TW201526772A - Heat dissipation structure applied to mobile device and manufacturing method of the heat dissipation structure - Google Patents

Heat dissipation structure applied to mobile device and manufacturing method of the heat dissipation structure Download PDF

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TW201526772A
TW201526772A TW102148645A TW102148645A TW201526772A TW 201526772 A TW201526772 A TW 201526772A TW 102148645 A TW102148645 A TW 102148645A TW 102148645 A TW102148645 A TW 102148645A TW 201526772 A TW201526772 A TW 201526772A
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heat dissipation
heat
mobile device
dissipation structure
plate body
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TW102148645A
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Chinese (zh)
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TWI573520B (en
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Chih-Ming Chen
Chih-Yeh Lin
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Asia Vital Components Co Ltd
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Abstract

A heat dissipation structure applied to mobile device and a manufacturing method of the heat dissipation structure. The heat dissipation structure applied to mobile device includes a heat conduction main body. The heat conduction main body has a heat dissipation side and a heat absorption side. A radiation heat dissipation layer is formed on the heat dissipation side. The heat dissipation structure is disposed in the mobile device to provide a very good heat dissipation effect for the closed space of the mobile device by way of natural convection and radiation. Therefore, the heat dissipation performance of the entire mobile device is greatly enhanced.

Description

應用於移動裝置之散熱結構及其製造方法Heat dissipation structure applied to mobile device and manufacturing method thereof

一種應用於移動裝置之散熱結構及其製造方法,尤指一種可於移動裝置封閉空間內,透過輻射自然散熱提高散熱效能的應用於移動裝置之散熱結構以及其製造方法。
A heat dissipating structure applied to a mobile device and a manufacturing method thereof, in particular, a heat dissipating structure applied to a mobile device and a manufacturing method thereof, which can improve heat dissipation performance by radiating natural heat dissipation in a closed space of the mobile device.

按,現行移動裝置(諸如薄型筆電、平板、智慧手機等)隨著運算速率越快,其內部計算執行單元所產生之熱量亦相對大幅提升,且其又為了具有能攜帶方便的前提考量下,該等裝置是越作越薄化;此外所述移動裝置為能防止異物及水氣進入內部,該等移動裝置除耳機孔或連接器之設置孔外,甚少具有呈開放之孔口與外界空氣形成對流,故因薄化的先天因素下,該等移動裝置內部因計算執行單元及電池所產生之熱量無法向外界快速排出,而又因為移動裝置之內部呈密閉空間,甚難產生對流散熱,進而易於移動裝置內部產生積熱或聚熱等情事,嚴重影響移動裝置之工作效率或產生熱當等問題。
  再者,由於有上述問題,亦有欲於該等移動裝置內部設置被動式散熱元件:諸如熱板、均溫板、散熱器等被動散熱元件進行解熱,但仍由於移動裝置被要求設計薄化的原因,致使該裝置內部的空間受到限制而狹隘,亦此所設置於該空間內之散熱元件勢必縮減至超薄之尺寸厚度,方可設置於狹隘有限之內部空間中,但隨著尺寸受限縮減之熱板、均溫板,則其內部之毛細結構及蒸汽通道更因為設置成超薄之要求亦相同受限縮減,致使令該等熱板、均溫板在整體熱傳導之工作效率上大打折扣,無法有效達到提升散熱效能;因此當移動裝置之內部計算單元功率過高時,習知熱板、均溫板均無法有效的因應對其進行解熱或散熱,故如何在狹窄之密閉空間內設置有效的解熱元件,則為該項業者目前首重之待改良之技術。
According to the current mobile devices (such as thin notebooks, tablets, smart phones, etc.), the faster the calculation rate, the heat generated by the internal computing execution unit is relatively increased, and it is also considered to be portable. The devices are made thinner and thinner; in addition, the mobile device prevents foreign matter and moisture from entering the interior, and the mobile device has few open apertures except for the hole of the earphone hole or the connector. The outside air forms convection. Therefore, due to the congenital factors of thinning, the heat generated by the calculation execution unit and the battery cannot be quickly discharged to the outside, and the convection is difficult to generate due to the closed space inside the mobile device. The heat dissipation is easy to cause heat accumulation or heat accumulation inside the mobile device, which seriously affects the working efficiency of the mobile device or generates heat.
Furthermore, due to the above problems, there is also a desire to provide passive heat dissipating components inside the mobile devices: passive heat dissipating components such as hot plates, temperature equalizing plates, heat sinks, etc., but still require thinning of the mobile device. The reason is that the space inside the device is limited and narrow, and the heat dissipating component disposed in the space is inevitably reduced to an ultra-thin size and thickness, and can be disposed in a narrow and limited internal space, but with limited size The reduced hot plate and the uniform temperature plate, the internal capillary structure and the steam passage are also limited by the requirement of being set to be ultra-thin, so that the heat plates and the uniform temperature plates are more efficient in overall heat conduction. Discounted, can not effectively achieve the improvement of heat dissipation performance; therefore, when the internal calculation unit power of the mobile device is too high, the conventional hot plate and the uniform temperature plate cannot effectively dissipate heat or dissipate heat, so how to be in a narrow confined space Setting up an effective anti-heating component is the industry's first priority to improve.

