW2與第1網部件7及第二 筛網部件8之導線之直徑界I因此,藉由使❹有較大 4孔之第二筛網部件8作為毛細管部件5,氣相流道之毛细 管半徑rv增加’且三個壓力損失…、·及他基於表達 式(4)、(6)及(7)而減少。因此,最大熱傳輸量Qmax可增 加,結果為熱傳輸器件100之熱傳輸效率得到改良。 如圖6中所示,毛細管部件5接合至下部平板二们。若 為了獲得較大毛細管力而將毛細管部们之篩孔之尺 寸設定為過小’則篩孔可歸因於 於接合至下部平板部件3而 朋、W,在此實施例中,具有較大筛孔之第二筛網部 件8接合至下部平板部件3。因此, u此,有可能防止此問題。 圖7A及圖7B為展示圖4中所文 園中所不之毛細管部件985之篩網 4件9 8 7及相比較的此貫施例之第—筛網部件7及第二筛網 部件8之部分放W。魏展Μ傳輸器件_之筛網部 件987,且圖7Β展示此實祐彻 貫施例之第1網部件7 部件8。 如圖7Α中所示,在毛細管部 筛目數之筛網部件987,使巾’層疊了具有相同 使付師網部件987之篩孔彼此重 璧:因二液相工作流體所移動穿過的一間隙不受保護, 相工作流體變得困難。使將適备毛細管力△一施加至液 149451.doc •20· 201116795 另方面,如圖7B中所示,此實施例之第一篩網部件7 f第二篩網部件8具有彼此不同的篩目數,此可防止第一 師網部件7之筛孔與第二筛網部件8之筛孔彼此重疊。因 此’可減小流道相對於液相工作流體之阻力,且可將適當 毛細管力APcap施加至液相工作流體。結 熱傳輸器件刚之熱傳輸效能。 "改良 圖8為展示熱傳輸器件1〇〇之熱傳輸效能及相比較的圖* 中所不之熱傳輸器件980之熱傳輸效能的圖式。此處,對 於熱傳輸器件_之毛細管部件985,使用三個㈣q筛網部 件987。量測熱傳輸器件98〇及此實施例之熱傳輸器件_ 中之每一者之最大熱傳輸量Qmax。 如上所述,藉由摺疊#1〇〇第二篩網部件8使得Η 第一 篩網。Ρ件7被夹住來形成根據此實施例之毛細管部件5。另 方面,熱傳輸器件980之毛細管部件985具有將三個#1〇〇 篩網部件堆疊於其中之結構。如圖8中所示,此實施例之 熱傳輸器件1〇〇之最大熱傳輸量伽狀大於熱傳輸器件98〇 之最大熱傳輸量Qmax。 (製造熱傳輸器件之方法) 圖9A至圖9C為用於解釋形成提供給根據此實施例的熱 傳輸器件100之毛細管部件5之方法的圖式。如圖9A中所 示’準備第二筛網部件8。當自上往下看時,第二筛網部 件8幾乎為容器i之内部空間2,的兩倍大。第二筛網部件8具 有一右邊區域R2、一左邊區域La及一對末端部分i6a及 16b。末端部分16a及16b在右邊區域&及左邊區域^所配 149451.doc 201116795 置的方向上彼此相對。 如圖9B中所示’將形成為與内部空間2,之形狀 ^狀之第―筛網部件7置放於第二篩網部件8之右邊= 2上。[篩網部件7具卜對在短邊方向上彼此 =部分m及m。如圖9B中所示,末端部分⑺與第二 師^件8之末端部分16b對齊。第一篩網部件 分17a大致置放於第二篩網部件8之中央。 邛 自#150網布(mesh sheet)切下一預 件7。自_0網布切下一預定形狀 網部 幽該等網布切下第一筛網部件第:網部件8。為了 干及弟—篩網部件8,你m Μ射切割器'—切割模具或其類似者。或者 使用- 放電機械加工(線切割)。 可使用一線 如圖9C中所示,摺疊第二篩網部件 件7被夹住。因此,第—筛網部件7夹在第二第二師網部 右邊區域R2與左邊區域L2之間。另外 件8之 末端部分1 7a藉由於此處摺蟲 篩網部件7之 端部分m及第二筛網部件8之末端部師網部件7之末 網部件8可人工權疊或可藉由—諸刀b對齊。第二篩 摺疊。 宜機益之處理機器 以此方式,形成具有與容器k 相同的形狀之毛細管部件5。圖 _㈤2之形狀幾乎 長邊方向對應於容器1之長邊方向,且不的毛細管部件5之 方向對應於容器1之短邊方向。。且毛細官部件5之短邊 14945J.doc •22· 201116795 圖i〇A及圖10B為用於解釋製造熱傳輪器件⑽之方法的 圖式。圖10展示沿著短邊方向截取將形成之熱傳輸器件 100之情況下的橫截面。 如圖1〇A中所示,毛細管部件5置放於下部平板部件3之 凹陷部分2中,使得第二筛網部件8之摺疊部分9沿著包圍 下部平板部件3之凹陷部分2的側壁18安置。 舉例而言,在圖4中所示之熱傳輸器件98〇中必須層最 師=部件987,同時以高準確度將其定位。對比而言,: 此貫施例中’由於藉由圖9A至圖9c中所示之過程所形成 之毛細管部件5置放於下部平柘邱 卜。丨十扳4件3之凹陷部分2中。因 此’無需執行如上所述之定位。紝 、 H疋位釔果,有可能在短時間内 1ΛΛ 具有局的熱傳輸效能之熱傳輸器件 丄U 0 〇 為了防止雜質進入容器中, 势立n &如 仕 2障況下,可在將毛細 吕部件置放於容器、 十其加以洗滌。在此情況下,在 熱傳輸器件980中,必須琢他 _ 負、個洗滌師網部件987。對比而 吕,在此實施例ψ,可 ,^ ^伙 了 一-人洗滌藉由圖9中所示之過程所 化成之毛細官部件5,社里办壯 、,、。果為裝配熱傳輸器件100時之可加 工性可得到改良。 此外’在圖4中所示之執傳輪哭杜+ # 987ffl ^ …傳輸盗件980中,將三個篩網部 用於形成毛細管部件98 ψ , ^ ^ S丨仔985。對比而言,在此實施例 Ύ 第一篩網部件7月链-f w Α , ^ ρ 及第一師網部件8形成毛細管部件5。 亦即,在此實施例中, ^ _ 斤使用的篩網部件之數目可減少, 、、-〇果為可節約篩網 丨仟之切割費用(cutting cost)。 149451.doc -23- 201116795 如圖1〇B中所示,上部平板部件4接合至下部平板部件3 二二壁18上。亦即’在此實施例中’下部平板部件3之側 =之上部表面對應於—接合區如,且第二篩 摺疊部分9係沿著接合區域S安置。在圖議中,以視覺上 可理解之方式展示下部平板部件3之凹陷部分2。作是,實 際上,對應於容器i之厚度的側壁18之高度相當小,且體 a之(例如)0.3 mm至5 mm。因此,實質上, 8之摺疊部分9係沿著接合區域s安置。 ''^〇P# 關於接合下部平板部件3與上部平板部…之方法 用擴散接合、超音波接合、銅焊、焊接或其類似者。在對 件3及上部平板部件4執行擴散接合的情況下, 卩》擴散接合之溫度及壓力,毛細 平板部件3可彼此接合。或者 牛…下^ 部平板部件4之接入過寇八_ 〃下。卩千板部件3及上 之接入古土, 之㈣中’可藉由如上所述 來接合毛細管部件5與下部平板部件3。 及由細金屬線製成之導線來形成第一筛網部件7 件8。因此,害怕導線可能插入第-篩網邱 件7及第二篩網部件8之太、 弟師網部 部平板部件3之接合區域二線r下 與上部平板部件4之間,則 七平板#件3 茂漏。對…,在此實二:成自夹住導線之部分之 接合第二在熱傳輸器件_中, 被覆蓋。接英,師網部件7之末端部分 ^ 〜著下部平板部件3之接合區域s安置第 —之摺疊部分9。因此,有可能防止二= 14945〗,doc -24- 201116795 7及第二筛網部件8之導線在安置有第二筛網部件8之摺疊 部分9的區域中進入接合區域s中。結果,熱傳輸器件1〇〇 之製造產量可得到改良。 <第一貫施例> 將描述根據本發明之第一貫施例之熱傳輸器件。在以 下杬述中,與在第一貫施例中所描述的熱傳輸器件1 00之 結構及動作相同的結構及動作將由相同參考數字及符號指 示’且將省略對該等結構及動作之描述。 圖11為展不一根據第二實施例之熱傳輸器件之示意橫截 f圖。圖12A及圖12B為用於解釋—形成此實施例之毛細 e P件之方法的圖式。圖j j展示沿著短邊方向截取此實施 例之熱傳輸器件之情況下的橫截面圖。 立如圖11中戶斤不,此實施例之熱傳輸器件200包括毛細管 ^件205 ’毛細管部件2G5之結構不同於第—實施例之毛細 管料5。此實施例之毛細管部件2〇5包括具有較小筛孔之 第4網部件2〇7及具有較大筛孔之第二筛網部件2⑽。指 且第一師網部件2〇8,使得第—篩網部件浙被夾住,藉此 形成毛細管部件2〇5。 在下文中’將描述形成此實施例之 毛細管部件2〇5之方法。 •,如圖12Α中所示,準備篩網部件208。當自上往下看時, Υ “邛件208幾乎為容器1之内部空間2’兩倍大。第二 篩網部件2〇8具有三個F々. &或.右邊區域r2、左邊區域L t央區域c:2。此外,第_ 第一師網部件208具有一對末端部分 】6a及2〗6b。末端部八,,( 木鳊。P刀216a及2】6b在該三個區域所配置的 149451.doc -25- 201116795 方向上彼此相對。將形成為與内部空間2,之形狀幾乎相同 的形狀之第一篩網部件斯置放於第二篩網部件之中央 區域。中。第一筛網部件2〇7具有一對在短邊方向上彼此 相對之末端部分2173及21几。如圖12A中所示,將第一筛 網部件2G7之該對末端部分心及㈣置放於第二筛網部 件208之中央區域(^中。 如圖12B中所示,摺疊第二篩網部件期,使得第一筛網 部件207被夾住。第―筛網部件2()7夾在第二篩網部件· 之中央區域C2與左邊區域一之間及第二篩網部件扇之中 央區域C2與右邊區域R2之間。因此,第-筛網部件207之 該對末端部分2l7a及2m藉由第二筛網部件之摺疊部 分職及鳩所覆蓋。安置第二薛網部件208之該對末端 部分216a及216b ’以使其大致在第一篩網部件2〇7之中央 被此相對°因此’形成此實施例之毛細管部件205。 圆11中所不,所形成之毛細管部件2〇5置放於下部平 板部件3之凹陷部分2中,且下部平板部件3及上部平板部 件4在下部平板部件3之側壁18上之接合區域S中接合。將 :細管部件205置放於下部平板部件3之凹陷部分2中,使 =第Γ"篩網部件208之摺疊部分2093及2〇91?係沿著接合區 域女置因此,製造此實施例之熱傳輸器件2〇〇。 貫施例中,第一篩網部件2〇8 :在容器R長邊方向上沿著接合區域s安置。因此^ y月b防止第一篩網部件2〇7及第二篩網部件汕8之導線在容 益1之長邊方向上進入接合區域8中。結果,熱傳輸器件 I49451.doc -26· 201116795 200之製造產量可得到改良。如上所述,藉由適當地設定 第一篩網部件208之摺疊方式可在短時間内以良好可加 工性製造具有南的熱傳輸效能之熱傳輸器件200。 此外,藉由增加大致在第一篩網部件207之中央彼此相 對的第一 4網部件2〇8之末端部分21仏及216b之間的一距 離,氣相流道6,可佔據容器1之内部空間2,的較大部分。藉 由適當地設定在圖丨i A中所示之過程中所準備的第二篩網 邰件208之面積,摺疊之後的末端部分以以及^❿之間的 距離可適當地设定。當適當地設定末端部分21^及21讣之 :的距離,且適當地設定内部空間2,中氣相流道6,與液相 C之間的比率時,熱傳輸器件2 之熱傳輸效率可得到 改良。 另外,在圖4中所示之熱傳輸器件980中,當將毛細管部 件985設置於容器981之内部空間982,中時,必須防止筛網 4件987之導線進入接合區域8中。因此,對於每—筛網部 件987 m了(例如)—移除延伸之導線之操作或一檢查 導線是否進入下部部件983之接纟區域s中之射。此外, 广居时,牌呷網部忏y87之面雨 設定成小於内部空間982,之面積,且筛網部件987與接合, 域S(側壁998)分離,藉此防止導線進入接合區郎中。 ••士比而σ在此Λ施例中,由於第二筛網部件期之指 疊部分職及鳩係沿著接合區域8安置故如上所述之 該等操作並非必要的,此改良熱傳輸ϋ件之製造時之 可加工性。此外,由於益雲骑主< # ',,、而將毛細官部件5之面積設定成 149451.doc -27- 201116795 小於内部空間2,之尺寸(當自上往下看時),故允許毛細管 部㈣5佔據内部區域2,中之較大部A。因A,可將-高的 毛細官力施加至工作流體’且可改良熱傳輸器件2〇〇之熱 傳輸效率。此外,為士卜香y | i 在此貫轭例中,即使在毛細管部件205 之面積略大於内部㈣2.之尺寸(當自上往下看時)的情況 下,亦可將具有彈性之毛細管部件2〇5推進下部平板部件3 之凹陷部分2中。g)此’毛細管部件2〇5之面積之尺寸公差 可增加’結果為形成毛細f部件加時之可加卫性可得 改良。 在此實施例中’將毛細管部件205置放於下部平板部件3 之凹陷4刀2中。或者’可將毛細管部件2〇5置放於—平坦 的下部平板部件上’且可將具有一凹陷部分之一上部平板 部件接合至下部平板部件之接合區域。在此情況下,將毛 細管部件205置放於下部平板部件上,使得第二_㈣件 2:之摺疊部分2_及2_沿著下部平板部件之接合區域 安置。此外’可由平坦的下部平板部件、上部平板部件及 構成容器1之側壁之-框架部件形成容^。藉由將該框架 部件接合至下部平板部件之接合區域且將上料板部件接 合至該框架部件之接合區域來形成容器丨。在此情況下, 將毛細管部件205置放於下部平板部件上使得第二筛網 部件208之指疊部分2〇9&及2〇外沿$下部平板部件之接合 區域安置。或者’在將下部平板部件接合至該框架部件I 後,可將毛細管部件205置放於下部平板部件上,使得摺 疊部分209a及209b沿著該框架部件之接合區域安置。 J49451.doc -28· 201116795 此外,在此實施例中,將第二篩網部件2〇8之摺疊部分 209a及209b安置在容器1之長邊方& μ 心食遠方向上。下部平板部件3之 接合區域S在容器i之長邊方向上的面積大於其在容器α 短邊方向上之面積。因此,者腺馇_松〜▲ C田將弟一師網部件208之摺疊 部分209a及209b安置在玄I、真士人 文夏隹合窃1之長邊方向上時,如上所述 之效應變大。然而,可摺疊第二篩網部件2〇8以便使其對 應於容器1之短邊方向,且可將第二篩網部件208之摺疊部 分安置在容器1之短邊方向上。 <第三實施例> 圖13為展讀據本發明之第三實施例之熱傳輸器件的示 意橫截面圖。圖U展示沿著短邊方向截取此實施例之熱傳 輸器件之情況下的橫截面圖。 在此實施例之熱傳輸器件3〇〇中’使用具有相同篩目數 之筛網部件作為第一筛網部件3 0 7及第二篩網部件3 〇 8。擅 疊第二筛網部件3〇8’使得第一篩網部件3〇7被夹住,藉此 形成毛細管部件305。此時,設定第一篩網部件307之篩孔 及第二篩網部件3〇8之篩孔,以便使其彼此配置在不同方 向上。第二篩網部件3〇8之摺疊方式與第二實施例中所描 述的第二篩網部件208之摺疊方式相同。 圖14A及圖14B為展示此實施例之第一篩網部件3〇7及第 一篩網部件308之平面圖。圖15A及圖15B為展示圖14中所 不之第一_網部件3〇7及第二篩網部件3〇8之放大平面圖。 圖MA及圖15A展示第二篩網部件,且圖及圖展 示第一筛網部件3〇7。 149451.doc -29. 201116795 如圖14A中所示,當自上往下看時,第二篩網部件3〇8幾 乎為内部空間2,的兩倍大。第二篩網部件308具有複數根第 一導線313及在一大致上垂直於第一導線313之方向上編織 的複數根第二導線3 14。第一導線3 13所延伸之方向對應於 容器1之長邊方向,且第二導線314所延伸之方向對庳於容 器1之短邊方向。因此’如圖14A及圖Isa中所示,第二筛 網部件308之篩孔3 1 5配置在容器1之長邊方向上及容器1之 短邊方向上。 如圖14B中所示,第一篩網部件307形成為一與容器丄之 内部空間2,之形狀幾乎相同的形狀。第一篩網部件3〇7具有 一對在短邊方向上彼此相對之末端部分3 17a及3 1 7b。該對 末端部分317a及317b所處之方向對應於容器1之長邊方 向。 在此實施例中,第一篩網部件307亦具有複數根第一導 線313及在垂直於第一導線313之方向上編織的複數根第二 導線314 ^然而,如圖14B及圖15B中所示,在第一筛網部 件307中’將第一導線313及第二導線314之延伸方向設定 成不同於該對末端部分317a及317b之延伸方向。因此,第 一篩網部件3〇7之第一導線313及第二導線3 14之延伸方向 不同於第二篩網部件3〇8之第一導線313及第二導線314的 延伸方向。因此,將第一篩網部件3〇7之篩孔3 12所配置的 方向設定成不同於第二篩網部件308之篩孔315所配置的方 向。 第—筛網部件307及第二篩網部件308係自第一導線313 149451.doc 201116795 及第二導線3 14係交替地編織之一網布切出。第二篩網部 件308係沿著第一導線3 13及第二導線3 14之延伸方向切 割。第一篩網部件307係在不同於第一導線3 1 3及第二導線 3 14之延伸方向之方向上切割。如上所述,在此實施例 中,無需準備具有不同篩目數之兩種網布,此可節約網布 之費用。 在此實施例之毛細管部件305中,由於將第一篩網部件 307及第一篩網部件308之篩孔(篩孔3 12及3 15)配置在不同 方向上,故有可能防止篩孔312與篩孔315彼此重疊。因 此,可減小流道相對於液相工作流體之阻力,且可將高的 毛細管力施加至液相工作流體。結果,熱傳輸器件3〇〇之 熱傳輸效能可得到改良。 如圖15B中所不,藉由角θ表示第一篩網部件3〇7之篩孔 3 12所配置的方向與第二篩網部件3〇8之篩孔3 1 $所配置的 方向之間的差異。舉例而言,當將角θ設定在5度至85度之 範圍内時,如上所述,熱傳輸器件3〇〇之熱傳輸效能可得 到改良。當將角θ設定成9〇度時,第一篩網部件3〇7之篩孔 312與第二篩網部件3〇8之_孔315可能彼此重疊。然而’ 第一導線313及第二導線314之編織形式存在變化,因此即 使在角Θ為90度的情況下,篩孔312與篩孔315亦可在一些 情況下不重疊。因此’即使在角鹇9〇度的情況下,亦有 可能改良熱傳輪器件300之熱傳輸效能,因此亦可選擇“ 度至90度之範圍作為角θ。 應主意’在此貫施例巾,第一筛網部件及第二筛網 149451.doc 201116795 部件308均由第一導線313及第二導線314形成’但不限於 此。另外,即使使用具有不同筛目數之第一篩網部件及第 二筛網部件,且將該等篩網部件之薛孔所處之方向設定成 不同’熱傳輸器件之熱傳輸效能亦可得到改良。 <第四實施例> 圖16為展示根據本發明之第四實施例之熱傳輸器件的示 意橫截面圖。圖17A至圖17C為用於解釋一形成此實施例 之毛細管部件之方法的圖式。圖16展示沿著短邊方向截取 此實施例之熱傳輸器件之情況下的橫截面圖。 此實施例之熱傳輸器件4 〇 〇之毛細管部件4 0 5係藉由交替 地摺疊第一篩網部件4〇7及第二篩網部件4〇8以便使其相互 夾住而形成。在下文中,將描述形成此實施例之毛細管部 件405之方法。 如圖17A中所示,準備第一筛網部件4〇7及第二篩網部件 4〇8田自上往下看時,第一篩網部件407及第二篩網部件 歲乎各自為内部空間2’的兩倍大。將第一篩網部件々ο? 之右邊區域置放於圖17A中所示的第二篩網部件408之左 邊區域L2上。第一篩網部件407具有一對末端部分417a及 417b。末端部分417&及41几在右邊區域&及左邊區域^所 配置的方向上彼此相對。末端部分417b大致上安置於第二 篩網部件4 0 8之中央。 如圖17B中所示’摺疊第二篩網部件408以便使其覆蓋第 篩網部件407之末端部分417b。第一篩網部件407之末端 ^”々^匕藉由第二篩網部件彳⑽之摺疊部分⑽外所覆蓋。 149451.doc -32· 201116795 此外,第一篩網部件4〇7之右邊區域Rl夾在第二篩網部件 4〇8之左邊區域Lz與右邊區域之間。因此,第二篩網部 件8之末*而部分416b大致上安置於第一篩網部件4〇7之中 央。 如圖17C中所示,摺疊第一篩網部件4〇7以便使其覆蓋第 二篩網部件408之末端部分416b。第二篩網部件4〇8之末端 部分416b藉由苐一篩網部件4〇7之摺疊部分4〇9a所覆蓋。 此外,第二筛網部件4〇8之右邊區域&夾在右邊區域心與 左邊區域L丨之間。以此方式’交替地摺疊第一篩網部件 407及第二篩網部件4〇8以便使其相互夾住,藉此形成此實 施例之毛細管部件4〇5。第一篩網部件4〇7及第二篩網部件 408之摺疊部分40%及4〇9b為對應於容器丨之長邊方向之部 分。 如在此實施例中,藉由交替地摺疊第一篩網部件及 第二篩網部件4〇8以便使其相互夹住,可增加所堆疊之構 成毛細管部件405之第一篩網部件407及第二篩網部件4〇8 的數目。SU匕’允許毛細管部件405佔據容^之内部空間 2’的較大部分’結果為熱傳輸器件4〇〇之熱傳輸效能可得到 改良。 應注意,如圖16中所示,與第一筛網部件4〇7之指疊部 分409a相比’接合至下部平板部件3的第二筛網部件^之 左邊區糾的末端部分4i6a(與末端部分侧相對之末端 部分)安置於容器1之内側上 之摺疊部分409b相比,第— 。此外,與第二篩網部件4〇8 篩網部件407之左邊區域口的 14945】.doc -33- 201116795 末端部分417a亦安置於容器1之内側上。 在圖17A至圖17C中所示之過程中,適當地設定所準備 的第一篩網部件407及第二篩網部件4〇8之面積及其類似 者,藉此使得有可能如上所述地安置第二篩網部件4〇8之 末螭部分416a及第二篩網部件4〇8之末端部分417&。由於 此結構,即使導線插入第二篩網部件4〇8之末端部分 中或插入第一篩網部件407之末端部分417a中,亦有可能 防止延伸之導線進入接合區域8中。結果,可在短時間^ 以良好可加工性製造此實施例之熱傳輸器件4〇〇。 <第五實施例> 圖18為展示根據本發明之第五實施例之熱傳輸器件的示 意橫截面圖。圖19為展示此實施例之熱傳輸器件之示意分 解透視圖。圖職示沿著短邊方向截取此實施例之熱傳輸 器件之情況下的橫截面圖。 一〜.q〜仰丨亏锏盗仵包 下部平板部件503、加強部件519及上部平板部件5〇4。 部平板部件503具有凹陷部分5〇2。加強部件519接合至 部平板部件503,且上部平板部件5〇4接合至加強部 519’藉此形成此實施例之容器5〇1。加強部㈣9係由 如)無氧銅、精.銅或一銅合金製成。 如圖U中戶斤示,纟加強部件519中,複數個加強部分 設置於毛細管部件505與上部平板部件5〇4之間。該複凄 加強部分520配置在容器5〇1之短邊方向上,且等力弓 分520各自在容器5〇1之長邊方向上延伸。該複㈣^ 149451.doc •34· 201116795 分520之間的間隙在此實施例中充當氣相流道5〇6,。應注 思,毛細管部件505具有與第二實施例中所描述之毛細管 部件205相同的結構。 如圖19中所示,加強部件519具有在容器5〇ι之長邊方向 上延伸形成之複數個通孔521。該複數個通孔521配置在容 器501之短邊方向上。該等通孔521充當圖18中所示之氣相 流道506,,且該等加強部分52〇分別夾在該等通孔521之 間。通孔521之數目(亦即,加強部分52〇之數目)可適當地 設定。 藉由在毛細管部件505與上部平板部件5〇4之間、一… 加強部分520,容器501之耐久性可得到改良。舉例而言 有可月t*防止Α器5G1歸因於—由熱傳輸器件之内部溫7 的增加所造成之内部壓力而變形。在匕外,例如,有可能p 止容器5〇1在工作流體於減麼狀態下注入至熱傳輸器件5。 