1288820 九、發明說明: 【發明所屬之技術領域】 本發明係關於-種檢職置,尤侧於—種檢測熱管性能的檢測裝置。 【先前技術】 熱管之基本構造係於密閉管材内壁襯以易吸收作動流體的多孔質毛細 結構層,而其中央的空間則為空胴狀態,並在抽真空的密閉管材内注入相當 於毛細結構層細孔總容積的作動流體,依吸收與散出熱量的相關位置可分為 条發段、冷凝段以及其間的絕熱段。 ’ 熱官的工作原理係當蒸發段吸收熱量使蘊含於毛細結構層中的液相作 動流體蒸發,並使蒸汽壓升高,而迅速將產生的高熱給蒸汽流沿中央的通道 移往壓力低的冷凝段散出熱量,凝結液則藉毛細結構層的毛細力再度返回蒸 發丰又吸收熱量’如此週而復始地藉由作動流體相變化過程中吸收與散出大量 潛熱的循環,進行連續性的熱傳輸,且由於作動流體在上述過程中的液相與 汽相共存,以致熱管可在溫度幾乎保持不變的狀況下扮演快速傳輸大量熱能 的超導體角色而廣為各種領域所應用。 由於熱管的性能測試主要著重在最大熱傳量(Qmax)以及由蒸發段至冷 凝段的溫度差(ΔΤ)兩項參數,因此在一給定的熱量傳輸狀況下可以藉由該溫 丨 度差而獲知其熱阻值,進而評估熱管的性能;當給定的熱量超過熱管的最大 熱傳ΐ時’由於原正常熱量傳輸機構遭到破壞而使熱阻值驟增,以致蒸發段 的溫度亦隨之驟升。 習知技術中的一種熱管性能檢測方法係將熱管蒸發段插入被加熱之衡 溫液體中,待熱管溫度穩定後,藉由溫度感測器例如熱電偶、電阻溫度感測 器(RTD)等量測衡溫液體與熱管冷凝端之間的溫度差以評估熱管的性能; 唯’上述習知技術無法有效量測出熱管的最大熱傳量及熱阻,因此不能準確 反映出熱管的熱傳性能。 習知技術中另一種如第一圖所示的熱管性能檢測裝置,係以電熱絲1為 熱源纏繞在熱管2的蒸發段2a表面,同時以冷卻水套3為熱沉套設於冷凝段2b 6 1288820 表面,藉由量測電熱絲1的電壓與電流可以給熱管2一定的加熱功率,並同時 藉由調制冷卻水套3的流量及入口水溫來移除該加熱功率,並藉以控制熱管2 在絕熱段2c的穩定操作溫度,而熱管2的最大熱傳量以及由蒸發段至冷凝 段2b之溫度差則可由設於熱管2表面的各溫度感測器4得知。 唯,上述習知熱管性能檢測裝置仍有以下缺點:由於蒸發段2填冷凝段 2b的長度不易準確控制,是造成評估熱管性能變異的重要因素;且由於熱量 的散失及溫度的制料受酬試環境的影響而產生變異;以及熱管和熱源 及熱沉的密合熱接觸$易有效控制等缺點,均不利於精確評估熱管的性能, =由於安裝與物十分費工,上㈣知熱紐能檢職題適用於實驗 室規模的小量,管測試,完全無法因應量產製程所需的檢測要求。 為H里產製㈣制要求,必需對數量龐大且形式多樣化的教管 ===品胸㈣於檢湖―形摘量產絲即f制日細大量的 的1且該4檢測機台需長期而頻繁的重複使用;因此,除了機台本身 料’更必賴大量_齡敝錢異及齡變異予以嚴格控 二^雜1置的_直接影響生產的良率與成本,業者勢必面臨檢測 鑒於此右2利性、快速性、一致性、重現性、與可靠性的多重挑戰;有 二製造的目前的歸檢測裝置作大幅改進,從而將組裝與操作及元 ^每的她化設計-賴人,以符合熱管量產製㈣檢測需求。 【發明内容】 本發明針對上述習知技術的缺點,提出—種熱管性能檢測裝置,特別 =適用於量產製簡熱管性能檢霄m固定部及—活動部,該固 冑ρ刀別叹有移除熱管自熱源傳輸之熱量的冷卻構造,該活動部 置敎以⑷進订離合,該固定部與活動部的相對表面之間設有至少一可容 f量測容置部及至少—使活動部與固定部離合時防止其相對位置偏 凹喊合機構,該量測容置部中設有至少一溫度感測器。當活動部移 n疋辦使制容置部義面與設置於其中的熱管管《合熱接觸以降 1288820 低熱阻,反之’當活動部移離固定部時可將完成檢測的熱管快速取出,並 將另-待測熱管快速插人至定位;再藉由設置於固定部與活動部之間的防 f凹凸機構,彳__喊卿㈣物响縣邮機構的深度 顺’且活動部與峡部維持滑動密合狀態,以確保活動部與固定部的 相對位置不致偏離,從而確保量測容置部壁面與熱管管壁密合執接觸;又 藉由在量測容置部壁面上設置的至少—支溫度❹m,當插人待測熱管時 使其密貼於鮮管壁均為制熱管性㈣指標;具有上述特徵的本發明 熱官性能檢難置係藉由模組化設計達到符合量產檢測需求,使所組裝與 知作的熱s檢測震置具有良好的準確性、便利性、快速性、—致性、重現 性、與可靠性等多重優點。 本發明有如下優點: 本制透顯組化設計使熱紐紐職㈣合量錄顺求,達到 在產線大里複製及使用該裝置時不論由何操作員組裝及測試,該等裝置所 篁測的結果具有良好的一雜、重現性、及可靠性。 本發明另藉由設於活動部上的驅動部,使其與固定部進行線性運動, 促使活動部與岐敎騎職的量翁置部可和插人鮮的管壁密合熱 接觸以降低熱阻,並將完成檢測的熱管快速取出或更換,達到檢測的便利 性及快速性之功效。 本發明再藉由設_定部絲動部上互_凸配合的㈣定位設計, 使活動部的線性運動受到準確導弓丨,避免長麵繁的使用而移位,^一步 確保檢測機台量測的結果具有良好的一致性與重現性。 【實施方式】 1288820 明 以下參照第二圖至第五圖 對本發明熱管性能檢職置予以進-步說 jnr明熱管,1裝置之第-實施例的-外_圖,第 置主要包括一固定部20及一活動 二圖為第__-立體分解圖。該檢測裝 部30。其中: 固疋部20為鎖固於一稃固么 m錢其他支撐鶴的不動件, 良好的刪成,該固定㈣内部設有供冷卻液通過的流道(圖 ㈣’起㈣液入出22_的‘岐冷綱環峰未句 連接,該岐部2G表面設有與熱管冷凝段管壁密合熱接觸的至少-散執凹 槽24 ’以便鮮順㈣自靖輸嶋购緣述目的,本發明 刀别在活動。卩3G及U㈣2Q之間設置互相凹凸匹_防呆定位機構,第 四圖⑷為本實施例活動部3Q的一立體示意圖,第四圖⑻為本實施例 固疋抑的—立體不意圖;其中’在活動㈣上_定勒方向設置複 數疋位柱35,該粒柱35係由活動部%朝岐部2Q上具有散熱凹槽^ 的平面方向延伸的餘Μ物,並仙定部2Q上具有雜哺Μ的平面 上設置對應的複蚊位孔25,當活動部3Q _定部2q進行線性運動時, 確保活動部3G的定錄35移向或移_定部20時觸蓋奴位孔25的 深度範_,且_定部2G的定位孔25轉滑動密合狀態,以確保活動 4 30與固疋部20的相對位置不致偏離,從而確保固定部2〇的散熱凹槽% 壁面與熱f讀密合難觸;並藉由在散熱哺%的壁面上設置可獨立運 作且能自動密驗鮮管壁醜少—支溫度感· %,作為制熱管性能 的指標;為防止固定部20的熱量分流至穩固平台,在固定部2〇背面與穩 1288820 固平台之間需設置一絕熱底板。 活動部3〇係由導熱性良好的材質製成,該活動部30内部設有供冷卻 液通過_(_),並裝_认心_ 33 __冷卻液 «系_未示)連接’活_ 30對應於峡部2〇的散熱凹槽Μ位置設 置相對應的定位散熱凹槽32,以便當活動部3〇移向固定部2〇時形成至少 —量測槽孔价使設置於量測槽孔料的熱管管壁與槽觸密合糊 以降低熱阻;為達上述目的,如第四圖⑷所示,活動部30罝有定位散 熱凹槽32的平咖定部2〇上具有散熱凹槽%的平面方向延伸的定位柱 35,其外形、尺寸及數量係配合固定部2〇所設置的複數定位孔Μ,使活動 部3〇嫉部2嶋時,活動㈣蚊位柱35得以嶋入定位孔^ 内’確保活動部3〇的定位柱35移向或移離固定部2〇時均涵蓋在定位孔μ 的深度範圍内’且與固定部20的定位孔25維持滑動密合狀態,從而確保 活動部的定位散熱凹槽32與固定部2Q的散_ %所構成的量測槽 孔5〇壁面與崎健樓觸;聽_觸崎鐵測槽孔% 壁面密合熱接觸’可以採用至少一扣件或螺絲使活動部%與固定部π可 物及扣合,但為制熱管量產製簡檢測需求以及在大量組裝時的準確 疋位本發明的霄施例中採用—種承載部1〇來負責熱管性能檢測裝置的整 聽構及精準定位,尊代上述_平台及扣件或螺轉傳固定與扣 合方式,使㈣2G綱輸iq _件,綱能準確進行 線性運動的驅動部奶,使活動部%藉峨於承載部W上的驅動相來 導引’達到活動部3G朝固定部2G進行精準線性運動之目的,使設置於量 測槽孔5〇中的熱管管壁與槽孔壁面密合熱接觸以降低熱阻。該活動部邓 1288820 勤奴槽32㈣W娜_瓣熱管管壁的 y支4❹彳& 36 ’作她賴管㈣_旨標4枝檢測,本發明 將熱管插入量測槽孔5〇的方向朝向接近操作者,而將冷卻液入出口接頭 乂及皿度感測器26、%的導線伸出方向朝向遠轉作者。 另外在g際顧巾解冷凝段的散熱面可能會經折賴壓扁製程, 該量測觀50的尺寸_鶴絲鮮冷赌_驗財與形狀作匹 配例如待測熱官的冷凝段為平板狀或扁平狀時,該固定部如與活動部% 之相對表面不必形成容置熱管的哺等結構,而直接由狀部顯活動部 30之相對平面組成容置熱管的量測容置部,藉由該量測容置部的平面抵緊 該平板狀或扁平狀熱管的冷凝段即可,溫度感· %、36赌置於該量測 容置部的平面上。在本發明中僅以最常使用的圓形管為例作說明。 再則上述δ又置於活動部3〇的定位柱35亦可設置於固定部如上,而 此時活動部30對應於固定部2Q上的定位柱的外形與尺寸亦需設置定位 孔,使活動部3G朝蚊部2G移動時,,部2Q的纽柱得以滑動嵌入活 動部30的定位孔的内面,亦可達到相同的準確定位效果。 承載部10包括一基體(例如電磁吸盤、升降調整座、固定支撐座等) 12、一與基體12鎖固的第一板14及兩端攻有螺紋的複數支撐桿15、以及 與第一板14呈一定間距並藉由複數支撐桿15固定於第一板14的第二板 16。