M379748 五、新型說明: 【新型所屬之技術領域】 本創作係關於一種散熱裝置,尤指一種空氣冷卻式散 熱裝置設計》 【先前技術】 現有之散熱裝置組成,其主要包含一支或多支u字形 的熱管,所述熱管以其中段作為熱源接觸段,並設有一導 熱塊,所述熱管以其平行延伸的兩端部穿設複數薄片狀的 散熱鰭片。前述散熱裝置於使用時,係令熱管之熱源接觸 段結合導熱管固設於熱源表面,使熱源散發的熱傳導至熱 管的熱源接觸段,再藉由熱管内部的冷媒向外傳遞,以及 進-步傳導至該複數散熱鰭片上,擴大其散熱表面積,而 為周遭的空氣或外加氣流予以冷卻。 惟别述散熱裝置雖利用熱管吸收熱源所散發的熱傳導 至複數散熱縛片1,但目U纟形熱管無法提供較佳冷媒流 通性,以致在散熱效能的表現方面尚無法達成較佳之效果 〇 【新型内容】 本創作之主要目的在於提供一種空氣冷卻式散熱裝置 ,希藉此設計,使其具有優於現有散熱裝置之散熱效能。 為達成前揭目的,本創作所設計的空氣冷卻式散熱裝 置係包含: 一散熱模組,其包含有二冷媒儲存腔體、複數熱管以 及複數散熱體’該二冷媒儲存腔體平行間隔設置,該複數 3 M379748 熱管連接於該二冷媒儲存腔體之間相連接且呈平行間隔排 列’該複數熱管各包含有一導熱材質製成的管體,該複數 散熱體分布設置於複數熱管側邊,與相鄰熱管的管體接觸 ;以及 複數熱導管’係設於該散熱模組同一侧,每一熱導管 包含有一導熱金屬材質製成的管體,所述管體包含至少一 熱源接觸段以及位於管體兩端的銜接端,所述管體之二銜 接端分別連通該二冷媒儲存腔體,用以提供冷媒於其中流 通,該複數熱管之熱源接觸段併列構成熱源接觸部位,使 熱源接觸段吸收熱源的熱可分散傳遞至散熱模組分散散熱 〇 本創作藉由上述空氣冷卻式散熱裝置設計,其特點在 於利用複數相鄰併列的熱導管提供熱源接觸段,用以吸收 熱源產生的熱,並藉熱導管内的冷媒吸熱而快速分散傳遞 至散熱模組中,接續,令吸熱後的冷媒由散熱模組兩側冷 媒儲存腔體分散至複數熱管再藉由接觸熱管的散熱體擴大 散熱表面積,而流通其間的氣流予以冷卻,故本創作確能 提供一項具有高散熱效能的空氣冷卻式散熱裝置。 【實施方式】 如第圖及第二圖所示,係揭示本創作空氣冷卻式散 熱裴置之數種較佳實施例,由該些圖式中可知,該空氣冷 卻式散熱裝置主要係包含一散熱模組(彳)以及複數熱導管 U),其中: 該散熱模組(1)包含有二冷媒儲存腔體(10)、複數熱管 (1υ以及複數散熱體(12),該二冷媒儲存腔體(10)内部各具 4 M379748 有一密封狀的儲存腔,提供冷媒存於其中,且該二冷媒儲 存腔體(10)平行間隔設置,該複數熱管(11)各包含有一、導 熱材質製成的管體,提供冷媒於其内部流通,該複數熱管 (11)連接於該二冷媒儲存腔體(10)之間呈平行間隔排列: 且與該二冷媒儲存腔體(10)相連通,該複數散熱體(12)係 分布設置於複數熱管(11)側邊,與相鄰熱管(11)的管體接 觸。 如第一、三圖所示,前述散熱模組(1)中,該複數熱管 (11)可為扁平狀管件,該複數散熱體(12)為連續彎曲狀(如 波浪狀等)的長條物件,每一散熱體(12)設於二相鄰熱管 (1 1)之間,且以其上的彎曲部接觸側鄰熱管(1彳)之管體。 該複數熱導管(2)係設於該散熱模組(彳)一側,每一熱 導管(2)包含有一導熱材質製成的管體,用以提供冷媒於其 内部流通,所述熱導管(2)可為扁平狀的管體,熱導管(2') 之管體包含至少一熱源接觸段(2〇)以及二銜接端(21),所 述二銜接端(21)位於各熱導管(2)的兩端,且分別連通該二 冷媒儲存腔體(10),用以提供冷媒於其中流通,該複數熱 管(11)之熱源接觸段(20)相鄰併構成熱源接觸部位。 如第一圖所示的空氣冷卻式散熱裝置第一較佳實施例 中,所述熱導官(2)為扁平狀的管體,並具有一平直狀的熱 源接觸段(20),以及分設於該熱源接觸段(2〇)兩端同朝— 側彎曲的銜接端,使所述熱導管(2)概成U形體,該複數熱 導管(2)相鄰而平行排列於散熱模組一側,其熱源接觸段 (2〇)等高,用以構成一熱源接觸部位,相鄰熱導管(2)連通 於同一冷媒儲存腔體(10)上之銜接端(21)呈非直線的錯位 5 M379748 排列狀。 如第一、二圖所示,前述空氣冷卻式散熱裝置第一較 佳實施例於使用時,係令該複數熱導管(2)之熱源接觸段 (20)貼抵固定於熱源表面’使熱源所散發的熱傳導至敎導 管⑵的熱源接觸段⑽’再藉㈣複數熱㈣⑵内部的冷 媒快速導向該散熱模組(1)之二冷媒儲存腔體(1〇)内,其中 ,因該複數熱導官(2)連通同_冷媒儲存腔體(1G)的銜接端 -(21)為錯位狀之安排,可分散吸熱的冷媒進位冷媒儲存腔 •體的部位,有助冷媒分散流動,進而藉由連通於該二冷媒 儲存腔體(10)間的複數熱管(11)向外延伸,以及利用複數 散熱體(12)吸收該複數熱管(11)上的熱,藉其本身連續彎 曲狀的型體擴大其散熱表面積’及其中形成的複數通風通 道’而為周遭的空氣或外加氣流予以冷卻。 如第二圖所示的空氣冷卻式散熱裝置第二較佳實施例 中,所述熱導管(2)為扁平狀的管體,並具有數段平直狀的 熱源接觸段(20)串接構成一形成連續彎曲狀的彎曲體,所 ❿述彎曲體兩端為同朝一側延伸的銜接端(21),該複數熱導 管(2)相鄰而平行排列於散熱模組(彳)上,該複數熱導管(2) 相對應的熱源接觸段(20)等高,用以形成複數熱源接觸部 位,相鄰熱導管(2)連通於同一冷媒儲存腔體(1〇)上之銜接 端(21)呈非直線的錯位排列狀。 如第二圖以及第四圖所示,前述空氣冷卻式散熱裝置 第二較佳實施例於使用時,同樣係令該複數熱導管(2)之熱 源接觸段(20)貼抵固定於熱源表面,因所述熱導管(2)具 有複數熱源接觸段(20) ’使用者可依使用環境選用合適的 6 M379748 熱源接觸段(20)接觸熱源(3)(如第四至六圖所示),如此, 使熱源所散發的熱傳導至熱導管(2)的熱源接觸段(2〇),再 藉由該複數熱導管(2)内部的冷媒快速導向該散熱模組(1) 之一冷媒儲存腔體(1〇)内,其中,因該複數熱導管連通 同一冷媒儲存腔體(10)的銜接端(21)為錯位狀之安排,可 分散吸熱的冷媒進位冷媒儲存腔體(1〇)的部位,有助冷媒 刀散机動,進而藉由連通於該二冷媒儲存腔體〇〇)間的複 數熱管⑴)向外延伸’以及利用複數散熱體(12)吸收該複M379748 V. New description: [New technical field] This creation is about a heat sink, especially an air-cooled heat sink design. [Prior Art] The existing heat sink consists of one or more u A heat pipe having a glyph shape, wherein the heat pipe contacts the segment as a heat source, and is provided with a heat conducting block, and the heat pipe is provided with a plurality of fin-shaped fins at both ends thereof extending in parallel. When the heat dissipating device is in use, the heat source contact section of the heat pipe is fixed to the heat source surface in combination with the heat pipe, so that heat radiated from the heat source is transmitted to the heat source contact section of the heat pipe, and then is transferred to the outside through the heat pipe inside the heat pipe, and further Conducted to the plurality of fins to expand the heat dissipating surface area to cool the surrounding air or the applied air