TWM562956U - Vapor chamber with runner constituted by embrossing - Google Patents
Vapor chamber with runner constituted by embrossing Download PDFInfo
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- TWM562956U TWM562956U TW106215015U TW106215015U TWM562956U TW M562956 U TWM562956 U TW M562956U TW 106215015 U TW106215015 U TW 106215015U TW 106215015 U TW106215015 U TW 106215015U TW M562956 U TWM562956 U TW M562956U
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F28—HEAT EXCHANGE IN GENERAL
- F28D—HEAT-EXCHANGE APPARATUS, NOT PROVIDED FOR IN ANOTHER SUBCLASS, IN WHICH THE HEAT-EXCHANGE MEDIA DO NOT COME INTO DIRECT CONTACT
- F28D15/00—Heat-exchange apparatus with the intermediate heat-transfer medium in closed tubes passing into or through the conduit walls ; Heat-exchange apparatus employing intermediate heat-transfer medium or bodies
- F28D15/02—Heat-exchange apparatus with the intermediate heat-transfer medium in closed tubes passing into or through the conduit walls ; Heat-exchange apparatus employing intermediate heat-transfer medium or bodies in which the medium condenses and evaporates, e.g. heat pipes
- F28D15/04—Heat-exchange apparatus with the intermediate heat-transfer medium in closed tubes passing into or through the conduit walls ; Heat-exchange apparatus employing intermediate heat-transfer medium or bodies in which the medium condenses and evaporates, e.g. heat pipes with tubes having a capillary structure
- F28D15/046—Heat-exchange apparatus with the intermediate heat-transfer medium in closed tubes passing into or through the conduit walls ; Heat-exchange apparatus employing intermediate heat-transfer medium or bodies in which the medium condenses and evaporates, e.g. heat pipes with tubes having a capillary structure characterised by the material or the construction of the capillary structure
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F28—HEAT EXCHANGE IN GENERAL
- F28D—HEAT-EXCHANGE APPARATUS, NOT PROVIDED FOR IN ANOTHER SUBCLASS, IN WHICH THE HEAT-EXCHANGE MEDIA DO NOT COME INTO DIRECT CONTACT
- F28D15/00—Heat-exchange apparatus with the intermediate heat-transfer medium in closed tubes passing into or through the conduit walls ; Heat-exchange apparatus employing intermediate heat-transfer medium or bodies
- F28D15/02—Heat-exchange apparatus with the intermediate heat-transfer medium in closed tubes passing into or through the conduit walls ; Heat-exchange apparatus employing intermediate heat-transfer medium or bodies in which the medium condenses and evaporates, e.g. heat pipes
- F28D15/0233—Heat-exchange apparatus with the intermediate heat-transfer medium in closed tubes passing into or through the conduit walls ; Heat-exchange apparatus employing intermediate heat-transfer medium or bodies in which the medium condenses and evaporates, e.g. heat pipes the conduits having a particular shape, e.g. non-circular cross-section, annular
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F28—HEAT EXCHANGE IN GENERAL
- F28F—DETAILS OF HEAT-EXCHANGE AND HEAT-TRANSFER APPARATUS, OF GENERAL APPLICATION
- F28F13/00—Arrangements for modifying heat-transfer, e.g. increasing, decreasing
- F28F13/06—Arrangements for modifying heat-transfer, e.g. increasing, decreasing by affecting the pattern of flow of the heat-exchange media
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- Life Sciences & Earth Sciences (AREA)
- Sustainable Development (AREA)
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- Thermal Sciences (AREA)
- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Cooling Or The Like Of Semiconductors Or Solid State Devices (AREA)
- Heat-Exchange Devices With Radiators And Conduit Assemblies (AREA)
Abstract
一種內凸紋構成流道之均溫板,包含有:一第一板,係定義一加熱區、一絕熱區以及一冷凝區;一第二板,結合於該第一板;一第一毛細材,設於該第二板或該第一板其中之一,且至少由該加熱區延伸至該絕熱區;以及一作動液;其中,該第一板面朝向該第二板之板面凸伸形成一內凸紋,該內凸紋係具有複數凸塊,該複數凸塊彼此相隔預定距離且有部分凸塊呈長形,前述呈長形的複數凸塊係沿複數預定路徑之兩側以間隔排列的方式形成複數流道,該複數流道係由該加熱區延伸經過該絕熱區而至冷凝區;該複數凸塊之末端係頂抵於該第一毛細材或該第二板。A temperature equalizing plate constituting a flow channel, comprising: a first plate defining a heating zone, an adiabatic zone and a condensation zone; a second plate coupled to the first plate; a first capillary a material disposed on one of the second plate or the first plate and extending from the heating zone to the heat insulating zone; and an actuating liquid; wherein the first plate surface is convex toward the surface of the second plate Extending to form an inner ridge, the inner rib has a plurality of bumps, the plurality of bumps are spaced apart from each other by a predetermined distance and a portion of the bumps are elongated, and the plurality of elongated bumps are along two sides of the predetermined path A plurality of flow channels are formed in a spaced-apart manner, the plurality of flow channels extending from the heating zone through the adiabatic zone to the condensation zone; the ends of the plurality of bumps are topped against the first capillary or the second plate.