中時由於一壓力而變形。 替代於加強部件519 ’可在容器501之内部空間5〇2.中言 置各自具有圓筒或多角柱之形狀的該複數個加強^ 或者,藉由在上部平板部件5Q4上形成該複數個加$ ^刀520且藉由將上部平板部件州與下部平板部件彼此去 1在内。P工間502 t設置該等加強部分52()。在此情力 曰由糾|屬電鑛、壓製過程、切割過程或其類也 卩平板。卩件504上形成該等加強部分52Q。在該複类 分㈣係形成於上部平板部㈣4上的情況下肩 可此在執行f曲過程時改良熱傳輸器件別之耐久性。另 149451.doc -35· 201116795 外’不使用加強部件5 19,因此可節約組件費用。 在根據此實施例之熱傳輸器件5〇〇中,將毛細管部件5〇5 設定成具有與第二實施例中所描述之毛細管部件2〇5相同 的結構。然而,根據上述之另一實施例的毛細管部件之結 構亦可應用於毛細管部件5 〇 5。 〈第六貫施例> 圖20為展示根據本發明之第六實施例之熱傳輸器件的示 意橫截面圖。圖20展示沿著短邊方向截取此實施例之熱傳 輸器件之情況下的橫截面圖。 如圖20中所不,在此實施例之熱傳輸器件6㈧中,設置 毛細管部件605 ^毛細管部件6〇5具有一大致等於容器 内部空間2’之厚度的厚度。毛細管部件6〇5係藉由摺疊具有 較大篩孔之第二篩網部件608使得將具有較小 筛網部件607夹在其間而形成。擅疊第二筛網部件608之方 式類似於第二實施例巾所描述的摺疊H網部件观之 方式。 藉由設置具有-預定厚度之第一筛網部件607及第二 網部件608,毛細管部件6〇5之厚度被設定成與容器^之 部空間2’之厚度幾乎相同。或者,藉由適當地設定下部 板部件3之側壁18之高度,可將毛細管部件6〇5之厚度與 部空間2,之厚度(側壁18之高度)設定成彼此大致上相等。 由於容器!之内部空間2,之厚度與熱傳輸器件_中之 細管部件605的厚度幾乎相同,故如圖2〇中所示,將毛; 官部件605設置於容器}之整個内部空間2,令。由於此; 14945!.doc •36· 201116795 構’容器1之耐久性可得到改良,此可防止容器1變形。另 外’無需提供用於改良内部空間2,中之容器1之耐久性的另 一部件’結果為可節約組件費用’且可在短時間内以良好 可加工性製造熱傳輸器件6〇〇。 此外’在此實施例中,.具有較大篩孔之第二篩網部件 608充當氣相流道608,,且具有較小篩孔之第一篩網部件 607充當液相流道607’。如第一實施例中所描述,在使用篩 網部件作為氣相流道的情況下,使用具有較大筛孔之篩網 部件使氣相流道之毛細管半徑”變大。使用具有較大毛細 管半徑Γν之氣相流道使最大熱傳輸量Qmax增加。因此,藉 由使用具有較大篩孔之第二篩網部件6〇8作為氣相流道 608',有可能改良熱傳輸器件600之熱傳輸效能。 應注意’在第-實施例至第四實施例中,將毛細管部件 之厚度設定成大致等於容器之内部空間之厚度,結果為可 獲得與此實施例中之效應相同的效應。 <第七實施例> 圖21為展示根據本發明之第七實施例之熱傳輸器件的干 意橫截面圖。圖22A及圖22B為展示此實施例之毛細管; :之圖式。圖21展示沿著短邊方向戴取此實施例 器件之情況下的橫截面圖。 ’、、' 則 如圖21中所示,在此實施例之熱傳輸器件?叫, 毛細管部件705。毛細管部件7〇5具有_大致等 : m:’:厚度的厚度。毛細管部件7。5之具有較大篩孔 師ή件7〇8充當氣相流道赠。複數個通孔722形 149451.d〇, 37- 201116795 成於第二篩網部件708中。 如圖22A中所不,當自上往下看時,準備幾乎為内部空 門2兩倍大的第二篩網部件7〇8。第二篩網部件Mg具有三 個區域.右邊區域R2、左邊區域L2及中央區域該複數 個通孔722形成於右邊區域&2及左邊區域w。該複數個 通孔722可容易地藉由㈣模具或其類似者形成。此外, 形成為與内部空間2,幾乎相同的形狀之第-筛網部件707置 放於第二筛網部件谓之中央區域Μ。第—篩網部件加 包括-對在短邊方向上彼此相對之末端部分Μ及m 如圖22B中所示,第二筛網部件2〇8經摺疊,使得第 網部件207被夹住。由於此結構’第一 _網部件而之末端 部分7m及717b藉由第二篩網部件7〇8之摺疊部分及 鳩所覆蓋。形成有該複數個通孔722的第二筛網部件彻 之右邊區域R2及左邊區域!^層疊在第__網部㈣7上。 藉由在充當氣相流道708m網部件7〇8中形成該 複數個通孔722’ &相流道7〇8,之毛細管半徑〜實質上辦 加。因此,熱傳輸器件之最大熱傳輪量一可得収 良。 應注意,在以上實施财,藉由在㈣的第二筛網部件 中形成通孔,熱傳輸器件之熱傳輸效能可得到改良。該等 通孔可形成於所夾之第一篩網部件中。 <第八實施例> 圖23為展示根據本發明之第人實施例之熱傳輸器件的示 意透視圖。圖24A至圖24C為用於解釋一製造此實施例之 149451.doc -38· 201116795 熱傳輸器件之方法的圖式。圖24A至圖24C展示沿著短邊 方向(沿著線B-B)截取此實施例之熱傳輸器件之情況下的 橫截面圖。 如圖23中所示’此實施例之熱傳輸器件8〇〇包括一藉由 摺叠單平板部件823所形成之容器80 1。通常,平板部件 823係由無氧銅、精銅或一銅合金製成。然而,材料並不 限於彼等材料,且除銅以外之金屬、樹脂或具有一較高熱 導率之另一材料可用作平板部件823。 如圖24A中所示,準備平板部件823。平板部件823在其 兩個末端部分上具有接合區域8且沿著一大致上為平板部 件823之中央的摺疊區域^^加以摺疊。為了使摺疊平板部件 823谷易,可在摺疊區域u中形成一凹槽、開口或其類似者。 如圖24B中所示,當向上摺疊平板部件823至一預定角度 時,第一實施例中所描述之毛細管部件5置放於摺疊之平 板4件823中。將毛細管部件5置放於平板部件⑵中,使 得第二篩網部件8之摺疊部分9沿著平板部件8 2 3之接合區 域S安置。因此’第一篩網部件7之末端部分m及第二篩 網部件8之該對末端部分16a及⑽與平板部件⑵之摺疊區 域U/目對。由於此結構’有可能防止於第-篩網部件7及第 一篩網部件8之末端部分步Μ | 丨刀處延伸之導線進入平板部件823之 接合區域S中。 在開始平板部件823之趨義+ ·ιι· 之晶疊之前,可將毛細管部件5置: 於平板部件823上。巖你丨而丄 牛例而s,可將毛細管部件5置放於 板部件8 2 3上,使得莖-益 第一師網部件8之摺疊部分9沿著圖24 149451.doc .39- 201116795 中之左邊接合區域s安置。 如圖24C中所示,進一步摺疊平板部件823,且藉由擴散 接合或其類似者將平板部件823接合在接合區域3中。應注 意,在此實施例中,使用了第一實施例之毛細管部件$, 但可替代地使用根據上述之另一實施例之毛細管部件。 在此實施例之熱傳輸器件8〇〇中,藉由摺疊單平板部件 823來形成容器801,結果為組件之數目減少,且可節约費 用。另外,在一由複數個組件構成之容器的情況下,該等 組件之預定定位準確度為必要的。對比而言,在此實施例 中,高定位準確度並非必要的。 <第九實施例> 圖25為展示根據本發明之第九實施例之熱傳輸器件的示 意透視圖。圖26八至圖26C為用於解釋一形成此實施例之 毛細管部件之方法的圖式。 如圖25中所示’此實施例之熱傳輸ϋ件9GG包括輪廓為 字母L之形狀的容器9()1。容器謝之内部空間亦具有字母匕 之升/狀|下文中’將描述一形成此實施例之毛細管部件 905之方法,毛細管部件9〇5設置於具有字母1之形狀的内 部空間中。 如圖26Α中所不,準備具有右邊區域r2及左邊區域l2之 第二筛網部件规。右邊區域&之形狀為字母l之形狀,其Port ί5 pieces 7 to protect. At J , , · σ fruit, the heat transfer efficiency of the working fluid is improved. In addition, the liquid; {; day τ ^ 乍 ^ body mainly through the liquid phase flow channel 5, the capillary mouth 丨 4 pieces 5, and Weng Zhi τ Β 6. However, the 〃-actuating fluid mainly passes through the hollow body member serving as the gas phase flow path 6, and the gas phase working fluid is moved (4) through the capillary tube Q, and the second screen member 8 on the upper plate 4 side is The portion of the folded H9451.doc 201116795 is the portion through which the gaseous and liquid working fluids pass. If the capillary member 5 is regarded as the gas phase flow path of the working fluid, based on the expression (9), the capillary radius rv is the size WjW2 of the mesh holes 12 and 15 of the first-net member 7 and the second sieve member 4, respectively. The diameter boundary I of the wires of the 1 mesh member 7 and the second mesh member 8 is therefore increased by the capillary screen radius rv of the gas phase flow path by using the second mesh member 8 having a larger 4 holes as the capillary member 5. And three pressure losses..., and he is reduced based on the expressions (4), (6), and (7). Therefore, the maximum heat transfer amount Qmax can be increased, with the result that the heat transfer efficiency of the heat transport device 100 is improved. As shown in Fig. 6, the capillary member 5 is joined to the lower plate member. If the size of the screen holes of the capillary portions is set to be too small in order to obtain a large capillary force, the mesh holes can be attributed to the bonding to the lower plate member 3, in this embodiment, having a larger sieve. The second screen member 8 of the hole is joined to the lower plate member 3. Therefore, u this is possible to prevent this problem. 7A and 7B are diagrams showing a screen 4 of the capillary member 985 of the type illustrated in FIG. 4, and a comparison of the first screen member 7 and the second screen member 8 of the embodiment. Part of the W. Wei Zhanxi transmits the screen component 987 of the device, and Fig. 7 shows the first mesh member 7 component 8 of this practical embodiment. As shown in Fig. 7A, the screen member 987 of the mesh portion of the capillary portion is formed such that the screens of the same type of the net member 987 are overlapped with each other: as the liquid phase of the two liquid phase moves through A gap is not protected and the phase working fluid becomes difficult. Applying the appropriate capillary force Δ to the liquid 149451.doc • 20· 201116795 On the other hand, as shown in FIG. 7B, the first screen member 7 f of the embodiment has the screens different from each other. This prevents the mesh of the first net member 7 and the mesh of the second screen member 8 from overlapping each other. Therefore, the resistance of the flow path to the liquid phase working fluid can be reduced, and the appropriate capillary force APcap can be applied to the liquid phase working fluid. The heat transfer performance of the junction heat transfer device. "Improvement Fig. 8 is a diagram showing the heat transfer performance of the heat transfer device 1 and the heat transfer performance of the heat transfer device 980 not shown in Fig.*. Here, for the capillary member 985 of the heat transport device, three (four) q screen members 987 are used. The maximum heat transfer amount Qmax of each of the heat transfer device 98 and the heat transfer device _ of this embodiment is measured. As described above, the first screen is made by folding the #1〇〇 second screen member 8. The jaw 7 is clamped to form the capillary member 5 according to this embodiment. On the other hand, the capillary member 985 of the heat transport device 980 has a structure in which three #1〇〇 screen members are stacked. As shown in Fig. 8, the maximum heat transfer amount gamma of the heat transfer device 1 of this embodiment is larger than the maximum heat transfer amount Qmax of the heat transfer device 98A. (Method of Manufacturing Heat Transfer Device) Figs. 9A to 9C are diagrams for explaining a method of forming the capillary member 5 supplied to the heat transport device 100 according to this embodiment. The second screen member 8 is prepared as shown in Fig. 9A. When viewed from the top, the second screen member 8 is almost twice as large as the inner space 2 of the container i. The second screen member 8 has a right side region R2, a left side area La and a pair of end portions i6a and 16b. The end portions 16a and 16b are opposed to each other in the direction in which the right region & and the left region ^ are disposed in 149451.doc 201116795. As shown in Fig. 9B, the first mesh member 7 formed in the shape of the inner space 2 is placed on the right side = 2 of the second screen member 8. [The screen member 7 has a pair of sides in the short-side direction = portions m and m. As shown in Fig. 9B, the end portion (7) is aligned with the end portion 16b of the second member 8. The first screen member portion 17a is placed substantially in the center of the second screen member 8.切 Cut the next item 7 from the #150 mesh sheet. The predetermined shape is cut from the _0 mesh. The mesh is cut by the first mesh member: the mesh member 8. For the dry and the younger-screen part 8, you m-cutting the cutter' - the cutting die or the like. Or use - electrical discharge machining (wire cutting). A line can be used. As shown in Fig. 9C, the folded second screen member 7 is clamped. Therefore, the first screen member 7 is sandwiched between the right region R2 and the left region L2 of the second second division. The end portion 17a of the further member 8 can be artificially stacked or can be used by the end portion m of the worm screen member 7 and the end mesh member 8 of the end portion of the second screen member 8 The knives b are aligned. The second screen is folded. The processing machine is preferably formed in this way to form the capillary member 5 having the same shape as the container k. The shape of Fig. 5(5) 2 is almost the same as the longitudinal direction of the container 1, and the direction of the capillary member 5 is not the direction of the short side of the container 1. . And the short side of the capillary member 5 14945J.doc • 22· 201116795 Figs. 1A and 10B are diagrams for explaining a method of manufacturing the heat transfer device (10). Fig. 10 shows a cross section in the case where the heat transport device 100 to be formed is taken along the short side direction. As shown in Fig. 1A, the capillary member 5 is placed in the recessed portion 2 of the lower plate member 3 such that the folded portion 9 of the second screen member 8 is along the side wall 18 of the recessed portion 2 surrounding the lower plate member 3. Placement. For example, in the heat transfer device 98A shown in Fig. 4, it is necessary to layer master = part 987 while positioning it with high accuracy. In contrast, in this embodiment, the capillary member 5 formed by the process shown in Figs. 9A to 9c is placed in the lower portion.