stream. However, although the heat dissipating device uses the heat absorbed by the heat pipe to transfer heat to the plurality of heat dissipating tabs 1, the U-shaped heat pipe cannot provide better refrigerant flowability, so that the effect of heat dissipating performance cannot be achieved. New Content] The main purpose of this creation is to provide an air-cooled heat sink that is designed to provide superior heat dissipation over existing heat sinks. In order to achieve the foregoing, the air-cooled heat sink designed by the present invention comprises: a heat dissipation module comprising two refrigerant storage chambers, a plurality of heat pipes and a plurality of heat sinks. The two refrigerant storage chambers are arranged in parallel. The plurality of M379748 heat pipes are connected to the two refrigerant storage chambers and are arranged in parallel intervals. The plurality of heat pipes each comprise a tube body made of a heat conductive material, and the plurality of heat radiators are disposed on the side of the plurality of heat pipes, and The tube body of the adjacent heat pipe contacts; and the plurality of heat pipes are disposed on the same side of the heat dissipation module, each heat pipe comprises a pipe body made of a heat conductive metal material, the pipe body includes at least one heat source contact section and is located The connecting ends of the two ends of the pipe body respectively communicate with the two refrigerant storage cavities to provide a refrigerant flow therein, and the heat source contact sections of the plurality of heat pipes are juxtaposed to form a heat source contact portion, so that the heat source contact section absorbs The heat source is dispersible and transferred to the heat dissipation module to dissipate heat. The present design is characterized by the above air-cooled heat sink. The heat source contact section is provided by using a plurality of adjacent heat pipes to absorb the heat generated by the heat source, and is rapidly dispersed and transferred to the heat dissipation module by the heat absorption of the refrigerant in the heat pipe, and the heat is absorbed by the heat dissipation module. The refrigerant storage chambers on both sides of the group are dispersed to the plurality of heat pipes, and then the heat dissipating surface of the heat pipe is used to expand the heat dissipating surface area, and the airflow flowing therethrough is cooled. Therefore, the present invention can provide an air cooling type heat dissipating device with high heat dissipation performance. [Embodiment] As shown in the figure and the second figure, several preferred embodiments of the present air-cooling heat dissipating device are disclosed. As can be seen from the drawings, the air-cooling heat dissipating device mainly comprises a The heat dissipation module (彳) and the plurality of heat pipes U), wherein: the heat dissipation module (1) comprises two refrigerant storage chambers (10), a plurality of heat pipes (1υ, and a plurality of heat radiators (12), the two refrigerant storage chambers Each of the bodies (10) has a sealed storage chamber of 4 M379748, and a refrigerant is stored therein, and the two refrigerant storage chambers (10) are arranged in parallel, and the plurality of heat pipes (11) each comprise a heat conductive material. The tube body is provided with a refrigerant circulating therein, and the plurality of heat pipes (11) are connected in parallel at intervals between the two refrigerant storage chambers (10): and communicate with the two refrigerant storage