五、新型說明: 【新型所屬之技術領域】 本創作係㈣i缺換設備,尤指—種兼具有提升 熱交換效率’進祕梭_防止異物侵人的效果之執交 換設備。 π 【先前技術】 一熱的傳導主要具有三種方式,即為傳導、對流、及輕 射了種#中傳導疋熱藉由介質由高溫處傳向低溫處的方 式,對流d氣或水等麵受熱碰纽變,造成循環流 動;不靠任何介質的直接傳遞則為輕射。 然’對流體來說最主要且有效的傳熱方式係為對流; 如參閱第8騎習知熱交換機6具有複數導流口、一第一 空⑽及-第二空間63,其中該第一、二導流口 6n、6i2 及^三、四導流口 613、614係分別開設在相鄰熱交換機6 端及其另-端’並該第—導流口 611係相對該第二導流 二612 ’且連通該第—空間62,該第三導流口⑽係相對 第四導流π 614,錢通該第二空間⑽。 另者則述第二導流口 612及第三導流口 613係分別對 接一風扇7 ’所以當習知熱交換機6裝設在-通訊機箱8 或機櫃進行熱交換時,透過於第三導流口 613的風扇?強 希w導n入第二空間63内’並再由該第四導流口 614 將氣抓引導入該通訊設傷8内,同時該第二導流口 612的 風扇7亦會_將通訊機箱8内電子元件所散發的熱量排 出到第一空間62内,然後再經該第一導流口 611排出外 面,以達到熱交換之效果。 惟’習知熱交換機6雖可達到熱交換之目的,但其命 無法防止異物由外界進入通訊機箱8,詳細說明如后:即 該第三、四導流口 613、614與第二空間63及通訊機箱8 内的容置空間81係相互連通,故使得異物(如灰塵、水氣) 容易隨著風扇7強制引導的氣流帶入該通訊機箱8内,以 導致通訊機箱内的電子元件受潮損壞,或是灰塵附著在電 子元件上而損壞。 以上所述’習知具有下列缺點: L無法防止異物侵入通訊機箱内之效果; 2.熱交換效率不佳; 3·散熱效果不佳。 是以,要如何解決上述習用之問題與缺失,即為本案 之創作人與從事此行業之相關廠商所亟欲研究改善之方向 斤在者。 【新型内容】 菱此為有效解决上述之問題,本創作之主要目的在 提供一種於—殼體内設置—熱交換器,並齡該熱交換琴 内各自獨立狀的第―、二空間内進行熱交換散 ’、、、’藉以有效提升熱交換效率及防止異物侵人之熱交換設 備。 ' 〇 熟交次要目的,係提供—種具有絕佳散熱效果之 Μ4Ό8233 為達上述目的,本創作係提供—種熱交換設備,係包 括:-殼體係具有至少一第一空間及至少一與相對該第一 空間相隔離之第二空間,一第一導流口及一第二導流口係 分別開設於該殼體上,且其分別對應連通前述第一、二空 間:及-熱交換器係設於該殼體内,且其位於該第一空間 與第-工間之間,所以透過本創作此結構的設計,得可有 效大t田提升熱交換效率,藉以達到絕佳散熱及防止異物侵 入之效果者。 【實施方式】 本創作之上述目的及其結構與功能上的特性,將依據 所附圖式之較佳實施例予以說明。 _本創作係一種熱交換設備,請參閱帛卜2、3圖係顯 不本創作之第—較佳實施例之示意圖,該熱交換設備1係 包括-喊體1〇及—熱交換II 2Q,前述殼體1()係具有一第 -導流口 104、-第二導流π 1G5、至少—第—空間13及 一至少第二空間14,其中該殼體10係由一第一殼體101 及第一喊體102對接構成,並共同界定前述第一空間13 及第二空間14。 刖述第一導流口 104及第二導流口 105係分別開設在 該殼體10 ±,且其分別與對應的第一空間13及第二空間 14相連通’而該第一空間13與相對第二空間14係相隔離, 亦即如參閱第1圖示,圖中前述第一空間13係不連通該第 一空間14 〇 瑜述熱交換器20係設於該殼體10内,且位於該第一 5 M408233 :間13'第—空間14之間,且其内更填充有一工作流體, 刖“體於該難實施細冷媒做說明表示,但並不 偈限於此’惟賤實鱗,凡'村浙絲健之流體為 如純水、無機化合物、醇類、_、液態金屬、有機化合 物或其混合^為所敘述的卫作流體,合先陳明。 另者月’J述熱父換器20係包含一冷凝部21、一蒸發 部22及-連接部23,該冷凝部21及蒸發部22係分另懷 置於該第一、二空間13、14内,該連接部23則設於該第 一二間13 14之間,且其兩端分別連接該冷凝部 及热發部22 ’於雜佳實施麵冷凝部21與蒸發部&及 連接部23絲示為管體做·,但並不限於此。於具體實 施時’使膽可以事先健、殼體1() _空間及散熱效果的 需求,設計前述冷凝部21、蒸發部22及連接部23選擇為 一具有腔室之板體,或其他具有腔室之形體,合先陳明。 、’只參閱第3圖示,輔以參閱第1圖示,前述冷凝部a 及蒸發部22内係分別界定有一第一腔室211及一第二腔室 221,並該連接部23係由複數管體所構成,且該等管體係 呈等距間格排列設置或呈非等距間格排列設置;並該等管 體内界定有一通道231,該通道231係分別連通該第一、 一腔室211、221 ’其用以分別供汽態之工作流體及液態之 工作流體流動。 另外前述每一管體彼此相鄰間設有複數散熱鳍片25, 該等散熱鳍片25係用以輔助加速散熱。而前述殼體1〇更 設有至少一隔板15,該隔板15係設於該蒸發部22與冷凝 6 部21之間’亦即如參閱第1圖示前述隔板15係形成在連 接部23之兩端間位置,以與該連接部23形成為一體,且 /、外周側緊岔貼靠在相對該殼體之内側,用以區隔該第 一空間13及第二空間14,令第一空間13與第二空間14 形成為各自獨立之空間。 所以當一氣流引導入該第二空間14内時,令於該第二 空間14内之蒸發部22會立即吸附前述氣流之熱量,並透 過5亥第二腔室221内的液態之工作流體吸收熱量後而產生 瘵發,以轉換為汽態之工作流體,又因該第一空間13内的 冷凝部21溫度較低故使汽態之工作流體會沿對應前述通 道231朝第一腔室211方向流動,直到該汽態之工作流體 流動至該冷凝部21冷卻後’迅速轉換為液態之卫作流體產 生回〃H·,S亥液怨之工作流體係藉由重力沿該通道23丨回流 至洛發部22而輯汽賴環,以有效大幅提升熱交換效 率,進而達到絕佳散熱及防止異物侵入的效果。 請參閱第4圖係表示前述熱交換設備之另一實施示意 圖,别述喊體10更包含複數第一通風孔161及複數第二通 風孔162,該等第-通風孔161係貫通形成在該隔板15盥 第一導流口 104之間_體10上,且連通該第一空間⑴ 該等第二通風孔162係貫通軸在該隔板15觸二導流口 105之間的殼體1〇上,且連通該第二空間14。 另者前述第-、二導流口遍、滿係分別對接一第一 強制對流件40及-第二強制對流件41,所述第一強制對 流件40係設於前述該第一空間13内,且其具有一第—入 M408233 :二―::出風側術,該第-入風側401係與第 氣流。 接,該第一強制對流件40係用以強制導引 其且=二強制對流件41係設於該第二空間U内,且 其,、有第一入風側411及一第二 風侧411與第二導流口 。亥第一入 淑⑯心 對接並該第二強制對流件41 對流件4G相同都是用以強购氣流;另 雜$—、二關對流件4G、41係表示為V. New description: [New technology field] This creation department (4) i lacks replacement equipment, especially the kind of equipment that has the effect of improving heat exchange efficiency, and the effect of preventing foreign objects from invading. π [Prior Art] There are three main ways of conducting heat, namely, conduction, convection, and light-emitting. The conduction heat in the medium is transmitted from the high temperature to the low temperature by the medium, and the convection d or the water is equal. It is caused by heat and collision, causing circular flow; direct transmission without any medium is light. However, the most important and effective heat