TW201502457A - Vapor chamber structure and manufacturing method thereof - Google Patents

Abstract

Disclosed are a vapor chamber structure and a manufacture method thereof. The vapor chamber structure comprises a main body and working fluid. The main body comprises a condenser section, a vaporizer section, and a chamber. The condenser section and the vaporizer section are respectively arranged at two sides of the chamber. The vaporizer section comprises a first lateral face and a second lateral face, and the first lateral face comprises convex parts; the working fluid is filled in the chamber. The convex parts formed by mechanical treatment are employed as a supporting structure and enhance structure strength. The manufacture cost can be tremendously diminished.

Description

均溫板結構及其製造方法Temperature uniform plate structure and manufacturing method thereof

一種均溫板結構及其製造方法，尤指一種可大幅降低製造成本的均溫板結構及其製造方法。
The invention relates to a temperature equalizing plate structure and a manufacturing method thereof, in particular to a temperature equalizing plate structure capable of greatly reducing manufacturing cost and a manufacturing method thereof.

隨現行電子設備逐漸以輕薄作為標榜之訴求，故各項元件皆須隨之縮小其尺寸，但電子設備之尺寸縮小伴隨而來產生的熱變成電子設備與系統改善性能的主要障礙。無論形成電子元件的半導體尺寸不斷地縮小，仍持續地要求增加性能。
當半導體尺寸縮小，結果熱通量增加，熱通量增加所造成將產品冷卻的挑戰超過僅僅是全部熱的增加，因為熱通量的增加造成在不同時間和不同長度尺寸會過熱，可能導致電子故障或損毀。
　 故習知業者為解決上述習知技術因散熱空間狹小之問題，故以一種VC(Vapor chamber)Heat Sink置於chip上方作為散熱器使用，為了增加毛細極限，利用銅柱coating燒結、燒結柱、發泡柱等毛細結構用以支撐作為回流道，但由於微均溫板上下壁厚較薄(1.5mm以下應用)，利用上述此毛細結構作為支撐之習知結構於應用在微均溫板上，會造成該習知微均溫板在有銅柱、燒結柱或發泡柱之處才有支撐，而其餘未設有之處即形成塌限或凹陷，造成該微均溫板結構之整體平面度與強度無法維持，因此無法實現薄型化。
　 前述均溫板中之工作流體當由蒸發區域受熱域產生蒸發，工作流體由液態轉換為汽態，汽態之工作流體至均溫板之冷凝區域後由汽態冷凝轉化成為液態，再回流於蒸發區域繼續循環，均溫板之冷凝區域通常為光滑面，又或者為具有燒結之毛細結構態樣，汽態之工作流體在該冷凝區域冷凝成液態小水珠狀後，因重力或毛細結構之關係使得可回流至蒸發區域，但前述習知冷凝區域之結構由於係呈光滑面，致使冷凝後之液態水珠需儲至一定容積方才依重力垂滴，造成其回流效率實顯不足，且因液態工作流體回流速率過慢，使得蒸發區域中無工作流體而產生乾燒之狀態，令熱傳導效率大幅降低；若為加強工作流體之回流效率則增設毛細結構則為習知不可或缺之結構，但此一毛細結構(如燒結體或網格)之設置則令均溫板無法實現薄型化之功效。
　　 薄型化熱板主要係透過蝕刻之方式於該板體開設溝槽做毛細結構或於板體上形成支撐結構，但由於蝕刻之缺點為精度不佳，以及加工時耗費時間，令薄型化熱板或均溫板製造成本無法降低。
With the current gradual appeal of electronic devices, all components must be reduced in size, but the heat generated by the shrinking of electronic devices has become a major obstacle to the improvement of performance of electronic devices and systems. Regardless of the ever-shrinking size of semiconductors forming electronic components, there is a continuing demand for increased performance.
As semiconductors shrink in size, the resulting heat flux increases, and the increase in heat flux causes the challenge of cooling the product more than just the increase in total heat, as the increase in heat flux causes overheating at different times and lengths, possibly leading to electrons. Failure or damage.
Therefore, in order to solve the above-mentioned conventional technology, the known technology has a problem of narrow heat dissipation space. Therefore, a VC (Vapor chamber) Heat Sink is placed above the chip as a heat sink. In order to increase the capillary limit, a copper column is used for coating sintering and sintering. A capillary structure such as a foaming column is used as a backflow path, but since the thickness of the lower and lower walls of the micro-average temperature is thin (application of 1.5 mm or less), the conventional structure using the above-described capillary structure as a support is applied to the micro-average temperature plate. , which will cause the conventional micro-average temperature plate to have support in the presence of a copper column, a sintered column or a foaming column, and the remaining portions are not formed to form a collapse limit or a depression, resulting in the overall structure of the micro-average temperature plate. The flatness and strength cannot be maintained, so thinning cannot be achieved.
The working fluid in the above-mentioned temperature equalizing plate evaporates from the heated domain in the evaporation zone, and the working fluid is converted from the liquid state to the vapor state, and the working fluid in the vapor state is converted into a liquid state by vapor condensation and then refluxed. The evaporation zone continues to circulate, and the condensation zone of the temperature equalization plate is usually a smooth surface, or has a sintered capillary structure, and the vaporous working fluid condenses into a liquid small water droplet shape in the condensation zone, due to gravity or capillary structure. The relationship is such that the structure can be returned to the evaporation zone, but the structure of the conventional condensation zone is smooth, so that the liquid water droplets after condensation need to be stored to a certain volume before being dripped by gravity, resulting in insufficient reflux efficiency. Because the liquid working fluid reflux rate is too slow, there is no working fluid in the evaporation zone to produce a dry burning state, which greatly reduces the heat conduction efficiency; if the reflow efficiency of the working fluid is strengthened, the addition of the capillary structure is an indispensable structure. However, the setting of such a capillary structure (such as a sintered body or a mesh) makes it impossible to achieve a thinning effect on the temperature equalizing plate.
The thinned hot plate mainly adopts etching to form a capillary structure on the plate body to form a capillary structure or form a support structure on the plate body, but the shortcoming of the etching is poor precision, and the processing takes time, and the thinned hot plate is made. Or the production cost of the uniform temperature plate cannot be reduced.