該基體12、第一板14、第二板16及支撐桿15組合形成一組立支架結 構。其中,該基體12除具有將熱管性能檢測裝置穩固於測試桌面外,並可 搭配具有高度、角度的調整機構以配合實際熱管性能檢測的需要,本發明 中僅以電磁吸盤為例作為以下實施例的說明。該固定部2〇為鎖固於承載部 11 1288820 第-板μ上的不動件,為防顧定部2Q的熱量分流至承載㈣的第一 板η ’在固定部2G背面與承載部1Q的第—板14之間需設置—絕熱底板 I8,為確保於大量組裝時的準確定位,在絕熱底板28上設有-與固定部20 背咖的防Μ槽285’在第—板14上亦設有一與絕熱底板Μ定位的 =呆疋位槽145 ’該絕熱底板28朝向承載部第—板的表面上設 V引出恤度感測n %的感溫線的導通槽撕及供感溫線穿過的出口 284 〇 另卜刖述基體12與第-板w連接的方式適用於本實施例的垂直組 立應用’在實際使用中可能使岭部2()與活動部π更動成水平或需作調 整角度的翻,因此該基體12可安裝於其他位置以配合實務需求。 驅動賴(例如氣缸、油壓缸、步進馬達等)制定於承載部的第 :板1上’通過一螺桿42穿過活動部蓋板34 (活動部蓋板34上設有與螺 的通孔)及承載部1〇第二板16與活動部3〇固接,以便將活動 I 30與固疋部2〇進行線性運動,·本發明藉由設於活動部%上的驅動部如 $吏舌動# 30朝固定部20進行線性運動,其功能包括:(1)使活動部 曰移離2Q _短距離(如約加吟崎將制熱管的冷紐順利插入 里^槽孔5〇中或將已完成檢測的熱管順利移離量測槽孔50 ; (2)使活動部 °疋Ρ 20短距離,以便對已插入量測槽孔50中的待測熱管冷凝 ” Ρ 2〇及’舌動部30的凹槽24、32的壁面密合熱接觸,從而降低冷 " …的接觸熱阻。上述藉由設於活動部3〇上的驅動部4〇,使其與固定 、行線14運動,達到檢測的準確性、便利性及快速性之功效。 另在實際應用中亦可使活動部3〇與固定部2〇的位置互換,並且亦 12 1288820 可使驅動部4〇安襄於靠近固 :上一__2=::= 的靡議w 4G㈣晴輸財載㈣ ^s及料定位,構成-種翻於量產製財的熱管妓檢測裝置。 五圖為本發明熱管性能檢測裝置第二實施例的活動部鱼固定部之— H體示意圖,其中細(a)為活麵之__立體示意圖,第五圖㈨ —疋。卩之-立體示意圖;本實施顺前述實施例的_在於:在活動部 30上朝固定部2〇方向設置嫩位翼35,,較位翼%,係由活動㈣上 具有定位3聊_ _ 2G增健_ Μ醉面方向延 伸的缺凸出物,並在岐部20上具有散熱凹槽24的平面位置上設置對 應物立槽25,,當活動部3〇朝固定部2◦進行線性運動時,確保活動㈣ 的定位翼35’移向或移離固定部2〇時均涵蓋在定位槽Μ,的深度範圍内,且 與固定部20的定鋪25,輸咖合雜,以確黯動部3咖定部 的相對位置不致偏離,從而確保活動部3〇的定位散熱凹槽幻與固定部如 的散熱凹槽24所構麵抓50裝與鮮管魏合熱接觸。 另外’上述设置於活動部30的定位翼35,亦可設置於固定部2〇上,而 此時活動部30對應於固定部20上的定位翼亦需設置定位槽,使活動部邓 朝固定部20移⑽’蚊部2G的定位翼得財動嵌人活動部%的定位槽 的内面,亦可達到相同的準確定位效果。 為達簡化加工及降低成本的需求,該絕熱底板28、活動部蓋板34可以 13 I288820 、用種易於成形且熱導性差的材料,例如塑膠、拖、觸等藉由射出、 =鳴造或以電木、鐵弗龍等藉由機械加工等成形方式製作,並與採用 生良好的金屬,如銅、轉所製成的固定部2q與活動部%匹配, 使凹槽24及梅熱凹槽32壁面錢銀、鱗來防制因長期 接觸面統,進而導致熱傳效率降低的缺失。 泰、,’·不上所述,本創作藉由模組合設計使熱管性能檢測裝置符合量產檢測 而求’為達上述絲本發_取的技術手段包括:1288820 IX. Description of the invention: [Technical field to which the invention pertains] The present invention relates to a type of inspection apparatus, and in particular to a detection apparatus for detecting the performance of a heat pipe. [Prior Art] The basic structure of the heat pipe is such that the inner wall of the closed pipe is lined with a porous capillary structure layer which easily absorbs the working fluid, and the central space thereof is in an open state, and the capillary structure is injected into the vacuum-tight closed pipe. The operating fluid of the total pore volume of the layer can be divided into a strip section, a condensation section and an adiabatic section depending on the position of the absorption and the dissipated heat. The working principle of the hot officer is to absorb the heat in the evaporation section to evaporate the liquid phase actuating fluid contained in the capillary structure layer and raise the vapor pressure, and quickly transfer the generated high heat to the steam flow along the central passage to the low pressure. The condensation section dissipates heat, and the condensate returns to the evaporation and absorbs heat by the capillary force of the capillary structure layer. Thus, the continuous heat is absorbed and dispersed by the cycle of the fluid phase change during the action of the fluid phase change. The transmission and the co-existence of the liquid phase and the vapor phase of the actuating fluid in the above process, so that the heat pipe can play the role of a superconductor that rapidly transfers a large amount of thermal energy while the temperature is almost constant, is widely used in various fields. Since the performance test of the heat pipe mainly focuses on the maximum heat transfer amount (Qmax) and the temperature difference (ΔΤ) from the evaporation section to the condensation section, the temperature difference can be obtained by a given heat transfer condition. Knowing the thermal resistance value, and then evaluating the performance of the heat pipe; when the given heat exceeds the maximum heat transfer of the heat pipe, the thermal resistance value increases due to the destruction of the original normal heat transfer mechanism, so that the temperature