爰此,為有效解決上述之問題,本發明之主要目的,係提供一種應用於移動裝置之散熱結構。
本發明次要目的,係提供一種應用於移動裝置之散熱結構之製造方法。
  為達成上述之目的,本發明係提供一種應用於移動裝置之散熱結構,係包含:一導熱本體;
所述導熱本體具有一散熱側及一吸熱側,所述散熱側形成一輻射散熱層。
為達到上述目的,本發明係提供一種應用於移動裝置之散熱結構之製造方法,係包含下列步驟:
提供一導熱本體,並定義一散熱側及一吸熱側;
  於所述導熱本體散熱側形成一輻射散熱層。
  本發明主要係透過於導熱本體之散熱側設置輻射散熱層,藉以提供導熱本體於該移動裝置封閉之容置空間中形成有自然輻射對流散熱,藉此大幅增加移動裝置整體之散熱效能。
Accordingly, in order to effectively solve the above problems, the main object of the present invention is to provide a heat dissipation structure applied to a mobile device.
A secondary object of the present invention is to provide a method of fabricating a heat dissipation structure for use in a mobile device.
In order to achieve the above object, the present invention provides a heat dissipation structure applied to a mobile device, comprising: a heat conducting body;
The heat conducting body has a heat dissipating side and a heat absorbing side, and the heat dissipating side forms a radiating heat dissipating layer.
In order to achieve the above object, the present invention provides a method for manufacturing a heat dissipation structure applied to a mobile device, comprising the following steps:
Providing a heat conducting body and defining a heat dissipating side and a heat absorbing side;
Forming a radiation heat dissipation layer on the heat dissipation side of the heat conduction body.
The invention mainly provides a radiating heat dissipation layer on the heat dissipating side of the heat conducting body, thereby providing a heat radiating body to form a natural radiation convection heat dissipation in the enclosed space of the mobile device, thereby greatly increasing the heat dissipating performance of the mobile device as a whole.

1‧‧‧應用於移動裝置之散熱結構
11‧‧‧導熱本體
111‧‧‧散熱側
112‧‧‧吸熱側
113‧‧‧輻射散熱層
11a‧‧‧銅材質板體
11b‧‧‧鋁材質板體
11c‧‧‧銅鍍層
1‧‧‧Solution structure for mobile devices
11‧‧‧thermal body
111‧‧‧heat side
112‧‧‧heat side
113‧‧‧radiation heat sink
11a‧‧‧Bronze plate
11b‧‧‧Aluminum plate
11c‧‧‧copper plating