丨 Ten pulls 4 pieces of 3 recessed part 2. Therefore, it is not necessary to perform the positioning as described above.纴, H 钇 钇 , , 有 有 有 有 有 有 有 有 有 ΛΛ ΛΛ ΛΛ ΛΛ ΛΛ ΛΛ ΛΛ ΛΛ ΛΛ ΛΛ ΛΛ ΛΛ ΛΛ ΛΛ ΛΛ ΛΛ ΛΛ ΛΛ ΛΛ 热 热 热 热 热 热 热 热 热 热 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 The capillary parts are placed in a container and washed. In this case, in the heat transfer device 980, the _ negative, scrubber net component 987 must be removed. In contrast, in this embodiment, a group of people can be washed by the process shown in Fig. 9 to form a capillary member 5. The workability when assembling the heat transport device 100 can be improved. Further, in the transmission wheel crying du + # 987ffl ^ ... transmission thief 980 shown in Fig. 4, three screen portions are used to form the capillary member 98 ψ , ^ ^ S丨 985. In contrast, in this embodiment, the first screen member 7-chain -f w Α , ^ ρ and the first division net member 8 form the capillary member 5. That is, in this embodiment, the number of screen members used by ^ _ kg can be reduced, and - the result is that the cutting cost of the screen can be saved. 149451.doc -23- 201116795 As shown in FIG. 1B, the upper plate member 4 is joined to the second plate member 18 of the lower plate member 3. That is, in the embodiment, the side of the lower plate member 3 = the upper surface corresponds to the joint portion, and the second screen folded portion 9 is disposed along the joint portion S. In the figure, the recessed portion 2 of the lower plate member 3 is shown in a visually understandable manner. Thus, in practice, the height of the side wall 18 corresponding to the thickness of the container i is relatively small, and the body a is, for example, 0.3 mm to 5 mm. Therefore, substantially, the folded portion 9 of 8 is placed along the joint region s. ''^〇P# Method for joining the lower plate member 3 and the upper flat plate portion... by diffusion bonding, ultrasonic bonding, brazing, welding or the like. In the case where diffusion bonding is performed on the opposing member 3 and the upper flat member 4, the temperature and pressure of the diffusion bonding, the capillary flat member 3 can be joined to each other. Or the cow...the lower part of the tablet part 4 is connected to the _ _ 〃. The top plate member 3 and the upper accessing earth can be joined by the capillary member 5 and the lower plate member 3 as described above. And a wire made of a thin metal wire to form the first screen member 7 member 8. Therefore, it is feared that the wire may be inserted between the second screen member 7 and the second screen member 8 and the joint portion of the flat member 3 of the division net portion between the second line r and the upper flat member 4, then the seven plate # Piece 3 leaks. To..., here is the second: the bonding of the portion from the clamping of the wire is covered in the heat transfer device_. In the end, the end portion of the net member 7 is placed in the joint region s of the lower plate member 3 to accommodate the first folded portion 9. Therefore, it is possible to prevent the wires of the doc-24-201116795 7 and the second screen member 8 from entering the joint region s in the region where the folded portion 9 of the second screen member 8 is placed. As a result, the manufacturing yield of the heat transport device 1 can be improved. <First Embodiment> A heat transfer device according to the first embodiment of the present invention will be described. In the following description, the same structures and operations as those of the heat transfer device 100 described in the first embodiment will be denoted by the same reference numerals and symbols, and descriptions of the structures and operations will be omitted. . Fig. 11 is a schematic cross-sectional view showing a heat transfer device according to a second embodiment. 12A and 12B are views for explaining a method of forming the capillary e P member of this embodiment. Figure jj shows a cross-sectional view in the case where the heat transfer device of this embodiment is taken along the short side direction. As shown in Fig. 11, the heat transfer device 200 of this embodiment includes a capillary member 205'. The capillary member 2G5 has a structure different from that of the capillary material 5 of the first embodiment. The capillary member 2〇5 of this embodiment comprises a fourth mesh member 2〇7 having a smaller mesh opening and a second mesh member 2 (10) having a larger mesh opening. Referring to the first division net member 2〇8, the first screen member is clamped, thereby forming the capillary member 2〇5. The method of forming the capillary member 2〇5 of this embodiment will be described hereinafter. • As shown in FIG. 12A, the screen member 208 is prepared. When viewed from the top, Υ "The 208 208 is almost twice as large as the internal space 2' of the container 1. The second screen member 2 〇 8 has three F 々. & or the right area r2, the left area L t central region c: 2. In addition, the first _ first net member 208 has a pair of end portions 6a and 2 〗 6b. The end portion VIII, (wood raft. P knives 216a and 2) 6b in the three The 149451.doc -25- 201116795 configured in the area is opposed to each other in the direction. The first screen member formed into a shape almost the same as the shape of the inner space 2 is placed in the central portion of the second screen member. The first screen member 2〇7 has a pair of end portions 2173 and 21 which are opposed to each other in the short-side direction. As shown in Fig. 12A, the pair of end portions of the first screen member 2G7 are placed and placed (4) Placed in the central region of the second screen member 208. As shown in Fig. 12B, the second screen member period is folded such that the first screen member 207 is clamped. The first screen member 2 () 7 Sandwiched between the central region C2 of the second screen member and the left region and between the central region C2 and the right region R2 of the second screen member fan Therefore, the pair of end portions 2l7a and 2m of the first screen member 207 are covered by the folded portion of the second screen member. The pair of end portions 216a and 216b' of the second Xuewang member 208 are disposed. The capillary member 205 of this embodiment is formed substantially in the center of the first screen member 2〇7. Thus, the capillary member 2〇5 formed in the circle 11 is placed on the lower plate member 3. In the recessed portion 2, and the lower plate member 3 and the upper plate member 4 are joined in the joint region S on the side wall 18 of the lower plate member 3. The thin tube member 205 is placed in the recessed portion 2 of the lower plate member 3, The folded portion 2093 and 2〇91 of the screen member 208 are placed along the joint region, thereby manufacturing the heat transport device 2 of this embodiment. In the embodiment, the first screen member 2 〇8: placed along the joint area s in the longitudinal direction of the container R. Therefore, the wire of the first screen member 2〇7 and the second screen member汕8 is prevented from being in the longitudinal direction of the tolerance 1 Entering the bonding area 8. As a result, the heat transfer device I49451.doc -26· 20111679 The manufacturing yield of 5 200 can be improved. As described above, the heat transfer device 200 having the south heat transfer performance can be manufactured with good workability in a short time by appropriately setting the folding manner of the first screen member 208. Further, the gas phase flow path 6 can occupy the container 1 by increasing a distance between the end portions 21A and 216b of the first 4 mesh member 2〇8 which are substantially opposite to each other at the center of the first screen member 207. a larger portion of the inner space 2. By appropriately setting the area of the second screen element 208 prepared in the process shown in Fig. i A, the end portion after folding is between The distance can be set as appropriate. When the distance between the end portions 21 and 21 is appropriately set, and the ratio between the internal space 2, the intermediate gas phase flow path 6, and the liquid phase C is appropriately set, the heat transfer efficiency of the heat transport device 2 can be Improved. Further, in the heat transport device 980 shown in Fig. 4, when the capillary member 985 is placed in the inner space 982 of the container 981, it is necessary to prevent the wires of the screen 4 piece 987 from entering the joint region 8. Thus, for each screen member 987 m, for example, the operation of removing the extended wire or an inspection of the wire into the joint region s of the lower member 983. Further, in the case of a wide residence, the surface rain of the plaque 忏 y87 is set to be smaller than the area of the inner space 982, and the screen member 987 is separated from the joint, the domain S (the side wall 998), thereby preventing the wire from entering the joint zone. • 士比和σ In this embodiment, the improved heat transfer is not necessary because the second screen component