of the evaporation section is also It has risen sharply. A heat pipe performance detecting method in the prior art is to insert a heat pipe evaporation section into a heated temperature-temperature liquid, and after the temperature of the heat pipe is stabilized, by a temperature sensor such as a thermocouple, a resistance temperature sensor (RTD), etc. Measure the temperature difference between the temperature-receiving liquid and the condensation end of the heat pipe to evaluate the performance of the heat pipe; Only the above-mentioned conventional technology cannot effectively measure the maximum heat transfer capacity and thermal resistance of the heat pipe, so the heat transfer performance of the heat pipe cannot be accurately reflected. . Another heat pipe performance detecting device as shown in the first figure is wound on the surface of the evaporation section 2a of the heat pipe 2 by using the heating wire 1 as a heat source, and the cooling water jacket 3 is set as a heat sink in the condensation section 2b. 6 1288820 surface, by measuring the voltage and current of the heating wire 1 can give a certain heating power to the heat pipe 2, and at the same time, by adjusting the flow rate of the cooling water jacket 3 and the inlet water temperature to remove the heating power, and thereby controlling the heat pipe 2 At the stable operating temperature of the adiabatic section 2c, the maximum heat transfer amount of the heat pipe 2 and the temperature difference from the evaporation section to the condensation section 2b are known by the temperature sensors 4 provided on the surface of the heat pipe 2. However, the above conventional heat pipe performance detecting device still has the following disadvantages: since the length of the condensing section 2b of the evaporating section 2 is not easily controlled accurately, it is an important factor for evaluating the performance variation of the heat pipe; and the heat is lost due to heat loss and temperature. Variations caused by the influence of the test environment; and the shortcomings of the heat pipe and the heat source and the heat sink, such as the easy heat control, are not conducive to the accurate evaluation of the performance of the heat pipe, = due to the installation and the work is very laborious, on (four) know the heat The inspection questions can be applied to a small amount of laboratory scale, tube testing, and completely unable to meet the testing requirements required for mass production processes. For the production system of H (four) system, it is necessary to have a large number of diversified and diversified teachings === chest (four) in the lake inspection - the amount of silk is produced, that is, the daily production of a large number of 1 and the 4 detection machine It needs to be reused in a long-term and frequent manner. Therefore, in addition to the fact that the machine itself is more likely to rely on a large amount of aging, and it is strictly controlled to control the yield and cost of production, the industry is bound to face In view of the multiple challenges of right-handedness, rapidity, consistency, reproducibility, and reliability, the current detection device of the second manufacturing has been greatly improved, so that the assembly and operation are improved. Design - Lai people, in line with the heat pipe mass production system (four) testing needs. SUMMARY OF THE INVENTION The present invention is directed to the shortcomings of the above-mentioned prior art, and proposes a heat pipe performance detecting device, in particular, which is suitable for mass production of a heat pipe performance inspection m fixed portion and a movable portion, and the solid 胄 刀 knife does not sigh a cooling structure for removing heat transferred from the heat pipe from the heat source, wherein the movable portion is disposed to (4) a binding