第1圖係為本發明之應用於移動裝置之散熱結構之第一實施例之立體分解圖;
第2圖係為本發明之應用於移動裝置之散熱結構之第一實施例之組合剖視圖;
第3圖係為本發明之應用於移動裝置之散熱結構之第二實施例之組合剖視圖;
第4圖係為本發明之應用於移動裝置之散熱結構之第三實施例之組合剖視圖;
第5圖係為本發明之應用於移動裝置之散熱結構之第四實施例之組合剖視圖;
第6圖係為本發明之應用於移動裝置之散熱結構之製造方法第一實施例之步驟流程圖。
1 is an exploded perspective view of a first embodiment of a heat dissipation structure applied to a mobile device of the present invention;
2 is a combined cross-sectional view of a first embodiment of a heat dissipation structure applied to a mobile device of the present invention;
Figure 3 is a cross-sectional view showing a combination of a second embodiment of the heat dissipation structure applied to the mobile device of the present invention;
Figure 4 is a cross-sectional view showing a combination of a third embodiment of a heat dissipation structure applied to a mobile device of the present invention;
Figure 5 is a cross-sectional view showing a combination of a fourth embodiment of the heat dissipation structure applied to the mobile device of the present invention;
Figure 6 is a flow chart showing the steps of the first embodiment of the manufacturing method of the heat dissipation structure applied to the mobile device 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圖,係為本發明之應用於移動裝置之散熱結構之第一實施例之立體分解及組合剖視圖,如圖所示,本發明之應用於移動裝置之散熱結構1,係包含:一導熱本體11;
其中所述導熱本體11可為一具有高熱傳導效率之金屬材質或合金及其組成物或複合材;其具有一散熱側111及一吸熱側112,所述散熱側111可直接形成或披覆設有一輻射散熱層113;本實施例中之所述導熱本體11係選擇由一銅材質板體11a及鋁材質板體11b兩板體相互疊合組成,並所述吸熱側112係設於該銅材質板體11a之一側,即為該銅材質板體11a與該鋁材質板體11b相互貼合的相反之一側,所述散熱側111係設於該鋁材質板體11b之一側,即為該鋁材質板體11b與前述銅材質板體11a相互貼合的相反之一側,所述銅材質板體及鋁材質板體係透過膠合接合或無介質擴散接合其中任一方式相互組合。
所述輻射散熱層113係為一種多孔結構或奈米結構體或高輻射陶瓷結構或高硬度陶瓷結構或多孔性陶瓷結構或多孔性石墨結構其中任一,並透過蒸鍍或濺鍍或電鍍或印刷塗佈或烤漆或奈米塗料噴塗或表面陽極氧化等其中任一形成於該導熱本體11之散熱側111,於本較佳實施例中所採取的是以所述奈米結構體來作輻射結構層,其係透過微弧氧化(Micro Arc Oxidation,MAO)或電漿電解氧化 (Plasma Electrolytic Oxidation, PEO)、陽極火花沉積 (Anodic Spark Deposition, ASD), 火花沉積陽極氧化(Anodic Oxidation by Spark Deposition, ANOF)其中任一方式於該導熱本體11之散熱側111形成陶瓷化(具有表面硬化及增強輻射效果) ,並為使將該輻射散熱層113能獲取更佳化的輻射效益,將輻射散熱層設為黑色或亞黑色或深色系顏色其中任一,則更有大幅提升輻射散熱之效果,本實施例係以黑色作為說明但並不引以為限,透過陶瓷及石墨之快速傳導散熱之特性更有助於自然輻射散熱之效能的提升。
請參閱第3圖,係為本發明之應用於移動裝置之散熱結構之第二實施例之組合剖視圖,如圖所示,本實施例部分結構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導熱本體11係由銅及鋁所組成之複合材料,並透過選用該銅及鋁之複合材料提升該導熱本體11之結構強度以及導熱之效能。
請參閱第4圖,係為本發明之應用於移動裝置之散熱結構之第三實施例之組合剖視圖,如圖所示,本實施例部分結構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導熱本體11係為一鋁材質或陶瓷材質其中任一之板體11b,並於該吸熱側112披附一銅鍍層11c,令該導熱本體11以鋁材質板體11b作為基底結構體,具有較佳之結構強度並可降低生產成本等優點,並於該吸熱側112披附一銅材質之銅鍍層11c係可提升導熱本體11之吸熱熱傳導效率。
請參閱第5圖,係為本發明之應用於移動裝置之散熱結構之第四實施例之組合剖視圖,如圖所示,本實施例部分結構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輻射散熱層113係為透過珠擊所產生之凹凸結構,藉以提升散熱之接觸面積,並於其表面以塗佈或披附之方式附著黑色顏料於該輻射散熱層113表面。
本發明之應用於移動裝置之散熱結構主要係欲解決移動裝置之積熱或聚熱問題,改善習知移動裝置內部封閉空間無法確實有效解熱之缺失。
本發明係透過以部分貼設或局部披附銅質金屬設於吸熱側,藉以提升導熱本體之吸熱效率,於散熱側設置黑色之輻射散熱層增加其散熱接觸面積提升熱輻射散熱效率。
請參閱第6圖,係為本發明之應用於移動裝置之散熱結構之製造方法第一實施例之步驟流程圖,並一併參閱前述第1~5圖,如圖所示,本發明之應用於移動裝置之散熱結構之製造方法係包含下列步驟:
S1:提供一導熱本體,並定義一散熱側及一吸熱側;
係提供一導熱本體11,並將該導熱本體11之兩側分別定義為一散熱側111及一吸熱側112。
本發明之所述導熱本體11之選用,本發明係揭示以下幾種型態之態樣:
其一所述導熱本體11亦可為由一鋁材質或陶瓷材質之板體11b於該吸熱側披附一銅鍍層11c之本體(如第4圖所示)。
其二所述導熱本體11亦可由一銅材質板體11a及一鋁材質板體11b疊合組成,所述吸熱側112設於該銅材質板體11a與該鋁材質板體11b貼合相反之一側,所述散熱側111係設於該鋁材質板體11b與前述銅材質板體11a貼合之相反的一側,並所述銅材質板體11a及鋁材質板體11b係透過膠合接合或無介質擴散接合其中任一方式相互貼合(如第1、2圖所示)。
其三所述導熱本體11係可為由銅及鋁所組成之複合材料(如第3圖所示)。
並本實施例所提之導熱本體11之結構態樣及說明其圖示亦可一併參閱前述應用於移動裝置之散熱結構之第一~四實施例及圖式。
  S2:於所述導熱本體之散熱側形成一輻射散熱層。
於前述導熱本體11之散熱側111形成一輻射散熱層113,所述輻射散熱層113係為一種多孔結構或一奈米結構體或一多孔性陶瓷結構或一多孔性石墨結構其中任一,並將該輻射散熱層113係設置呈黑色或亞黑色或深色系之顏色其中任一。