爰此，為解決上述習知技術之缺點，本發明之主要目的，係提供一種可降低製造成本的均溫板結構。
本發明另一目地係提供一種可大幅降低均溫板製造成本的均溫板製造方法。
為達上述目的本發明係提供一種均溫板結構，係包含：一本體、一凸部、一工作流體；
　所述本體具有一冷凝區及一蒸發區及一腔室，所述冷凝區及該蒸發區分設於該腔室之兩側；所述凸部係選擇由該蒸發部或冷凝區其中任一凸起所構形；所述工作流體填充於前述腔室內。
　 為達上述目的本發明係提供一種均溫板結構製造方法，係包含下列步驟：
提供一第一板體及一第二板體；
透過機械加工之方式選擇於前述第一、二板體其中任一或二者都成型至少一凸體；
將第一、二板體對應蓋合，將其四周圍封閉並進行抽真空與填入工作流體之作業。
為達上述目的本發明係提供一種均溫板結構製造方法，係包含下列步驟：
提供一扁平管體；
透過機械加工之方式於前述管體內部一側成型至少一凸體；
將該管體兩端封閉並進行抽真空與填入工作流體之作業。
透過本發明均溫板結構及其製造方法係可大幅降低均溫板之製造成本，並進一步可提升製造精度者。
Accordingly, in order to solve the above disadvantages of the prior art, the main object of the present invention is to provide a temperature equalizing plate structure which can reduce manufacturing costs.
Another object of the present invention is to provide a method for producing a uniform temperature plate which can greatly reduce the manufacturing cost of a uniform temperature plate.
In order to achieve the above object, the present invention provides a temperature equalizing plate structure, comprising: a body, a convex portion, and a working fluid;
The body has a condensation zone and an evaporation zone and a chamber, and the condensation zone and the evaporation zone are disposed on both sides of the cavity; the protrusions are selected by any one of the evaporation section or the condensation zone The configuration is configured; the working fluid is filled in the chamber.
In order to achieve the above object, the present invention provides a method for manufacturing a uniform temperature plate structure, which comprises the following steps:
Providing a first plate body and a second plate body;
Forming at least one protrusion by either or both of the first and second plates by mechanical processing;
The first and second plates are correspondingly closed, and the four surrounding portions are closed and vacuumed and filled with the working fluid.
In order to achieve the above object, the present invention provides a method for manufacturing a uniform temperature plate structure, which comprises the following steps:
Providing a flat tube;
Forming at least one protrusion on the inner side of the tube body by means of machining;
The ends of the tube are closed and vacuumed and filled with the working fluid.
According to the temperature equalizing plate structure and the manufacturing method thereof of the present invention, the manufacturing cost of the temperature equalizing plate can be greatly reduced, and the manufacturing precision can be further improved.

