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TW202120881A - Ultra-thin vapor chamber and a manufacturing method thereof by welding and sealing the first metal plate with a thin and thermally conductive second metal plate after the sintering process, and then vacuumizing and injecting with a working fluid - Google Patents

Ultra-thin vapor chamber and a manufacturing method thereof by welding and sealing the first metal plate with a thin and thermally conductive second metal plate after the sintering process, and then vacuumizing and injecting with a working fluid Download PDF

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TW202120881A
TW202120881A TW108143703A TW108143703A TW202120881A TW 202120881 A TW202120881 A TW 202120881A TW 108143703 A TW108143703 A TW 108143703A TW 108143703 A TW108143703 A TW 108143703A TW 202120881 A TW202120881 A TW 202120881A
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TWI819157B (en
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秦文隆
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Abstract

The present invention relates to an ultra-thin vapor chamber and a manufacturing method thereof. The manufacturing method is to select a metal powder with good thermal conductivity, mix the aforementioned metal powder with good thermal conductivity with a solvent suitable for screen printing, print the aforementioned mixture by screen printing on a thin first metal plate with good thermal conductivity to form a support part having a predetermined height, area, and shape, then sinter the first metal plate of the aforementioned process to form the support part into a porous structure to be combined with the first metal plate, weld and seal the first metal plate with a thin and thermally conductive second metal plate after the aforementioned sintering process, and then perform vacuum pumping and inject a working fluid therein to form an ultra-thin vapor chamber. The aforementioned thermally conductive metal powder is copper powder. The first metal plate and the second metal plate are sealed by diffusion welding.

Description

超薄型均溫板及其製造方法 Ultra-thin temperature equalizing plate and manufacturing method thereof

本發明屬均溫散熱技術領域,特別係指一種超薄型均溫板及其製造方法嶄新設計,具有環保製程及高效率均溫功效。 The invention belongs to the technical field of uniform temperature and heat dissipation, and particularly refers to a new design of an ultra-thin uniform temperature plate and a manufacturing method thereof, which has an environmentally friendly manufacturing process and a high-efficiency uniform temperature effect.

按,習用電子元件的散熱大都採用金屬散熱片,或結合熱導管、致冷晶片、散熱風扇等方式為之,普遍具有散熱效果不佳、散熱速度不夠迅速、散熱模組結構複雜、成本高等缺失。 According to the heat dissipation of conventional electronic components, most of them use metal heat sinks, or combine heat pipes, cooling chips, cooling fans, etc., which generally suffer from poor heat dissipation, insufficient heat dissipation speed, complex heat dissipation module structure, and high cost. .