並所述多孔性結構之輻射散熱層113係可透過微弧氧化(Micro Arc Oxidation,MAO)或電漿電解氧化 (Plasma Electrolytic Oxidation, PEO)、陽極火花沉積 (Anodic Spark Deposition, ASD), 火花沉積陽極氧化(Anodic Oxidation by Spark Deposition, ANOF)其中任一方式,而本發明係以微弧氧化方式於該導熱本體11之散熱側111形成該輻射散熱層113。
另,所述輻射散熱層亦可係為一種透過珠擊法所產生之表面凹凸結構(如第5圖所示)。
本發明主要係應用熱的熱輻射傳導作為散熱之應用,而熱傳導和對流作用,都必須靠物質作為媒介,才能傳播熱能。熱輻射則不需要介質,即能直接傳播熱能,故在密閉空間中得以在僅存的微小空間中將熱量傳遞至移動裝置之殼體,再透過殼體與外界作熱交換。
熱輻射就是物質以電磁波的形式來傳播,但電磁波以光速傳播,需要介質傳播,物體會持續產生熱輻射,同時也吸收外界給予的熱輻射。物體發出熱的能力,與其表面溫度、顏色與粗糙程度有關,故本發明所設置之輻射散熱層則係以相關應用原理設置一可提升表面散熱面積及散熱效率的自然散熱的輻射散熱層,物體表面的熱輻射強度,除了與溫度有關之外,也和其表面的特性有關,例如黑色表面的物體容易吸收,也容易發出熱輻射,故本發明輻射散熱層設置為黑色或令其表面為黑色更可進一步提升其熱輻射效率。
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.
1 and 2 are perspective exploded and combined cross-sectional views of a first embodiment of a heat dissipation structure applied to a mobile device of the present invention. As shown, the heat dissipation structure 1 of the present invention applied to a mobile device is Including: a heat conducting body 11;
The heat conducting body 11 can be a metal material or alloy having high heat conduction efficiency and a composition or composite thereof; and has a heat dissipating side 111 and a heat absorbing side 112, and the heat dissipating side 111 can be directly formed or covered. The heat-dissipating heat-dissipating layer 11 is formed by the two heat-insulating bodies 11 and the two-layer aluminum plate body 11b, and the heat-absorbing side 112 is disposed on the copper. One side of the material plate body 11a is the opposite side of the copper material plate body 11a and the aluminum material plate body 11b, and the heat dissipation side 111 is disposed on one side of the aluminum material plate body 11b. That is, the opposite side of the aluminum material plate body 11b and the copper material plate body 11a are bonded to each other, and the copper material plate body and the aluminum material plate system are combined with each other by either a glue joint or a medium diffusion joint.
The radiation heat dissipation layer 113 is a porous structure or a nanostructure or a high-radiation ceramic structure or a high-hardness ceramic structure or a porous ceramic structure or a porous graphite structure, and is vapor-deposited or sputtered or plated or Any one of the heat-dissipating side 111 of the heat-conducting body 11 is formed by printing coating or baking paint or nano-coating or surface anodizing. In the preferred embodiment, the nanostructure is used for radiation. The structural layer is subjected to Micro Arc Oxidation (MAO) or Plasma Electrolytic Oxidation (PEO), Anodic Spark Deposition (ASD), and Anodic Oxidation by Spark Deposition. , ANOF) forming a ceramization (having surface hardening and enhancing radiation effect) on the heat dissipating side 111 of the heat conducting body 11 and dissipating heat for the radiation radiating layer 113 to obtain better radiation benefits If the layer is set to black or sub-black or dark color, the effect of radiating heat is greatly improved. This embodiment uses black as an illustration but He cited that limit, fast heat conduction through the characteristics of ceramics and graphite but also help enhance the effectiveness of natural radiation of heat.
Referring to FIG. 3, it is a sectional view of a second embodiment of the heat dissipation structure applied to the mobile device of the present invention. As shown in the figure, the partial structure of the embodiment is the same as that of the first embodiment, and therefore will not be herein. Further, the difference between the embodiment and the first embodiment is that the heat conducting body 11 is a composite material composed of copper and aluminum, and the heat conducting body 11 is raised by using the composite material of copper and aluminum. Structural strength and thermal conductivity.