period and the shackle are placed along the joint area 8 as described above. Machinability of the manufacture of the piece. In addition, due to Yiyun rider <# ',,, and the area of the capillary member 5 is set to 149451.doc -27- 201116795 is smaller than the internal space 2, the size (when viewed from the top), so the capillary portion (4) 5 is allowed to occupy the inner region 2 , the larger part of A. Because of A, a high capillary force can be applied to the working fluid' and the heat transfer efficiency of the heat transport device 2 can be improved. Further, in the case of the yoke y | i, in the case of the yoke, even if the area of the capillary member 205 is slightly larger than the size of the inner (four) 2. (when viewed from the top), the capillary having elasticity may be used. The part 2〇5 is pushed into the recessed portion 2 of the lower plate member 3. g) The dimensional tolerance of the area of the 'capillary member 2〇5 can be increased'. As a result, the additivity of forming the capillary f part can be improved. In this embodiment, the capillary member 205 is placed in the recess 4 of the lower plate member 3. Alternatively, the capillary member 2〇5 may be placed on the flat lower plate member and the upper plate member having one recessed portion may be joined to the joint region of the lower plate member. In this case, the capillary member 205 is placed on the lower plate member such that the second - (four) member 2: the folded portions 2_ and 2_ are disposed along the joint region of the lower plate member. Further, the flat lower plate member, the upper flat member, and the frame member constituting the side wall of the container 1 can be formed. The container magazine is formed by joining the frame member to the joint region of the lower plate member and engaging the upper plate member to the joint region of the frame member. In this case, the capillary member 205 is placed on the lower plate member so that the finger-folding portions 2〇9& and 2〇 of the second screen member 208 are placed along the joint region of the lower plate member. Alternatively, after the lower plate member is joined to the frame member 1, the capillary member 205 can be placed on the lower plate member such that the folded portions 209a and 209b are disposed along the joint region of the frame member. J49451.doc -28· 201116795 Further, in this embodiment, the folded portions 209a and 209b of the second screen member 2〇8 are placed in the long side of the container 1 & μ in the far direction of the heart. The area of the joint region S of the lower plate member 3 in the longitudinal direction of the container i is larger than the area in the direction of the short side of the container α. Therefore, the adenine_松~▲ C field will be placed on the long side of the Xuan I, the realist, the Xia, the sneak, and the effect of the above-mentioned effect Big. However, the second screen member 2〇8 can be folded so as to correspond to the short side direction of the container 1, and the folded portion of the second screen member 208 can be placed in the short side direction of the container 1. <Third Embodiment> Fig. 13 is a schematic cross-sectional view showing a heat transfer device according to a third embodiment of the present invention. Figure U shows a cross-sectional view in the case where the heat transfer device of this embodiment is taken along the short side direction. In the heat transfer device 3 of this embodiment, a screen member having the same mesh number is used as the first screen member 3 0 7 and the second screen member 3 〇 8. The second screen member 3〇8' is slid by the first screen member 3〇7, whereby the capillary member 305 is formed. At this time, the mesh of the first mesh member 307 and the mesh of the second mesh member 3〇8 are set so as to be disposed in different directions from each other. The second screen member 3〇8 is folded in the same manner as the second screen member 208 described in the second embodiment. 14A and 14B are plan views showing the first screen member 3〇7 and the first screen member 308 of this embodiment. 15A and 15B are enlarged plan views showing the first mesh member 3〇7 and the second mesh member 3〇8 which are not shown in Fig. 14. Figures MA and 15A show the second screen component, and the figures and figures show the first screen component 3〇7. 149451.doc -29. 201116795 As shown in Fig. 14A, the second screen member 3〇8 is almost twice as large as the internal space 2 when viewed from the top. The second screen member 308 has a plurality of first wires 313 and a plurality of second wires 314 woven in a direction substantially perpendicular to the first wires 313. The direction in which the first wire 3 13 extends corresponds to the longitudinal direction of the container 1, and the direction in which the second wire 314 extends is opposite to the short side direction of the container 1. Therefore, as shown in Figs. 14A and 11a, the mesh 3 15 of the second screen member 308 is disposed in the longitudinal direction of the container 1 and in the short side direction of the container 1. As shown in Fig. 14B, the first screen member 307 is formed into a shape almost the same as the inner space 2 of the container casing. The first screen member 3〇7 has a pair of end portions 317a and 317b which are opposed to each other in the short-side direction. The pair of end portions 317a and 317b are oriented in the direction of the long side of the container 1. In this embodiment, the first screen member 307 also has a plurality of first wires 313 and a plurality of second wires 314 woven in a direction perpendicular to the first wires 313. However, as shown in FIGS. 14B and 15B. In the first screen member 307, the direction in which the first wire 313 and the second wire 314 extend is set to be different from the extending direction of the pair of end portions 317a and 317b. Therefore, the direction in which the first wire 313 and the second wire 314 of the first wire mesh member 3〇7 extend is different from the direction in which the first wire 313 and the second wire 314 of the second wire mesh member 3〇8 extend. Therefore, the direction in which the screen holes 3 12 of the first screen member 3〇7 are disposed is set to be different from the direction in which the screen holes 315 of the second screen member 308 are disposed. The first screen member 307 and the second screen member 308 are cut out from one of the first wires 313 149451.doc 201116795 and the second wire 3 14 alternately woven. The second screen member 308 is cut along the direction in which the first wire 3 13 and the second wire 3 14 extend. The first screen member 307 is cut in a direction different from the direction in which the first wire 313 and the second wire 314 extend. As described above, in this embodiment, it is not necessary to prepare two kinds of mesh cloths having different mesh numbers, which can save the cost of the mesh cloth. In the capillary member 305 of this embodiment, since the mesh holes (mesh holes 3 12 and 3 15) of the first mesh member 307 and the first mesh member 308 are disposed in different directions, it is possible to prevent the mesh holes 312. The screen holes 315 overlap each other. Therefore, the resistance of the flow path with respect to the liquid phase working fluid can be reduced, and a high capillary force can be applied to the liquid phase working fluid. As a result, the heat transfer performance of the heat transfer device 3 can be improved. As shown in Fig. 15B, the angle θ indicates the direction in which the mesh 3 12 of the first screen member 3〇7 is disposed and the direction in which the mesh 3 1 $ of the second screen member 3〇8 is disposed. The difference. For example, when the angle θ is set in the range of 5 to 85 degrees, as described above, the heat transfer performance of the heat transfer device 3 can be improved. When the angle θ is set to 9 〇, the mesh 312 of the first screen member 3〇7 and the hole 315 of the second screen member 3〇8 may overlap each other. However, there is a variation in the weaving form of the first wire 313 and the second wire 314, so that even in the case where the corner angle is 90 degrees, the mesh hole 312 and the mesh hole 315 may not overlap in some cases. Therefore, even in the case of a corner angle of 9 degrees, it is possible to improve the heat transfer performance of the heat transfer wheel device 300. Therefore, it is also possible to select the range of degrees to 90 degrees as the angle θ. The towel, the first screen member and the second screen 149451.doc 201116795 The components 308 are each formed by the first wire 313 and the second wire 314 'but are not limited thereto. In addition, even if a first screen having a different mesh number is used The components and the second screen member, and the direction in which the Xuekong holes of the screen members are located are different. The heat transfer performance of the heat transfer device can also be improved. <Fourth Embodiment> Fig. 16 is a schematic cross-sectional view showing a heat transfer device according to a fourth embodiment of the present invention. 