chambers (10), The plurality of heat sinks (12) are distributed on the side of the plurality of heat pipes (11) and are in contact with the tubes of the adjacent heat pipes (11). As shown in the first and third figures, in the heat dissipation module (1), the plurality The heat pipe (11) can be a flat pipe member, and the plurality of heat radiators (12) ) is a long strip of continuous curved shape (such as wavy, etc.), each heat sink (12) is disposed between two adjacent heat pipes (11), and the curved portion thereof contacts the side adjacent heat pipe (1彳) The plurality of heat pipes (2) are disposed on one side of the heat dissipation module (彳), and each heat pipe (2) comprises a pipe body made of a heat conductive material for providing a refrigerant to circulate therein The heat pipe (2) may be a flat pipe body, and the pipe body of the heat pipe (2') includes at least one heat source contact section (2〇) and two joint ends (21), and the two joint ends (21) Between the two ends of each heat pipe (2), and respectively connected to the two refrigerant storage chambers (10) for providing refrigerant flow therein, the heat source contact segments (20) of the plurality of heat pipes (11) are adjacent to each other and constitute The heat source contact portion. In the first preferred embodiment of the air-cooling heat sink shown in the first figure, the heat guide (2) is a flat tube body and has a flat heat source contact section ( 20), and a connecting end which is disposed at both ends of the heat source contact section (2〇) and which is curved toward the side, so that the heat pipe (2) is formed into a U-shaped body The plurality of heat pipes (2) are adjacent to each other and arranged in parallel on the side of the heat dissipation module, and the heat source contact section (2〇) is equal in height to form a heat source contact portion, and the adjacent heat pipes (2) are connected to the same refrigerant. The connecting end (21) on the storage cavity (10) is arranged in a non-linear misalignment 5 M379748. As shown in the first and second figures, the first preferred embodiment of the air-cooling heat dissipating device is in use. The heat source contact section (20) of the plurality of heat pipes (2) is attached to the surface of the heat source to transmit heat radiated from the heat source to the heat source contact section (10) of the helium duct (2), and then (4) the plurality of heats (4) (2) the internal refrigerant is quickly guided to the heat dissipation In the refrigerant storage chamber (1〇) of the module (1), wherein the plurality of thermal guides (2) are connected to the connection end of the refrigerant storage chamber (1G), and the (21) is misaligned. The dispersible heat-absorbing refrigerant is carried in the refrigerant storage chamber body portion, which helps the refrigerant to disperse and flow, and then extends outward through the plurality of heat pipes (11) connected between the two refrigerant storage chambers (10), and utilizes a plurality of heat dissipation The body (12) absorbs heat on the plurality of heat pipes (11), by which The continuously curved shape itself expands its heat dissipating surface area & the plurality of ventilation passages formed therein to cool ambient air or applied air flow. In the second preferred embodiment of the air-cooling heat sink shown in the second figure, the heat pipe (2) is a flat tube body and has a plurality of flat heat source contact segments (20) connected in series. Forming a curved body formed in a continuous curved shape, the ends of the curved body