而熱管這項技術早在1963年就在位於美國的LosAlamos國家實驗室中誕生了。其發明人是G.M.Grover。熱管屬於一種傳熱元件,它充分利用了熱傳導原理與致冷介質的快速熱傳遞性質,透過熱管將發熱物體的熱量迅速傳遞到熱源外,其導熱能力已遠遠超過任何已知金屬的導熱能力。以前熱管技術一直被廣泛應用在航太、軍工等行業,被引入散熱器製造業還是近幾年的事情。熱管技術為什麽會有如此的高性能呢?這個問題我們要從熱力學的角度看。物體的吸熱、放熱是相對的,凡是有溫度差存在的時候,就必然出現熱從高溫處向低溫處傳遞的現象。熱傳遞有3種方式:輻射、對流、傳導,其中熱傳導最快。熱管就是利用蒸發製冷,使得熱管兩端溫度差很小,使熱量快速傳導。常見的熱管均是由管殼、吸液芯和端蓋組成。製作方法是將熱管內部抽成負壓狀態,然後充入適當的液體,這種液體沸點很低,容易揮發。管壁有吸液芯,由毛細多孔材料構成。熱 管一端為蒸發端,另外一端為冷凝端。當熱管一段受熱時,毛細管中的液體迅速蒸發,蒸氣在微小的壓力差下流向另外一端,並且釋放出熱量,重新凝結成液體。液體再沿多孔材料靠毛細力的作用流回蒸發段,如此迴圈不止。熱量由熱管一端傳至另外一端,這種迴圈是快速進行的,熱量可以被源源不斷地傳導開來。然而,現行鰭片式散熱器在熱量傳導上之效率不彰,無法瞬間吸收大量熱量為其缺失,如何結合熱管與鰭片式散熱器來提升散熱效率,乃有均溫板之發明。如我國專利M255446號平板型擴熱板(2005年01月11日專利公告資料參照),其主要包括有一對導熱良好的殼體,該對殼體一側具有開口,內具有適當數量的支柱,並形成有氣流通道,該殼體內緣燒結有一層多孔性導熱良好的粉末層,並藉封蓋密封,使殼體內部形成複數個交錯的管狀通道,且經注入工作流體並抽真空,使該金屬粉末層吸附有工作流體,而構成平板型擴熱板。惟,習用均溫板係在二殼體內或燒結有導熱性良好的粉末、或設置導熱性良好的金屬網所構成,雖然均具有擴熱均溫的效能,但在現今使用於4G機房的電子元件,其可能在瞬間因為大流量產生瞬間高熱,習用均溫板的結構,其熱擴散均溫的速度不夠快速,將會導致電子元件過熱當機或損壞的缺失。申請人先前申請一種均溫元件(公告號M494289),其主要包括有一對導熱佳金屬構成之殼體,該對殼體內部並具有一工作空間,工作空間內具有適當數量的導熱柱連結該對殼體,藉密封該對殼體,使殼體內部形成複數個交錯的通道,再經抽真空並注入適量工作流體,而構成均溫板,其特徵在於:該導熱柱為導熱佳之粉末構成多孔洞結構,藉該多孔洞結構之導熱柱吸附工作流體,在工作時具有更佳的毛細現象,確能加速溫度之擴散,具有更高效率的均溫效果。 The heat pipe technology was born in Los Alamos National Laboratory in the United States as early as 1963. Its inventor is G.M. Grover. The heat pipe is a kind of heat transfer element, which makes full use of the principle of heat conduction and the fast heat transfer properties of the refrigerating medium. The heat of the heating object is quickly transferred to the heat source through the heat pipe. Its thermal conductivity has far exceeded the thermal conductivity of any known metal. . In the past, heat pipe technology has been widely used in aerospace, military industry and other industries, and it is only a few years ago that it was introduced into the radiator manufacturing industry. Why does heat pipe technology have such high performance? We have to look at this issue from the perspective of thermodynamics. The heat absorption and heat release of an object are relative. Whenever there is a temperature difference, the phenomenon of heat transfer from a high temperature to a low temperature will inevitably occur. There are three ways of heat transfer: radiation, convection, and conduction, of which heat conduction is the fastest. The heat pipe uses evaporative cooling, so that the temperature difference between the two ends of the heat pipe is small, and the heat is quickly transferred. Common heat pipes are composed of a tube shell, a wick and an end cap. The production method is to pump the inside of the heat pipe into a negative pressure state, and then fill it with an appropriate liquid, which has a very low boiling point and is easy to volatilize. The tube wall has a wick, which is made of capillary porous material. heat One end of the tube is the evaporating end, and the other end is the condensing end. When a section of the heat pipe is heated, the liquid in the capillary tube evaporates quickly, and the vapor flows to the other end under a slight pressure difference, releases heat, and recondenses into a liquid. The liquid flows back to the evaporation section along the porous material by capillary force, and the loop is endless. The heat is transferred from one end of the heat pipe to the other end. This loop is carried out quickly, and the heat can be continuously conducted away. However, the current fin-type radiator is inefficient in heat conduction, and it cannot absorb a large amount of heat instantly. It is the invention of how to combine the heat pipe and the fin-type radiator to improve the heat dissipation efficiency. For example, China's patent No. M255446 flat heat expansion plate (refer to the patent announcement data on January 11, 2005), which mainly includes a pair of shells with good heat conduction. The pair of shells has an opening on one side and an appropriate number of pillars. An air flow channel is formed. The inner edge of the shell is sintered with a porous powder layer with good heat conduction, and sealed by a cover, so that a plurality of staggered tubular channels are formed inside the shell, and the working fluid is injected and vacuumed to make the The metal powder layer adsorbs the working fluid to form a flat plate type heat spreading plate. However, the conventionally used uniform temperature plate is composed of sintered powder with good thermal conductivity or a metal mesh with good thermal conductivity in the two shells. Although both have the effect of expanding heat and uniform temperature, they are currently used in the electronics of 4G computer rooms. Components, which may generate instantaneous high heat due to large flow in an instant, the structure of the conventional uniform temperature plate, the speed of heat diffusion and uniform temperature is not fast enough, will cause the electronic components to overheat and crash or be damaged. The applicant previously applied for a temperature equalizing element (Announcement No. M494289), which mainly includes a pair of shells made of metal with good heat conduction. The pair of shells has a working space inside, and the working space has an appropriate number of heat conducting columns to connect the pair The shell, by sealing the pair of shells, forms a plurality of staggered channels inside the shell, and then evacuates and injects an appropriate amount of working fluid to form a uniform temperature plate, which is characterized in that the heat conduction column is made of powder with good heat conduction. The porous structure, through the use of the porous structure of the heat conduction column to absorb the working fluid, has better capillary phenomenon during work, can indeed accelerate the temperature diffusion, and has a more efficient temperature uniformity effect.