Description
本創作係與均溫板(Vapor Chamber)有關,特別是指一種內凸紋構成流道之均溫板。This creation is related to the Vapor Chamber, and in particular refers to a temperature equalization plate in which the inner relief forms a flow path.
習知的均溫板,通常是由二板體相疊並於周圍焊接而於內部形成一密閉腔室,並在該密閉腔室內置入毛細結構及作動液,藉由該作動液的液態及汽態的轉換來達到均溫導熱的效果。The conventional temperature equalizing plate is usually formed by stacking two plates and welding around to form a closed chamber inside, and a capillary structure and an actuating liquid are built in the sealed chamber, and the liquid liquid of the actuating liquid is The vapor state is converted to achieve the effect of uniform temperature heat conduction.
我國公告第I476361號專利即揭露了一種均溫板毛細成型方法及其結構,其內部設有複數支撐凸體,而可以提供支撐強度,並達到均溫導熱的效果。然而,此種技術對於內部的汽態作動液以及液態作動液並沒有導流的效果,而是任其自由活動,無法有效提升導熱及均溫的效果。China Patent Publication No. I476361 discloses a method for forming a uniform temperature plate capillary and a structure thereof, which are provided with a plurality of supporting protrusions therein, and can provide support strength and achieve uniform temperature heat conduction effect. However, this technique has no effect of diverting the internal vaporous liquid and the liquid working fluid, but is free to move and cannot effectively improve the heat conduction and the uniform temperature.
本案申請人之前曾申請M532046號專利,係為具有液汽分離結構的均溫板,其主要提出了對液態作動液及汽態作動液的導流技術,藉以增加均溫板的導熱及均溫效果。然而,在實際使用時發現,此技術之汽態作動液通道除了兩端之外其餘側邊均為封閉,但事實上並沒有需要完全使其封閉,適度的開放同時適度的導流亦有助於汽態作動液的流通,而且,對於液態作動液的迴流而言,亦不一定需要如同此案的毛細材設置方式。The applicant of this case has previously applied for the M532046 patent, which is a temperature equalizing plate with a liquid-vapor separation structure. It mainly proposes a diversion technique for liquid actuating liquid and vaporous actuating liquid, thereby increasing the heat conduction and temperature uniformity of the uniform temperature plate. effect. However, in actual use, it has been found that the steam actuating channel of this technology is closed except for the two ends, but in fact there is no need to completely close it. Moderate opening and moderate diversion also help. In the flow of the vaporous actuating liquid, and for the reflux of the liquid actuating liquid, the capillary material setting method as in this case is not necessarily required.
習知均溫板大多沒有對內部的液態作動液及汽態作動液的導流技術,而即使有導流技術,對於讓液態作動液及汽態作動液的流動更為順暢的技術而言,尚有改善空間。Most of the conventional temperature-average plates do not have a diversion technique for the internal liquid working fluid and the vaporous liquid, and even if there is a diversion technique, the technology for making the liquid liquid and the vaporous liquid flow smoother is There is still room for improvement.
