201008463 九、發明說明: ♦ 【發明所屬之技術領域】 ‘ 本發明涉及一種散熱裝置,尤指一種對 極體模組散熱之散熱裝置。 【先前技術】 電子元件工作時會產生大量熱量,該等 果得不到及時地散出,就會影響電子元件之 命,甚至導致電子元件損毀。 ® 目前通常都在電子元件上安裝一散熱 其進行散熱。常見之一種散熱裝置,包括一 電子元件接觸之基板及設於基板上之複數 列之散熱鰭片。然而,習知散熱裝置基本上 地將熱量排出系統外,排出之熱量不僅會使 境升溫而危害環境,同時也係一種沒有合理 循環能量而造成能量浪費之行為。 0 【發明内容】 一種散熱裝置,包括一第一散熱器、設 第一散熱器上方之一動力轉換裝置、安裝於 換裝置另一端之一風扇及導熱連接該第一 與動力轉換裝置一端之複數熱管,該動力轉 包括一中空殼體、裝設於殼體内之一動力活 氣密活塞、與該動力活塞及氣密活塞分別相 柄連桿組及與該曲柄連桿組相傳動連接之 飛輪組,該動力活塞及氣密活塞在殼體内 發光二 熱量如 工作壽 裝置對 與發熱 間距排 係一味 周圍壞 使用可 置於該 動力轉 散熱器 換裝置 塞、一 連之曲 一曲幸由 往復運 7 201008463 動,並通過曲柄連桿組驅動與曲軸飛輪組連接之風 扇旋轉。 一與習知技術相比,本發明之散熱裝置利用發熱 元件工作日守產生之熱量,經動力轉換裝置轉換為帶 動風扇疑轉之機械能,從而有效利用能量之循環進 仃輔助散熱’進而提高散熱裝置之散熱效率,且不 需要供電設備提供動力。 【實施方式】 卜明參閱圖1至圖2’本發明之散熱裝置包括— 第一散熱器10、設置於該第一散熱器1〇上之— 力轉換裂置40、安裝於該動力轉換裝置40 —端並 面向該第一散熱器1〇之一風扇5〇及導熱連接該 一散熱器10與動力轉換裝置4〇另一端之複數埶管 30°該散熱裝置還包括套設於該動力轉換裝置4〇 亡並支標固定於第一散熱器10之上之一第二散熱 =60。- #熱元件如發光二極體模組 第一散熱器10底面上。 该 請一併參閱圖3,卜沭笛 ^ ^ ώ 上迷弟一散熱器10由導熱 十月b良好之金屬如銅、铭等制 1Π 3 , J鋁寺裂成。該第一散熱器 10呈長方體形,其包括一拓 ^ _ 括矩$基板12及設置於該 :丄面上之複數第一散熱鰭片“。該發光二 極體极組20貼設於該基板12之底面。該基板12 之頂面中部開設有相互平行間 反卞4丁间隔之三溝槽120,以 供對應容置該熱管3〇。該算遒 U為寻属槽120沿該基板12 8 201008463 之縱長方向延伸並平行於基板12之兩相對長側邊 * 緣。該第一散熱器10頂面靠近居中之一溝槽120 • 兩側分別開設有一固定孔122以與二固定件100分 別配合而將該第二散熱器60固定到第一散熱器1 0 之基板12上。該等第一散熱鰭片14相互間隔並平 行於基板12溝槽120排列,在該等第一散熱鰭片 14之間形成複數氣流通道(未標示)。該等第一201008463 IX. Description of the invention: ♦ [Technical field to which the invention pertains] ‘ The present invention relates to a heat dissipating device, and more particularly to a heat dissipating device for dissipating heat from a polar body module. [Prior Art] When an electronic component operates, a large amount of heat is generated, and if it is not released in time, it will affect the life of the electronic component and even cause the electronic component to be damaged. ® Currently, a heat sink is usually installed on the electronic components to dissipate heat. A common heat sink includes a substrate in contact with an electronic component and a plurality of heat dissipating fins disposed on the substrate. However, the conventional heat sink basically discharges heat out of the system, and the heat that is discharged not only causes the environment to heat up and harms the environment, but also acts as a waste of energy without reasonable circulating energy. [Disclosed] A heat dissipating device includes a first heat sink, a power conversion device above the first heat sink, a fan mounted at the other end of the changing device, and a plurality of heat conduction connecting the first end and the power conversion device The heat pipe includes a hollow casing, a power active airtight piston installed in the casing, and a phase connecting rod set of the power piston and the airtight piston, and a driving connection with the crank connecting rod group. In the flywheel group, the power piston and the airtight piston emit two heats in the casing, such as the working life device, and the heat-dissipating distance is arranged in the vicinity, and the surrounding power can be placed in the power-converting radiator to change the device plug, and the one-piece song is fortunately Reciprocating 7 201008463 moves and drives the fan rotation connected to the crankshaft flywheel set through the crank link set. Compared with the prior art, the heat dissipating device of the present invention utilizes the heat generated by the heating element to be operated by the power conversion