201144738 六、發明說明: 【發明所屬之技術領域】 本發明係關於一種可撓式散熱導管,特別關於一種利用在内 部設置至少-吸液導管,以毛細作用傳導至少一種流體熱介質 散熱與無方向限制循環之可撓式散熱導管。 … 【先前技術】 按,習知積體電路、功率電晶體、晶月組、發光二極體(led) 燈具…等等高熱能產生之電子㈣,在使用上需要细散献器或 散熱機構搭配,方能正常操作’習知電子負載採用被動式的散執 鰭片或散熱器之空氣冷卻方式已不敷制,除了散熱速度慢,執 源或熱點之降溫效率亦是很差,且電子負载與散熱器之接面上^ 各點散熱溫度不均勻,並不符合產業利用需求,而逐漸被淘汰。 ^有因此萌生改良者,以金屬管路配置並於㈣注入 ===並再連結散熱器方式提供上述電子負载散熱,但由於 動速率緩慢問題,如果單純靠熱對流推動冷卻 =或散ϋ本無法_迅紐熱之效果 載裝設方向’例如:發光二極體燈具裝設方向在散負 即投射燈光向上時’如單單靠熱職方 上推動冷赠錢驗鴨及快賴動,因此,通常 電純散熱液’但此種方式,勢必讓小型 =:=:力 外一個缺子負載,以提供散熱之機構’另 構設計,例如:配置於狹,n需配合電子負載之裝設場合或機 〜響其產業利用價值’並且,該金屬管路在彎折角度上: 201144738 上 ,會纽齡辭__肖度酿 f不同形狀及元件配置位置㈣子產品機射,諸如 =ί繞過或避t某些機構或電子元件,而必需作大幅度之“ 二知之金屬管路配置之散熱並無法被適用,因而 限制其應用之範疇。 口叨 在相關之先前專利技術文獻方面,如中華民國專利公報 =65772號「液冷系統」發明專利案,則揭示典型習知金屬管路配 之液冷系統,同樣地,會產生金屬管路散熱效 路配置彎折紋鶴雜、戦與電子元雜置⑽_之^ 與缺點。 μ 專利公報第5536G2號「散熱器改良 、’。」1L猶’職露則、躲浦配合可紐散熱管所組成 之散熱器,提供給電子貞载作為散熱之用,雖可改善上述金屬管 路彎折配置之_ ’但仍無祕齡躲絲驗_速率緩慢 問題’而必需依靠小贱浦加壓輸送H肖耗額外之電力及增 加設備成本,不具經濟效益。 s 【發明内容】 已知之電子負載之散熱裝置,藉由空氣冷卻方式之散熱速 度、效率不佳與接面散熱不均,如以前案中藉由金屬管路配置之 循環散熱’則該電子負载之設置位置受限,另外,如要加設小型 電動泵浦加齡動冷卻液循環散熱,職耗f額外電力、成本偏 高及佔用安裝空間。 因此,需要發展-種成本低、不需耗費額電力與設備,且不 論在液、氣或氣、液兩相變化之狀態下,均可快速提供至少一種 流體導熱介質自體循環散熱效果之可撓式散熱導管,並且,具有 可撓性,不受電子負載之設置位置、方向與機構、空間限制,可 201144738 乂應用在不_狀、機構郎大小 本發明之可赋散轉營,㈣裝與應用。 :部及至少-内管,其中,杆 合於該外_,該導熱件㈣5 別結 結於!齡内緣,該内管及吸液導管納 液導官χ崎之包覆,邮分職合於料件*散師,内^ 外管間之容室則被區隔形成至少一 ·,:;、件牛,内官與 後,^ # ’喊該貞祕源產生熱能由導熱件吸收 _毛/^.、、、件和触财_流料齡#,錢料熱介質 沿吸液導管傳導至散熱件散熱降溫,再由散熱件』 %官道循環回到導熱件端之均熱環。 爾 ^發明之可撓式散熱導管之功效,係在於藉由該吸液導管的 2作用使如冷魏之流體導齡論在於液、紐数或氣、 ^冷卻狀態,柯_作魏散触果,且外管 =不受限電子負載設置於上、下、左或右之方向、位置: 導ΐ可糟由該内管與外管之間所區隔形成之容室,使吸液 二/、谷至内之流體導熱介質具有溫差區隔,而形成具毛細作用 2的熱對流循環散熱效果’讓電子負載的熱源可以迅速被循環 溫’並且,透過均熱環的設置,使電子負載的接面上之各點散 度均勻,以達到不使用額外電力與設備,且具高效散熱的節 月匕%保自體無方向限制之循環散熱功效。 【實施方式】 =參閱第-圖、第二圖及第三圖所示,為本發明之可撓式散 ·、’、,& 100之第一實施例,其中’該可挽式散熱導管獅包括一 卜言10該外管10為一導熱體,且為一可撓性管,例如:軟質石夕 201144738 膠管,可作撓性f折,該外管1〇内 … 11上端内壁設有若干鎖合螺牙lu y 7 —谷室U,該容室 於外=====㈣或合金等金屬材料, 限,在本發明中係以-發電子負载200之型式不 緣形成-接合部21,該接、21二、為例’該導熱件20並於内 211對應螺鎖至外管心i η上::=11 咖上端 -散熱件30,為導熱材料構成,如銘 應===== 上述之導熱件2〇、散熱件3〇與外管1〇 以螺牙2U、鎖合螺牙⑴與螺牙祀鎖 等效鎖Ϊ式為限’舉凡是等效之組合結構,如黏合等 荨效結構’當不脫本發明之範禱。 。域。寺 材料至ί均^^4〇 ’為吸液材料構成,如不織布、海棉等吸液 孰環於導熱件2〇内緣之接合部21表面,該均 =〇中元成至少-穿孔41,該穿孔41吻對該導熱件2〇之插孔 材料5〇及至少一内管6〇,該吸液導管50為吸液 祖❹ &不織布、海料吸液材料,該崎6G為耐熱隔、、田姑 ’ ’如橡膠或塑膠,該内管60包覆於吸液導管5〇 ^外:, 201144738 1兩端局部露出’該吸液導管5G兩端分別對應插 句…衣40之穿孔41與導熱件20之插孔212、散熱件30之插孔 312 ’使該吸液導管50連結於均熱環4〇、導熱件20與散熱件30 間t容室U空間中,讓該内管6〇與外管1〇間被區隔形成至少一 ,環管道113,該猶環管道113内至少填充一種流體導熱介質 4 ’該流料齡f 114之型式不限,在本發明巾仙冷卻液為 二’其他如水或油等具散熱效果之流體介質,當不脫本發明之範 嘴0 上述之吸液導管50兩端與導熱件2〇、散熱件3〇間之連結結 構,並不以插接於插孔212及插孔312為限 : 構如黏合或嵌合,當不脫本發明之齡。 Μ之連― 一請再配合第四圖所示’為本發明之可撓式散熱導管動的第 一應用例,其中,顯示該發光二極體燈具型態之電子負載2〇〇產 ^熱源時,該辦原透過導熱件2〇吸收後,再加熱導熱件1〇和均 ‘:、裱40中間的流體導熱介質114,使流體導熱介質ιΐ4產生液、 ,兩相變化’再藉由毛細作用沿吸液導管5G向下傳導至散熱件% 散熱降溫冷卻,再由散齡3〇經讀道⑴循環回到導熱 之均熱環40(如第四圖中箭頭方向所示),最後,再由該触 二⑽吸收該流體導熱介質114,而重覆上述之循環散熱降溫動作, ,均熱環40並提供電子負載及其所連結之導熱件2〇表面上 母一點之均勻散熱功能。 藉由上述之散熱循環路徑,可迅速讓電子負載之執源或 ^之高溫可迅速經由吸液導管50毛細作用而帶往散熱件%端 =降>皿,並且,不論該流體導熱介質114是 或液冷狀糾目義,均可_歧液效散果熱 並错由該内管60與外管10隔開形成溫度差,使吸液導管50内之] 7 201144738 熱介質114與循環管道113中之流體導熱介質114形成一 循=:二次加速魏效果’讓流體導熱介質114的散熱201144738 VI. Description of the Invention: [Technical Field] The present invention relates to a flexible heat dissipating duct, and more particularly to a method for providing at least one liquid-absorbent conduit internally to conduct at least one fluid heat medium with capillary action for heat dissipation and non-directional A flexible heat sink that limits circulation. ... [Prior Art] According to the conventional integrated circuit, power transistor, crystal moon group, light-emitting diode (LED) lamps, etc., the electrons generated by high heat energy (4) need fine distributor or heat dissipation mechanism in use. With the combination, it can operate