Referring to FIG. 4, it is a sectional view of a third embodiment of the heat dissipation structure applied to the mobile device of the present invention. As shown in the figure, the partial structure of the embodiment is the same as that of the first embodiment, and therefore will not be herein. Further, the difference between the embodiment and the first embodiment is that the heat conducting body 11 is a plate body 11b of any one of aluminum material or ceramic material, and a copper plating layer is attached to the heat absorbing side 112. 11c, the heat-conducting body 11 has the aluminum material plate body 11b as the base structure body, has the advantages of better structural strength and lowering the production cost, and the copper-plated layer 11c of the copper material is attached to the heat absorption side 112 to improve the heat conduction. The heat absorbing heat transfer efficiency of the body 11.
Referring to FIG. 5, it is a sectional view of a fourth embodiment of the heat dissipation structure applied to the mobile device of the present invention. As shown in the figure, the partial structure of the embodiment is the same as that of the first embodiment, and therefore will not be herein. Further, the difference between the embodiment and the first embodiment is that the radiation heat dissipation layer 113 is a concave-convex structure generated by a bead strike, thereby improving the contact area of the heat dissipation and coating or coating the surface thereof. A black pigment is attached to the surface of the radiation heat dissipation layer 113 in a draped manner.
The heat dissipation structure applied to the mobile device of the present invention is mainly intended to solve the problem of heat accumulation or heat accumulation of the mobile device, and to improve the lack of effective heat dissipation in the closed space of the conventional mobile device.
The invention is provided on the heat absorbing side by partially or partially affixing a copper metal, thereby improving the heat absorbing efficiency of the heat conducting body, and providing a black radiation heat dissipating layer on the heat dissipating side to increase the heat dissipating contact area and improving the heat radiating heat dissipating efficiency.
Please refer to FIG. 6 , which is a flow chart of the steps of the first embodiment of the manufacturing method of the heat dissipation structure applied to the mobile device of the present invention, and refer to the first to fifth figures, as shown in the figure, the application of the present invention. The manufacturing method of the heat dissipation structure of the mobile device comprises the following steps:
S1: providing a heat conducting body and defining a heat dissipating side and a heat absorbing side;
A heat-conducting body 11 is provided, and two sides of the heat-conducting body 11 are defined as a heat-dissipating side 111 and a heat-absorbing side 112, respectively.
In the selection of the heat-conducting body 11 of the present invention, the present invention discloses the following aspects:
The heat conducting body 11 may also be a body of a copper plating layer 11c (as shown in FIG. 4) on the heat absorbing side of an aluminum or ceramic material body 11b.