device, and is converted into a mechanical energy that drives the fan to be turned by the power conversion device, thereby effectively utilizing the energy circulation to assist the heat dissipation, thereby improving The heat dissipation efficiency of the heat sink is not required to provide power to the power supply device. [Embodiment] Referring to Figures 1 to 2, the heat dissipating device of the present invention includes a first heat sink 10, a force conversion split 40 disposed on the first heat sink 1〇, and a power conversion device a heat sink connected to the first heat sink 1 风扇 a fan 5 〇 and a heat transfer connecting the heat sink 10 and the power conversion device 4 at the other end of the plurality of manifolds 30° The device 4 is dying and the support is fixed to one of the first heat sinks 10 and the second heat dissipation is 60. - #Thermal element such as the light-emitting diode module The first heat sink 10 is on the bottom surface. Please refer to Figure 3 together, Bu Yi flute ^ ^ 上 On the fan of a radiator 10 by heat conduction October b good metal such as copper, Ming, etc. 1 Π 3, J aluminum temple split. The first heat sink 10 has a rectangular parallelepiped shape, and includes a top surface of the substrate 12 and a plurality of first heat dissipation fins disposed on the surface of the crucible. The light emitting diode pole set 20 is attached thereto. a bottom surface of the substrate 12. The middle surface of the top surface of the substrate 12 is provided with three trenches 120 spaced apart from each other in parallel to accommodate the heat pipe 3. The calculation port U is the seek channel 120 along the substrate 12. 8 201008463 extends in the longitudinal direction and is parallel to the two opposite long sides* of the substrate 12. The top surface of the first heat sink 10 is adjacent to one of the central trenches 120. • Two fixing holes 122 are defined on both sides to respectively fix the two holes The second heat sink 60 is fixed to the substrate 12 of the first heat sink 110. The first heat sink fins 14 are spaced apart from each other and are arranged parallel to the trenches 120 of the substrate 12, and the first heat dissipation is performed. A plurality of airflow channels (not labeled) are formed between the fins 14. These first
散熱鰭片14對應基板12之二固定孔122處形成一 A 方形通口 140,便於安裝該固定件100。每一散熱 鰭片14之底部均形成有一折邊(未標示),該等 折邊相接共同形成一底平面(未標示),該底平面 與基板1 2之頂面相貼合。 上述發光二極體模組20包括一矩形電路板22 及複數貼設於該電路板22 —面之發光二極體24。 該電路板22在外形上與第一散熱器10之基板12 φ 對應一致,使其另一面貼合於該第一散熱器10之 基板1 2之底面上。該等發光二極體24呈矩陣均勻 排佈於該電路板2 2上,從而將其工作時產生熱量 均勻地傳導至該第一散熱器1 0上。 上述熱管30包括一第一傳熱段32、與該第一 傳熱段32平行間隔設立之一第二傳熱段34及連接 該第一及第二傳熱段32、34之一連接段36。該熱 管30之數量在不同之實施例中可以不同,在本實 施例中,熱管30之數量為三。該三熱管30並列豎 9 201008463The heat dissipating fins 14 form an A-shaped opening 140 corresponding to the two fixing holes 122 of the substrate 12 for facilitating the mounting of the fixing member 100. A bottom edge (not shown) is formed on the bottom of each of the heat dissipating fins 14. The fringes are joined together to form a bottom plane (not shown) which conforms to the top surface of the substrate 12. The LED module 20 includes a rectangular circuit board 22 and a plurality of LEDs 24 attached to the surface of the circuit board 22. The circuit board 22 is identical in shape to the substrate 12 φ of the first heat sink 10, and the