本創作之主要目的乃在於提供一種內凸紋構成流道之均溫板,其可對汽態作動液提供開放性的導流效果,亦即除了導流之外也容許汽態作動液由流道旁散出,可使得汽態作動液的流動更為順暢,此外,也可避免液態作動液在均溫板內因為汽態作動液的流動而產生飛濺效應。The main purpose of the present invention is to provide a temperature equalizing plate which constitutes a flow channel in the inner embossing, which can provide an open diversion effect to the vaporous actuating liquid, that is, allow the vaporous actuating liquid to flow in addition to the diversion flow. Dispersed by the road, the flow of the vaporous actuating liquid can be made smoother. In addition, the splashing effect of the liquid actuating liquid in the temperature equalizing plate due to the flow of the vaporous actuating liquid can be avoided.
為了達成上述目的,本創作提供一種內凸紋構成流道之均溫板,包含有:一第一板,係定義一加熱區、一絕熱區以及一冷凝區;一第二板,結合於該第一板,且該第一板與該第二板之間形成密閉的一容置空間;一第一毛細材,設於該第二板或該第一板其中之一,且至少由該加熱區延伸至該絕熱區;以及一作動液,填入該容置空間中;其中,該第一板面朝向該第二板之板面凸伸形成一內凸紋,該內凸紋係具有複數凸塊,該複數凸塊彼此相隔預定距離且有部分凸塊呈長形,前述呈長形的複數凸塊係沿複數預定路徑之兩側以間隔排列的方式形成複數流道,該複數流道係由該加熱區延伸經過該絕熱區而至冷凝區;該複數凸塊之末端係頂抵於該第一毛細材或該第二板。In order to achieve the above object, the present invention provides a temperature equalizing plate constituting a flow channel, comprising: a first plate defining a heating zone, an adiabatic zone and a condensation zone; and a second plate coupled to the a first plate, and a sealed space is formed between the first plate and the second plate; a first capillary material is disposed on one of the second plate or the first plate, and at least by the heating a region extending to the heat insulating region; and an activating liquid filled in the accommodating space; wherein the first plate surface protrudes toward the plate surface of the second plate to form an inner ridge, the inner rib has a plurality of a bump, the plurality of bumps are spaced apart from each other by a predetermined distance and a portion of the bumps are elongated, and the plurality of elongated bumps form a plurality of flow paths along the two sides of the plurality of predetermined paths at intervals, the complex flow path The heating zone extends through the adiabatic zone to the condensation zone; the ends of the plurality of bumps are topped against the first capillary or the second plate.
藉由該複數流道兩側的凸塊之間的間隔排列的間隙,可對汽態作動液提供開放性的導流效果,亦即除了導流之外也容許汽態作動液由流道旁散出,可使得汽態作動液的流動更為順暢,此外,也可避免液態作動液在均溫板內因為汽態作動液的流動而產生飛濺效應。By the gaps arranged between the bumps on both sides of the plurality of flow channels, an open flow guiding effect can be provided to the vaporous actuating liquid, that is, the vaporous actuating liquid is allowed to be bypassed by the flow path in addition to the diversion flow. Dispersion can make the flow of the vaporous actuating fluid smoother. In addition, the splashing effect of the liquid actuating liquid in the temperature equalizing plate due to the flow of the vaporous actuating liquid can be avoided.
為了詳細說明本創作之技術特點所在,茲舉以下之較佳實施例並配合圖式說明如後,其中:In order to explain in detail the technical features of the present invention, the following preferred embodiments are described below with reference to the following:
如第1圖至第6圖所示,本創作第一較佳實施例所提供之一種內凸紋構成流道之均溫板10,主要由一第一板11、一第二板21、一第一毛細材31、複數第二毛細材35以及一作動液所組成,其中:As shown in FIG. 1 to FIG. 6 , a first embodiment of the present invention provides a temperature equalizing plate 10 for forming a flow channel, which is mainly composed of a first plate 11 , a second plate 21 , and a first plate The first capillary material 31, the plurality of second capillary materials 35 and an operating fluid are composed of:
該第一板11,係定義一加熱區H、一絕熱區A以及一冷凝區C。The first plate 11 defines a heating zone H, an adiabatic zone A and a condensation zone C.