clutch, and at least one of the fixed portion and the opposite surface of the movable portion is provided with a measuring portion and at least When the movable portion is engaged with the fixed portion, the relative position of the movable portion is prevented from being deviated, and at least one temperature sensor is disposed in the measuring and receiving portion. When the movable part is moved, the heat-receiving section of the heating part is placed in contact with the heat pipe disposed therein to reduce the thermal resistance of 1288820, and vice versa. When the moving part moves away from the fixed part, the heat pipe for detecting the test can be quickly taken out, and The other heat pipe to be tested is quickly inserted into the positioning; and by the anti-convex mechanism disposed between the fixed portion and the movable portion, the __ shouting (four) is the depth of the county postal agency and the active part and the isthmus Maintaining the sliding close state to ensure that the relative positions of the movable portion and the fixed portion are not deviated, thereby ensuring that the wall surface of the measuring receiving portion is in close contact with the wall of the heat pipe; and at least the wall surface of the measuring receiving portion is disposed - The temperature ❹m, when inserted into the heat pipe to be tested, is closely attached to the fresh pipe wall to be the heating pipe (four) index; the thermal performance test of the present invention having the above characteristics is achieved by modular design. The production inspection requirements make the thermal s detection of assembly and knowledge have good advantages such as accuracy, convenience, rapidity, consistency, reproducibility and reliability. The invention has the following advantages: The transparent design of the system makes the hot New Zealand job (4) compliant, and the device is assembled and tested by the operator when copying and using the device in the production line. The measured results have good miscellaneous, reproducible, and reliable results. According to the invention, the driving portion provided on the movable portion is linearly moved with the fixed portion, so that the movable portion and the squatting portion of the squatting position can be in close contact with the inserted tube wall to reduce heat. Resist and quickly remove or replace the heat pipe that has completed the test to achieve the convenience and rapidity of the test. The invention further provides the (4) positioning design of the mutual-convex fitting on the spinning portion of the fixed portion, so that the linear motion of the movable portion is accurately guided and prevented from being displaced by the use of the long surface, and the detection machine is ensured in one step. The measured results have good consistency and reproducibility. [Embodiment] 1288820 Hereinafter, referring to the second to fifth figures, the heat pipe performance inspection device of the present invention is further described as a jnr heat pipe, and the first embodiment of the first embodiment of the device includes a fixed The part 20 and the second activity diagram are the __-stereoscopic exploded view. The detecting unit 30. Among them: the solid part 20 is fixed to the fixed part of the crane, which is well-cut, and the fixed (4) has a flow passage for the coolant to pass through (Fig. 4) '(4) liquid in and out 22 _ The '岐 纲 环 环 环 连接 连接 连接 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 The knife of the invention is in the activity. 