other surface thereof is attached to the bottom surface of the substrate 12 of the first heat sink 10. The light-emitting diodes 24 are evenly arranged in a matrix on the circuit board 22, so that heat generated during operation is uniformly conducted to the first heat sink 10. The heat pipe 30 includes a first heat transfer section 32, a second heat transfer section 34 disposed in parallel with the first heat transfer section 32, and a connection section 36 connecting the first and second heat transfer sections 32, 34. . The number of heat pipes 30 may vary in different embodiments, and in this embodiment, the number of heat pipes 30 is three. The three heat pipes 30 are juxtaposed 9 201008463
直安置於該第一散熱器10上,其中每一熱管3〇之 第一傳熱段32分別對應容置於該基板12上之二、、A 槽120内並夾置於該基板12與第一散熱鰭片14之 底面之間。該第一傳熱段3 2之頂部呈扁平狀,以 使第一傳熱段32容置於基板12溝槽120内時,其 頂面與基板12之頂面齊平以供該第一散熱鳍片I* 貼設。該熱管30之連接段36由第一傳熱段32垂 直向上彎折設置,該三熱管30之第二傳熱段34相 互平行並位於該第一散熱鰭片14之上方。該第— 傅熱段32在長度‘八π砀乐—",,,…〜。踢熟管 30第二傳熱段34之自由端可直接與動力轉換裝1 40導熱連接,也可以通過一連接元件與動力轉換 裝置40連接。在本實施該 設在動力轉換裝置4。一端之吸熱體 38為一具有一端開口之中空筒體,其内形成一剛 好谷置该動力轉換裝置4〇 一端之容置部(未標 示)。該吸熱體38之筒壁於靠近第一散埶器1〇: 3一Λ上第平二行間隔開設有三通孔38°,以供該三熱管 内,從而之自由端分別對應穿置於其 熱性相連。該三通孔训沿該吸熱 "妹—、/延伸並平行於該第一散熱器10。 吸熱^ 圖4 ’上述動力轉換裝置4 0與該 相連亚裝设於該第一散熱器1()之上方, 201008463 其包括一中空殼體41、裝設於殼體41内之一動力 ,活塞42、一氣密活塞422、與該動力活塞42、氣 '密活塞422分別相連之一曲柄連桿組43及與續曲 柄連桿組43相傳動連接之一曲轴飛輪纟且。該殼 體41包括一端容置於吸熱體38内之一杈狀主體部 411、一供該曲轴飛輪組44裝設之柱狀頌部412及 一與該頭部41 2 —體形成並與該主體部4 i i相正對 ❹連接之連接部413。該氣密活塞422呈圓杈狀,其 對應置於該主體部411之中部。該氣密活塞4 2 2之 外周緣與該主體部411之内壁相緊密貼合。在氣密 活塞422與該主體部411之密封端之間形成一密封 腔415。該動力活塞42呈圓柱狀,其對應置於該 密封腔415之中部。該動力活塞42之外徑略小於 該密封腔415之内徑,使得該密封腔415被分隔為 相對獨立之動力活塞42與主體部411封閉端之間 ❹之一吸熱腔4151及動力活塞42與該氣密活塞422 之間之一放熱腔4152。該曲柄連桿組43包括一端 與動力活塞42相連接之一第一曲柄連桿431及一 端與該氣密活塞422相速之一第二曲柄連桿432。 §亥第一曲柄連桿431之另一端、該第二曲柄連桿 43 2之另一端分別與置於該殼體41之頭部412内 之曲軸飛輪組44相傳動連接。該曲軸飛輪組44包 括二上下疊置之飛輪441及分別置於二飛輪441之 上並與二飛輪441呈偏心設置之一曲軸442,且下 201008463 面 交 之曲軸442連接該二飛輪441。該二曲轴442相 錯β又置’以與該曲柄連桿組43相配合傳動。該 第一曲柄連桿431與上面之飛輪441上之曲軸442 相連接’該第二曲柄連桿432與下面之飛輪441上 之曲轴442相連接。當動力活塞42、氣密活塞422 在主體部411内往復運動時,與其相連之第一、第 二曲柄連桿431、432將力分別傳給曲軸飛輪組44 ❹之曲轴442 ’由二曲轴442將直線運動轉變為飛 輪441之旋轉運動。該氣密活塞422中央具有一貫 通孔(未標示),以供該第一曲柄連桿431穿過並 連接於該曲軸飛輪組“上。該柱狀頭部412之軸 向與該主體部411之轴向相垂直,且 散熱器W所在平面。該曲轴飛輪二第- 部412内之底邱由a 文裝於該頭 <底邛中央0該頭部412之 一穿孔(未桿干、 _ 4中央具有 木孫不)’以供該曲轴飛輪 ^ 〇 部穿過,進而诖社斗 、、且44之下她 罾 進而連接該風扇5〇。該風 卜柒 一散熱器10之笛 Λ 面向該笛 第一散熱鰭片14,且 喵第 第—散熱器10相平行設置。 取屬50與 述第一散熱器6〇包括一中空 :該散熱筒62外周緣向外延伸而出之散熱筒62、 :鰭片64及由該散熱筒62底部向下延二數第二散 呆政熱器10上之一支架6 ^出迷連 之内徑與該畤鲈,, 该散執衿广 、成成體41之主體部411 .、、、_ 62 致,以使該散妖钤 卜傻對廄 欢熱畸62緊密套設於該主 了應〜 土體部411之 12 201008463 外侧壁上。該散熱筒6 2在位置上對應置於該主體 部411之氣密活塞422及放熱腔4152之週邊。§亥 等第二散熱鰭片64呈放射狀由該散熱筒62之外周 緣垂直向外延伸而出。該支架66通過該二固定件 100與該基板12相垂直連接,進而將該第二散熱 器60以及動力轉換裝置40支撐固定於該第一散熱 器10上。 該散熱裝置處於使用狀態時,發光二極體模組 2〇發光時產生熱量直接被該第一散熱器10之基板 12吸收,再經該三熱管30傳遞至該吸熱體38上, 進而傳遞至動力轉換裝置40之主體部411内之吸 熱腔4151所在一端,根據卡諾循環定理,該密封 腔415之吸熱腔4151内之氣體受熱膨脹,推動動 力活塞42移動,熱空氣隨之進入該放熱腔4152 内,氣雄活塞422被推動向前,放熱腔内之 氣體溫度經由第二散熱器6〇散出而逐漸降低,氣 體壓力也隨著降低,氣密活塞422反向運動,並將 2體:放熱腔4152推往吸熱腔4151,繼而推動 動力活塞42往回移動’周而復始,形成 4力 =密:塞422之往復循環運動過程,帶動4 力活塞…氣密活塞422分別相連之曲柄=桿: 3連動,曲柄連桿組43進而帶動 : 轉動’從而使得與曲軸飛輪組 、且二4 動’產生吹向該第-散熱器10之強制氣:扇5〇轉 13 4 201008463 本發明之散熱裝置,利用發光二極體模組20 ▼ 發光時產生熱量,經動力轉換裝置40轉換為帶動 ^ 風扇5 0旋轉之機械能,從而有效利用能量之循環 提高散熱裝置之散熱效率,且不需要應用供電設備 提供動力。 綜上所述,本發明符合發明專利要件,爰依法 提出專利申請。惟,以上所述者僅為本發明之較佳 實施例,舉凡熟悉本案技藝之人士,在爰依本發明 ® 精神所作之等效修飾或變化,皆應涵蓋於以下之申 請專利範圍内。 【圖式簡單說明】 圖1係本發明之散熱裝置與一發光二極體模 組之立體組合圖。 圖2係圖1之立體分解圖。 圖3係圖1之倒置立體分解圖。 © 圖4係圖1之剖面示意圖。 