transfer mode for fluids is convection; as described in Chapter 8, the heat exchanger 6 has a plurality of air outlets, a first air (10) and a second space 63, wherein the first The two air guiding ports 6n, 6i2 and ^3, and the four air guiding ports 613 and 614 are respectively opened at the end of the adjacent heat exchanger 6 and the other end thereof, and the first air guiding port 611 is opposite to the second guiding flow. Two 612' and connected to the first space 62, the third air guiding port (10) is opposite to the fourth guiding flow π 614, and the money passes through the second space (10). In addition, the second air guiding port 612 and the third air guiding port 613 are respectively connected to a fan 7'. Therefore, when the conventional heat exchanger 6 is installed in the communication chassis 8 or the cabinet for heat exchange, the third guide is transmitted through the third guide. Fan of the flow port 613? The strong guide w introduces n into the second space 63 and then guides the air catch into the communication set 8 by the fourth air guiding port 614, and the fan 7 of the second air guiding port 612 also communicates The heat dissipated by the electronic components in the chassis 8 is discharged into the first space 62, and then discharged to the outside through the first air guiding port 611 to achieve the effect of heat exchange. However, although the conventional heat exchanger 6 can achieve the purpose of heat exchange, its life cannot prevent foreign matter from entering the communication chassis 8 from the outside, as described in detail later: the third and fourth air guiding ports 613, 614 and the second space 63. And the accommodating space 81 in the communication chassis 8 are connected to each other, so that foreign matter (such as dust and moisture) is easily brought into the communication chassis 8 with the airflow forcedly guided by the fan 7, so that the electronic components in the communication chassis are damp. Damage, or dust attached to the electronic components and damaged. The above description has the following disadvantages: L can not prevent the intrusion of foreign matter into the communication chassis; 2. The heat exchange efficiency is not good; 3. The heat dissipation effect is not good. Therefore, how to solve the above problems and problems in the past, that is, the creators of this case and the relevant manufacturers engaged in this industry are eager to study the direction of improvement. [New content] In order to effectively solve the above problems, the main purpose of the present invention is to provide a heat exchanger disposed in the casing, and to carry out the space in the first and second spaces of the heat exchange piano. The heat exchange device ',, ' is used to effectively improve the heat exchange efficiency and prevent foreign matter from invading the heat exchange equipment. ' 〇 交 交 , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , a first air guiding port and a second air guiding port are respectively disposed on the housing, and respectively corresponding to the first and second spaces: and - heat exchange The device is disposed in the casing and is located between the first space and the first space. Therefore, through the design of the structure, the heat exchange efficiency can be effectively improved, thereby achieving excellent heat dissipation and The effect of preventing foreign matter from entering. [Embodiment] The above object of the present invention, as well as its structural and functional features, will be described in accordance with the preferred embodiments of the