normally. [The electronic cooling method using passive floating fins or heat sinks is not suitable, except for the slow heat dissipation, the cooling efficiency of the source or hotspot is also very poor, and the electronic load On the junction with the heat sink, the heat dissipation temperature at each point is not uniform, which does not meet the needs of industrial utilization, and is gradually eliminated. ^Therefore, there is a reformer who uses the metal pipe configuration and (4) injects === and reconnects the heat sink to provide the above-mentioned electronic load heat dissipation. However, due to the slow moving rate problem, if the cooling is simply driven by heat convection = or divergence Can't _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ , usually electric pure heat sink 'but this way, it is bound to make small =:=: force a lack of sub-load, to provide heat dissipation mechanism's another design, for example: configuration in narrow, n need to cooperate with electronic load installation Occasion or machine ~ ring its industrial use value 'and, the metal pipe in the bending angle: 201144738, will New Year's words _ _ xiao xiao f different shapes and component configuration position (four) sub-products, such as = ί By bypassing or avoiding certain mechanisms or electronic components, it is necessary to make a large-scale "heat dissipation of the metal piping configuration of the two know-how and it is not applicable, thus limiting the scope of its application. The relevant patent documents in the related prior art, The invention patent case of the Republic of China Patent Gazette = 65772 "Liquid Cooling System" reveals the liquid cooling system of a typical conventional metal pipe. Similarly, the heat dissipation effect of the metal pipe is generated. Electron miscellaneous (10) _ ^ and shortcomings. μ Patent Bulletin No. 5536G2 "Improvement of Radiator, '." 1L Jue's work, the faucet and the radiator of the New Zealand heat pipe, provided for the electronic load as a heat sink, although the above metal pipe can be improved The road bend configuration _ 'but still no secret age to avoid silk _ slow rate problem' and must rely on small 贱 加压 输送 输送 输送 肖 肖 肖 肖 肖 肖 肖 肖 肖 肖 肖 肖 肖 肖 肖 肖 肖 肖 肖 肖 肖 肖 肖 肖 肖 肖s [Summary of the Invention] The heat sink of the known electronic load has a heat dissipation rate, an inefficient efficiency, and an uneven heat dissipation of the joint by the air cooling method, such as the circulating heat dissipation by the metal piping configuration in the previous case. The installation position is limited. In addition, if a small electric pump is used to add cooling fluid to the cooling fluid, the utility cost is extra, the cost is high, and the installation space is occupied. Therefore, it is necessary to develop a kind of low cost, no need to consume power and equipment, and can quickly provide at least one fluid heat conduction medium with self-circulating heat dissipation effect regardless of the state of liquid, gas or gas and liquid changes. Heat-dissipating duct, and flexible, not limited by the position, direction and mechanism of the electronic load, space limitation, can be used in 201144738 乂 application in the _ shape, the body lang size of the invention can be transferred to the camp, (four) installed and application. : the part and at least the inner tube, wherein the rod is integrated with the outer _, the heat conducting member (4) 5 is not tied to the inner edge of the inner tube, and the inner tube and the liquid suction conduit In conjunction