互相3G and U(4)2Q are arranged with each other, and the fourth figure (4) is a three-dimensional schematic diagram of the active part 3Q of the embodiment, and the fourth figure (8) is the embodiment of the present invention. - a stereoscopic not-intention; wherein a plurality of clamping posts 35 are disposed on the movable (four)-definite direction, the granular post 35 being the embers extending from the movable portion % toward the flat portion of the crotch portion 2Q having the heat dissipating groove ^, And the corresponding mosquito bit hole 25 is arranged on the plane having the hybrid feeding on the 2Q of the Xianding Department 2, and when the movable part 3Q_fixed part 2q performs linear motion, it is ensured that the fixed position 35 of the movable part 3G moves or moves to the fixed part At 20 o'clock, the depth of the slave hole 25 is touched, and the positioning hole 25 of the fixed portion 2G is slidably closed to ensure the state. The relative position of the movable portion 40 and the solid portion 20 is not deviated, thereby ensuring that the heat dissipating groove % of the fixing portion 2 is hard to be contacted with the heat f reading; and is independently operable by being disposed on the wall of the heat dissipating portion It can automatically check the fresh pipe wall ugly - the temperature sense · %, as an indicator of the performance of the heating pipe; in order to prevent the heat transfer of the fixing portion 20 to the stable platform, it is necessary to set between the fixed portion 2 〇 back and the stable 1288820 solid platform A heat-insulating base plate. The movable part 3 is made of a material having good thermal conductivity, and the movable part 30 is provided with a coolant for passing _(_), and the _ _ _ 33 __ 冷却 _ _ The connection 'live_ 30 corresponds to the heat dissipating groove 峡 position of the isthmus 2〇, and the corresponding positioning heat dissipating groove 32 is disposed so as to form at least the measuring slot hole price when the movable portion 3 is moved toward the fixing portion 2〇 The heat pipe wall and the groove of the measuring slot material are in close contact with each other to reduce the thermal resistance; for the above purpose, as shown in the fourth figure (4), the movable portion 30 has a flat portion for positioning the heat dissipating groove 32. Positioning bar 35 having a heat dissipating groove % extending in the plane direction, its shape, size and number When the movable portion 3 is 2 嶋, the movable (4) mosquito position post 35 can be inserted into the positioning hole ^ to ensure that the positioning post 35 of the movable portion 3〇 moves toward the plurality of positioning holes 固定 provided in the fixed portion 2〇 Or moving away from the fixing portion 2〇 covers the depth range of the positioning hole μ′ and maintaining a sliding close contact with the positioning hole 25 of the fixing portion 20, thereby ensuring the dispersion of the positioning heat dissipation groove 32 and the fixing portion 2Q of the movable portion. _ % The measuring slot 5 〇 wall surface and the Qi Jian building touch; listening _ _ 触 铁 铁 % % % % % % % % % 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以 可以The object and the fastening, but for the production and control of the heating pipe, and the accurate positioning in the mass assembly, the carrier is used in the embodiment of the invention to be responsible for the overall structure and precision of the heat pipe performance testing device. Positioning, respect the above-mentioned _ platform and fasteners or screw transfer transmission and fastening method, so that (4) 2G can be transferred to the iq _ piece, the guide can accurately carry out the linear motion of the driving part of the milk, so that the active part% borrows from the carrying part W Drive the phase to guide 'to reach the active part 3G to the fixed part 2G for precise line Movement of the object, the heat pipe wall with a slot provided in the wall surface of the heat adhesion measurement 5〇 slots in order to reduce the contact resistance. The activity department Deng 1288820 diligent slot 32 (four) W na _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ Close to