再者,熱管類產品(包含均溫板),係藉由內部工作流體液汽相變化及流動傳熱,其熱傳導與擴散能力優於目前已知相同尺寸的所有材料。若能將熱管類產品導入現行輕薄化的行動裝置產品中,利用其均溫之特性使高發熱晶片產生之廢熱快速由熱管方向擴散,將可使系統運作更為穩定。但輕薄化行動裝置產品的散熱模組,常使用之熱管直徑大多為6mm或8mm,此直徑甚至比行動裝置還厚,另外傳統之均溫板厚度亦超過2~3mm,因此無法直接使用於行動裝置上,必須透過薄型化之工藝,才有機會導入空間有限之行動裝置中。有鑑於行動裝置之散熱需求,近年來有許多熱管廠商不斷投入開發薄型化之熱管或均溫板產品,做為未來產業發展方向,並發表了厚度小於1mm之超薄型熱管或均熱板。熱管與均溫板運作原理大同小異,因此其設計原則幾乎是一樣的。不過,相較於薄型化熱管寬度有限,僅能於一維長度方向上改變之狀況。薄型化均溫板的優勢則是其面積可依需求而改變,因此設計上之變化度非常高,可視為二維方向之均溫體。例如工研院以微機電製程開發矽基薄型化均溫板,其係利用矽晶圓為基板蝕刻出微米級毛細結構,亦有其它業者以蝕刻製程製備傳統金屬均溫板,惟因為蝕刻製程所採用的蝕刻液非常不環保為其缺失,如何以其它不破壞環境的環保製程來薄型化均溫板,乃成業界亟待克服之難題。 In addition, heat pipe products (including temperature equalizing plates) use internal working fluid liquid-vapor phase change and flow heat transfer, and their heat conduction and diffusion capabilities are better than all currently known materials of the same size. If heat pipe products can be introduced into the current thinner and lighter mobile device products, using their uniform temperature characteristics to quickly diffuse the waste heat generated by the high-heating chip from the heat pipe direction, the system operation will be more stable. However, in the heat dissipation modules of light and thin mobile device products, most of the heat pipes commonly used have a diameter of 6mm or 8mm, which is even thicker than that of mobile devices. In addition, the thickness of traditional uniform temperature plates is also more than 2~3mm, so they cannot be directly used in mobile devices. On the device, it must be thinned to have the opportunity to be introduced into mobile devices with limited space. In view of the heat dissipation needs of mobile devices, in recent years, many heat pipe manufacturers have continuously invested in the development of thinner heat pipes or uniform temperature plate products, as the future industry development direction, and released ultra-thin heat pipes or uniform heat plates with a thickness of less than 1mm. The operating principles of the heat pipe and the uniform temperature plate are similar, so the design principles are almost the same. However, compared with the limited width of the thinned heat pipe, it can only be changed in the one-dimensional length direction. The advantage of the thinner temperature equalizing plate is that its area can be changed according to the requirements, so the degree of change in the design is very high, which can be regarded as a two-dimensional temperature equalizing body. For example, the Industrial Technology Research Institute develops a silicon-based thin-type uniform temperature plate using a micro-electromechanical process. It uses silicon wafers as the substrate to etch micron-level capillary structures. Other companies also use etching processes to prepare traditional metal uniform temperature plates, but because of the etching process The etching solution used is not environmentally friendly and it is lacking. How to use other environmentally friendly manufacturing processes to thin the temperature equalizing plate is a problem that the industry needs to overcome urgently.