The heat-conducting body 11 can also be composed of a copper material plate body 11a and an aluminum material plate body 11b. The heat-absorbing side 112 is disposed on the opposite side of the copper material plate body 11a and the aluminum material plate body 11b. On one side, the heat dissipation side 111 is disposed on the opposite side of the aluminum material plate body 11b and the copper material plate body 11a, and the copper material plate body 11a and the aluminum material plate body 11b are bonded by gluing. Or no medium diffusion bonding in any way to fit each other (as shown in Figures 1 and 2).
The three heat conducting bodies 11 may be a composite material composed of copper and aluminum (as shown in FIG. 3).
For the structure and description of the heat-conducting body 11 of the present embodiment, reference may be made to the first to fourth embodiments and the drawings of the heat-dissipating structure applied to the mobile device.
S2: forming a radiation heat dissipation layer on the heat dissipation side of the heat conduction body.
Forming a radiation heat dissipation layer 113 on the heat dissipation side 111 of the heat conduction body 11, the radiation heat dissipation layer 113 is a porous structure or a nanostructure or a porous ceramic structure or a porous graphite structure. And the radiation heat dissipation layer 113 is set to any one of black or sub-black or dark color.
And the porous heat radiating layer 113 of the porous structure is permeable to Micro Arc Oxidation (MAO) or Plasma Electrolytic Oxidation (PEO), Anodic Spark Deposition (ASD), spark deposition. The anodic oxidation (Anodic Oxidation by Spark Deposition, ANOF) is formed in any manner, and the radiation dissipation layer 113 is formed on the heat dissipation side 111 of the heat conduction body 11 by micro-arc oxidation.
In addition, the radiation heat dissipation layer may also be a surface relief structure produced by a bead blasting method (as shown in FIG. 5).
The invention mainly uses the application of thermal heat radiation conduction as heat dissipation, and the heat conduction and convection effects must rely on the substance as a medium to propagate thermal energy. Thermal radiation does not require a medium, that is, it can directly transmit thermal energy, so that heat can be transferred to the housing of the mobile device in the only small space in the confined space, and then exchange heat with the outside through the housing.
Thermal radiation means that matter propagates in the form of electromagnetic waves, but electromagnetic waves propagate at the speed of light, which requires the propagation of the medium. The object will continue to generate heat radiation and also absorb the heat radiation given by the outside. The ability of an object to emit heat is related to its surface temperature, color and roughness. Therefore, the radiation heat dissipation layer provided by the present invention is provided with a radiation heat dissipation layer that can enhance the surface heat dissipation area and heat dissipation efficiency by using the relevant application principle. The thermal radiation intensity of the surface is related to the characteristics of the surface in addition to the temperature. For example, the object on the black surface is easily absorbed, and the heat radiation is easily emitted. Therefore, the radiation heat dissipation layer of the present invention is set to black or the surface thereof is black. It can further improve its heat radiation efficiency.

