M425315 '五、新型說明: 【新型所屬之技術領域】 本創作係涉及一種散熱風扇樽造, 提昇散熱效益功效之新式散熱風屬= 新設計者。 片 【先前技術】 ' 按,散熱風扇應用於電腦、昝 - Β<« ^ 〜盗產品時 ® ]电窃產品之薄形化空間並達到較佳散熱 _令導熱管之—端組合接觸於發熱辟、(二cpu、 另一端則組合接觸於一鰭片構件,以將熱導 ’並將該鰭片構件組設於散熱風扇二」 W <出風口 風扇轉動運作時所產生的出風氣流,以加速 散熱,由此不難瞭解所述鰭片構件於散熱模 本創作所欲探討的技術課題,即是特別 出風口之鰭片構件型態設計加以思索,且特 構件是設置在散熱風扇出風口内部之結構型 扇處於橫置狀態之條件而言,其出風口内部 _之各單元鰭片係呈直立面向間隔配置的型態 韓片與散熱風扇之轉子葉片均為直立面向之 態,且各單元鰭片之間隔均為等分設置,即 道之截面積皆相同,惟,此一習知型態設計 際使用過程中仍舊會產生下述問題點: 以散熱風扇處於橫置狀態之條件而言, 轉子葉片轉動時,其各轉子葉片旋轉時所產 平均分佈狀態’而是散熱風扇外圍產生之氣 央氣流流量之不均等狀態’如此一來,當氣 道過程中’由於習知結構各單元鰭片之間隔 亦即各出風通道截面積大小皆相同,因此反 100. 12. 2 6 特別 組配 是指一種具有 置構造型態創 ’為了配合電 效果’通常係 ),導熱管之 至該續片構件 ’俾藉由散熱 鰭片構件進行 組中之重要角 針對散熱風扇 別是針對鰭片 態,以散熱風 所設鰭片構件 ,亦即各單元 對應關係與型 各單元出風通 於散熱風扇實 當散熱風扇的 生的氣流並非 流流量大於中 流通過出風通 為等分型態’ 而造成散熱風 M425315 100. 12. 2 6 -扇外圍氣流流量受到侷限的情況,進而影響出風量及散熱 效杲,如此造成此種習知散熱風扇鰭片設計上因配置型態 不妥而仍舊不符合實用需求,故仍有加以改善突破之空間 .與必要性存在。 是以,針對習知散熱風扇出風口之鰭片配置結構型態 所存在之問題點,如何開發一種更具理想實用性之創新結 構,'實使用者所企盼,亦係相關業者須努力研發突破之目 標及方向。 ' 有鑑於此,創作人本於多年從事相關產品之製造開發 φ 與設計經驗,針對上述之目標,詳加設計與審慎評估後, 終得一確具實用性之本創作。 【新型内容】 本創作之主要目的,係在提供一種可提昇散熱效益之 散熱模組鰭片配置構造,其所欲解決之問題點,係針對如 何研發出一種更具理想實用性之新式散熱風扇鰭片配置構 造為目標加以改良突破者;所述散熱模組鰭片係設置於散 熱風扇外殼一側之出風口對應位置處,該外殼内部設有具 多數葉片之一旋轉扇葉组與外殼所設入風口相對應,該外 殼外部並配置有導熱管,該導熱管之冷卻端係接觸組合於 . 該出風口一侧以將熱傳導至散熱模組鰭片,該散熱模組鰭 片係包括間隔配置的多數單元片體所構成,各該相臨單元 片體之間相對界定形成有單元出風通道; 本創作解決問題之技術特點,主要是在於該散熱模组 鰭片之各單元片體配置型態,以散熱風扇處於橫置狀態條 件而言,本創作散熱模組鰭片之各單元片體係成橫向配置 型態,令所述單元片體與散熱風扇旋轉扇葉組葉片之直立 面向係互成垂直或交錯對應關係,各單元片體之間相對形 成單元出風通道,各單元出風通道包括臨近旋轉扇葉組之 4 M425315M425315 'V. New description: 【New technology field】 This creation relates to a new type of cooling fan that is designed to reduce the efficiency of heat dissipation. [Previous technology] ' Press, cooling fan is applied to the computer, 昝- Β<« ^ 盗 产品 ® ] ] 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电 电, (two cpu, the other end is combined with a fin member to heat the 'and set the fin member to the cooling fan two' W < the outlet air generated by the fan outlet rotating operation In order to accelerate the heat dissipation, it is not difficult to understand the technical subject to be discussed in the creation of the fin member in the heat dissipation model, that is, the fin member design of the special air outlet is considered, and the special member is disposed in the cooling fan. In the condition that the structural fan inside the air outlet is in a horizontal state, the fins of each unit in the air outlet are arranged in an upright orientation, and the rotor blades of the cooling fan are in an upright orientation. The spacing of the fins of each unit is equally divided, that is, the cross-sectional areas of the channels are the same. However, the following problems still occur during the use of the conventional design: The cooling fan is in a horizontal state. In terms of conditions, when the rotor blades rotate, the average distribution state of the rotor blades when they rotate is 'the uneven state of the airflow flow generated by the periphery of the radiator fan'. Thus, during the airway process, 'because of the conventional structure The spacing of the fins of each unit, that is, the cross-sectional area of each air outlet channel are the same, so the reverse 100. 12. 2 6 special combination refers to a type of structural type created in order to match the electrical effect 'usually), the heat pipe The slab member 俾 the important angle in the group by the heat dissipating fin member is directed to the fin state for the heat dissipating fan, and the fin member is disposed by the heat dissipating wind, that is, the correspondence between each unit and the unit of the type The wind that passes through the cooling fan and the cooling fan is not the flow rate is greater than the middle flow through the outlet. The cooling air is M425315 100. 12. 