with the material * scattered, the inner chamber and the outer chamber are separated by at least one, :;;, cattle, inner and rear, ^ # 'call the secret source to generate heat energy absorbed by the heat-conducting parts _毛/^.,,, and touch the _流料龄#, the heat medium of the money is conducted along the liquid suction conduit to the heat sink to cool down, and then the heat sink is recycled to the heat sink. ring. The effect of the flexible heat-dissipating duct of the invention is that the fluid-guided theory of the cold-week is based on the action of the liquid-absorbent conduit 2 in the liquid, the number or the gas, the cooling state, and the _ Fruit, and the outer tube = unrestricted electronic load is set in the direction of the upper, lower, left or right, position: the guide can be separated by the compartment formed between the inner tube and the outer tube, so that the liquid absorption two /, the fluid heat transfer medium inside the valley has a temperature difference interval, and the heat convection circulation heat dissipation effect of the capillary action 2 is formed, so that the heat source of the electronic load can be quickly circulated and heated, and the electronic load is transmitted through the soaking ring setting. The divergence of each point on the joint surface is uniform, so as to achieve the cycle heat dissipation effect without the use of extra power and equipment, and the efficient heat dissipation. [Embodiment] Referring to the first, second, and third figures, a first embodiment of the flexible type, ',, & 100 of the present invention, wherein the 'removable heat sink The lion includes a circular body 10, the outer tube 10 is a heat conductor, and is a flexible tube, for example, a soft stone eve 201144738 hose, which can be used for flexible f folding, the outer tube 1 ...... 11 upper end inner wall is provided a plurality of locking threads lu y 7 - a valley U, the chamber is external ===== (4) or a metal material such as an alloy, and in the present invention, the type is formed by an electron-emitting load 200-bonding Section 21, the connection, 21 2, for example, the heat-conducting member 20 and the inner 211 correspondingly screwed to the outer tube core i η::=11 upper end of the coffee-heat sink 30, which is composed of a heat conductive material, such as Ming Ying = ==== The above-mentioned heat-conducting member 2〇, heat-dissipating member 3〇 and outer tube 1〇 are limited to the screw 2U, the locking screw (1) and the screw-locking equivalent lock type. , such as bonding and other effective structures 'when not leaving the scope of the invention. . area. The temple material to ί均^^4〇' is composed of a liquid absorbing material, such as non-woven fabric, sponge, etc., which is attached to the surface of the joint portion 21 of the inner edge of the heat-conducting member 2, which is at least - the perforation 41 The perforation 41 kisses the hole material 5〇 of the heat conducting member 2〇 and at least one inner tube 6〇, and the liquid suction conduit 50 is a liquid-absorbent ancestor & non-woven fabric, marine absorbent material, and the Saki 6G is heat-resistant隔,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,, The through hole 41 and the insertion hole 212 of the heat conducting member 20 and the insertion hole 312 ′ of the heat dissipating member 30 connect the liquid suction conduit 50 to the soaking chamber U, the heat conducting member 20 and the heat dissipating member 30, and let the space The inner tube 6〇 and the outer tube 1 are separated to form at least one, a ring duct 113, and the juxta tube 113 is filled with at least one fluid heat conductive medium 4'. The type of the flow material f 114 is not limited, and the towel of the present invention is not limited. The fairy coolant is a second fluid medium such as water or oil that has a heat-dissipating effect, and does not deviate from the nozzle of the present invention. 