11‧‧‧本體
11a‧‧‧第一板體
11b‧‧‧第二板體
111‧‧‧凸部
1111‧‧‧凸體
1111a‧‧‧自由端
2‧‧‧工作流體
3‧‧‧毛細結構
112‧‧‧冷凝區
113‧‧‧發區
114‧‧‧腔室
11‧‧‧Ontology
11a‧‧‧First board
11b‧‧‧Second plate
111‧‧‧ convex
1111‧‧‧ convex
1111a‧‧‧Free end
2‧‧‧Working fluid
3‧‧‧Capillary structure
112‧‧‧Condensation zone
113‧‧‧
114‧‧‧ chamber

第1圖係為本發明均溫板結構第一實施例之立體分解圖；
第2圖係為本發明均溫板結構第一實施例之立體組合圖；
第3圖係為本發明均溫板結構第一實施例之剖視圖；
第4圖係為本發明均溫板結構第二實施例之剖視圖；
第5圖係為本發明均溫板結構第三實施例之剖視圖；
第6圖係為本發明均溫板結構第四實施例之剖視圖；
第7圖係為本發明均溫板結構製造方法第一實施例之步驟流程圖；
第8圖係為本發明均溫板結構製造方法第二實施例之步驟流程圖；
第9圖係為本發明均溫板結構製造方法第三實施例之步驟流程圖；
第10圖係為本發明均溫板結構製造方法第四實施例之步驟流程圖。

1 is an exploded perspective view of a first embodiment of a temperature equalizing plate structure of the present invention;
Figure 2 is a perspective assembled view of the first embodiment of the temperature equalizing plate structure of the present invention;
Figure 3 is a cross-sectional view showing a first embodiment of the temperature equalizing plate structure of the present invention;
Figure 4 is a cross-sectional view showing a second embodiment of the temperature equalizing plate structure of the present invention;
Figure 5 is a cross-sectional view showing a third embodiment of the temperature equalizing plate structure of the present invention;
Figure 6 is a cross-sectional view showing a fourth embodiment of the temperature equalizing plate structure of the present invention;
Figure 7 is a flow chart showing the steps of the first embodiment of the method for manufacturing a uniform temperature plate structure of the present invention;
Figure 8 is a flow chart showing the steps of the second embodiment of the method for manufacturing a uniform temperature plate structure of the present invention;
Figure 9 is a flow chart showing the steps of the third embodiment of the method for manufacturing a uniform temperature plate structure of the present invention;
Figure 10 is a flow chart showing the steps of the fourth embodiment of the method for manufacturing a uniform temperature plate structure of the present invention.