本發明發明人鑒於前述習用技術之缺失,積其多年實際從事精密陶瓷科技工業產品之設計製造專業知識,經不斷研究、改良後,終有本發明之研發成功,公諸於世。 In view of the aforementioned shortcomings of the conventional technology, the inventor of the present invention has been engaged in the design and manufacture of precision ceramic technology industrial products for many years. After continuous research and improvement, the present invention has finally been successfully developed and made public.

緣是,本發明之主要目的在提供一種超薄型均溫板製造方 法,其製造方法為選用導熱佳金屬粉末(以較粗顆粒為較佳),將前述導熱佳金屬粉末與適用於網版印刷溶劑混合,以網板印刷方式將前述混合物印刷於薄型導熱佳之第一金屬板上,形成預定高度、面積、形狀之支撐部,燒結前述製程第一金屬板,使支撐部形成多孔性結構並與第一金屬板結合,將前述製程燒結後的第一金屬板與薄型導熱佳之第二金屬板焊接封閉,再經抽真空及注入工作流體後製成超薄型均溫板。 The reason is that the main purpose of the present invention is to provide an ultra-thin uniform temperature plate manufacturing method The manufacturing method is to select metal powder with good thermal conductivity (preferably coarser particles), mix the aforementioned metal powder with good thermal conductivity with a solvent suitable for screen printing, and print the aforementioned mixture on a thin, good thermal conductivity by screen printing. On a metal plate, a support portion of predetermined height, area, and shape is formed, and the first metal plate of the aforementioned process is sintered, so that the support portion forms a porous structure and is combined with the first metal plate, and the first metal plate after the aforementioned process is sintered with The thin second metal plate with good heat conduction is welded and closed, and then vacuumized and injected with working fluid to form an ultra-thin uniform temperature plate.

本發明前述第二金屬板內端面上先以導熱佳金屬粉末燒結一多孔結構層,再與第一金屬板焊接封閉,以增加擴熱均溫效率。 In the present invention, the inner end surface of the second metal plate is firstly sintered with a porous structure layer with metal powder with good thermal conductivity, and then welded and sealed with the first metal plate to increase the efficiency of heat expansion and temperature uniformity.

本發明前述導熱佳金屬粉末為銅粉。 The aforementioned metal powder with good thermal conductivity is copper powder.

本發明前述第一金屬板與第二金屬板係以擴散焊接方式封閉。 The aforementioned first metal plate and the second metal plate of the present invention are closed by diffusion welding.

本發明之另一主要目的在提供一種超薄型均溫板,其主要包括有薄型導熱佳之第一金屬板與第二金屬板,第一金屬板與第二金屬板間具有工作空間,第一金屬板內緣具有以網版印刷構成預定高度、面積、形狀之支撐部,該支撐部為導熱佳金屬粉末燒結成多孔性結構,前述支撐部在密封第一金屬板與第二金屬板時並焊接於第二金屬板相對內緣,藉密封第一金屬板與第二金屬板,使第一金屬板與第二金屬板內部工作空間形成複數個交錯的通道,再經抽真空並注入適量工作流體,而構成超薄型均溫板,由於該支撐部為導熱佳之粉末燒結構成多孔洞結構,藉該多孔洞結構支撐部吸附工作流體,在工作時具有更佳的毛細現象,以加速溫度之擴散,具有更高效率的均溫效果。 Another main purpose of the present invention is to provide an ultra-thin uniform temperature plate, which mainly includes a thin first metal plate and a second metal plate with good heat conduction. There is a working space between the first metal plate and the second metal plate. The inner edge of the metal plate has a support part with a predetermined height, area, and shape formed by screen printing. The support part is a porous structure sintered with metal powder with good thermal conductivity. The support part is combined when sealing the first metal plate and the second metal plate. Welded to the opposite inner edge of the second metal plate, by sealing the first metal plate and the second metal plate, the inner working space of the first metal plate and the second metal plate form a plurality of staggered channels, and then evacuated and injected with proper amount of work Fluid to form an ultra-thin uniform temperature plate. Since the supporting part is a porous structure formed by sintering powder with good heat conduction, the porous structure supporting part absorbs the working fluid and has better capillary phenomenon during work to accelerate the temperature. Diffusion, with a more efficient uniform temperature effect.

本發明前述第二金屬板內端面具有以導熱佳金屬粉末燒結 構成之多孔結構層,以增加擴熱均溫效率。 The inner end surface of the aforementioned second metal plate of the present invention has a metal powder sintered with good thermal conductivity The porous structure layer is formed to increase the efficiency of heat expansion and temperature uniformity.