2〇 heat member, heat dissipating member between the coupling structure 3〇 not plugged into socket 212 to the jack 312, and limited to: configuration such as bonding or fitting, if not from age present invention. Μ之连--Please cooperate with the first application example of the flexible heat-dissipating duct of the present invention as shown in the fourth figure, wherein the electronic load of the light-emitting diode type is shown. At the time, the original heat is absorbed by the heat-conducting member 2, and then the heat-conducting member 1〇 and the fluid heat-conducting medium 114 in the middle of the ':, 裱40 are heated, so that the fluid heat-transfer medium ιΐ4 generates liquid, and the two-phase change 'by the capillary The action is conducted along the liquid suction conduit 5G to the heat dissipating member. The heat dissipation is cooled and cooled, and then circulated back to the heat-conducting soaking ring 40 (as indicated by the direction of the arrow in the fourth figure) by the three-dimensional read channel (1), and finally, Then, the fluid contact heat transfer medium 114 is absorbed by the touch device (10), and the above-mentioned circulating heat dissipation and temperature reduction operation is repeated. The heat equalizing ring 40 provides a uniform heat dissipation function of the electronic load and the female point on the surface of the heat conducting member 2 connected thereto. By means of the above-mentioned heat-dissipating circulation path, the high-temperature source of the electronic load or the high temperature can be quickly brought to the heat dissipating member % end = drop by the capillary action of the liquid-absorbent conduit 50, and regardless of the fluid heat-conducting medium 114 It is either liquid or cold, and can be separated from the outer tube 10 to form a temperature difference, so that the liquid absorption conduit 50 is in the liquid absorption conduit 50. The fluid heat transfer medium 114 in the pipe 113 forms a cycle of: secondary acceleration of the heat effect of the fluid heat transfer medium 114
示’為本發明之可撓式散熱導管100的第 其中,顯示電子負载綱朝下設置之狀態,同樣地, ::目同的机體導熱介質114猶環散熱路徑(如第五圖中箭頭 。所不)’财由導齡2〇經由該錄料5G毛轉用傳導至 賴冷卻’錢獅_113魏__牛20端 ,同理可得,該電子負载2⑽無論設置方向朝左或朝 右,亦均有此自_環餘之效果,因此,本發啊不受電子負 载設置位置及方向的限制,均可細吏流體導熱介質ιΐ4盔 方向限制的自體循環散熱功效。 —請再參閱第六圖所示,為本發明之可撓式散熱導管1〇〇的第 二應用例,其中’顯示該導熱件20表面連結一晶片組之電子負載 ’該散熱件30表面則連結一散熱鰭片組綱,並藉由該外管 之可撓性彎折特性,可以在如電腦機殼或主機板等場合中進行 各種角度之彎折配置,同樣可使該晶片組之電子負載勘,之轨能 迅速及有效地傳導至遠端之散熱籍片組·進行散熱降溫,並使 该,體導熱介質114於外管10内之吸液導管5〇、均熱環4〇與循 環官道113騎行自體無方向關的循環散熱操作。 —請再參閱第七圖所示,為本發明的可撓式散熱導管的第 -實施例’其中’顯示該外管1G與内管⑼間之循環管道⑴内 填充至少-吸液中管70 ’該吸液中管7〇為吸液材料所構成,如不 織布或海棉,以吸收該流體導熱介f 114,_可以如該吸液導管 5〇之毛細作用’發揮迅速傳導流體導熱介f m之功效,同樣可 乂達到第ffi至第”圖所不之第—實施例中的單純液態流體導献 ’、、、m 201144738 介質114之熱對流循環效果。 請配合第八圖所示’為本發明的可撓式散熱導管励的第三 實施例,其中,顯不該散熱件30内緣之接合部31表面結合一均 熱環40,該均熱環40之穿孔41吻對該接合部31之插孔312,供 該吸液導管50 -端穿過’使散熱件3G之表面之每—點部位之散 熱更加均勻,並加速該流體導熱介質m於如第四圖及第五圖所 示自體循環路徑之循環散熱效率。