【主要元件符號說明】 第 一 散 献 器 10 基 板 12 溝槽 120 固 定 孔 122 第 一 散 熱 鰭 片 14 通 σ 140 發 光 二 極 體 模組20 電 路 板 22 發 光 二 極 體 24 熱 管 30 第 一 傳 熱 段 32 第 二 傳熱段 34 14 201008463 連接段 36 吸熱體 38 通孔 380 轉換動力裝置 40 殼體 41 主體部 411 頭部 412 連接部 413 密封腔 415 吸熱腔 4151 放熱腔 4152 動力活塞 42 氣密活塞 422 曲柄連桿組 43 第一曲柄連桿 431 第二曲柄連桿 432 曲軸飛輪組 44 飛輪 441 曲轴 442 風扇 50 第二散熱器 60 散熱筒 62 第二散熱鰭片 64 支架 66 固定件 100Directly disposed on the first heat sink 10, wherein the first heat transfer sections 32 of each heat pipe 3 are respectively disposed in the second slot 120 of the substrate 12, and are sandwiched between the substrate 12 and the first Between the bottom surfaces of a heat sink fin 14. The top of the first heat transfer section 32 is flat, such that when the first heat transfer section 32 is received in the trench 120 of the substrate 12, the top surface thereof is flush with the top surface of the substrate 12 for the first heat dissipation. Fin I* is attached. The connecting section 36 of the heat pipe 30 is vertically bent upwardly from the first heat transfer section 32. The second heat transfer sections 34 of the three heat pipes 30 are parallel to each other and above the first heat radiating fins 14. The first - Fu hot section 32 is in the length 'eight π 砀 — -",,,...~. The free end of the second heat transfer section 34 can be directly thermally coupled to the power conversion unit 140 or can be coupled to the power conversion unit 40 via a connecting member. In the present embodiment, the power conversion device 4 is provided. The heat absorbing body 38 at one end is a hollow cylinder having an opening at one end, and a receiving portion (not shown) which is located at one end of the power conversion device 4 is formed. The wall of the heat absorbing body 38 is adjacent to the first diffuser 1 〇: 3 Λ on the second line is spaced apart by a three-way hole 38° for the three heat pipes, so that the free ends are respectively placed correspondingly Heat connected. The three-way hole is extended along the heat absorption and/or parallel to the first heat sink 10. The heat absorbing device is as shown in Fig. 4, wherein the power conversion device 40 and the connecting device are mounted above the first heat sink 1 (), and the 201008463 includes a hollow casing 41 and a power installed in the casing 41. The piston 42, a hermetic piston 422, a crank link set 43 connected to the power piston 42, the gas 'tight piston 422, respectively, and one of the crank flywheels are connected to the continuous crank link set 43. The housing 41 includes a cylindrical body portion 411 which is received in the heat absorbing body 38 at one end, a columnar shank portion 412 for the crank wheel flywheel assembly 44, and a body portion formed with the head portion 41 2 and The main body portion 4 ii faces the connection portion 413 which is connected to the front side. The airtight piston 422 has a circular shape which is correspondingly placed in the middle of the main body portion 411. The outer periphery of the airtight piston 42 is closely attached to the inner wall of the main body portion 411. A sealed cavity 415 is formed between the hermetic piston 422 and the sealed end of the body portion 411. The power piston 42 has a cylindrical shape and is correspondingly placed in the middle of the sealed chamber 415. The outer diameter of the power piston 42 is slightly smaller