該第二板21,結合於該第一板11,且該第一板11與該第二板21之間形成密閉的一容置空間22。The second plate 21 is coupled to the first plate 11 , and a sealed receiving space 22 is formed between the first plate 11 and the second plate 21 .
該第一毛細材31,設於該第二板21,且由該加熱區H延伸至該絕熱區A再延伸至該冷凝區C。該第一毛細材31係可以為織網或銅粉燒結而成,於本第一實施例中係以織網為例,且該第一毛細材31係呈平面狀而覆蓋該加熱區H以及該絕熱區A。The first capillary material 31 is disposed on the second plate 21 and extends from the heating zone H to the heat insulating zone A to the condensation zone C. The first capillary material 31 may be formed by sintering a woven mesh or a copper powder. In the first embodiment, the woven mesh is taken as an example, and the first capillary material 31 is planar and covers the heating zone H and The adiabatic zone A.
該複數第二毛細材35,係呈長條形且具有預定厚度,設於該第一板11且接觸於該第一毛細材31,該複數第二毛細材35由該加熱區H經過該絕熱區A而延伸至該冷凝區C。該複數第二毛細材35可以選自纖維束、銅粉或織網,本實施例中以纖維束為例。該第二毛細材35的數量亦可以僅為一個,在均溫板為狹長形的狀態時,僅需要一個即可,由於狹長形均溫板係以圖式表示於本案第三實施例,因此於此容不以圖式表示之。The plurality of second capillary materials 35 are elongated and have a predetermined thickness, are disposed on the first plate 11 and are in contact with the first capillary material 31, and the plurality of second capillary materials 35 are heated by the heating zone H. Zone A extends to the condensation zone C. The plurality of second capillary materials 35 may be selected from a fiber bundle, a copper powder or a woven mesh. In the present embodiment, a fiber bundle is exemplified. The number of the second capillary materials 35 may be only one. When the temperature equalization plate is in an elongated state, only one need is needed. Since the elongated uniform temperature plate is shown in the drawings in the third embodiment of the present invention, This is not represented by a schema.
該作動液,係填入該容置空間22中。由於作動液係吸附於該第一毛細材31及該複數第二毛細材35中,圖式難以表示,且又為所屬技術領域中具有通常知識者所能理解之必要元件,因此容不以圖式表示之。The actuating liquid is filled into the accommodating space 22. Since the actuating liquid is adsorbed in the first capillary material 31 and the plurality of second capillary materials 35, the drawing is difficult to represent, and is an essential component that can be understood by those skilled in the art, and therefore cannot be illustrated. Expression.
其中,該第一板11面朝向該第二板21之板面凸伸形成一內凸紋12而位於該容置空間22中,該內凸紋12係具有複數凸塊121,該複數凸塊121彼此相隔預定距離且有部分凸塊121呈長形,前述呈長形的複數凸塊121係沿複數預定路徑之兩側以間隔排列的方式形成複數流道P,該複數流道P係由該加熱區H延伸經過該絕熱區A而至冷凝區C。而位於一該流道P一側的兩兩凸塊121之間的間隙G寬度係小於或等於該流道P的寬度,這個設計有助於引導汽態作動液能主要沿著流道P走,而僅有少量汽態作動液由該間隙G流出。該複數第二毛細材35係位於該複數流道P之中的部分流道P內。於本實施例中該內凸紋12雖然是以由該第一板11所形成者為例,然而,該內凸紋12也可以是以銅粉燒結而成形於該第一板11,並不以與該第一板11一體成形為限制。The inner surface of the first plate 11 protrudes toward the surface of the second plate 21 to form an inner ridge 12 in the accommodating space 22, the inner rib 12 has a plurality of bumps 121, and the plurality of bumps 121 are spaced apart from each other by a predetermined distance and a part of the bumps 121 are elongated. The plurality of elongated bumps 121 are formed in a plurality of channels along the two sides of the plurality of predetermined paths, and the plurality of flow paths P are formed by The heating zone H extends through the adiabatic zone A to the condensing zone C. The width of the gap G between the two protrusions 121 on one side of the flow channel P is less than or equal to the width of the flow channel P. This design helps to guide the vaporous actuating liquid to mainly follow the flow path P. Only a small amount of vaporous actuating fluid flows out of the gap G. The plurality of second capillary materials 35 are located in a portion of the flow path P among the plurality of flow paths P. In the embodiment, the inner rib 12 is exemplified by the first plate 11. However, the inner rib 12 may be formed by sintering the copper powder to the first plate 11, and It is restricted to be integrally formed with the first plate 11.