17A to 17C are views for explaining a method of forming the capillary member of this embodiment. Fig. 16 is a cross-sectional view showing a state in which the heat transfer device of this embodiment is taken along the short side direction. The capillary member 405 of the heat transfer device 4 of this embodiment is formed by alternately folding the first screen member 4〇7 and the second screen member 4〇8 so as to be sandwiched therebetween. Hereinafter, a method of forming the capillary member 405 of this embodiment will be described. As shown in Fig. 17A, when the first screen member 4〇7 and the second screen member 4〇8 are prepared from the top down, the first screen member 407 and the second screen member are each internally internal. The space 2' is twice as large. The right region of the first screen member 々ο? is placed on the left side region L2 of the second screen member 408 shown in Fig. 17A. The first screen member 407 has a pair of end portions 417a and 417b. The end portions 417 & and 41 are opposed to each other in the direction in which the right region & and the left region ^ are disposed. The end portion 417b is disposed substantially at the center of the second screen member 408. The second screen member 408 is folded as shown in Fig. 17B so as to cover the end portion 417b of the first screen member 407. The end of the first screen member 407 is covered by the folded portion (10) of the second screen member 彳 (10). 149451.doc -32· 201116795 In addition, the right portion of the first screen member 4〇7 Rl is sandwiched between the left region Lz and the right region of the second screen member 4A. Thus, the end of the second screen member 8 and the portion 416b are disposed substantially at the center of the first screen member 4A. As shown in Fig. 17C, the first screen member 4〇7 is folded so as to cover the end portion 416b of the second screen member 408. The end portion 416b of the second screen member 4〇8 is formed by a screen member The folded portion 4〇9a of the 4〇7 is covered. Furthermore, the right region & of the second screen member 4〇8 is sandwiched between the right region core and the left region L丨. In this way, the first screen is alternately folded. The mesh member 407 and the second screen member 4 are so as to be clamped to each other, thereby forming the capillary member 4〇5 of this embodiment. The folded portion of the first screen member 4〇7 and the second screen member 408 40% and 4〇9b are portions corresponding to the longitudinal direction of the container 。. As in this embodiment, by alternately folding The first screen member and the second screen member 4 are stacked so as to be sandwiched from each other, and the number of the first screen member 407 and the second screen member 4A8 which are stacked to constitute the capillary member 405 can be increased. SU匕' allows the capillary member 405 to occupy a larger portion of the internal space 2' of the capacitor. The result is that the heat transfer performance of the heat transfer device 4 can be improved. It should be noted that, as shown in Fig. 16, with the first screen The finger-receiving portion 409a of the mesh member 4〇7 is disposed on the inner side of the container 1 than the end portion 4i6a (the end portion opposite to the end portion side) of the left side region of the second screen member joined to the lower plate member 3. The upper folded portion 409b is compared to the first portion. Further, the end portion 417a of the left side of the screen portion 407 of the second screen member 4〇8 mesh member 407 is also disposed on the inner side of the container 1. In the process shown in Figs. 17A to 17C, the areas of the prepared first screen member 407 and second screen member 4〇8 and the like are appropriately set, thereby making it possible to Positioning the end portion 416a of the second screen member 4〇8 The end portion 417 & of the second screen member 4〇8. With this configuration, even if the wire is inserted into the end portion of the second screen member 4〇8 or inserted into the end portion 417a of the first screen member 407, it is possible The extended wire is prevented from entering the bonding region 8. As a result, the heat transfer device 4 of this embodiment can be manufactured in a short time with good workability. <Fifth Embodiment> Fig. 18 is a schematic cross-sectional view showing a heat transport device according to a fifth embodiment of the present invention. Fig. 19 is a schematic exploded perspective view showing the heat transport device of this embodiment. The figure shows a cross-sectional view in the case where the heat transfer device of this embodiment is taken along the short side direction. A ~.q~ 丨 丨 锏 锏 下部 lower plate member 503, reinforcing member 519 and upper plate member 5 〇 4. The flat plate member 503 has a recessed portion 5〇2. The reinforcing member 519 is joined to the flat plate member 503, and the upper flat member 5〇4 is joined to the reinforcing portion 519' to thereby form the container 5〇1 of this embodiment. The reinforcement (4) 9 series is made of, for example, oxygen-free copper, refined copper or a copper alloy. As shown in Fig. U, in the dam member 519, a plurality of reinforcing portions are provided between the capillary member 505 and the upper plate member 5〇4. The retanning reinforcing portion 520 is disposed in the short side direction of the container 5〇1, and the equal force lobes 520 each extend in the longitudinal direction of the container 5〇1. The gap between the complex (four) ^ 149451.doc • 34· 201116795 minutes 520 acts as a gas phase flow path 5〇6 in this embodiment. It should be noted that the capillary member 505 has the same structure as the capillary member 205 described in the second embodiment. As shown in Fig. 19, the reinforcing member 519 has a plurality of through holes 521 which are formed to extend in the longitudinal direction of the container 5〇. The plurality of through holes 521 are disposed in the short side direction of the container 501. The through holes 521 serve as the gas phase flow passages 506 shown in Fig. 18, and the reinforcing portions 52 are sandwiched between the through holes 521, respectively. The number of through holes 521 (i.e., the number of reinforcing portions 52A) can be appropriately set. By the reinforcing portion 520 between the capillary member 505 and the upper flat member 5〇4, the durability of the container 501 can be improved. For example, there is a month t* preventing the 5 5G1 from being deformed due to internal pressure caused by an increase in the internal temperature 7 of the heat transfer device. Outside the crucible, for example, it is possible to inject the container 5〇1 into the heat transfer device 5 in a state where the working fluid is reduced. The middle time is deformed due to a pressure. Instead of the reinforcing member 519', the plurality of reinforcings each having a shape of a cylinder or a polygonal column may be disposed in the inner space 5?2 of the container 501, by forming the plurality of additions on the upper plate member 5Q4. $^Knife 520 and by removing the upper plate member state and the lower plate member from each other. The P-workplace 502t sets the reinforcement sections 52(). In this situation, 纠 曰 属 属 属 属 belongs to the electric mine, pressing process, cutting process or the like also slab. The reinforcing portions 52Q are formed on the member 504. In the case where the complex type (4) is formed on the upper flat plate portion (4) 4, the shoulder can improve the durability of the heat transfer device while performing the f-curve process. In addition, 149451.doc -35· 201116795 does not use the reinforcing member 5 19, so the component cost can be saved. In the heat transport device 5A according to this embodiment, the capillary member 5〇5 is set to have the same structure as the capillary member 2〇5 described in the second embodiment. However, the structure of the capillary member according to another embodiment described above can also be applied to the capillary member 5 〇 5. <Sixth Embodiment> Fig. 20 is a schematic cross-sectional view showing a heat transfer device according to a sixth embodiment of the present invention. Figure 20 is a cross-sectional view showing a state in which the heat transfer device of this embodiment is taken along the short side direction. As shown in Fig. 20, in the heat transport device 6 (eight) of this embodiment, the capillary member 605 is provided, and the capillary member 6〇5 has a thickness substantially equal to the thickness of the container inner space 2'. The capillary member 6〇5 is formed by folding a second screen member 608 having a larger mesh opening such that a smaller screen member 607 is sandwiched therebetween. The manner in which the second screen member 608 is folded is similar to the manner in which the H mesh member is described in the second embodiment. By providing the first screen member 607 and the second web member 608 having a predetermined thickness, the thickness of the capillary member 6〇5 is set to be almost the same as the thickness of the space 2' of the container. Alternatively, by appropriately setting the height of the side wall 18 of the lower plate member 3, the thickness of the capillary member 6〇5 and the thickness of the space 2 (the height of the side wall 18) can be set to be substantially equal to each other. Thanks to the container! The inner space 2 has a thickness which is almost the same as the thickness of the thin tube member 605 in the heat transfer device_, so that the hair member; the member member 605 is disposed in the entire inner space 2 of the container} as shown in Fig. 2A. Because of this; 14945!.doc • 36· 201116795 The durability of the container 1 can be improved, which prevents the deformation of the container 1. Further, it is not necessary to provide another member for improving the durability of the container 1 in the internal space 2, which results in a component cost saving, and the heat transfer device 6 can be manufactured with good workability in a short time. Further, in this embodiment, the second screen member 608 having a larger mesh opening serves as the gas phase flow path 608, and the first screen member 607 having the smaller mesh opening serves as the liquid phase flow path 607'. As described in the first embodiment, in the case of using a screen member as a gas phase flow passage, the screen radius of the gas phase flow passage is made larger by using a screen member having a larger sieve hole. The gas phase flow path of radius Γν increases the maximum heat transfer amount Qmax. Therefore, by using the second screen member 6〇8 having a larger mesh opening as the gas phase flow path 608', it is possible to improve the heat transfer device 600. Heat transfer efficiency. It should be noted that in the first to fourth embodiments, the thickness of the capillary member is set to be substantially equal to the thickness of the inner space of the container, with the result that the same effect as that in this embodiment can be obtained. <Seventh Embodiment> Fig. 21 is a schematic cross-sectional view showing a heat transfer device according to a seventh embodiment of the present invention. 