the operator, the coolant is introduced into the outlet fitting 乂 and the degree sensor 26, the wire extension direction is toward the remote author. In addition, the heat dissipating surface of the condensing section of the g-zone towel may be subjected to the squeezing process, and the size of the measuring object 50 is matched with the shape, for example, the condensation section of the heat officer to be tested is In the case of a flat shape or a flat shape, the fixing portion does not need to form a feeding structure for accommodating the heat pipe, and the measuring surface of the fixing portion 30 directly accommodates the measuring portion of the heat pipe. By measuring the plane of the accommodating portion against the condensation section of the flat or flat heat pipe, the temperature sense %, 36 is placed on the plane of the measuring accommodating portion. In the present invention, only the most commonly used circular tube will be described as an example. Further, the positioning post 35 in which the δ is placed on the movable portion 3〇 may be disposed on the fixing portion as above. At this time, the positioning portion of the movable portion 30 corresponding to the positioning column on the fixing portion 2Q also needs to be provided with a positioning hole for the activity. When the portion 3G moves toward the mosquito portion 2G, the column of the portion 2Q is slidably fitted into the inner surface of the positioning hole of the movable portion 30, and the same accurate positioning effect can be achieved. The carrying portion 10 includes a base body (such as an electromagnetic chuck, a lifting and adjusting seat, a fixed support base, etc.) 12, a first plate 14 locked with the base body 12, and a plurality of support rods 15 threaded at both ends, and the first plate 14 is spaced apart and secured to the second panel 16 of the first panel 14 by a plurality of support bars 15. The base 12, the first plate 14, the second plate 16, and the support bars 15 are combined to form a set of upright support structures. In addition, the base body 12 has the function of fixing the heat pipe performance detecting device to the test table, and can be matched with the height and angle adjusting mechanism to meet the requirements of the actual heat pipe performance detection. In the present invention, only the electromagnetic chuck is taken as an example. instruction of. The fixing portion 2〇 is a fixed member that is locked on the first plate μ of the bearing portion 11 1288820, and is configured to prevent the heat of the fixed portion 2Q from being shunted to the first plate η′ of the bearing (4) on the back surface of the fixing portion 2G and the bearing portion 1Q. The first plate 14 is provided with a heat insulating bottom plate I8. In order to ensure accurate positioning during mass assembly, the heat insulating bottom plate 28 is provided with a tamper-proof groove 285' on the first plate 14 The utility model is provided with a stagnation tank 145 which is positioned with the heat insulating bottom plate '. The heat insulating bottom plate 28 is provided with a V-belt for sensing the n% temperature sensing line on the surface of the first plate of the bearing portion and a temperature sensing line for the temperature sensing line. The exit 284 〇 〇 刖 基 基 基 基 基 基 基 基 基 基 基 基 基 基 适用 适用 适用 适用 适用 适用 适用 适用 连接 连接 连接 连接 连接 连接 连接 连接 连接 连接 连接 连接 连接 ' ' ' 连接 ' ' ' ' ' ' ' ' ' ' ' The angle is turned so that the base 12 can be mounted in other locations to meet practical needs. The drive (for example, a cylinder, a hydraulic cylinder, a stepping motor, etc.) is formed on the first plate 1 of the carrying portion, and passes through the movable cover plate 34 through a screw 42 (the movable cover plate 34 is provided with a screw The hole and the carrying portion 1 are fixed to the second plate 16 and the movable portion 3 to