位於該加熱區H及該絕熱區A的該複數凸塊121之末端係頂抵於該第一毛細材31,位於該冷凝區C的該複數凸塊121係頂抵於該第二板21。The ends of the plurality of bumps 121 located in the heating zone H and the heat insulating zone A are in contact with the first capillary material 31, and the plurality of bumps 121 located in the condensation zone C are abutted against the second plate 21.
以上說明了本第一實施例的架構,接下來說明本第一實施例的工作狀態。The architecture of the first embodiment has been described above, and the operational state of the first embodiment will be described next.
請參閱第5圖,使用時,係將本第一實施例之均溫板10貼置於一發熱體(圖中未示)上,並且使該加熱區H對應該發熱體。在該發熱體發熱時,位於該加熱區H的第一毛細材31所吸附的作動液即受熱而蒸發為汽態,並經由該複數流道P以及未形成流道P的該複數凸塊121之間移動,而由該加熱區H經由該絕熱區A而移動至該冷凝區C。位於該冷凝區C的汽態作動液遇冷凝結成液態,再經由該複數第二毛細材35位於該冷凝區C的部分吸附,經由毛細現象快速的導流回該加熱區H。此外,液態作動液在流經該複數第二毛細材35時,也會經由該第一毛細材31藉由毛細現象而迴流至該加熱區H。藉此,即構成循環而達到均溫導熱的效果。Referring to Fig. 5, in use, the temperature equalizing plate 10 of the first embodiment is placed on a heating element (not shown), and the heating zone H corresponds to the heating element. When the heating element generates heat, the operating fluid adsorbed by the first capillary material 31 located in the heating zone H is heated to evaporate into a vapor state, and passes through the plurality of flow channels P and the plurality of bumps 121 in which the flow path P is not formed. Moving between and moving from the heating zone H to the condensation zone C via the adiabatic zone A. The vaporous actuating liquid located in the condensing zone C is condensed into a liquid state, and is adsorbed through the portion of the plurality of second capillary materials 35 located in the condensing zone C, and is quickly guided back to the heating zone H via the capillary phenomenon. Further, when the liquid operating fluid flows through the plurality of second capillary materials 35, it is also returned to the heating zone H by the capillary phenomenon through the first capillary material 31. Thereby, the cycle is formed to achieve the effect of uniform temperature heat conduction.
在前述工作狀態中,該複數流道P可以發揮對汽態作動液的導流效果,使得汽態作動液較容易的被引導至冷凝區C。而位於該複數流道P兩側的長形凸塊121,其彼此間的間隙G也可以讓汽態作動液略為的流出而呈現開放性的導流效果。因此,本創作之流道P並非在兩側完全封閉來完全導引汽態作動液的架構,而是讓汽態作動液可以有部分由該複數凸塊121之間的間隙G流出流道P,造成部分的汽態作動液仍然受到導引而其餘部分的汽態作動液流出流道P的效果,這樣可以讓汽態作動液大致上受到該複數流道P的導引的效果,使得汽態作動液在該複數流道P中移動的時候速度較為緩慢,較不容易對該第一毛細材31所吸附的液態作動液造成飛濺效應,而且又可使得汽態作動液的流動更為順暢。In the foregoing working state, the plurality of flow passages P can exert a flow guiding effect on the vaporous actuating liquid, so that the vaporous actuating liquid is relatively easily guided to the condensing zone C. The elongated bumps 121 located on both sides of the plurality of flow passages P, and the gap G between them can also cause the vaporous actuating liquid to slightly flow out to exhibit an open flow guiding effect. Therefore, the flow path P of the present creation is not completely closed on both sides to completely guide the structure of the vaporous actuating liquid, but allows the vaporous actuating liquid to partially flow out of the flow path P from the gap G between the plurality of bumps 121. , causing part of the vaporous actuating liquid to be guided and the remaining part of the vaporous actuating fluid to flow out of the flow path P, so that the vaporous actuating liquid is substantially guided by the complex flow path P, so that the steam When the moving liquid moves in the plurality of flow passages P, the speed is relatively slow, and it is less likely to cause a splash effect on the liquid working fluid adsorbed by the first capillary material 31, and the flow of the vaporous actuating liquid can be made smoother. .