本發明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。
請參閱第1、2、3圖，係為本發明均溫板結構第一實施例之立體分解及組合與剖視圖，如圖所示，所述均溫板結構，係包含：一本體11、一凸部111、一工作流體2；
所述本體11具有一冷凝區112及一蒸發區113及一腔室114，並所述本體11更具有一第一板體11a及一第二板體11b所述第一、二板體11a、11b對應蓋合並共同界定前述腔室114，所述冷凝區112設於該第一板體11a一側，該蒸發區113設於該第二板體11b一側，即所述冷凝區112及該蒸發區113分設於該腔室114之兩側並相互對應。
所述凸部111係選擇由該蒸發區113或冷凝區112其中任一或二者(蒸發區113、冷凝區112)都凸起所構形，本實施例之所述凸部111係具有複數凸體1111，該等凸體1111係由該蒸發區113向相反該蒸發區113之方向延伸所構成，並該凸體1111具有一自由端1111a，該自由端1111a與前述冷凝區112連接，該本體11相鄰該等凸體1111之周邊處係對應呈凹狀，本實施例之該等凸體1111係透過壓浮花法所成型，故該等凸體1111之另一側係呈平坦狀，該工作流體2係填充於前述腔室114內。
　 請參閱第4圖，係為本發明均溫板結構第二實施例之剖視圖，如圖所示，本實施例係與前述第一實施例部分結構技術特徵相同，故在此將不再贅述，惟本實例與前述第一實施例之不同處係為所述蒸發區113之複數凸體1111相對之另一側係呈凹狀。
　 請參閱第5圖，係為本發明均溫板結構第三實施例之剖視圖，如圖所示，本實施例係與前述第一實施例部分結構技術特徵相同，故在此將不再贅述，惟本實例與前述第一實施例之不同處係為所述凸部111係具有複數凸體1111，該等凸體1111係由該冷凝區112向相反該冷凝區112之方向延伸所構成，該本體11相鄰該等凸體1111之周邊處係對應呈凹狀。
請參閱第6圖，係為本發明均溫板結構第四實施例之剖視圖，如圖所示，本實施例係與前述第一、二、三實施例部分結構技術特徵相同，故在此將不再贅述，惟本實例與前述第一、二、三實施例之不同處係為所述本體11係為一扁狀管體。
前述各實施例中係更具有一毛細結構3，所述毛細結構3係設於前述腔室114表面，即該等凸體1111與該冷凝區112間具有前述毛細結構3。
請參閱第7圖，係為本發明均溫板結構製造方法第一實施例之步驟流程圖，並一併參閱前述第1～6圖，如圖所示，所述均溫板結構製造方法，係包含下列步驟：
S1：提供一第一板體及一第二板體；
　 係提供一第一板體11a及一第二板體11b，所述第一、二板體11a、11b係為導熱性質較佳之材料，如銅或鋁材質。
S2：透過機械加工之方式選擇於前述第一、二板體其中任一成型至少一凸體；
　 係透過以機械加工之方式選擇於前述第一、二板體11a、11b其中任一上成型至少一凸體1111，所述機械加工係可選擇為沖壓加工或壓花加工或鍛造加工其中任一，所述沖壓加工亦可選擇以壓浮花法或壓模法或打凸法其中任一方式形成該凸體1111。
S3：將第一、二板體對應蓋合，將其四周圍封閉並進行抽真空與填入工作流體之作業。
將透過機械加工成型凸體1111後將第一、二板體11a、11b對應蓋合，並將該第一、二板體11a、11b以焊接或擴散接合之方式進行封閉，並進行抽真空以及填入工作流體2等作業。
請參閱第8圖，係為本發明均溫板結構製造方法第二實施例之步驟流程圖，並一併參閱第1～6圖，如圖所示，所述均溫板結構製造方法，係包含下列步驟：
S1：提供一第一板體及一第二板體；
　 S2：透過機械加工之方式選擇於前述第一、二板體其中任一成型至少一凸體；
　 S3：將第一、二板體對應蓋合，將其四周圍封閉並進行抽真空與填入工作流體之作業。
　 本實施例部分步驟係與前述第一實施例相同，故在此將不再贅述，惟本實施例與前述第一實施例之不同處係為所述步驟S2：透過機械加工之方式選擇於前述第一、二板體其中任一成型至少一凸體此一步驟後更具有一步驟S4：該第一、二板體相對應之一側成型毛細結構。
所述毛細結構3係可選用燒結粉末結構或置入網格體或開設溝槽之方式於該第一、二板體11a、11b另外設置毛細結構3。
請參閱第9圖，係為本發明均溫板結構製造方法第三實施例之步驟流程圖，並一併參閱第1～6圖，如圖所示，所述均溫板結構製造方法，係包含下列步驟：
A1：提供一扁平管體；
係提供至少一端為開放狀之扁平狀管體。
　A2：透過機械加工之方式於前述管體內部一側成型至少一凸體；
係透過以機械加工之方式選擇於前述管體內部一側成型至少一凸體1111，所述機械加工係可選擇為沖壓加工或壓花加工或鍛造加工其中任一，所述沖壓加工亦可選擇以壓浮花法或壓模法或打凸法其中任一方式形成該凸體1111。
　A3：將該管體兩端封閉並進行抽真空與填入工作流體之作業。
將透過機械加工成型凸體後該扁平管體呈開放狀之一端以焊接或擴散接合之方式進行封閉，並進行抽真空以及填入工作流體等作業。
請參閱第10圖，係為本發明均溫板結構製造方法第四實施例之步驟流程圖，並一併參閱第1～6圖，如圖所示，所述均溫板結構製造方法，係包含下列步驟：
A1：提供一扁平管體；
　A2：透過機械加工之方式於前述管體內部一側成型至少一凸體；
　A3：將該管體兩端封閉並進行抽真空與填入工作流體之作業。
本實施例部分步驟係與前述第三實施例相同，故在此將不再贅述，惟本實施例與前述第一實施例之不同處係為步驟A2：透過機械加工之方式於前述管體內部一側成型至少一凸體此一步驟後更具有一步驟A4：於該管體內部成型一毛細結構3，所述毛細結構3係可選用燒結粉末結構或置入網格體或開設溝槽之方式於該管體內部另外設置毛細結構3。
以上實施例中所述之機械加工均係可選擇為沖壓加工或壓花加工或鍛造加工或滾輾加工或刻印加工或鑄造加工等其中任一。
　 透過本發明之均溫板結構及其製造方法係可進一步提供一種可節省製造工時以及提升製造精度的均溫板結構以及製造方法。
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.
Please refer to Figures 1, 2 and 3, which are perspective exploded, combined and cross-sectional views of the first embodiment of the temperature equalizing plate structure of the present invention. As shown, the temperature equalizing plate structure comprises: a body 11 and a a convex portion 111, a working fluid 2;
The body 11 has a condensing area 112 and an evaporation area 113 and a chamber 114, and the body 11 further has a first plate body 11a and a second plate body 11b. The first and second plates 11a, 11b corresponds to the cover to jointly define the chamber 114, the condensation zone 112 is disposed on the side of the first plate body 11a, and the evaporation zone 113 is disposed on the side of the second plate body 11b, that is, the condensation zone 112 and the The evaporation zone 113 is disposed on both sides of the chamber 114 and corresponds to each other.
The convex portion 111 is selected to be convexly formed by either or both of the evaporation zone 113 or the condensation zone 112 (the evaporation zone 113 and the condensation zone 112). The convex part 111 of the embodiment has a plurality of a convex body 1111, the convex body 1111 is formed by extending the evaporation zone 113 in a direction opposite to the evaporation zone 113, and the convex body 1111 has a free end 1111a, and the free end 1111a is connected to the condensation zone 112. The protrusions 1111 are formed in a concave shape adjacent to the periphery of the protrusions 1111. The protrusions 1111 of the embodiment are formed by a pressure float method, so that the other side of the protrusions 1111 is flat. The working fluid 2 is filled in the chamber 114.