本發明前述導熱佳金屬粉末為銅粉。 The aforementioned metal powder with good thermal conductivity is copper powder.

(1)‧‧‧超薄型均溫板 (1)‧‧‧Ultra-thin uniform temperature plate

(2)‧‧‧第1金屬板 (2)‧‧‧The first metal plate

(3)‧‧‧第2金屬板 (3)‧‧‧Second metal plate

(30)‧‧‧多孔結構層 (30)‧‧‧Porous structure layer

(4)‧‧‧工作空間 (4)‧‧‧Working space

(40)‧‧‧通道 (40)‧‧‧Channel

(5)‧‧‧支撐部 (5)‧‧‧Support

第1圖係本發明實施例上視圖; Figure 1 is a top view of an embodiment of the present invention;

第2圖係本發明實施例部份組立剖面圖; Figure 2 is a partial assembly sectional view of the embodiment of the present invention;

第3圖係本發明另一實施例部份組立剖面圖。 Fig. 3 is a partial assembly sectional view of another embodiment of the present invention.

為達成本發明前述目的之技術手段,茲列舉一實施例,並配合圖式說明如後,貴審查委員可由之對本發明之方法、結構、特徵及所達成之功效,獲致更佳之瞭解。 In order to achieve the above-mentioned technical means of the invention, here is an example, with the description of the drawings as follows, from which your reviewer can gain a better understanding of the method, structure, features and effects achieved by the invention.

本發明超薄型均溫板,通常係指如厚度在1mm以下,亦有具有可撓(彎曲)性者,稱之為軟性均溫板,可適用於手機等輕薄化行動裝置。 The ultra-thin temperature equalizing plate of the present invention generally refers to those having a thickness of less than 1 mm and also have flexibility (bendability), which is called a soft temperature equalizing plate, which can be applied to light and thin mobile devices such as mobile phones.

本發明超薄型均溫板製造方法,其製造方法為: The manufacturing method of the ultra-thin uniform temperature plate of the present invention is as follows:

選用選用導熱佳金屬粉末(以較粗顆粒為較佳); Use metal powder with good thermal conductivity (coarse particles are better);

將前述導熱佳金屬粉末與適用於網版印刷溶劑混合; Mix the aforementioned metal powder with good thermal conductivity with a solvent suitable for screen printing;

以網板印刷方式將前述混合物印刷於薄型導熱佳之第一金屬板上,形成預定高度、面積、形狀之支撐部(如第1圖所示支撐部的形狀、面積,該支撐部的形狀、面積等,係配合待貼合均溫部件設計); The aforementioned mixture is printed on a thin first metal plate with good thermal conductivity by screen printing to form a support portion of predetermined height, area, and shape (like the shape and area of the support portion shown in Figure 1, the shape and area of the support portion Etc., it is designed to cooperate with the temperature equalizing parts to be bonded);

燒結前述製程第一金屬板,使支撐部形成多孔性結構並與第一金屬板結合,並將網版印刷混入溶劑燒除,藉該多孔結構支撐部吸附工作流體,在工作時具有更佳的毛細現象,以加速溫度之擴散,具有更高效 率的均溫效果,此外該支撐部可避免後續在進行均溫板內部的抽真空除氣作業而使第一金屬板與第二金屬板表面產生凹陷,防止均溫板在與電子發熱元件表面接觸時因前述凹陷問題而無法達到面與面的平整接觸,進而影響熱導效率; Sintering the first metal plate of the aforementioned process to form a porous structure on the support part and combine it with the first metal plate, and mix the screen printing into the solvent to burn off, and the porous structure support part absorbs the working fluid, and has better performance during work. Capillary phenomenon to accelerate the diffusion of temperature, with more efficient In addition, the supporting part can avoid the subsequent vacuuming and degassing operation inside the uniform temperature plate, which will cause the surface of the first metal plate and the second metal plate to dent, and prevent the uniform temperature plate from contacting the surface of the electronic heating element. During the contact, due to the aforementioned depression problem, the surface-to-surface smooth contact cannot be achieved, which affects the thermal conductivity efficiency;

將前述製程燒結後的第一金屬板與薄型導熱佳之第二金屬板焊接封閉; Welding and sealing the first metal plate sintered by the aforementioned manufacturing process and the thin, thermally conductive second metal plate;

再經抽真空及注入工作流體後製成超薄型均溫板。 After vacuuming and injecting working fluid, an ultra-thin uniform temperature plate is made.