請再參閱第7圖至第8圖,本創作第二較佳實施例所提供之一種內凸紋構成流道之均溫板10’,主要概同於前揭第一實施例,不同之處在於:Please refer to FIG. 7 to FIG. 8 again. A temperature equalizing plate 10 ′ for forming a flow channel is provided in the second preferred embodiment of the present invention, which is mainly similar to the first embodiment disclosed above. Lie in:
該第一毛細材31’除了覆蓋於該加熱區H’及該絕熱區A’之外,還進一步覆蓋於該冷凝區C’,該複數凸塊121’之末端則全部頂抵於該第一毛細材31’。The first capillary material 31' is further covered in the condensation zone C' except for the heating zone H' and the heat insulation zone A'. The ends of the plurality of bumps 121' are all offset to the first Capillary material 31'.
此外,本第二實施例中不設置該複數第二毛細材。Further, the plural second capillary material is not provided in the second embodiment.
本第二實施例之工作狀態係概同於前揭第一實施例,只不過位於該冷凝區C’的液態作動液的迴流乃是完全藉由該第一毛細材31’來導流至該加熱區H’。The working state of the second embodiment is similar to that of the first embodiment except that the reflow of the liquid operating fluid located in the condensation zone C' is completely guided to the first capillary 31'. Heating zone H'.
本第二實施例之其餘結構及所能達成之功效係概同於前揭第一實施例,容不贅述。The remaining structure of the second embodiment and the achievable functions are the same as those of the first embodiment, and are not described here.
請再參閱第9圖,本創作第三較佳實施例所提供之一種內凸紋構成流道之均溫板10’’,主要概同於前揭第一實施例,不同之處在於:Referring to FIG. 9, a temperature equalizing plate 10'' of the inner channel which constitutes the flow channel provided by the third preferred embodiment of the present invention is mainly similar to the first embodiment disclosed above, except that:
該第一毛細材31’’係為長條形且具有預定厚度,而由該加熱區H’’經過絕熱區A’’而延伸至該冷凝區C’’,且該第一毛細材31’’係位於該複數流道P’’之中的一流道P’’內。The first capillary material 31'' is elongated and has a predetermined thickness, and the heating zone H'' extends through the heat insulating zone A'' to the condensation zone C'', and the first capillary material 31' 'The system is located in the first-class track P'' of the complex flow path P''.
此外,本第三實施例中不設置該複數第二毛細材。Further, the plural second capillary material is not provided in the third embodiment.
本第三實施例之工作狀態係概同於前揭第一實施例,只不過位於該冷凝區C’’的液態作動液的迴流乃是完全藉由該第一毛細材31’’來導流至該加熱區H’’。The working state of the third embodiment is similar to that of the first embodiment, except that the recirculation of the liquid operating fluid located in the condensing zone C'' is completely guided by the first capillary 31''. To the heating zone H''.
本第三實施例之其餘結構及所能達成之功效係概同於前揭第一實施例,容不贅述。The remaining structure and the achievable functions of the third embodiment are the same as those of the first embodiment, and are not described here.