linearly move the movable I 30 and the fixed portion 2〇. The present invention is provided by a driving portion such as $ on the movable portion. The tongue movement #30 performs a linear motion toward the fixing portion 20, and its functions include: (1) moving the movable portion away from 2Q_ short distance (for example, the cold button of the heat pipe is smoothly inserted into the slot hole 5〇) Or the heat pipe that has completed the detection is smoothly moved away from the measuring slot 50; (2) the movable portion is 疋Ρ 20 short distance so as to condense the heat pipe to be tested inserted into the measuring slot 50 ” 2〇 The wall surfaces of the grooves 24, 32 of the tongue portion 30 are in close contact with each other to reduce the thermal contact resistance of the cold. The above-mentioned driving portion 4 provided on the movable portion 3 is fixed and fixed. The line 14 moves to achieve the accuracy, convenience and rapidity of the detection. In addition, in the practical application, the movable part 3〇 and the fixed part 2 can also be Interchangeable, and also 12 1288820 can make the drive unit 4 〇 靠近 close to the solid: the last __2=::= w w 4G (four) clear loss (four) ^ s and material positioning, composition - kind of turn over mass production The heat pipe 妓 detecting device for making money. The fifth figure is a schematic view of the H-body of the movable part of the movable part of the second embodiment of the heat pipe performance detecting device of the present invention, wherein the thin (a) is a three-dimensional view of the living surface, and the fifth figure (9) - 疋 卩 - 立体 立体 立体 ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; 3 chat _ _ 2G 健健 _ 缺 Μ 面 面 延伸 延伸 缺 面 面 面 面 面 Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ Μ ◦ When performing linear motion, ensure that the positioning wings 35' of the movable (4) are moved to or away from the fixed portion 2〇, and are covered in the depth range of the positioning groove, and are fixed with the fixed portion 20 of the fixed portion 20. In order to ensure that the relative position of the swaying portion 3 does not deviate, thereby ensuring the positioning of the movable portion 3 散热The fixing groove 50 of the fixed portion such as the heat dissipating groove 24 is in thermal contact with the fresh tube. In addition, the positioning wing 35 disposed on the movable portion 30 may be disposed on the fixing portion 2, and the movable portion is The positioning wing corresponding to the fixing portion 20 also needs to be provided with a positioning groove, so that the movable portion Deng is fixed toward the fixing portion 20 (10). The positioning wing of the mosquito portion 2G can be obtained by the inner surface of the positioning groove of the movable portion of the movable portion. The same accurate positioning effect. In order to simplify the processing and reduce the cost, the heat insulating bottom plate 28 and the movable cover plate 34 can be 13 I288820, which is easy to form and has poor thermal conductivity, such as plastic, drag, touch, etc. Injection, =Ming, or made by bakelite, Teflon, etc. by mechanical processing, and matching with the movable part 2q made of a good metal such as copper, turn, and concave The silver 24 and the scale of the groove 24 and the hot groove 32 are used to prevent the long-term contact system, which leads to the loss of heat transfer efficiency. Tai,, ‘·Not mentioned, this design uses the modular combination design to make the heat pipe performance testing device meet the mass production test.