In the first embodiment of the flexible heat dissipating duct 100 of the present invention, the state in which the electronic load is placed downward is displayed, and similarly, the body heat transfer medium 114 of the same body is in the ring heat dissipation path (such as the arrow in the fifth figure). No.] The financial guidance of the age of 2, through the recording of 5G hair transfer to the Lai cooling 'Qianshi _113 Wei __ cattle 20 end, the same is available, the electronic load 2 (10) regardless of the direction of the left or To the right, there is also the effect of this self-circle. Therefore, the hair is not limited by the position and direction of the electronic load setting, and the self-circulating heat dissipation effect of the fluid heat conduction medium ιΐ4 helmet direction can be finely detailed. - Please refer to the sixth figure, which is a second application example of the flexible heat dissipating duct 1 of the present invention, wherein 'the surface of the heat conducting member 20 is connected to an electronic load of a chip set'. Connecting a heat sink fin assembly, and by virtue of the flexible bending characteristics of the outer tube, it can be bent at various angles in a computer case or a motherboard, etc., and the electronic of the chip set can also be The load can be quickly and efficiently transmitted to the remote heat-dissipating group, heat-dissipating and cooling, and the body heat-transfer medium 114 is in the outer tube 10, and the soaking tube 5〇, the soaking ring 4〇 The circulation official road 113 rides a self-contained non-directional closed heat dissipation operation. - Please refer to the seventh embodiment, which is a first embodiment of the flexible heat dissipating duct of the present invention, in which the circulating pipe (1) between the outer pipe 1G and the inner pipe (9) is filled with at least a liquid-absorbent pipe 70. 'The pipette 7 〇 is composed of a liquid absorbing material, such as non-woven fabric or sponge, to absorb the heat conduction of the fluid f 114, _ can act as the capillary mechanism of the pipette 5 发挥 to rapidly conduct fluid heat conduction fm The effect can also achieve the thermal convection circulation effect of the simple liquid fluid guide ',,, m 201144738 medium 114 in the first embodiment of the ffi to the first figure. Please match the figure in the eighth figure. A third embodiment of the flexible heat dissipation conduit of the present invention, wherein the surface of the joint portion 31 of the inner edge of the heat sink 30 is combined with a soaking ring 40, and the through hole 41 of the soaking ring 40 kisses the joint portion The jack 312 of the 31, the end of the liquid-absorbent conduit 50-passing through to make the heat dissipation of the surface of each surface of the heat dissipating member 3G more uniform, and accelerate the fluid heat-conducting medium m as shown in the fourth and fifth figures. Shows the cycle heat dissipation efficiency of the autogenous circulation path.
請再參閱第九圖、第傾及第十—圖所示,為本發明之可挽 式散熱導管100的第四實施例’射,顯示該導熱件加之接入部 内緣設有複數插孔212,該散熱件3〇之接合部31崎設^复 數插孔312,該結合於導熱件20及散熱件3〇巾之均熱環4〇中設 有複數穿孔41,該複触膽6〇及錄導管5()組合,各吸 管5〇兩端分別穿過各穿孔^再插接於導熱件2〇之接合部21之 各插孔212,以及散熱件30之接合部31之各插孔312之 複數組内管60將外管1G之容室^區隔職複數循環管道出了 116、117及118,使該填充於各循環管道115、116、丨口及… 内之流體導熱介質U4,有更多組的吸液導管%與循環管道出、 II6、m及m共同形成綿密之自體循環網絡(如第十圖所 加速該流㈣齡質114之自賴環散熱速度與提昇該 200之散熱效率。 