 

1‧‧‧應用於移動裝置之散熱結構 1‧‧‧Solution structure for mobile devices

11‧‧‧導熱本體 11‧‧‧thermal body

111‧‧‧散熱側 111‧‧‧heat side

112‧‧‧吸熱側 112‧‧‧heat side

113‧‧‧輻射散熱層 113‧‧‧radiation heat sink

11a‧‧‧銅材質板體 11a‧‧‧Bronze plate

11b‧‧‧鋁材質板體 11b‧‧‧Aluminum plate

Claims (22)

一種應用於移動裝置之散熱結構,係包含:
一導熱本體,具有一散熱側及一吸熱側,所述散熱側形成一輻射散熱層。
A heat dissipation structure applied to a mobile device, comprising:
A heat conducting body has a heat dissipating side and a heat absorbing side, and the heat dissipating side forms a radiating heat dissipating layer.
如申請專利範圍第1項所述之應用於移動裝置之散熱結構,其中所述導熱本體係由一銅材質板體及鋁材質板體疊合組成,所述吸熱側設於該銅材質板體與該鋁材質板體貼合相反之一側,所述散熱側係設於該鋁材質板體與前述銅材質板體貼合之相反的一側。The heat dissipation structure applied to the mobile device according to claim 1, wherein the heat conduction system is composed of a copper material plate body and an aluminum material plate body, and the heat absorption side is disposed on the copper material plate body. On the opposite side of the aluminum material plate body, the heat dissipation side is disposed on the opposite side of the aluminum material plate body and the copper material plate body. 如申請專利範圍第1項所述之應用於移動裝置之散熱結構,其中所述導熱本體係由銅及鋁所組成之複合材料。The heat dissipation structure applied to the mobile device according to claim 1, wherein the heat conduction system is a composite material composed of copper and aluminum. 如申請專利範圍第1項所述之應用於移動裝置之散熱結構,其中所述導熱本體係為一鋁材質板體,並於該吸熱側披附一銅鍍層。The heat dissipation structure applied to the mobile device according to claim 1, wherein the heat conduction system is an aluminum plate body, and a copper plating layer is attached to the heat absorption side. 如申請專利範圍第1項所述之應用於移動裝置之散熱結構,其中所述導熱本體係為一陶瓷板體,並於該吸熱側披附一銅鍍層。The heat dissipation structure applied to the mobile device according to claim 1, wherein the heat conduction system is a ceramic plate body, and a copper plating layer is attached to the heat absorption side. 如申請專利範圍第1項所述之應用於移動裝置之散熱結構,其中輻射散熱層係為一種多孔結構或奈米結構體其中任一。The heat dissipation structure applied to the mobile device according to claim 1, wherein the radiation heat dissipation layer is any one of a porous structure or a nanostructure. 如申請專利範圍第1項所述之應用於移動裝置之散熱結構,其中輻射散熱層透過微弧氧化(Micro Arc Oxidation,MAO)或電漿電解氧化 (Plasma Electrolytic Oxidation, PEO)、陽極火花沉積 (Anodic Spark Deposition, ASD), 火花沉積陽極氧化(Anodic Oxidation by Spark Deposition, ANOF)其中任一於該導熱本體之散熱側形成一多孔性結構。The heat dissipation structure applied to the mobile device according to claim 1, wherein the radiation heat dissipation layer is subjected to Micro Arc Oxidation (MAO) or Plasma Electrolytic Oxidation (PEO), and anode spark deposition ( Anodic Spark Deposition (ASD), any of the Anodic Oxidation by Spark Deposition (ANOF) forms a porous structure on the heat dissipating side of the thermally conductive body. 如申請專利範圍第1項所述之應用於移動裝置之散熱結構,其中輻射散熱層係為透過珠擊所產生之凹凸結構。The heat dissipation structure applied to the mobile device according to claim 1, wherein the radiation heat dissipation layer is a concave-convex structure generated by the bead impact. 如申請專利範圍第1項所述之應用於移動裝置之散熱結構,其中輻射散熱層係為一多孔性陶瓷結構或一多孔性石墨結構其中任一。The heat dissipation structure applied to the mobile device according to claim 1, wherein the radiation heat dissipation layer is any one of a porous ceramic structure or a porous graphite structure. 如申請專利範圍第1至9項其中任一項所述之應用於移動裝置之散熱結構,其中輻射散熱層係呈黑色或亞黑色或深色系之顏色其中任一。The heat dissipation structure applied to the mobile device according to any one of claims 1 to 9, wherein the radiation heat dissipation layer is in the form of black or sub-black or dark color. 如申請專利範圍第2項所述之應用於移動裝置之散熱結構,其中所述銅材質板體及鋁材質板體係透過膠合接合或無介質擴散接合其中任一方式相互貼合。The heat dissipation structure applied to the mobile device according to claim 2, wherein the copper material plate and the aluminum material plate system are adhered to each other by either glue bonding or medium diffusion bonding. 一種應用於移動裝置之散熱結構之製造方法,係包含下列步驟:
    提供一導熱本體,並定義一散熱側及一吸熱側;