22A and 22B are diagrams showing the capillary of this embodiment; Figure 21 shows a cross-sectional view in the case where the device of this embodiment is taken in the short-side direction. ',,' Then, as shown in Fig. 21, the heat transfer device in this embodiment? Called, capillary member 705. The capillary member 7〇5 has a thickness of _substantially: m:': thickness. Capillary part 7.5 has a larger mesh hole. The ή 〇 7〇8 acts as a gas phase flow channel. A plurality of through holes 722 149451.d〇, 37-201116795 are formed in the second screen member 708. As shown in Fig. 22A, when viewed from the top, the second screen member 7〇8 which is almost twice as large as the inner shutter 2 is prepared. The second screen member Mg has three regions. The right region R2, the left region L2, and the central region are formed in the right region & 2 and the left region w. The plurality of through holes 722 can be easily formed by a (iv) mold or the like. Further, the first screen member 707 formed into almost the same shape as the inner space 2 is placed in the central portion of the second screen member. The first screen member is added to include end portions Μ and m which are opposed to each other in the short side direction. As shown in Fig. 22B, the second screen member 2 is folded so that the first net member 207 is caught. The end portions 7m and 717b of the structure 'first mesh member' are covered by the folded portions of the second screen member 7〇8 and the crucible. The second screen member in which the plurality of through holes 722 are formed is completely laminated on the right side region R2 and the left region. By forming the plurality of through holes 722' & phase flow paths 7〇8 in the mesh member 〇8 serving as the gas phase flow path 708m, the capillary radius 〜 is substantially increased. Therefore, the maximum heat transfer amount of the heat transfer device can be improved. It should be noted that in the above implementation, the heat transfer performance of the heat transfer device can be improved by forming the through holes in the second screen member of (4). The through holes may be formed in the first screen member that is sandwiched. <Eighth Embodiment> Fig. 23 is a schematic perspective view showing a heat transport device according to a first embodiment of the present invention. 24A to 24C are diagrams for explaining a method of manufacturing the 149451.doc -38·201116795 heat transfer device of this embodiment. 24A to 24C are cross-sectional views showing a state in which the heat transport device of this embodiment is taken along the short side direction (along line B-B). As shown in Fig. 23, the heat transfer device 8 of this embodiment includes a container 80 1 formed by folding a single flat member 823. Typically, the plate member 823 is made of oxygen-free copper, fine copper or a copper alloy. However, the materials are not limited to these materials, and a metal other than copper, a resin or another material having a higher thermal conductivity may be used as the flat member 823. As shown in FIG. 24A, the plate member 823 is prepared. The plate member 823 has a joint region 8 on its both end portions and is folded along a folded region substantially at the center of the flat member 823. In order to fold the flat plate member 823, a groove, an opening or the like can be formed in the folded region u. As shown in Fig. 24B, when the flat plate member 823 is folded upward to a predetermined angle, the capillary member 5 described in the first embodiment is placed in the folded flat plate 4 member 823. The capillary member 5 is placed in the flat member (2) such that the folded portion 9 of the second screen member 8 is placed along the joint region S of the flat member 8 2 3 . Therefore, the end portion m of the first screen member 7 and the pair of end portions 16a and (10) of the second screen member 8 are aligned with the folding portion U/ of the flat member (2). Since this structure is made possible, it is possible to prevent the lead wires extending at the end portions of the first screen member 7 and the first screen member 8 from entering the joint region S of the flat plate member 823. The capillary member 5 can be placed on the flat member 823 before starting the stack of the flat member 823 + ιι. Rock, you can squat, and the capillary member 5 can be placed on the plate member 8 2 3 so that the folded portion 9 of the stem-Yi first division net member 8 is along Figure 24 149451.doc .39-201116795 The left joint area s is placed. As shown in Fig. 24C, the plate member 823 is further folded, and the plate member 823 is joined in the joint region 3 by diffusion bonding or the like. It should be noted that in this embodiment, the capillary member $ of the first embodiment is used, but a capillary member according to another embodiment described above may alternatively be used. In the heat transport device 8 of this embodiment, the container 801 is formed by folding the single plate member 823, with the result that the number of components is reduced and the cost can be saved. Further, in the case of a container composed of a plurality of components, the predetermined positioning accuracy of the components is necessary. In contrast, in this embodiment, high positioning accuracy is not necessary. <Ninth Embodiment> Fig. 25 is a schematic perspective view showing a heat transport device according to a ninth embodiment of the present invention. Fig. 26 through Fig. 26C are diagrams for explaining a method of forming the capillary member of this embodiment. As shown in Fig. 25, the heat transfer member 9GG of this embodiment includes a container 9 () 1 having a shape of a letter L. The inner space of the container also has a letter 匕 liter/shape|hereinafter, a method of forming the capillary member 905 of this embodiment will be described, and the capillary member 〇5 is disposed in the inner space having the shape of the letter 1. As shown in Fig. 26A, a second screen member gauge having a right region r2 and a left region l2 is prepared. The shape of the right area & is the shape of the letter l, which
大致等於容H901之内部空間。左邊區域L2之形狀為字母L 之形狀左邊區域L2及右邊區域R2之形狀在圖26A中具有 左右對稱性。 149451.doc 201116795 如圖26B中所示,將具有大致等於容器9〇1之内部空間之 形狀的字母L之形狀之第一篩網部件9〇7置放於第二篩網部 件908之右邊區域R2上。將第一篩網部件9〇7疊加在第二篩 網部件908之右邊區域&上。此外,第一筛網部件9〇7之末 端部分91 7a大致上安置於第二篩網部件9〇8之中央。 如圖26C中所不,摺疊第二篩網部件9〇8以便使其覆蓋第 一筛網部件907之末端部分917a。因此,第一篩網部件9〇7 被夾在第二篩網部件908之右邊區域&與左邊區域^之 間,藉此形成根據此實施例之具有字母[之形狀的毛細管 部件905。 在此,將描述根據此實施例之毛細管部件9〇5之另一實 例。圖27A及圖27B為用於解釋一形成另一實例之毛細管 部件955之方法的圖式。 如圖27A中所示,將具有大致等於容器9〇1之内部空間之 形狀的字母L之形狀之第-i網部件957置放於形成有複數 個翻起區域Ο之第二篩網部件958上。設置第二篩網部件 958之該複數個翻起區域〇 ’以便使其對應於第—篩網部件 957之各別末端部分917。在該等翻起區域◦之間,形成截 斷部分924或縫隙925。 如圖27B中所示,措疊第二筛網部件州,使得第二筛網 部件州之該等翻㈣域〇與第—筛網料957重疊。因 此’第一筛網部件957被失在該第二篩網部件之間,且第 Γ筛網部件957之末端部分917藉由第二筛網部件958之該 等翻起區域〇所覆蓋。 14945 丨.doc -41 · 201116795 舉例而言,如上所述,在此實施例中,根據熱傳輪器件 900之容器901之形狀適當地設定摺疊的第二篩網部件 908(958)之形狀,藉此形成該 等翻起區域〇 ^結果,可來 成具有所要形狀之毛細,管部件905(955)。 <第十實施例> 圖28為展示根據本發明之第十實施例之電子裝置的示魚 透視圖。此實施例之電子裝置15〇包括根據以上實施例之 熱傳輸器件。在此實施例中,給出一膝上型個人電腦(pc) 作為電子裝置1 5 0之一實例。 電子裝置150包括主體151及連接至主體151之顯示單元 I52。主體151與顯示單元152係經由鉸鏈153連接,且顯示 單70 152可相對於主體151打開及閉合(摺疊)。 鍵盤154及觸控板155係設置於主體151上。一其上安裝 有諸如cPU之電路組件156之控制電路板(未圖示)係設置於 主體151中。 邊、’彖發光型背光1 58係設置於顯示單元丨52中。背光丨58 …、射顯不單元152之螢幕157。如圖28中所示,背光158設 置於顯示單元152之上部部分及下部部分中。舉例而言, 月光15 8係藉由將複數個白光發光二極體(led)安置於一銅 板上來形成。 在此實施例中’熱傳輸器件1000係設置於主體151中且 與電路組件156接觸。或者,在顯示單元152中’熱傳輸器 件1〇〇〇可與形成背光158之銅板接觸。在此情況下,如圖 28之虚線所指示’複數個熱傳輸器件1000設置於顯示單元 149451.doc •42· 201116795 152中。該複數個熱傳輸器件1〇〇〇係沿著顯示單元i52之垂 直方向於一垂直位置安裝。 如以上實施例中所描述,由於熱傳輸器件1〇〇〇具有高的 熱傳輸效能,故電路組件156、背光158或其類似者中所產 生之熱可迅速地釋放至電子裝置15〇之外部。因此,有可 旎防止電子裝置150歸因於電路組件156、背光或其類 似者中所產生之熱而毀壞。另外,熱傳輸器件⑽^可使主體 151或顯示單元152之内部溫度均勻,此可防止低溫燃燒。 在此實施例中,使用膝上型pc作為電子裝置15〇之實 例。然而’電子裝置1 5 0 Rp -tK lL 丁 电丁衣直DU不限於此。電子裝置15〇之實例包 括視聽設備、顯示裝置、投影機、博弈機、汽車導航系 統、機器人裝置、個人數位助理(PDA)、電子辭典、相 機、蜂巢式電話及其他電子器件。 <修改實例> 本發明不限於以上實旛你丨Β π χ ^ < J且了加以各種修改而不脫離本 發明之要旨。 舉例而5 ’在除參看圖1 3所七―奸+够 韦a U所描述之第三實施例以外的以 上實施例中’可使用具有輕 负毕又大蛘孔之第一篩網部件及且有 較小筛孔:第二筛網部件。換言<,可使用具有較小筛目 數之第一師網部件及具有較大篩目數之第二篩網部件。即 使在使用此第一篩網部件!黛_ * 仵及第一師網部件的情況下,亦可 獲得與以上實施例相同的 ^ J 文應舉例而言,在根據參看圖 20所描述之第六實施例典 毛s °P件605中,可將具有較 大師孔之第一篩網部件的 … °又疋為氣相流道,且可將具有 149451.doc -43- 201116795 較小師孔之第二篩網部件⑽設^為液相流道。 a圖中所不,在電子裝置150中之顯示單元152打開的 提供至顯不單兀】5 2之下侧上之背光^ 5 8的該等熱 傳輸器们_與料熱傳輸Μ之T部末端部分上之背光 "8接觸。以此方式’在熱源與垂直安褒的該等熱傳輸器 件之下部末端部分接觸的情況下,該等熱傳輸器件處於底 熱(bottom-heat)模式下。扁昝,斤π 丁 在此If况下,液相工作流體之移 動由重力驅策。 另一方面’在熱源與垂直安裝的該等熱傳輸器件之上部 末端部分接觸的情況下,該等熱傳輸器件處於頂熱⑽_ heat)模式下。在此情況下,液相工作流體對抗重力而移 動’因此必須將一高的毛細管力施加至液相工作流體。 如上所述,視所安裝之熱傳輸器件之定向、與熱源之接 觸位置或其類似者而定,熱傳輸器件之所需特徵變化。考 慮到(例如)是否增加施加至液相工作流體之毛細管力或是 否增加氣相卫作㈣之氣㈣道之尺寸,僅必須根據熱傳 輸器件之所需特徵來適當選擇第一篩網部件及第二篩網部 件之篩目數。 圖29Α、圖29Β、圖30Α及圖30Β為展示根據第一實施例 之熱傳輸器件1〇〇之修改實例的圖式。在熱傳輸器件ι〇〇 中,毛細管部件105係藉由摺疊一個篩網部件1〇7而形成。 如圖29及圖30中所示,可適當地設定摺疊篩網部件ι〇7之 方式。 藉由如上所述地摺疊該一篩網部件1〇7,允許毛細管部 149451.doc -44 - 201116795 件i〇5佔據容m之内部空間2,的較大部分。