本發明前述第二金屬板內端面上先以導熱佳金屬粉末燒結一多孔結構層,再與第一金屬板焊接封閉,以增加擴熱均溫效率。 In the present invention, the inner end surface of the second metal plate is firstly sintered with a porous structure layer with metal powder with good thermal conductivity, and then welded and sealed with the first metal plate to increase the efficiency of heat expansion and temperature uniformity.

本發明前述導熱佳金屬粉末為銅粉。 The aforementioned metal powder with good thermal conductivity is copper powder.

本發明前述第一金屬板與第二金屬板係以擴散焊接方式封閉。擴散焊接(Diffusion Bonding Technology)是一種固態接合技術,在真空環境下利用高溫及壓力使兩件工件的接觸面之間的距離達到原子間距,令原子間相互嵌入擴散結合,從而接合金屬及或陶瓷部件。相對傳統的焊接技術,擴散焊接能令接合面更堅固及減少變形情況。 The aforementioned first metal plate and the second metal plate of the present invention are closed by diffusion welding. Diffusion Bonding Technology is a solid-state bonding technology that uses high temperature and pressure in a vacuum environment to make the distance between the contact surfaces of two workpieces reach the atomic distance, so that the atoms are embedded and diffused and bonded to each other to bond metals and or ceramics. part. Compared with traditional welding technology, diffusion welding can make the joint surface stronger and reduce deformation.

請參閱第1圖之本發明實施例上視圖及第2圖之本發明實施例部份組立剖面圖,由圖可知本發明超薄型均溫板(1),其主要包括有薄型導熱佳之第一金屬板(2)與第二金屬板(3),第一金屬板(2)與第二金屬板(3)間具有工作空間(4),第一金屬板(2)內緣具有以網版印刷構成預定高度、面積、形狀之支撐部(5)【如第1圖實施例所示支撐部(5)的形狀、面積,該支撐部(5)的形狀、面積等,係配合待貼合均溫部件設計】,該支撐部(5)為導熱佳金屬粉末燒結成多孔性結構,前述支撐部(5)在密封第一金屬板(2)與第二金屬 板(3)時並焊接於第二金屬板(3)相對內緣,藉密封第一金屬板(2)與第二金屬板(3),使第一金屬板(2)與第二金屬板(3)內部工作空間(4)形成複數個交錯的通道(40),再經抽真空並注入適量工作流體,而構成超薄型均溫板(1),由於該支撐部(5)為導熱佳之粉末燒結構成多孔洞結構,藉該多孔洞結構支撐部(5)吸附工作流體,在工作時具有更佳的毛細現象,確能加速溫度之擴散,具有更高效率的均溫效果,此外該支撐部(5)可避免在後續進行均溫板內部的抽真空除氣作業而使第一金屬板(2)與第二金屬板(3)表面產生凹陷,防止均溫板在與電子發熱元件表面接觸時因前述凹陷問題而無法達到面與面的平整接觸,進而影響熱導效率。 Please refer to the top view of the embodiment of the present invention in Figure 1 and the partial assembly cross-sectional view of the embodiment of the present invention in Figure 2. It can be seen from the figures that the ultra-thin uniform temperature plate (1) of the present invention mainly includes a thin section with good heat conduction. A metal plate (2) and a second metal plate (3). There is a working space (4) between the first metal plate (2) and the second metal plate (3). The inner edge of the first metal plate (2) has a mesh The plate printing constitutes a predetermined height, area, and shape of the supporting portion (5) [as shown in the embodiment in Figure 1, the shape and area of the supporting portion (5), the shape and area of the supporting portion (5), etc., are matched to the to-be-applied Combined temperature-equalizing component design], the support part (5) is a porous structure sintered with metal powder with good thermal conductivity, and the aforementioned support part (5) seals the first metal plate (2) and the second metal When the plate (3) is welded to the opposite inner edge of the second metal plate (3), by sealing the first metal plate (2) and the second metal plate (3), the first metal plate (2) and the second metal plate (3) The internal working space (4) forms a plurality of staggered channels (40), and then vacuumizes and injects an appropriate amount of working fluid to form an ultra-thin uniform temperature plate (1), because the support part (5) is heat-conducting The fine powder sintered to form a porous structure, the porous structure support part (5) absorbs the working fluid, has better capillary phenomenon during work, can indeed accelerate the temperature diffusion, and has a more efficient temperature uniformity effect. The supporting part (5) can avoid the subsequent vacuuming and degassing operation inside the temperature equalizing plate to cause the surface of the first metal plate (2) and the second metal plate (3) to dent, and prevent the equalizing plate from contacting the electronic heating element When the surface is in contact, due to the aforementioned depression problem, it is impossible to achieve a smooth surface-to-surface contact, which in turn affects the thermal conductivity efficiency.