    於所述導熱本體之散熱側形成一輻射散熱層。
A manufacturing method for a heat dissipation structure of a mobile device includes the following steps:
Providing a heat conducting body and defining a heat dissipating side and a heat absorbing side;
Forming a radiation heat dissipation layer on the heat dissipation side of the heat conductive body.
如申請專利範圍第12項所述之應用於移動裝置之散熱結構之製方法,其中所述導熱本體係由一銅材質板體及鋁材質板體疊合組成,所述吸熱側設於該銅材質板體與該鋁材質板體貼合相反之一側,所述散熱側係設於該鋁材質板體與前述銅材質板體貼合之相反的一側。The method for manufacturing a heat dissipation structure for a mobile device according to claim 12, wherein the heat conduction system is composed of a copper material plate body and an aluminum material plate body, and the heat absorption side is disposed on the copper material. The material plate body is opposite to the aluminum material plate body, and the heat dissipation side is disposed on a side opposite to the aluminum material plate body and the copper material plate body. 如申請專利範圍第12項所述之應用於移動裝置之散熱結構之製方法,其中所述導熱本體係由銅及鋁所組成之複合材料。The method for manufacturing a heat dissipation structure for a mobile device according to claim 12, wherein the heat conduction system is a composite material composed of copper and aluminum. 如申請專利範圍第12項所述之應用於移動裝置之散熱結構之製方法,其中所述導熱本體係為一鋁材質板體,並於該吸熱側披附一銅鍍層。The method for manufacturing a heat dissipation structure for a mobile device according to claim 12, wherein the heat conduction system is an aluminum plate body, and a copper plating layer is attached to the heat absorption side. 如申請專利範圍第12項所述之應用於移動裝置之散熱結構之製方法,其中所述導熱本體係為一陶瓷板體,並於該吸熱側披附一銅鍍層。The method for manufacturing a heat dissipation structure for a mobile device according to claim 12, wherein the heat conduction system is a ceramic plate body, and a copper plating layer is attached to the heat absorption side. 如申請專利範圍第12項所述之應用於移動裝置之散熱結構之製方法,其中輻射散熱層係為一種多孔結構或奈米結構體其中任一。The method for manufacturing a heat dissipation structure for a mobile device according to claim 12, wherein the radiation heat dissipation layer is any one of a porous structure or a nanostructure. 如申請專利範圍第12項所述之應用於移動裝置之散熱結構之製方法,其中輻射散熱層透過微弧氧化(Micro Arc Oxidation,MAO)或電漿電解氧化 (Plasma Electrolytic Oxidation, PEO)、陽極火花沉積 (Anodic Spark Deposition, ASD), 火花沉積陽極氧化(Anodic Oxidation by Spark Deposition, ANOF)其中任一於該導熱本體之散熱側形成多孔性結構。The method for manufacturing a heat dissipation structure for a mobile device according to claim 12, wherein the radiation heat dissipation layer transmits Micro Arc Oxidation (MAO) or Plasma Electrolytic Oxidation (PEO), anode. Anodic Spark Deposition (ASD), or any of the Anodic Oxidation by Spark Deposition (ANOF) forms a porous structure on the heat dissipating side of the thermally conductive body. 如申請專利範圍第12項所述之應用於移動裝置之散熱結構之製方法,其中輻射散熱層係為透過珠擊所產生之凹凸結構。The method for manufacturing a heat dissipation structure for a mobile device according to claim 12, wherein the radiation heat dissipation layer is a concave-convex structure generated by a bead shot. 如申請專利範圍第12項所述之應用於移動裝置之散熱結構之製方法,其中輻射散熱層係為一多孔性陶瓷結構或一多孔性石墨結構其中任一。The method for manufacturing a heat dissipation structure for a mobile device according to claim 12, wherein the radiation heat dissipation layer is any one of a porous ceramic structure or a porous graphite structure. 如申請專利範圍第12至20項其中任一項所述之應用於移動裝置之散熱結構之製方法,其中輻射散熱層係呈黑色或亞黑色或深色系之顏色其中任一。The method for manufacturing a heat dissipation structure for a mobile device according to any one of claims 12 to 20, wherein the radiation heat dissipation layer is in the form of black or sub-black or dark color. 如申請專利範圍第13項所述所述之應用於移動裝置之散熱結構之製方法,其中所述銅材質板體及鋁材質板體係透過膠合接合或無介質擴散接合其中任一方式相互貼合。


The method for manufacturing a heat dissipation structure for a mobile device according to claim 13, wherein the copper material plate and the aluminum material plate system are adhered to each other by glue bonding or medium diffusion bonding. .


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