FIG. 4 is a cross-sectional view showing a second embodiment of the temperature equalizing plate structure of the present invention. As shown in the figure, the present embodiment is identical to the structural features of the first embodiment, and thus will not be further described herein. However, the difference between the present example and the first embodiment described above is that the other side of the plurality of convex bodies 1111 of the evaporation zone 113 is concave.
FIG. 5 is a cross-sectional view showing a third embodiment of the temperature equalizing plate structure of the present invention. As shown in the figure, the present embodiment is identical to the structural features of the first embodiment, and thus will not be described again. However, the difference between the present embodiment and the first embodiment is that the convex portion 111 has a plurality of convex bodies 1111, and the convex bodies 1111 are formed by extending the condensation region 112 in a direction opposite to the condensation region 112. The body 11 is adjacent to the periphery of the protrusions 1111 and has a concave shape.
Please refer to FIG. 6 , which is a cross-sectional view of a fourth embodiment of the temperature equalizing plate structure of the present invention. As shown in the figure, the present embodiment is identical to the technical features of the first, second and third embodiments, and thus will be It will not be described again, but the difference between this example and the foregoing first, second and third embodiments is that the body 11 is a flat tube.
In the foregoing embodiments, a capillary structure 3 is further disposed. The capillary structure 3 is disposed on the surface of the chamber 114, that is, the capillary structure 3 is disposed between the protrusions 1111 and the condensation region 112.
Please refer to FIG. 7 , which is a flow chart of the steps of the first embodiment of the method for manufacturing the uniform temperature plate structure of the present invention, and refer to the first to sixth figures, as shown in the figure, the manufacturing method of the uniform temperature plate structure, The system consists of the following steps:
S1: providing a first plate body and a second plate body;
A first plate body 11a and a second plate body 11b are provided. The first and second plate bodies 11a and 11b are made of a material having better thermal conductivity, such as copper or aluminum.
S2: selecting at least one protrusion formed by one of the first and second plates by mechanical processing;
Forming at least one protrusion 1111 on one of the first and second plates 11a, 11b by mechanical processing, the machining system may be selected from stamping or embossing or forging. The stamping process may also select the protrusion 1111 by any one of a pressure float method or a compression molding method or a convex method.
S3: The first and second plates are correspondingly closed, and the four surrounding portions are closed and vacuumed and filled with the working fluid.
After the male body 1111 is formed by machining, the first and second plates 11a and 11b are correspondingly closed, and the first and second plates 11a and 11b are closed by welding or diffusion bonding, and vacuuming is performed. Fill in the work fluid 2 and other operations.
Please refer to FIG. 8 , which is a flow chart of the steps of the second embodiment of the method for manufacturing the uniform temperature plate structure of the present invention, and refer to FIGS. 1 to 6 together, as shown in the figure, the manufacturing method of the uniform temperature plate structure is Contains the following steps:
S1: providing a first plate body and a second plate body;
S2: selecting at least one protrusion formed by one of the first and second plates by mechanical processing;
S3: The first and second plates are correspondingly closed, and the four surrounding portions are closed and vacuumed and filled with the working fluid.
The steps in this embodiment are the same as those in the foregoing first embodiment, and therefore will not be described again here. However, the difference between the embodiment and the first embodiment is the step S2: the above is selected by means of machining. The first and second plates are formed by at least one protrusion. After the step, there is a step S4: the first and second plates are formed on one side to form a capillary structure.
The capillary structure 3 may be additionally provided with a capillary structure 3 in the first and second plates 11a, 11b by using a sintered powder structure or by inserting a mesh body or opening a groove.
Please refer to FIG. 9 , which is a flow chart of the third embodiment of the method for manufacturing the temperature equalizing plate structure of the present invention, and refer to FIGS. 1 to 6 together, as shown in the figure, the manufacturing method of the uniform temperature plate structure is Contains the following steps:
A1: providing a flat tube;
A flat tube body having at least one end open is provided.
A2: forming at least one protrusion on the inner side of the tube body by means of machining;
Forming at least one protrusion 1111 by mechanically selecting one side of the inner side of the tube body, and the machining system may be selected from a stamping process or an embossing process or a forging process, and the press process may also be selected. The convex body 1111 is formed by any one of a pressure float method, a compression molding method, or a convex method.
A3: The ends of the tube are closed and vacuumed and filled with the working fluid.
After the convex body is machined, the flat tube is closed at one end of the flat tube by welding or diffusion bonding, and vacuuming and filling of the working fluid are performed.
Please refer to FIG. 10 , which is a flow chart of the steps of the fourth embodiment of the method for manufacturing the temperature equalizing plate structure of the present invention, and refer to FIGS. 1 to 6 together. As shown in the figure, the method for manufacturing the uniform temperature plate structure is Contains the following steps:
A1: providing a flat tube;
A2: forming at least one protrusion on the inner side of the tube body by means of machining;
A3: The ends of the tube are closed and vacuumed and filled with the working fluid.
The steps in this embodiment are the same as those in the foregoing third embodiment, and therefore will not be described again here. However, the difference between the present embodiment and the first embodiment is the step A2: the mechanical processing is performed inside the tube body. Forming at least one protrusion on one side. After the step, there is a step A4: forming a capillary structure 3 inside the tube body, and the capillary structure 3 can be selected from a sintered powder structure or placed in a mesh body or grooved. In a manner, a capillary structure 3 is additionally provided inside the tube body.
The machining described in the above embodiments may be selected from stamping or embossing or forging or tumbling or engraving or casting.
The uniform temperature plate structure and the manufacturing method thereof according to the present invention can further provide a temperature equalizing plate structure and a manufacturing method which can save manufacturing man-hours and improve manufacturing precision.