請參閱第3圖所示,本發明前述第二金屬板(3)內端面具有以導熱佳金屬粉末(如銅粉)燒結構成之多孔結構層(30),以增加擴熱均溫效率。 As shown in Figure 3, the inner end surface of the aforementioned second metal plate (3) of the present invention has a porous structure layer (30) formed by sintering metal powder (such as copper powder) with good thermal conductivity to increase the efficiency of heat diffusion and temperature uniformity.

本發明前述導熱佳金屬粉末為銅粉。 The aforementioned metal powder with good thermal conductivity is copper powder.

綜上所述,本發明所揭露之一種「超薄型均溫板及其製造方法」為昔所無,亦未曾見於國內外公開之刊物上,理已具新穎性之專利要件,又本發明確可摒除習用技術缺失,並達成設計目的,亦已充份符合專利要件,爰依法提出申請,謹請貴審查委員惠予審查,並賜予本案專利,實感德便。 In summary, the "ultra-thin uniform temperature plate and its manufacturing method" disclosed in the present invention is unprecedented, and has not been seen in publications published at home and abroad. It is a novel patent requirement. It is clear that the lack of conventional technology can be eliminated, and the design purpose has been achieved. It has fully met the patent requirements. I filed an application in accordance with the law. I sincerely ask your review committee for the review and grant the patent for this case.

惟以上所述者,僅為本發明之一較佳可行實施例而已,並非用以拘限本發明之範圍,舉凡熟悉此項技藝人士,運用本發明說明書及申請專利範圍所作之替代性方法或等效結構變化,理應包括於本發明之專利範圍內。 However, what has been described above is only one of the preferred and feasible embodiments of the present invention, and is not intended to limit the scope of the present invention. For those skilled in the art, alternative methods or alternative methods or methods made by using the specification of the present invention and the scope of the patent application are used to limit the scope of the present invention. The equivalent structure change should be included in the patent scope of the present invention.

(1)‧‧‧超薄型均溫板 (1)‧‧‧Ultra-thin uniform temperature plate

(2)‧‧‧第1金屬板 (2)‧‧‧The first metal plate

(3)‧‧‧第2金屬板 (3)‧‧‧Second metal plate

(4)‧‧‧工作空間 (4)‧‧‧Working space

(40)‧‧‧通道 (40)‧‧‧Channel

(5)‧‧‧支撐部 (5)‧‧‧Support

Claims (7)