、戰 為本發明之可撓:散:導:十二五圖所示’ -、_及流_介請之習未知 === TZT 1 A1 ^ A2 ^^Γ;;〇 S] ^面之兩點’第十三圖顯示量測點Α3及M分別為散献件 面之兩點’本發明之可撓式散熱導管刚的量測結果如下列表一 9 201144738 及第十四圖所示,而對照組的習知空氣冷卻式散熱 下列表二及第十五圖所示,該橫向軸為時間轴 轴p,其中: (表一) 器量測結果如 ’縱向軸為溫度 主曼里丄^(單位 時間\量測Referring to the ninth diagram, the first tilting, and the tenth-figure, the fourth embodiment of the portable heat dissipating duct 100 of the present invention is configured to display the heat conducting member and the inner edge of the access portion is provided with a plurality of jacks 212. The joint portion 31 of the heat dissipating member 3 is provided with a plurality of jacks 312, and the plurality of through holes 41 are formed in the soaking ring 4 of the heat conducting member 20 and the heat dissipating member 3, and the double contact hole is disposed. In the combination of the recording tube 5 (), the two ends of each of the suction tubes 5 are respectively inserted through the respective through holes and then inserted into the respective insertion holes 212 of the joint portion 21 of the heat conducting member 2, and the respective insertion holes 312 of the joint portion 31 of the heat sink 30. The multi-array inner tube 60 separates the plurality of circulating pipes of the outer tube 1G from the plurality of circulating pipes 116, 117 and 118, so that the fluid heat-conducting medium U4 filled in the circulating pipes 115, 116, the mouth and the ... There are more groups of pipettes % together with the circulating pipe, II6, m and m to form a dense autogenous circulation network (such as the acceleration of the flow in the tenth figure (4) ageing 114, the heat dissipation speed of the self-reliant ring and the improvement of the 200 Heat dissipation efficiency. War is the flexibility of the invention: scatter: guide: 12-fifth diagram '-, _ and flow _ introduce the unknown unknown === TZT 1 A1 ^ A2 ^^Γ;;〇S] ^Two points of the surface 'Thirteenth figure shows the measurement points Α3 and M are the two points of the surface of the piece separately. 'The measurement results of the flexible heat pipe of the present invention are as follows. A 9 201144738 and a fourteenth figure, while the conventional air-cooled heat of the control group is shown in the second and fifteenth figures, the horizontal axis is the time axis axis p, where: (Table 1) The result is as follows: 'The longitudinal axis is the temperature of the main Manly 丄 ^ (unit time \ measurement
分鐘minute
[SI 10 201144738 22 77.6 75 75.2 74.7 23 77.6 75.1 75.8 74.7 (表二) 習知,溢度(單位:°C),時間(單位:分鐘) 時間\量測 點溫度 A1 A2 A3 A4 1 38.7 36.5 36.1 34 2 45.7 43.8 43.3 42 3 49.9 47.1 46 45.6 4 53.4 49.5 48.8 48.5 5 55 53 52 51.6 6 58.2 57.4 56.8 55 7 60 58.8 56 55.5 8 65 61.9 61.3 60.3 9 67 62.5 62.1 61.7 10 71.1 63.9 63.1 62 11 73.8 64.1 63.3 62.8 12 74.2 64.5 63.8 63.5 13 75.1 65.4 64.1 63.9 14 75.7 67.8 65.9 65.5 15 76.5 68.1 67.6 67 16 78 69.6 68.1 68 17 79.5 70.2 69.3 69 18 80 71.1 69.9 69.5 19 82 71.4 70.5 70.1 20 83 72.8 70.8 70.6 21 84 73.2 72.5 72.1 22 84.1 73.8 73.4 72.2 [s] 11 201144738[SI 10 201144738 22 77.6 75 75.2 74.7 23 77.6 75.1 75.8 74.7 (Table 2) Conventional, overflow (unit: °C), time (unit: minute) Time\measuring point temperature A1 A2 A3 A4 1 38.7 36.5 36.1 34 2 45.7 43.8 43.3 42 3 49.9 47.1 46 45.6 4 53.4 49.5 48.8 48.5 5 55 53 52 51.6 6 58.2 57.4 56.8 55 7 60 58.8 56 55.5 8 65 61.9 61.3 60.3 9 67 62.5 62.1 61.7 10 71.1 63.9 63.1 62 11 73.8 64.1 63.3 62.8 12 74.2 64.5 63.8 63.5 13 75.1 65.4 64.1 63.9 14 75.7 67.8 65.9 65.5 15 76.5 68.1 67.6 67 16 78 69.6 68.1 68 17 79.5 70.2 69.3 69 18 80 71.1 69.9 69.5 19 82 71.4 70.5 70.1 20 83 72.8 70.8 70.6 21 84 73.2 72.5 72.1 22 84.1 73.8 73.4 72.2 [s] 11 201144738