错由设於活動部上的驅動部,使其與固定部進行線性運動,促使活動 部與固定部之fa_彡娜她爾入辦崎絲接觸而進行 高效率熱傳; 藉由裝設於活動部與固定部上互相凹凸匹配的防呆定位機構,使活動 部的線性運動受_縣定位機構之_密合肋畴確糾,避免長期 頻繁使用而移位,進而使本發明裝置及其所量_結果具有良好的準確 欧便利性、快速性、一致性、重現性、及可靠性等多重優點。The driving part provided on the movable part is linearly moved with the fixed part to promote the high-efficiency heat transfer between the movable part and the fixed part of the fa 彡 娜 娜 尔 尔 尔 尔; The anti-slipping positioning mechanism that matches the concave and convex portions of the movable portion and the fixed portion makes the linear motion of the movable portion be corrected by the tight-fitting rib region of the _ county positioning mechanism, avoiding long-term frequent use and shifting, thereby enabling the device of the present invention and The quantity _ results have many advantages such as good accuracy, speed, consistency, reproducibility, and reliability.
車乂之習知技觸柯於準確評估熱管性能,安裝與拆卸十分繁項費 工以及僅適合實驗㈣小制鱗缺點,實難以因應量產製程所需的檢 測要求,本創作已大幅改善習知技術的缺點,故不論就成本效益言、就產 品可靠度言、就量產細言、就檢測效能言,本創作經模組化設計之熱管 測裝置鶴優於習知熱管性能檢測裝置,並同時細於實驗室及量 產製程的各項熱管性能參數的量測。 综上所述’本發明確已符合發明專利之要件,遂依法提出專利申請。 准以上所述者僅為本發明之較佳實施例,自不能以此限制本案之申請專 14 1288820 利範圍。舉凡熟悉本案技藝之人士援依本發明之精神所作之等效修飾戋變 化,皆應涵蓋於以下申請專利範圍内。 【圖式簡單說明】 第一圖係習知熱管性能檢測裝置的結構示意圖。 第二圖係本發明熱管性能檢測裝置第一實施例之立體圖。 第三圖係第二圖之立體分解圖。The know-how of the rut is to accurately evaluate the performance of the heat pipe. It is very complicated to install and disassemble, and it is only suitable for the experiment. (4) The shortcomings of small scales are difficult to meet the testing requirements required for the mass production process. This creation has been greatly improved. Knowing the shortcomings of technology, no matter the cost-effectiveness, the reliability of the product, the mass production, and the test performance, the heat-testing device designed by the modular design is superior to the conventional heat pipe performance testing device. At the same time, it is more detailed in the measurement of various heat pipe performance parameters in the laboratory and mass production process. In summary, the present invention has indeed met the requirements of the invention patent, and has filed a patent application according to law. The above is only the preferred embodiment of the present invention, and it is not possible to limit the scope of the application of the present application. Equivalent modifications and modifications made by persons skilled in the art in light of the spirit of the present invention are intended to be included within the scope of the following claims. [Simple description of the drawing] The first figure is a schematic structural view of a conventional heat pipe performance detecting device. The second drawing is a perspective view of a first embodiment of the heat pipe performance detecting device of the present invention. The third figure is a perspective exploded view of the second figure.
第四圖(a)係第二圖中活動部之一外觀立體示意圖。 第四圖(b)係第二圖中固定部之一外觀立體示意圖。 第五圖(a)係本發明熱管性能檢測裝置第二實施例活動部之—立體圖 第丑圖⑻係本發明熱管性能檢測裝置第三實施例固定部之一立體圖 【主要元件符號說明】 承載部 10 第一板 14 支撐桿 15 固定部 20 散熱凹槽 24 定位槽 25, 絕熱底板 28 感溫線出π 284 定位散熱凹槽 32 定位柱 35 驅動部 40 量測槽孔 50 基體 12 防呆定位槽 145、285 第二板 16 冷卻液入出口接頭 22 定位孔 25 溫度感測器 26、36 導通槽 282 活動部 30 活動部蓋板 34 定位翼 35, 螺桿 42The fourth figure (a) is a perspective view showing the appearance of one of the movable parts in the second figure. The fourth figure (b) is a perspective view showing the appearance of one of the fixing portions in the second figure. Figure 5 (a) is a perspective view of a second embodiment of the heat pipe performance detecting device of the present invention. The ugly figure (8) is a perspective view of a fixing portion of the third embodiment of the heat pipe performance detecting device of the present invention. 10 First plate 14 Support rod 15 Fixing part 20 Heat sink groove 24 Positioning groove 25, Thermal insulation bottom plate 28 Temperature sensing line π 284 Positioning heat dissipation groove 32 Positioning post 35 Drive part 40 Measuring slot 50 Base body 12 Anti-staying positioning groove 145, 285 Second plate 16 Coolant inlet and outlet fittings 22 Positioning holes 25 Temperature sensor 26, 36 Conducting groove 282 Moving part 30 Moving part cover 34 Positioning wing 35, screw 42
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