 

11‧‧‧本體 11‧‧‧Ontology

11a‧‧‧第一板體 11a‧‧‧First board

11b‧‧‧第二板體 11b‧‧‧Second plate

111‧‧‧凸部 111‧‧‧ convex

1111‧‧‧凸體 1111‧‧‧ convex

1111a‧‧‧自由端 1111a‧‧‧Free end

2‧‧‧工作流體 2‧‧‧Working fluid

3‧‧‧毛細結構 3‧‧‧Capillary structure

112‧‧‧冷凝區 112‧‧‧Condensation zone

113‧‧‧蒸發區 113‧‧‧Evaporation zone

114‧‧‧腔室 114‧‧‧ chamber

Claims (15)

一種均溫板結構，係包含：
一本體，具有一冷凝區及一蒸發區及一腔室，所述冷凝區及該蒸發區分設於該腔室之兩側；
一凸部，係選擇由該蒸發區或冷凝區其中任一凸起所構形；
一工作流體，填充於前述腔室內。A uniform temperature plate structure comprising:
a body having a condensation zone and an evaporation zone and a chamber, the condensation zone and the evaporation zone being disposed on both sides of the cavity;
a convex portion selected to be configured by any one of the evaporation zone or the condensation zone;
A working fluid is filled in the chamber. 如申請專利範圍第1項之所述均溫板結構，其中所述凸部係具有複數凸體，該等凸體係由該蒸發區向相反該蒸發區之方向延伸所構成，該本體相鄰該等凸體之周邊處係對應呈凹狀。The uniform temperature plate structure according to claim 1, wherein the convex portion has a plurality of convex bodies, and the convex system is formed by extending the evaporation region in a direction opposite to the evaporation region, the body being adjacent to the body The periphery of the convex body corresponds to a concave shape. 如申請專利範圍第1項之所述均溫板結構，其中所述凸部係具有複數凸體，該等凸體係由該冷凝區向相反該冷凝區之方向延伸所構成，該本體相鄰該等凸體之周邊處係對應呈凹狀。The uniform temperature plate structure according to claim 1, wherein the convex portion has a plurality of convex bodies, and the convex system is formed by extending the condensation region in a direction opposite to the condensation region, the body being adjacent to the body The periphery of the convex body corresponds to a concave shape. 如申請專利範圍第1項之所述均溫板結構，其中所述本體具有一第一板體及一第二板體所述第一、二板體對應蓋合並共同界定前述腔室，所述冷凝區設於該第一板體一側，該蒸發區設於該第二板體一側。The uniform temperature plate structure according to claim 1, wherein the body has a first plate body and a second plate body, and the first and second plate body corresponding covers jointly define the chamber, The condensation zone is disposed on a side of the first plate body, and the evaporation zone is disposed on a side of the second plate body. 如申請專利範圍第1項之所述均溫板結構，其中所述本體係為一扁狀管體。The uniform temperature plate structure as claimed in claim 1, wherein the system is a flat pipe body. 如申請專利範圍第2項之所述均溫板結構，其中所述凸體具有一自由端，該自由端係與該冷凝區相連接，即該等凸體與該冷凝區間具有前述毛細結構。The uniform temperature plate structure according to claim 2, wherein the convex body has a free end connected to the condensation zone, that is, the convex body and the condensation section have the aforementioned capillary structure. 如申請專利範圍第1項之所述均溫板結構，其中所述凸部係具有複數凸體，該等凸體係由該蒸發區向相反該蒸發區之方向延伸所構成，該本體相反該等凸體之另一側處係對應呈凹狀。The uniform temperature plate structure according to claim 1, wherein the convex portion has a plurality of convex bodies, and the convex system is formed by extending the evaporation region in a direction opposite to the evaporation region, and the body is opposite. The other side of the convex body is correspondingly concave. 