由以上表-與表二,以及第十四圖與第十五關的實驗數據 加以比對分析下,可以得到下列之結論: 1. 從本發明之可撓式散熱導管腦試驗量測資料分析比較…點的 最高溫度為77.6°C,A2點的最高溫度為75.rC,A3點的最高溫 度為A4 ·點的最高溫度為74坑。M點與A4點的溫度差 約在3°C範圍内,且在2〇分鐘左右就達到熱平衡狀態,ι〇個小 時後置測Al」fi溫度為76 3度,並制發光二極雜具型態的電 子負載2〇0免度’和原來的亮度一樣,未見衰減。 2. 從習知之空氣冷卻絲熱器試驗量測資料分析比較,相對於第十 -圖之A1」點的最高溫度為87 ιχ:、A2點的最高溫度為75 !;相 對於第十三圖之A3點的最高溫度為74穴,M點的最高溫度為 73.5C ’ A1點的溫度與M點的溫度差最大為12 π:,且還未達 熱平衡,經ίο個小時後A1點量測温度達到urc,再量測該相 對於第十二圖之發光二極體燈具型態的電子負載200亮度,僅為 原來的60% ’有明顯的光衰減現象。 3. =發明之可撓式散熱導㈣〇㈣知空氣冷卻式散熱器的散熱體 /皿度低13.6 C,顯示本發明之可撓式散熱導管1〇〇具有較快 好的散熱效率。 、 4. 由本發明之可撓式散熱導管卿的整體溫度差僅在3°C微小範圍 以,,而習知之空氣冷卻式散熱器的整體溫度差在13。(:以上,此 =兒明了本㈣能有效的把電子貞載2⑻所有熱腿速送達到外 管H之散熱鰭片11及散熱件30的所有點,使其能快速的和外 ’工氣進行熱父換,以降低節點溫度tempe加⑽s),進 而保障電子負載200的壽命與光源亮度之穩定。 •由本發明之可撓式散熱導管10〇中的A1點和A4點的溫差僅在狹 12 201144738 小範圍内,而顯得證本發明可以掸 =:環_傳導效率;而 这個效果,如本發明要進—步丨力1、_沒有 能很有鱗_加_賴^;^ ’就 無法達成此-效果。 積m乳冷部式散熱器則 的時間來比較,本發明之可撓式散熱導管1⑻比習知空 軋冷郃式散熱器能快速達到熱平衡。 二 明ftr,本發明之可撓式散熱導管所鱗之各圖式及說 係為便於說明本發明之技術内容,所列舉之實施例之一隅, ^非用以關本發明之齡,舉凡是針對本發明之結構細部或元 效變更與置換,當屬本發明之_,其範圍將㈣下的申 5月專利範圍來界定之。 【圖式簡單說明】 第-圖係本發明之可撓式散鱗管第—實_之立體外觀結 構圖。 第二圖係第一圖之立體分解結構圖。 第二圖係第一圖之剖視放大圖。 第四圖係本發明之可撓式散熱導管第一應用例圖。 第五圖係本發明之可撓式散熱導管第二應用例圖。 第六圖係本發明之可撓式散熱導管第三應用例圖。 第七圖係本發明之可撓式散熱導管第二實施例圖。 第八圖係本發明之可撓式散熱導管第三實施例圖。 第九圖係本發明之可撓式散熱導管第四實施例圖。 第十圖係第九圖之剖視放大圖。 第十一圖係第十圖之A-A’剖視圖。 第十二圖為本發明之可撓式散熱導管之導熱件端實際量測點 13 201144738 示意圖。 第十三圖為本發明之可撓式散熱導管之散熱件端實際量測點 示意圖。 第十四圖為第十二圖及第十三圖之量測點的實際量測數據曲 線圖。 第十五圖為習知空氣冷卻式散熱器之量測點的實際量測數據 曲線圖。 【主要元件符號說明】From the above table-to-table 2, and the experimental data of the fourteenth and fifteenth levels, the following conclusions can be obtained: 1. Analysis of the measured data from the flexible heat-dissipating catheter brain test of the present invention The highest temperature at the point of comparison is 77.6 ° C, the maximum temperature at point A2 is 75.rC, and the maximum temperature at point A3 is A4. The maximum temperature at point is 74 pits. The temperature difference between point M and point A4 is about 3 °C, and the heat balance is reached in about 2 minutes. After ι〇, the temperature of Al"fi is 76 3 degrees, and the light-emitting diode is made. The type of electronic load 2〇0 exemption 'is the same as the original brightness, no attenuation. 2. From the analysis and comparison of the conventional air-cooled wire heater test data, the maximum temperature of the A1 point relative to the tenth-graph is 87 ιχ: the maximum temperature of the A2 point is 75!; compared with the thirteenth figure The maximum temperature of the A3 point is 74 points, and the maximum temperature of the M point is 73.5C. The temperature difference between the temperature of the A1 point and the M point is at most 12 π:, and the thermal equilibrium has not yet reached, and the A1 point is measured after ίο hours. The temperature reaches urc, and then the brightness of the electronic load 200 relative to the type of the light-emitting diode lamp of the twelfth figure is measured, which is only 60% of the original 'has a significant light attenuation phenomenon. 3. = Invented flexible heat-dissipating guide (4) 四 (4) Knowing that the heat-dissipating body of the air-cooled heat sink has a low degree of 13.6 C, which shows that the flexible heat-dissipating duct 1 of the present invention has a faster heat-dissipating efficiency. 4. The overall temperature difference of the flexible heat dissipating conduit of the present invention is only in the range of 3 ° C, and the overall temperature difference of the conventional air-cooled radiator is 13. (: Above, this = child clearly this (four) can effectively send all the hot legs of the electronic load 2 (8) to all the points of the heat sink fin 11 and the heat sink 30 of the outer tube H, so that it can quickly and externally The hot father is replaced to reduce the node temperature tempe plus (10) s), thereby ensuring the stability of the life of the electronic load 200 and the brightness of the light source. • The temperature difference between the A1 