are opposite ends extending toward the one side, and the plurality of heat pipes (2) are adjacent to each other and arranged in parallel on the heat dissipation module (彳). The heat source contact section (20) of the plurality of heat pipes (2) is equal in height to form a plurality of heat source contact portions, and the adjacent heat pipes (2) are connected to the joint ends of the same refrigerant storage cavity (1〇) ( 21) Arranged in a non-linear misalignment. As shown in the second and fourth figures, the second preferred embodiment of the air-cooling heat sink is also used to fix the heat source contact section (20) of the plurality of heat pipes (2) to the heat source surface. Because the heat pipe (2) has a plurality of heat source contact sections (20) 'The user can select a suitable 6 M379748 heat source contact section (20) to contact the heat source (3) according to the use environment (as shown in the fourth to sixth figures) In this way, the heat emitted by the heat source is transmitted to the heat source contact section (2〇) of the heat pipe (2), and the refrigerant inside the plurality of heat pipes (2) is quickly guided to the heat dissipation module (1). In the cavity (1〇), wherein the junction end (21) of the plurality of heat pipes connected to the same refrigerant storage cavity (10) is dislocated, the heat-absorbing refrigerant carrier refrigerant storage cavity (1〇) can be dispersed. a portion that facilitates the movement of the refrigerant knife, and then extends outward through a plurality of heat pipes (1) connected between the two refrigerant storage chambers 以及 and absorbs the complex body by using a plurality of heat sinks (12)
數熱管⑴)上的熱,藉其本身連續彎曲狀的型體擴大其散 熱表面積’及其中形成的複數通風通道,巾為周遭的空氣 或外加氣流予以冷卻。 本創作雖已於前述較佳 於前述實施例令所提及之内 神和技術範圍内所作之任何 保護範圍。 實施例中所揭露,但並不僅限 各’在不脫離本創作之設計精 變化與修改,均屬於本創作之 【圖式簡單說明】 第一圖係本創作空氣冷卻 ^ ^ .g ^ _ 散…裝置第一較佳實施例 提供熱源接觸之立體示意圖。 第二圖係第一圖所示空氣冷卻式散熱裝置第一較佳實 施例提供熱源接觸散熱之使用狀態參考圖。 第一圖係本創作空氣冷卻式i㈣ 提供熱源接之立體示意圖。 一較佳貫施例 第四〜六圖係第三圖所 口尸π不空氣冷卻式散埶萝 佳實施例提供熱源接觸散埶 .、、、褒置弟一敉 …、之使用狀態參考圖(—)〜(:)。 7 M379748 【主要元件符號說明】 (1)散熱模組 (10)冷媒儲存腔體 (11)熱管 (12)散熱體 (2) 熱導管 (21)銜接端 (3) 熱源 (20)熱源接觸段The heat on the heat pipe (1) is expanded by its continuously curved profile to expand its heat-dissipating surface area and the plurality of venting channels formed therein, which are cooled by ambient air or an applied gas stream. This creation has been made to the extent that it is within the scope of the above-mentioned embodiments. The disclosures in the examples, but not limited to each of the design changes and modifications without departing from the creation, are all in the creation of the [simplified description of the drawings] The first picture is the creation of air cooling ^ ^ .g ^ _ scattered The first preferred embodiment of the apparatus provides a perspective view of the heat source contact. The second figure is a first preferred embodiment of the air-cooled heat sink shown in the first figure, which provides a reference view of the state of use of the heat source contact heat sink. The first picture is a three-dimensional schematic diagram of the heat source connection provided by the present air-cooled type i (4). A preferred embodiment of the fourth to sixth figures is the third figure of the corpse π non-air-cooled dilute radix. The embodiment provides a heat source to contact the divergence,,,,,,,,,,,,,,, (—)~(:). 7 M379748 [Explanation of main component symbols] (1) Thermal module (10) Refrigerant storage cavity (11) Heat pipe (12) Heat sink (2) Heat pipe (21) Connecting end (3) Heat source (20) Heat source contact section