一種超薄型均溫板製造方法,其製造方法為: A manufacturing method of ultra-thin uniform temperature plate, the manufacturing method is as follows: 選用導熱佳金屬粉末; Use metal powder with good thermal conductivity; 將前述導熱佳金屬粉末與適用於網版印刷溶劑混合; Mix the aforementioned metal powder with good thermal conductivity with a solvent suitable for screen printing; 以網板印刷方式將前述混合物印刷於薄型導熱佳之第一金屬板上,形成預定高度、面積、形狀之支撐部; Print the aforementioned mixture on a thin, thermally conductive first metal plate by screen printing to form a supporting portion with a predetermined height, area, and shape; 燒結前述製程第一金屬板,使支撐部形成多孔性結構並與第一金屬板結合; Sintering the first metal plate of the aforementioned process to form a porous structure on the support part and combine with the first metal plate; 將前述製程燒結後的第一金屬板與薄型導熱佳之第二金屬板焊接封閉; Welding and sealing the first metal plate sintered by the aforementioned manufacturing process and the thin, thermally conductive second metal plate; 再經抽真空及注入工作流體後製成超薄型均溫板。 After vacuuming and injecting working fluid, an ultra-thin uniform temperature plate is made. 如申請專利範圍第1項所述之超薄型均溫板製造方法,其中,前述第二金屬板內端面上先以導熱佳金屬粉末燒結一多孔結構層,再與第一金屬板焊接封閉,以增加擴熱均溫效率。 The method for manufacturing an ultra-thin uniform temperature plate as described in the first item of the scope of patent application, wherein the inner end surface of the second metal plate is first sintered with a porous structure layer with metal powder with good thermal conductivity, and then welded and sealed with the first metal plate , In order to increase the heat expansion efficiency. 如申請專利範圍第1項所述之超薄型均溫板製造方法,其中,前述導熱佳金屬粉末為銅粉。 According to the manufacturing method of the ultra-thin uniform temperature plate described in the first item of the scope of patent application, the aforementioned metal powder with good thermal conductivity is copper powder. 如申請專利範圍第1項所述之超薄型均溫板製造方法,其中,前述第一金屬板與第二金屬板係以擴散焊接方式封閉。 According to the method for manufacturing an ultra-thin uniform temperature plate described in the first item of the scope of patent application, the first metal plate and the second metal plate are sealed by diffusion welding. 一種超薄型均溫板,主要包括有薄型導熱佳之第一金屬板與第二金屬板,第一金屬板與第二金屬板間具有工作空間,第一金屬板內緣具有以網版印刷構成預定高度、面積、形狀之支撐部,該支撐部為導熱佳金屬粉末燒結成多孔性結構,前述支撐部在密封第一金屬板與第二金屬板時並焊接於第二金屬板相對內緣,藉密封第一金屬板與第二金屬板,使第一金屬板與第二金屬板內部工作空間形成複數個交錯的通道,再經抽真空並注入適量工作流體,而構成超薄型均溫板,藉該多孔洞結構支撐部吸附工作流體 及支撐,在工作時具有更佳的毛細現象,以加速溫度之擴散,達成高效率的均溫效果。 An ultra-thin uniform temperature plate, which mainly includes a thin first metal plate and a second metal plate with good heat conduction. There is a working space between the first metal plate and the second metal plate, and the inner edge of the first metal plate is formed by screen printing. A support portion of predetermined height, area, and shape, the support portion is a porous structure sintered with metal powder with good thermal conductivity, and the aforementioned support portion is welded to the opposite inner edge of the second metal plate when sealing the first metal plate and the second metal plate, By sealing the first metal plate and the second metal plate, the inner working space of the first metal plate and the second metal plate form a plurality of staggered channels, and then vacuuming and injecting an appropriate amount of working fluid to form an ultra-thin uniform temperature plate , The working fluid is adsorbed by the support part of the porous structure And support, it has better capillary phenomenon at work to accelerate temperature diffusion and achieve high-efficiency uniform temperature effect. 如申請專利範圍第5項所述之超薄型均溫板,其中,前述第二金屬板內端面具有以導熱佳金屬粉末燒結構成之多孔結構層,以增加擴熱均溫效率。 The ultra-thin temperature equalizing plate described in item 5 of the scope of patent application, wherein the inner end surface of the second metal plate has a porous structure layer formed by sintering metal powder with good thermal conductivity to increase the efficiency of heat diffusion and temperature equalization. 如申請專利範圍第5項所述之超薄型均溫板,其中,前述導熱佳金屬粉末為銅粉。 The ultra-thin uniform temperature plate described in item 5 of the scope of patent application, wherein the aforementioned metal powder with good thermal conductivity is copper powder.
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* Cited by examiner, † Cited by third party
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TWI811772B (en) * 2021-07-20 2023-08-11 南韓商Cgi股份有限公司 Vapor chamber and working fluid used therefor
US11892242B2 (en) 2021-12-24 2024-02-06 Asia Vital Components (China) Co., Ltd. Multi-angle adjustable and transformable heat pipe

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TWI639806B (en) * 2016-02-05 2018-11-01 業強科技股份有限公司 Heat conduction device and manufacturing method thereof
TWI699507B (en) * 2017-12-13 2020-07-21 奇鋐科技股份有限公司 Basic structural body for constructing heat dissipation device and manufacturing method thereof

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TWI811772B (en) * 2021-07-20 2023-08-11 南韓商Cgi股份有限公司 Vapor chamber and working fluid used therefor
US11892242B2 (en) 2021-12-24 2024-02-06 Asia Vital Components (China) Co., Ltd. Multi-angle adjustable and transformable heat pipe
CN115625484A (en) * 2022-10-14 2023-01-20 广东畅能达科技发展有限公司 Bent special-shaped ultrathin soaking plate and manufacturing process and application thereof
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