drawings. _ This creation is a heat exchange device, please refer to the schematic diagram of the preferred embodiment of the present invention. The heat exchange device 1 includes a body 1 and a heat exchange II 2Q. The housing 1() has a first air guiding port 104, a second guiding flow π 1G5, at least a first space 13 and an at least a second space 14, wherein the housing 10 is composed of a first shell The body 101 and the first shouting body 102 are butted together and define the first space 13 and the second space 14 in common. The first air inlet 104 and the second air outlet 105 are respectively disposed in the housing 10±, and are respectively connected to the corresponding first space 13 and the second space 14 and the first space 13 is The second space 14 is isolated from the second space 14 , that is, as shown in FIG. 1 , the first space 13 is not connected to the first space 14 , and the whirl heat exchanger 20 is disposed in the casing 10 , and Located between the first 5 M408233: between the 13' first spaces 14 and filled with a working fluid, the body is said to be difficult to implement the fine refrigerant, but is not limited to this. The fluids of 'Zhejiang Silk Health' are such as pure water, inorganic compounds, alcohols, _, liquid metals, organic compounds or mixtures thereof, which are described by Wei Ming. The hot parent converter 20 includes a condensation portion 21, an evaporation portion 22, and a connection portion 23, and the condensation portion 21 and the evaporation portion 22 are disposed in the first and second spaces 13, 14 respectively. 23 is disposed between the first two rooms 13 14 , and the two ends of the two are respectively connected to the condensation portion and the heat generating portion 22 ′ 21 and the evaporating portion & and the connecting portion 23 are shown as a tube body, but the present invention is not limited thereto. In the specific implementation, the design of the gallbladder can be used in advance, the housing 1 () space and heat dissipation effect are designed. The condensing portion 21, the evaporating portion 22, and the connecting portion 23 are selected as a plate body having a chamber, or another body having a chamber, which is first and foremost. "See only the third figure, supplemented by the first drawing. The condensation chamber a and the evaporation portion 22 respectively define a first chamber 211 and a second chamber 221, and the connection portion 23 is composed of a plurality of tubes, and the tube systems are equidistantly spaced. Arranging or arranging in a non-equal space; and defining a channel 231 in the tube, the channel 231 is respectively connected to the first and a chambers 211, 221' for respectively supplying a working fluid in a vapor state And the liquid working fluid flows. Further, each of the tubes is disposed adjacent to each other with a plurality of heat dissipating fins 25 for assisting in accelerating heat dissipation, and the housing 1 is further provided with at least one partition. a plate 15, the partition 15 is disposed between the evaporation portion 22 and the condensation portion 21' Referring to FIG. 1 , the partition plate 15 is formed at a position between both ends of the connecting portion 23 so as to be integrally formed with the connecting portion 23 , and/or the outer peripheral side abuts against the inner side of the housing for Separating the first space 13 and the second space 14 to form the first space 13 and the second space 14 into separate spaces. Therefore, when an air flow is guided into the second space 14, the second space is The