10‧‧‧內凸紋構成流道之均溫板
11‧‧‧第一板
12‧‧‧內凸紋
121‧‧‧凸塊
21‧‧‧第二板
22‧‧‧容置空間
31‧‧‧第一毛細材
35‧‧‧第二毛細材
A‧‧‧絕熱區
C‧‧‧冷凝區
G‧‧‧間隙
H‧‧‧加熱區
P‧‧‧流道
10’‧‧‧內凸紋構成流道之均溫板
121’‧‧‧凸塊
31’‧‧‧第一毛細材
A’‧‧‧絕熱區
C’‧‧‧冷凝區
H’‧‧‧加熱區
10’’‧‧‧內凸紋構成流道之均溫板
31’’‧‧‧第一毛細材
A’’‧‧‧絕熱區
C’’‧‧‧冷凝區
H’’‧‧‧加熱區
P’’‧‧‧流道10‧‧‧ Inner ridges form the average temperature plate of the flow channel
11‧‧‧ first board
12‧‧‧ inside relief
121‧‧‧Bumps
21‧‧‧ second board
22‧‧‧ accommodating space
31‧‧‧First capillary
35‧‧‧Second capillary
A‧‧‧Insulation zone
C‧‧‧Condensation zone
G‧‧‧ gap
H‧‧‧heating area
P‧‧‧ runner
10'‧‧‧ inner ridges form the average temperature plate of the flow channel
121'‧‧‧Bumps
31'‧‧‧First capillary
A'‧‧‧ insulated area
C'‧‧‧ Condensation zone
H'‧‧‧heating area
10''‧‧‧ inner ridges form the average temperature plate of the flow channel
31''‧‧‧First capillary
A''‧‧‧ insulated area
C''‧‧‧ Condensation Zone
H''‧‧‧heating area
P''‧‧‧ flow path
第1圖係本創作第一較佳實施例之立體圖。 第2圖係本創作第一較佳實施例之爆炸圖。 第3圖係沿第1圖中3-3剖線之剖視圖。 第4圖係本創作第一較佳實施例之局部放大圖。 第5圖係本創作第一較佳實施例之部分元件俯視圖,顯示第一板之結構。 第6圖係本創作第一較佳實施例之部分組合俯視圖,顯示第一毛細材覆蓋於第一板的狀態。 第7圖係本創作第二較佳實施例之部分元件立體圖,顯示第一毛細材覆蓋於第一板的結構。 第8圖係本創作第二較佳實施例類似第3圖視角之圖式。 第9圖係本創作第三較佳實施例之爆炸圖。Figure 1 is a perspective view of a first preferred embodiment of the present invention. Figure 2 is an exploded view of the first preferred embodiment of the present invention. Fig. 3 is a cross-sectional view taken along line 3-3 of Fig. 1. Figure 4 is a partially enlarged view of the first preferred embodiment of the present invention. Figure 5 is a plan view of a portion of the components of the first preferred embodiment of the present invention showing the structure of the first panel. Fig. 6 is a partially combined plan view showing the first preferred embodiment of the present invention, showing a state in which the first capillary material covers the first plate. Figure 7 is a perspective view of a part of the second preferred embodiment of the present invention, showing the structure in which the first capillary material covers the first plate. Fig. 8 is a view similar to the perspective of Fig. 3 of the second preferred embodiment of the present invention. Figure 9 is an exploded view of a third preferred embodiment of the present invention.
Claims (9)
Priority Applications (3)
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TW106215015U TWM562956U (en) | 2017-10-12 | 2017-10-12 | Vapor chamber with runner constituted by embrossing |
JP2017005014U JP3214513U (en) | 2017-10-12 | 2017-11-02 | Vapor chamber whose flow path has an inner convex pattern |
US15/821,987 US20190113290A1 (en) | 2017-10-12 | 2017-11-24 | Vapor chamber with inner ridge forming passage |
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TW106215015U TWM562956U (en) | 2017-10-12 | 2017-10-12 | Vapor chamber with runner constituted by embrossing |
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TWM562956U true TWM562956U (en) | 2018-07-01 |
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US20190113290A1 (en) | 2019-04-18 |
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