由於此結構, 熱傳輸效率可得到改良。此外,層疊複數個篩網部件時之 定位操作並非必要的,從而改良熱傳輸器件1〇〇之製造時 =可加工性。此外’有可能防止該篩網部件之導線進入容 态1之接合區域s中,結果為可在短時間内以良好可加工性 製造具有高的熱傳輸效能之熱傳輸时1〇〇。 本申請案含有與於2_年1G月15日在日本專利局申請之 曰本優先專利申請案JP2_伽54中所揭示之内容相關 之標的物’該案之全部内容特此以引用的方式併入。 【圖式簡單說明】 圖1為展示根據本發明之第 意透視圖; 一實施例之熱傳輸器件的示 其係沿著短邊方向 二筛網部件之放大 圖2為圖1之熱傳輸器件之橫截面圖, (沿著線A-A)截取; 圖3為圖2中所示之第_ λ* 心乐 師網部件及第 平面圖; 圖4為展示作為比較實 面圖; 例給出的熱傳輸器 件之示意橫截 為普通熱傳輪器件之冷卻模型圖. 圖6為用於解釋根據第— 示意橫截面圖; …、得輸益件之操作的 圖7為展不圖4中所 的第一實施例之第— 視圖; 149451.doc ‘45· 201116795 圖8為展示根據第一實施例之熱傳輸器件之熱傳輸效能 及相比較的圖4中所示之熱傳輸器件之熱傳輸效能的圖 式; 圖9為用於解釋形成提供給根據第一實施例 件之毛細管部件之方法的圖式; “輸裔 圖10為用於解釋製造根據第一實施例之熱傳輸器件之方 法的圖式; 圖; 圖11為展示根據第二實施例之熱傳輸器件之示意橫截面 之方法 圖12為用於解釋根據第二實施例形成毛細管部件 的圖式; 圖13為展*根據第三實施例之熱傳輸器件之示意橫截面 圖; 篩網 圖為展示根據第三實施例之第一篩網部件及第 部件的平面圖; 之第一筛網部件及第二筛網部件 圖15為展示圖14中所示 之放大平面圖; 圖圖⑽展示根據第四實施例之熱傳輸器件之示意橫截面 二為用於解釋根據第四實施例形成毛細管部件之方法 圖圖U為展示根據第五實施例之熱傳輸器件之示意橫截面 圖19為展示根據第五實施例之熱傳輪器件之示意分解透 149451.doc • 46 · 201116795 視圖; 輪器件之示意橫截面 圖圖2。為展示根據第六實施例之熱傳輸器件之示意橫載面 圖21為展示根據第七實施例之熱傳 圖; 圖22為用於解釋根據第七實施例 的圖式; 形成毛細管部件之方法 圖2 3為展示根據第八實施例之熱傳輸 圖; 用於解釋製造根據第八實施例之熱傳輸器件之方 之示意透視 法的圖式; 圖25為展示根據第九實施例之熱傳輪 圖; 圖26為用於解釋根據第九實施例形成毛細管部件之方法 之示意透視 的圖式; 圖27為用於解釋作為第九實施例中之另—一, 細管部件之方法的圖式; ' 圖2 8為展示根據第十實施例之電子穿晋夕一 u 、罝艾不意透視圖; 圖29為展示根據第-實施例的圖2之熱傳輪 實例的圖式;及 ° 圖30為展示根據第一實施例的圖2之熱傳輪 實例的圖式。 '月'J 【主要元件符號說明】 1 容器 的形成毛 之修改 器件之修改 ]49451.doc -47· 201116795 2 凹陷部分 2' 容器之内部空間/内部區域 3 下部平板部件 4 上部平板部件 5 毛細管部件 5' 液相流道 6 中空體 6, 氣相流道 7 第一篩網部件 8 第二筛網部件 9 於此處摺疊第二筛網部件之部分 10 第一導線 11 第二導線 12 第一篩網部件之篩孔 13 第一導線 14 第二導線 15 第二篩網部件之篩孔 15a 熱傳輸器件之末端部分 15b 熱傳輸器件之末端部分 16a 末端部分 16b 末端部分 17a 末端部分 17b 末端部分 18 側壁 149451.doc -48- 201116795 100 熱傳輸器件 150 電子裝置 151 主體 152 顯示單元 153 鉸鏈 154 鍵盤 155 觸控板 156 電路組件 157 螢幕 158 邊緣發光型背光 200 熱傳輸器件 205 毛細管部件 207 第一篩網部件 208 第二筛網部件 209a 第二篩網部件之摺疊部分 209b 第二篩網部件之摺疊部分 216a 第二篩網部件之末端部分 216b 第二篩網部件之末端部分 217a 第一篩網部件之末端部分 217b 第一篩網部件之末端部分 300 熱傳輸器件 305 毛細管部件 307 第一篩網部件 308 第二篩網部件 149451.doc • 49- 201116795 312 第一篩網部件之篩孔 313 第一導線 314 第二導線 315 第二篩網部件之篩孔 317a 第一 1帛網部件之末端部分 317b 第一薛網部件之末端部分 400 熱傳輸器件 405 毛細管部件 407 第一篩網部件 408 第二篩網部件 409a 第一篩網部件之摺疊部分 409b 第二篩網部件之摺疊部分 416a 第二篩網部件之末端部分 416b 第二筛網部件之末端部分 417a 第一篩網部件之末端部分 417b 第一篩網部件之末端部分 500 熱傳輸器件 501 容器 502 凹陷部分 502, 容器之内部空間 503 下部平板部件 504 上部平板部件 505 毛細管部件 506' 氣相流道 149451.doc -50- 201116795 519 加強部件 520 加強部分 521 通孔 600 熱傳輸器件 605 毛細管部件 607 第一篩網部件 607' 液相流道 608 第二篩網部件 608' 氣相流道 700 熱傳輸器件 705 毛細管部件 707 第一篩網部件 708 第二篩網部件 708' 氣相流道 709a 第二篩網部件之摺疊部分 709b 第二篩網部件之摺疊部分 717a 第一篩網部件之末端部分 717b 第一篩網部件之末端部分 722 通孔 800 熱傳輸器件 801 容器 823 單平板部件 900 熱傳輸器件 901 容器 I49451.doc -51 - 201116795 905 毛細管部件 907 第一篩網部件 908 第二筛網部件 917 第一韩網部件之末端部分 917a 第一筛網部件之末端部分 924 截斷部分 925 缝隙 955 毛細管部件 957 第一篩網部件 958 第二篩網部件 980 熱傳輸器件 981 容器 982' 容器之内部空間 983 下部平板部件 984 上部平板部件 985 毛細管部件 985' 液相流道 986 中空體 986' 氣相流道 987 篩網部件 995a 熱傳輸器件之末端部分 995b 熱傳輸器件之末端部分 998 側壁 999 熱源 149451.doc -52- 201116795 1000 熱傳輸器件 A-A 線 B-B 線 C 冷凝區域 c2 中央區域 E 蒸發區域 Li 左邊區域 l2 左邊區域 Ο 第二篩網部件 1午之翻起區域 Qmax 最大熱傳輪量 Ri 第-_網部件之右邊區域 r2 右邊區域 S 接合區域 U 摺疊區域 w 孰 Μ»、 W] 第一篩網部件之篩孔之尺 w2 第一篩網部件之篩孔之尺. Θ 角 API 液相工作流體之壓力損失 △ Pc 蒸氣麼力差/歸因於冷凝之 △ Pcap 毛細管力 APe 蒸氣壓力差/歸因於蒸發之 APh 歸因於體積力之壓力差 ΔΡν 氣相工作流體之壓力損失 一尺寸) 二尺寸) 差 I49451.doc -53-It is roughly equal to the internal space of H901. The shape of the left area L2 is the shape of the letter L. The shape of the left area L2 and the right area R2 has left-right symmetry in Fig. 26A. 149451.doc 201116795 As shown in FIG. 26B, a first screen member 9〇7 having the shape of the letter L having a shape substantially equal to the inner space of the container 910 is placed on the right side of the second screen member 908. On R2. The first screen member 9A is superimposed on the right side & of the second screen member 908. Further, the end portion 91 7a of the first screen member 9〇7 is disposed substantially at the center of the second screen member 9〇8. As shown in Fig. 26C, the second screen member 9A is folded so as to cover the end portion 917a of the first screen member 907. Therefore, the first screen member 9A is sandwiched between the right region & and the left region ^ of the second screen member 908, thereby forming the capillary member 905 having the shape of the letter according to this embodiment. Here, another example of the capillary member 9〇5 according to this embodiment will be described. 27A and 27B are diagrams for explaining a method of forming the capillary member 955 of another example. As shown in Fig. 27A, the i-th mesh member 957 having the shape of the letter L having a shape substantially equal to the inner space of the container 910 is placed on the second mesh member 958 in which a plurality of turned-up regions 形成 are formed. on. The plurality of raised regions 〇' of the second screen member 958 are disposed so as to correspond to the respective end portions 917 of the first screen member 957. Between the turned-up regions 截, a cut-away portion 924 or slit 925 is formed. As shown in Fig. 27B, the second screen member state is overlaid such that the four (four) domains of the second screen member state overlap with the first screen material 957. Therefore, the first screen member 957 is lost between the second screen members, and the end portion 917 of the second screen member 957 is covered by the turned-up region 第二 of the second screen member 958. 14945 丨.doc -41 · 201116795 For example, as described above, in this embodiment, the shape of the folded second screen member 908 (958) is appropriately set according to the shape of the container 901 of the heat transfer wheel device 900, As a result of the formation of the raised areas, the capillary member 905 (955) having the desired shape can be formed. <Tenth Embodiment> Fig. 28 is a perspective view showing a fish according to a tenth embodiment of the present invention. The electronic device 15 of this embodiment includes the heat transfer device according to the above embodiment. In this embodiment, a laptop personal computer (PC) is given as an example of an electronic device 150. The electronic device 150 includes a main body 151 and a display unit I52 connected to the main body 151. The main body 151 and the display unit 152 are connected via a hinge 153, and the display unit 70 152 can be opened and closed (folded) with respect to the main body 151. The keyboard 154 and the touchpad 155 are disposed on the main body 151. A control circuit board (not shown) on which a circuit component 156 such as a cPU is mounted is disposed in the main body 151. The side, '彖 light-emitting backlight 1 58 is provided in the display unit 丨52. The backlight 丨 58 ... emits a screen 157 of the unit 152. As shown in Fig. 28, the backlight 158 is disposed in the upper portion and the lower portion of the display unit 152. For example, the moonlight 15 8 is formed by placing a plurality of white light emitting diodes (LEDs) on a copper plate. In this embodiment, the heat transfer device 1000 is disposed in the body 151 and is in contact with the circuit assembly 156. Alternatively, in the display unit 152, the 'heat transfer device 1' may be in contact with the copper plate forming the backlight 158. In this case, as indicated by the broken line in Fig. 28, a plurality of heat transfer devices 1000 are disposed in the display unit 149451.doc • 42· 201116795 152. The plurality of heat transfer devices 1 are mounted in a vertical position along the vertical direction of the display unit i52. As described in the above embodiments, since the heat transfer device 1 has high heat transfer efficiency, heat generated in the circuit component 156, the backlight 158, or the like can be quickly released to the outside of the electronic device 15 . Therefore, it is possible to prevent the electronic device 150 from being destroyed due to heat generated in the circuit component 156, the backlight, or the like. Further, the heat transfer device (10) can make the internal temperature of the main body 151 or the display unit 152 uniform, which can prevent low temperature combustion. In this embodiment, a laptop PC is used as an example of the electronic device 15A. However, the electronic device 1 50 Rp - tK lL is not limited to this. Examples of electronic devices 15 include audiovisual equipment, display devices, projectors, gaming machines, car navigation systems, robotic devices, personal digital assistants (PDAs), electronic dictionaries, cameras, cellular phones, and other electronic devices. <Modified Example> The present invention is not limited to the above, and various modifications are made without departing from the gist of the present invention. For example, 5' may be used in the above embodiment other than the third embodiment described in the description of FIG. 13 and the third embodiment described above, and may use a first screen member having a light negative and a large pupil. And there are smaller mesh holes: the second screen component. In other words, a first mesh member having a smaller mesh number and a second mesh member having a larger mesh number can be used. Even when using this first screen part! In the case of 黛_* 仵 and the first division network component, the same as the above embodiment can also be obtained. For example, in the sixth embodiment according to the description of FIG. 20, the s In the middle, the first screen member having the larger division hole can be turned into a gas phase flow passage, and the second screen member (10) having the smaller division hole of 149451.doc -43-201116795 can be set as Liquid phase flow path. In the figure, the display unit 152 in the electronic device 150 is turned on to provide the backlights of the backlights on the lower side of the substrate 5 to the heat transfer devices. Backlight "8 contact on the end section. In this manner, the heat transfer devices are in a bottom-heat mode in the case where the heat source is in contact with the lower end