evaporation portion 22 in the 14 immediately adsorbs the heat of the airflow, and absorbs the heat through the liquid working fluid in the second chamber 221, and then generates a burst to convert into a working fluid of the vapor state. The temperature of the condensing portion 21 in a space 13 is low, so that the working fluid in the vapor state flows in the direction corresponding to the aforementioned passage 231 toward the first chamber 211 until the working fluid of the vapor state flows to the condensing portion 21 after cooling. The conversion of the liquid to the liquid is generated by the H., and the workflow system of the SH liquid is reflowed to the Luofa part 22 by gravity along the channel 23 to effectively increase the heat exchange efficiency. Achieve excellent heat dissipation and prevent foreign matter from invading fruit. FIG. 4 is a schematic view showing another embodiment of the heat exchange device. The shunt body 10 further includes a plurality of first vent holes 161 and a plurality of second vent holes 162. The first vent holes 161 are formed therethrough. The partition 15 is disposed between the first flow guiding port 104 and the body 10, and communicates with the first space (1). The second ventilation holes 162 are through the casing of the shaft between the two guiding ports 105 of the partition 15. 1〇, and connected to the second space 14. In addition, the first and second air guiding ports are respectively connected to the first forced convection member 40 and the second forced convection member 41, and the first forced convection member 40 is disposed in the first space 13 And it has a first-into M408233: two::: wind side, the first-intake side 401 is the first airflow. The first forced convection member 40 is configured to be forcibly guided and the second forced convection member 41 is disposed in the second space U, and has a first air inlet side 411 and a second wind side. 411 and the second air inlet. The first convection member 41G is the same as the second convection member 41, and the convection member 4G is used to forcibly purchase the airflow; the other $ convection members 4G and 41 are expressed as
離〜式風扇做說明,作不供PP认L ^ 騎縣_散熱之 風扇p為刖述第-、二強制對流件4〇、41,合先述明。 所以當第-強制對流件4G由第—人風側強制引進 氣^並經其增壓後則由該第一出風側402排出’並進入 該第工間13内’其魏m經該冷凝部21以加速對 其内未冷卻之汽態的工作趙冷卻,紐再由該等第一通 風孔161排出該第一空間丨3。 而前述第二強制對流件41由該第二入風側4ιι強制引 進氣流,並經其增壓後從該第二出風側412排出而進入該 第二空間14内,其後該氣流流經該蒸發部22後,有助於 加快蒸發部22吸附氣流之熱量,然後再由該等第二通風孔 收排出該第二空間14 ’故藉由前述第―、二強制對流件 4〇、有效增進所述第-、二空間13、u内的氣流循環 速度。 請參閱第5圖係顯示本創作之第二較佳實施例示咅 圖;該較佳實施例大致與前述第-較佳實施例的結構及連 8 結關係及其功效綱,故在此不重㈣述,其兩者不同處 在於:前述前述第一腔室211及第二腔室221内係分別設 有一毛細結構5〇 ,該毛細結構50係分別形成在該第一、 二腔室21卜221内之相對内壁上,該通道231内設有另一 毛細結構50 ’該另-毛細結構5〇係形成在該通道231之 相對内壁上,·並所述第―、二腔室21卜221及通道231内 壁上的毛細結構5〇係用以辅助液態之工作流體加速回流 至蒸發部22之第二腔室221内’以有效更進一步促進汽液 循環之效率。 另者前述毛細結構50係選擇為網目(mesh)、纖維 (f iber)、燒結粉末(sintered p〇wder)、網目及燒結粉末 組合及微溝槽(groove)其中任一。 明參閱第6A、6B圖係顯示本創作之第三較佳實施例示 意圖;該較佳實施例大致與前述第—較錄心以忠及 連結關係及其功效相同’故在此不麵資述,其兩者不同 處在於.前述熱交換器2〇係包含複數熱管26,該等熱管 26係依序穿套設有複數呈間格排歹,】設置之散熱縛片扔,並 5亥等熱官26具有-冷凝端26卜-蒸發端262及-腔室 264 ’其中該腔室264内設有-毛細結構5Q,該毛細結構 50係形成在該腔室264之相_壁上;並複數冷凝端261 及複數蒸發端262係分別共同界定出—冷凝部21及一蒸發 部22’該冷凝部21及蒸發部22係分別設於該第一空間13 及第二空間14内。 5月參閱第7圖係表示前述熱交換設備之另一實施示意 M408233 圖;前賴體10更包含複數第—通觀161及複數第二通 風孔162,該等第-通風孔161係貫通形成在該隔板Η與 第-導流口 104之間的殼體1〇上,且連通該第一空間13, 該等第二通風孔162係貫通形成在該 啲之間的刚上,且連通該第二空間14:第-導-口 另者前述第-、二導流口 1〇4、1〇5係分別對接一第一 強制對流件40及-第二強制對流件41,該第―、二強制 對流件4G、41的結構及其功效與_第—較佳實施例相 同,故不再重新贅述。 因此’藉由上述本創作之熱交換設備j的設計,應用 裳叹於-通訊機箱(或f子設備或其他綠熱設備)上時, 可有效提供紐的熱交換效率,且又有效能夠達到防止異 物侵入通訊機箱内之效果。 以上所述’本創作相較於f知具打列優點: 1. 具有防止(或隔絕)異物侵入之效果; 2. 熱交換效率佳; 3. 散熱效果佳。 惟以上所述者’僅係本創作之較佳可行之實施例而 已’舉凡利用本創作上述之方法、形狀、構造、裝置所為 之變化’皆應包含於本案之權利範圍内。 