如申請專利範圍第1項之所述均溫板結構，其中所述凸部係具有複數凸體，該等凸體係由該冷凝區向相反該冷凝區之方向延伸所構成，該本體相反該等凸體之另一側處係對應呈凹狀。The uniform temperature plate structure according to claim 1, wherein the convex portion has a plurality of convex bodies, and the convex system is formed by extending the condensation region in a direction opposite to the condensation region, and the body is opposite. The other side of the convex body is correspondingly concave. 如申請專利範圍第1項之所述均溫板結構，其中更具有一毛細結構，所述毛細結構設於前述腔室表面。The uniform temperature plate structure according to claim 1, wherein a capillary structure is further provided, and the capillary structure is disposed on the surface of the chamber. 一種均溫板結構製造方法，係包含下列步驟：
提供一第一板體及一第二板體；
透過機械加工之方式選擇於前述第一、二板體其中任一成型至少一凸體；
將第一、二板體對應蓋合，將其四周圍封閉並進行抽真空與填入工作流體之作業。A method for manufacturing a uniform temperature plate structure, comprising the following steps:
Providing a first plate body and a second plate body;
Forming at least one protrusion in any one of the first and second plates described above by mechanical processing;
The first and second plates are correspondingly closed, and the four surrounding portions are closed and vacuumed and filled with the working fluid. 如申請專利範圍第10項之所述均溫板結構製造方法，其中所述機械加工係選擇為沖壓加工或壓花加工或鍛造加工或滾輾加工或刻印加工或鑄造加工等其中任一。The method for manufacturing a uniform temperature plate structure according to claim 10, wherein the machining system is selected from the group consisting of press working or embossing or forging or rolling or engraving or casting. 如申請專利範圍第10項之所述均溫板結構製造方法，其中所述透過機械加工之方式選擇於前述第一、二板體其中任一成型至少一凸體此一步驟後更具有一步驟，於該第一、二板體相對應之一側成型毛細結構。The method for manufacturing a uniform temperature plate structure according to claim 10, wherein the step of mechanically processing is selected from the first and second plates to form at least one protrusion. And forming a capillary structure on one side of the first and second plates. 一種均溫板結構製造方法，係包含下列步驟：
提供一扁平管體；
透過機械加工之方式於前述管體內部一側成型至少一凸體；
將該管體兩端封閉並進行抽真空與填入工作流體之作業。A method for manufacturing a uniform temperature plate structure, comprising the following steps:
Providing a flat tube;
Forming at least one protrusion on the inner side of the tube body by means of machining;
The ends of the tube are closed and vacuumed and filled with the working fluid. 如申請專利範圍第13項之所述均溫板結構製造方法，其中所述透過機械加工之方式於前述管體內部一側成型至少一凸體此一步驟後更具有一步驟於該管體內部成型一毛細結構。The method for manufacturing a uniform temperature plate structure according to claim 13 , wherein the forming the at least one convex body on the inner side of the tubular body by means of machining is further stepped inside the tubular body. Form a capillary structure. 如申請專利範圍第13項之所述均溫板結構製造方法，其中所述機械加工係選擇為沖壓加工或壓花加工或鍛造加工或滾輾加工或刻印加工或鑄造加工等其中任一。The method for manufacturing a uniform temperature plate structure according to claim 13, wherein the machining system is selected from the group consisting of press working or embossing or forging processing or rolling processing or engraving processing or casting processing.