than the inner diameter of the sealing cavity 415, so that the sealing cavity 415 is divided into a heat absorbing cavity 4151 and a power piston 42 between the relatively independent power piston 42 and the closed end of the main body portion 411. One of the airtight pistons 422 radiates a cavity 4152. The crank link set 43 includes a first crank link 431 whose one end is connected to the power piston 42, and a second crank link 432 whose one end is at a phase speed with the airtight piston 422. The other end of the first crank link 431 and the other end of the second crank link 43 2 are respectively drivingly coupled to the crankwheel group 44 disposed in the head 412 of the housing 41. The crankshaft flywheel assembly 44 includes two flywheels 441 stacked one above another, and a crankshaft 442 disposed on the second flywheel 441 and eccentrically disposed with the two flywheels 441, and a crankshaft 442 that is interposed with 201008463 is connected to the two flywheels 441. The two crankshafts 442 are in error β and are disposed in cooperation with the crank link set 43. The first crank link 431 is coupled to the crankshaft 442 on the upper flywheel 441. The second crank link 432 is coupled to the crankshaft 442 on the underlying flywheel 441. When the power piston 42 and the airtight piston 422 reciprocate in the main body portion 411, the first and second crank links 431, 432 connected thereto transmit the force to the crankshaft flywheel group 44, respectively, to the crankshaft 442' by the two crankshafts 442. The linear motion is converted into the rotational motion of the flywheel 441. The airtight piston 422 has a through hole (not shown) at the center for the first crank link 431 to pass through and is connected to the crank wheel flywheel group. The axial direction of the cylindrical head portion 412 and the main body portion 411 The axial direction is perpendicular to the plane of the radiator W. The bottom of the crankshaft flywheel second portion 412 is mounted on the head <the bottom of the bottom 00. One of the heads 412 is perforated (not dry, _ 4 Central has a wood grandson not) 'for the crankshaft flywheel ^ 〇 穿过 , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , Facing the flute first heat dissipating fins 14, and the first heat sink 10 is disposed in parallel. The take-up 50 and the first heat sink 6〇 include a hollow: the outer peripheral edge of the heat dissipating tube 62 extends outward to dissipate heat. The tube 62, the fin 64 and the bottom of the heat sink 62 are extended downwards by a number of the second staggered economizer 10, and the inner diameter of the bracket 6 is fascinated by the inner diameter of the bracket. , the main body of the adult body 41 411 ., ,, _ 62 to make the enchanting 傻 傻 廄 廄 廄 廄 62 62 紧密 紧密 紧密 紧密 紧密 紧密 紧密 紧密 紧密 紧密 紧密 土 土The portion of the heat dissipating tube 62 is correspondingly disposed at the periphery of the airtight piston 422 and the heat releasing cavity 4152 of the main body portion 411. The second heat dissipating fin 64 is radially radiated by the portion 411 The outer periphery of the heat sink 62 extends vertically outwardly. The bracket 66 is perpendicularly connected to the substrate 12 through the two fixing members 100, thereby supporting and fixing the second heat sink 60 and the power conversion