【圖式簡單說明】 $ 1 作之第—健實關之分解立體示意圖; $ 2 ®#'Hj作之第—較佳實施例之組合立體示意圖; 第3圖係本創作 圖; 弟一較佳實施例之熱交換器剖面示意 第4 固 ♦ 圖, 圖係本創作之 第一較佳實施例之另一分解立體示意 岡5圖縣創作之第二較佳實關之熱交㈣剖面示竟 圚, ^ ,6A圖縣創作之第三健實關之分解立體示意圖; 第6B ®係本創作之第三較佳實施例之熱交換 剖面示意 第7圖係本創作之第三較佳實施例之另一分解立體示意 圖; " 第8圖係習知之實施態樣剖面示意圖。 【主要元件符號說明】 熱交換設備… 1 第二腔室 … 221 殼體 … 10 連接部 *·· 23 第一殼體 … 101 通道 … 231 第二殼體 … 102 散熱鳍片 … 25 第一導流口 … 104 熱管 … 26 第二導流口… 105 冷凝端 … 261 第一空間 … 13 蒸發端 … 262 第二空間 … 14 腔室 … 264 隔板 … 15 第一強制對流件… 40 第一通風孔… 161 第一入風側 ... 401 M408233 第二通風孔… 熱交換器 … 冷凝部 … 第一腔室 … 蒸發部 … 162 第一出風側 … 402 20 第二強制對流件… 41 21 第二入風側 … 411 211 第二出風側 … 412 22 毛細結構 … 50 12From the fan of the ~ type, do not provide PP recognition L ^ riding county _ heat dissipation fan p for the description of the first - and second forced convection parts 4 〇, 41, first stated. Therefore, when the first-forced convection member 4G is forced to introduce the gas from the first-side wind side and is pressurized by the first convection member 4G, it is discharged from the first air outlet side 402 and enters the first working chamber 13 The portion 21 is cooled by accelerating the operation of the uncooled vapor state therein, and the first venting holes 161 are discharged from the first space 丨3. The second forced convection member 41 is forcibly introduced into the airflow by the second air inlet side 4, and is discharged from the second air outlet side 412 into the second space 14 after being pressurized, and then the airflow flows through After the evaporating portion 22, the heat of the evaporating portion 22 is accelerated, and then the second venting hole is discharged from the second space 14'. Therefore, the first and second forced convection members are effective. The air circulation speed in the first and second spaces 13, u is increased. Please refer to FIG. 5 for a second preferred embodiment of the present invention. The preferred embodiment is substantially similar to the structure and the connection between the foregoing and the preferred embodiment. (4) The difference between the two is that the first chamber 211 and the second chamber 221 are respectively provided with a capillary structure 5, and the capillary structure 50 is formed in the first and second chambers 21, respectively. On the opposite inner wall of the inner wall 221, another wick structure 50' is disposed in the channel 231. The other-capillary structure 5 is formed on the opposite inner wall of the channel 231, and the first and second chambers 21 221 And the capillary structure 5 on the inner wall of the passage 231 is used to assist the liquid working fluid to accelerate back into the second chamber 221 of the evaporation portion 22 to effectively further promote the efficiency of the vapor-liquid circulation. Alternatively, the capillary structure 50 is selected from the group consisting of a mesh, a fiber, a sintered powder, a mesh and a sintered powder combination, and a microgroove. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 6A and FIG. 6B are views showing a third preferred embodiment of the present invention; the preferred embodiment is substantially the same as the above-mentioned first-common recording with the loyalty and the connection relationship and its efficacy. The difference between the two is that the heat exchanger 2 includes a plurality of heat pipes 26, and the heat pipes 26 are sequentially provided with a plurality of spaces, and the heat-dissipating pieces are disposed, and 5 Hai, etc. The heat officer 26 has a condensation end 26 - an evaporation end 262 and a chamber 264 ' wherein the chamber 264 is provided with a capillary structure 5Q formed on the