portions of the heat transfer devices of the vertical ampoule. Bianque, jin π Ding In this case, the movement of the liquid phase working fluid is driven by gravity. On the other hand, in the case where the heat source is in contact with the upper end portion of the heat transfer devices mounted vertically, the heat transfer devices are in the top heat (10) heat mode. In this case, the liquid phase working fluid moves against gravity' so a high capillary force must be applied to the liquid phase working fluid. As noted above, the desired characteristics of the heat transfer device vary depending on the orientation of the heat transfer device being mounted, the location of contact with the heat source, or the like. Considering, for example, whether to increase the capillary force applied to the liquid phase working fluid or to increase the size of the gas (4) channel of the gas phase, it is only necessary to appropriately select the first screen member according to the desired characteristics of the heat transfer device and The number of meshes of the second screen component. Fig. 29A, Fig. 29A, Fig. 30A and Fig. 30A are diagrams showing a modified example of the heat transport device 1A according to the first embodiment. In the heat transport device ι, the capillary member 105 is formed by folding a screen member 1〇7. As shown in Figs. 29 and 30, the manner of folding the screen member ι 7 can be appropriately set. By folding the screen member 1〇7 as described above, the capillary portion 149451.doc - 44 - 201116795 is allowed to occupy a larger portion of the internal space 2 of the volume m. Due to this structure, heat transfer efficiency can be improved. Further, the positioning operation when laminating a plurality of screen members is not necessary, thereby improving the manufacturing time of the heat transfer device 1 = workability. Further, it is possible to prevent the wire of the screen member from entering the joint region s of the container 1, and as a result, heat transfer with high heat transfer performance can be manufactured with good workability in a short time. The present application contains the subject matter related to the contents disclosed in Japanese Priority Patent Application No. JP2_Gam 54 filed by the Japanese Patent Office on the 1st of the 1st, the entire contents of which are hereby incorporated by reference. In. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view showing the first embodiment of the present invention. The heat transfer device of one embodiment is shown in the short-side direction of the two screen members. FIG. 2 is the heat transfer device of FIG. Cross-sectional view, taken along line AA; Figure 3 is the _ λ* core music network component and the first plan shown in Figure 2; Figure 4 is shown as a comparative real surface; The schematic cross section of the transmission device is a cooling model diagram of a conventional heat transfer wheel device. Fig. 6 is a diagram for explaining the operation according to the first schematic cross-sectional view of Fig. 7, which is shown in Fig. 4. The first embodiment of the first embodiment; 149451.doc '45· 201116795 FIG. 8 is a diagram showing the heat transfer performance of the heat transfer device according to the first embodiment and the heat transfer performance of the heat transfer device shown in FIG. Figure 9 is a diagram for explaining a method of forming a capillary member provided to a member according to the first embodiment; "Transmission Figure 10 is a method for explaining the method of manufacturing the heat-transporting device according to the first embodiment. Figure 11 is a diagram showing a second embodiment FIG. 12 is a view for explaining the formation of a capillary member according to the second embodiment; FIG. 13 is a schematic cross-sectional view of the heat transfer device according to the third embodiment; To show a plan view of the first screen member and the first member according to the third embodiment; the first screen member and the second screen member are shown in Fig. 15 as an enlarged plan view showing the same as shown in Fig. 14; The schematic cross section of the heat transfer device of the fourth embodiment is for explaining the method of forming the capillary member according to the fourth embodiment. FIG. 5 is a schematic cross section showing the heat transfer device according to the fifth embodiment. FIG. 5 is a schematic cross-sectional view of a wheel device. Figure 2 is a schematic cross-sectional view of a heat transfer device according to a sixth embodiment. A heat transfer diagram according to a seventh embodiment is shown; Fig. 22 is a diagram for explaining a seventh embodiment; a method of forming a capillary member; and Fig. 23 is a view showing heat transfer according to the eighth embodiment FIG. 25 is a view for explaining a schematic perspective view of a method of manufacturing a heat transport device according to an eighth embodiment; FIG. 25 is a view showing a heat transfer wheel according to a ninth embodiment; FIG. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 27 is a view for explaining a method of a thin tube member as another one of the ninth embodiment; FIG. 28 is a view showing a tenth embodiment according to the tenth embodiment. FIG. 29 is a view showing an example of the heat transfer wheel of FIG. 2 according to the first embodiment; and FIG. 30 is a view showing the heat of FIG. 2 according to the first embodiment. The pattern of the transfer wheel example. 'Month' J [Description of main component symbols] 1 Modification of the device for forming the hair of the container] 49451.doc -47· 201116795 2 Recessed part 2' Interior space of the container / Internal area 3 Lower plate Component 4 Upper plate member 5 Capillary member 5' Liquid phase flow path 6 Hollow body 6, gas phase flow path 7 First screen member 8 Second screen member 9 Here the portion of the second screen member is folded 10 First Wire 11 second wire 12 Screen of the first screen member 13 First wire 14 Second wire 15 Screen hole 15 of the second screen member End portion 15b of the heat transfer device End portion 16a of the heat transfer device End portion 16b End portion 17a End portion 17b End portion 18 side wall 149451.doc -48- 201116795 100 heat transfer device 150 electronic device 151 body 152 display unit 153 hinge 154 keyboard 155 touch pad 156 circuit component 157 screen 158 edge light type backlight 200 heat transfer device 205 capillary member 207 A screen member 208, a second screen member 209a, a folded portion 209b of the second screen member, a folded portion 216a of the second screen member, an end portion 216b of the second screen member, an end portion 217a of the second screen member, a first screen End portion 217b of the mesh member End portion 300 of the first screen member Heat transfer device 305 Capillary member 307 First screen member 308 Second screen member 149451.doc • 49- 201116795 312 Screen of the first screen member 313 First wire 314 second wire 315 second mesh member screen hole 317a End portion 317b of the first 1 mesh member End portion 400 of the first Xuewang member Heat transfer device 405 Capillary member 407 First screen member 408 Second screen member 409a Folded portion 409b of the first screen member Second screen Folding portion 416a of mesh member End portion 416b of second screen member End portion 417a of second screen member End portion 417b of first screen member End portion of first screen member 500 Heat transfer device 501 Container 502 recessed portion 502, inner space of the container 503 lower plate member 504 upper plate member 505 capillary member 506' gas phase flow passage 149451.doc -50- 201116795 519 reinforcing member 520 reinforcing portion 521 through hole 600 heat transfer device 605 capillary member 607 first screen Net member 607' liquid phase flow path 608 second screen member 608' gas phase flow channel 700 heat transfer device 705 capillary member 707 first screen member 708 second screen member 708' gas phase flow path 709a second screen Folded portion 709b of the second screen member folded portion 717a end of the first screen member Sub-section 717b End portion of the first screen member 722 Through-hole 800 Heat transfer device 801 Container 823 Single plate member 900 Heat transfer device 901 Container I49451.doc -51 - 201116795 905 Capillary member 907 First screen member 908 Second screen Component 917 End portion of the first Korean mesh member 917a End portion of the first screen member 924 Truncated portion 925 Slot 955 Capillary member 957 First screen member 958 Second screen member 980 Heat transfer device 981 Container 982 ' Interior of the container Space 983 Lower plate member 984 Upper plate member 985 Capillary member 985' Liquid phase flow path 986 Hollow body 986' Gas phase flow path 987 Screen member 995a End portion of heat transfer device 995b End portion of heat transfer device 998 Side wall 999 Heat source 149451 .doc -52- 201116795 1000 Heat transfer device AA line BB line C Condensation area c2 Central area E Evaporation area Li Left area l2 Left area Ο Second screen part 1 Midday up area Qmax Maximum heat transfer quantity Ri - _ mesh part right area r2 right area S joint area U Folding area w 孰Μ», W] The size of the mesh of the first screen part w2 The size of the screen of the first screen part. Θ Angle API Pressure loss of the liquid working fluid △ Pc Vapor force difference / return Δ Pcap due to condensation Capillary force APe Vapor pressure difference / APh attributed to evaporation Pressure difference due to volume force ΔΡν Pressure loss of gas phase working fluid one size) Two dimensions) Difference I49451.doc -53-