device 40 to the first heat dissipation. When the heat dissipating device is in use, the heat generated by the LED module 2 is directly absorbed by the substrate 12 of the first heat sink 10, and then transmitted to the heat absorbing body 38 via the three heat pipes 30. And passing to the end of the heat absorption chamber 4151 in the main body portion 411 of the power conversion device 40. According to the Carnot cycle theorem, the gas in the heat absorption chamber 4151 of the sealed chamber 415 is thermally expanded to push the power piston 42 to move, and the hot air follows. Entering the heat release chamber 4152, the gas male piston 422 is pushed forward, the temperature of the gas in the heat release chamber is gradually decreased by the second heat sink 6 , and the gas pressure is also lowered, and the airtight piston 422 is reversely transported. Move, and the 2 body: the heat release chamber 4152 is pushed to the heat absorption chamber 4151, and then the power piston 42 is moved back to the 'return' to form a 4 force = dense: plug 422 reciprocating cycle motion, driving the 4 force piston ... airtight piston 422 The cranks that are connected respectively = the rods: 3 linkages, the crank link group 43 in turn drives: rotates 'so that the crankshaft flywheel set, and the two 4's generate a forced air that blows toward the first radiator_fan: 5 turns 13 4 201008463 The heat dissipating device of the present invention uses the LED module 20 to generate heat during illumination, and is converted by the power conversion device 40 into mechanical energy that drives the rotation of the fan 50, thereby effectively utilizing the energy cycle to improve the heat dissipation of the heat dissipation device. Efficiency, and does not require the application of power equipment to provide power. In summary, the present invention complies with the requirements of the invention patent, and proposes a patent application according to law. However, the above description is only the preferred embodiment of the present invention, and equivalent modifications or variations made by those skilled in the art of the present invention should be included in the following claims. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective assembled view of a heat sink device and a light emitting diode module of the present invention. 2 is an exploded perspective view of FIG. 1. Figure 3 is an inverted perspective exploded view of Figure 1. © Figure 4 is a schematic cross-sectional view of Figure 1. [Main component symbol description] First dispenser 10 Substrate 12 Groove 120 Fixed hole 122 First heat sink fin 14 Pass σ 140 Light-emitting diode module 20 Circuit board 22 Light-emitting diode 24 Heat pipe 30 First heat transfer Section 32 Second heat transfer section 34 14 201008463 Connection section 36 Heat absorbing body 38 Through hole 380 Conversion power unit 40 Housing 41 Main body portion 411 Head portion 412 Connection portion 413 Sealing chamber 415 Heat absorption chamber 4151 Heat release chamber 4152 Power piston 42 Airtight piston 422 crank link set 43 first crank link 431 second crank link 432 crankshaft flywheel set 44 flywheel 441 crankshaft 442 fan 50 second heat sink 60 heat sink 62 second heat sink fin 64 bracket 66 fixture 100
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