phase wall of the chamber 264; The plurality of condensation ends 261 and the plurality of evaporation ends 262 respectively define a condensation portion 21 and an evaporation portion 22'. The condensation portion 21 and the evaporation portion 22 are respectively disposed in the first space 13 and the second space 14. Referring to FIG. 7 in May, another embodiment of the heat exchange apparatus is shown in the figure of M408233. The front body 10 further includes a plurality of first-view 161 and a plurality of second vent holes 162, and the first-ventilating holes 161 are formed through The partition Η and the first guide port 104 are connected to the first space 13 and communicate with the first space 13 . The second vent holes 162 are formed through the gap between the rafts and communicate with the The second space 14: the first guide port and the other first and second air guide ports 1〇4 and 1〇5 are respectively connected to a first forced convection member 40 and a second forced convection member 41, respectively. The structure of the forced convection members 4G, 41 and their functions are the same as those of the first preferred embodiment, and therefore will not be described again. Therefore, the design of the heat exchange device j of the above-mentioned creation can effectively provide the heat exchange efficiency of the New Zealand when it is applied to the communication chassis (or the f sub-device or other green heat device), and can effectively achieve Prevent foreign objects from entering the communication chassis. The above descriptions are compared with the advantages of f-knowledge: 1. It has the effect of preventing (or isolating) the intrusion of foreign matter; 2. The heat exchange efficiency is good; 3. The heat dissipation effect is good. However, the above-mentioned embodiments are merely preferred embodiments of the present invention, and variations of the methods, shapes, structures, and devices described above are intended to be included in the scope of the present invention. [Simple diagram of the diagram] $1 is the first--------------------------------------------------------------------------------------------------------------------------------------------------------------------------- The cross section of the heat exchanger of the preferred embodiment is shown in Fig. 4, which is another exploded perspective view of the first preferred embodiment of the present invention. Actually, ^, 6A Figure 3 is a three-dimensional schematic diagram of the third practical embodiment of the creation; the sixth preferred embodiment of the heat exchange profile of the third preferred embodiment of the present invention is the third preferred embodiment of the present invention. Another exploded perspective view of the example; " Fig. 8 is a schematic cross-sectional view of a conventional embodiment. [Explanation of main component symbols] Heat exchange equipment... 1 Second chamber... 221 Housing... 10 Connections*·· 23 First housing... 101 Channel... 231 Second housing... 102 Cooling fins... 25 First guide Flow port... 104 Heat pipe... 26 Second air inlet... 105 Condensing end... 261 First space... 13 Evaporation end... 262 Second space... 14 Chamber... 264 Partition... 15 First forced convection... 40 First ventilation Hole... 161 First air inlet side... 401 M408233 Second air vent... Heat exchanger... Condensing section... First chamber... Evaporation section... 162 First air outlet side... 402 20 Second forced convection section... 41 21 Second air inlet side... 411 211 Second air outlet side... 412 22 Capillary structure... 50 12