point and the A4 point in the flexible heat dissipating duct 10 of the present invention is only in the small range of the narrow 12 201144738, and it appears that the present invention can be 掸=:ring_conduction efficiency; and this effect, such as this Invented to advance - step 丨 1, 1, _ can not be very _ _ _ _ ^ ^ ^ ^ can not achieve this - effect. Comparing the time of the m-milk-type heat sink, the flexible heat-dissipating duct 1 (8) of the present invention can quickly achieve thermal equilibrium than the conventional air-rolled cold head heat sink. The drawings and the description of the flexible heat-dissipating duct of the present invention are for convenience of explaining the technical content of the present invention, and one of the enumerated embodiments is not used for the age of the present invention. The structural details or meta-effects and permutations of the present invention are within the scope of the present invention, and the scope thereof is defined by the scope of the May patent under (4). BRIEF DESCRIPTION OF THE DRAWINGS The first figure is a three-dimensional appearance structure diagram of the flexible scale tube of the present invention. The second figure is a perspective exploded view of the first figure. The second drawing is a cross-sectional enlarged view of the first figure. The fourth figure is a first application example of the flexible heat dissipation conduit of the present invention. Figure 5 is a second application diagram of the flexible heat sink of the present invention. The sixth drawing is a third application example of the flexible heat dissipation conduit of the present invention. Figure 7 is a view of a second embodiment of the flexible heat sink of the present invention. Figure 8 is a view of a third embodiment of the flexible heat sink of the present invention. Figure 9 is a view of a fourth embodiment of the flexible heat sink of the present invention. The tenth figure is a cross-sectional enlarged view of the ninth figure. The eleventh drawing is a cross-sectional view taken along line A-A' of the tenth drawing. Figure 12 is a schematic view of the actual measurement point of the heat-conducting end of the flexible heat-dissipating duct of the present invention. Figure 13 is a schematic view showing the actual measuring point of the heat dissipating end of the flexible heat dissipating duct of the present invention. Figure 14 is a graph showing the actual measurement data of the measurement points in the twelfth and thirteenth drawings. The fifteenth figure is a graph of the actual measurement data of the measuring points of the conventional air-cooled radiator. [Main component symbol description]
100 可撓式散熱導管 10 外管 11 容室 111 鎖合螺牙 112 鎖合螺牙 113 循環管道 114 流體導熱介質 115 循環管道 116 循環管道 117 循環管道 118 循環管道 20 導熱件 21 接合部 211 螺牙 212 插孔 30 散熱件 31 接合部 311 螺牙 312 插孔 40 均熱環 41 穿孔 50 吸液導管 60 内管 70 吸液中管 200 電子負載 200, 電子負載 300 散熱鰭片組 A1 量測點 A2 量測點 A3 量測點 A4 量測點 T 時間轴 P 溫度轴 m 14100 flexible heat sink 10 outer tube 11 chamber 111 locking screw 112 locking screw 113 circulation pipe 114 fluid heat transfer medium 115 circulation pipe 116 circulation pipe 117 circulation pipe 118 circulation pipe 20 heat conducting member 21 joint portion 211 thread 212 Jack 30 Heat sink 31 Engagement part 311 Screw 312 Jack 40 Soaking ring 41 Perforation 50 Suction duct 60 Inner tube 70 Liquid absorbing tube 200 Electronic load 200, Electronic load 300 Heat sink fin group A1 Measuring point A2 Measuring point A3 Measuring point A4 Measuring point T Time axis P Temperature axis m 14