2 6 - The fan airflow is limited, and then Affecting the air volume and heat dissipation effect, this kind of conventional cooling fan fin design still does not meet the practical needs due to the improper configuration type, so it still needs to be changed. The space for good breakthroughs and the necessity exists. Therefore, in view of the problems existing in the fin configuration structure of the conventional cooling fan air outlet, how to develop an innovative structure with more ideal and practicality, 'the real user hopes, and the related industry must strive to develop breakthroughs. Goals and directions. In view of this, the creator has been engaged in the manufacturing and development of related products and design experience for many years. After detailed design and careful evaluation, the author has finally achieved a practical and practical creation. [New content] The main purpose of this creation is to provide a heat dissipation module fin configuration that can improve the heat dissipation efficiency. The problem to be solved is to develop a new type of cooling fan that is more ideal and practical. The fin arrangement is configured to improve the breakout target; the heat dissipation module fin is disposed at a corresponding position of the air outlet on one side of the heat dissipation fan casing, and the outer casing is provided with a rotating blade group and a casing Corresponding to the air inlet, a heat pipe is disposed outside the casing, and the cooling end of the heat pipe is combined and combined with the air outlet side to conduct heat to the heat dissipation module fins, and the heat dissipation module fins include a space. The majority of the unit body is configured, and each of the adjacent unit pieces is oppositely defined to form a unit air outlet channel; the technical feature of the solution to the problem is mainly the unit configuration of the fins of the heat dissipation module In terms of the type, in the condition that the cooling fan is in the horizontal state, the unit system of the fins of the heat dissipation module of the present invention is in a horizontal configuration type, so that the unit The body and the fan of the cooling fan rotate the blade set upright. The facing faces are perpendicular or staggered, and the unit body forms a unit air outlet passage. The unit air outlet channel includes the adjacent rotating fan blade group. 4 M425315
' 100. 12. 2 G 内側部,以及相對遠離旋轉扇葉組之外側部;且其中,各 橫向配置的單元片體係呈傾斜設置型態,並構成各單元出 風通道之外側部高度係大於内側部之空間型態; 藉此f新獨特設計’使本創作對照先前技術而言,俾 可f應旋轉扇某组旋轉時外圍氣流流量大於中央氣流流量 之狀態’進而達到大幅提昇散熱風扇散熱效率之實用進步 性。'100. 12. 2 G inner side portion, and relatively far from the outer side of the rotating blade group; and wherein the laterally arranged unit piece systems are in an inclined arrangement type, and the heights of the outer side portions of the unit outlet passages are larger than The spatial pattern of the inner part; thus, the new unique design of 'following the creation of the original fan, the external airflow of the rotating fan should be greater than the state of the central airflow when rotating a group of rotating fans' Practical and progressive efficiency.
3 、4圖所 配置構造之 專利申請上 設置於散熱 實施例是設 具多數葉片 對應,該外 卻端31係接 模組鰭片10 元片體11所' 有單元出風 風屬20處於 片體11係成 單元片體11 交錯對應關 元片體11之 各單元出風 及相對遠 向配置的單 風通道12之 【實施方式 請參閱 熱效益之散 施例僅供說 所述散熱模 風口 22對應 ),該外殼 外殼21所設 管30 ,該導 側’以將熱 包括間隔配 體丨1之間相 設計主要在 熱模組鰭片 圖所揭狀態 直立面向係 23之立向角 道12,如第 茶組24之内 部121 ;且 型態,並構 第 1、2、 熱模組鰭片 明之用,在 組鰭片10係 位置處(本 21内部設有 入風口 25相 熱管30之冷 傳導至散熱 置的多數單 對界定形成 於:以散熱 10之各單元 ),令所述 互成垂直或 度),各單 6圖所示, 側部122 , 其中,各横 成各單元出 示,係本創 較佳實施例 並不受此結 風扇20外殼 在出風口 22 23之一旋轉 殼21外部並 觸組合於該 ,該散熱模 構成,各該 通道12 ;本 橫置狀態條 橫向配置型 與散熱風扇 係(註:此 間相對形成 $ $ 12包括 離旋轉扇葉 元片體11係 外側邹121 作可提昇散 ,惟此等實 構之限制。 21 —側之出 内部空間中 扇葉組24與 配置有導熱 出風口 22 — 組鰭片10係 相臨單元片 創作之核心 件而言,散 態(參第2 20葉片23之 取決於葉片 單元出風通 臨近旋轉扇 組24之外側 呈傾斜設置 南度係大於 M425315 100. 12. 2 6 •内側部122之空間型態(僅標示於第5 、6圖)。 運作 作時 推送 W1及 標不 置, 122 出風 多, 12外 散敎 大圖 之連 ,且 於對 構成 元片 21内 散熱 20外 所示 置構 藉由上述之結構组成設計,本創作之散熱風扇.20 時,如第4圖所示,該旋轉扇葉組24之葉片23旋轉運 (如箭號R1所示),即朝出風口 22之散熱模組鰭片10 出氣流,該氣流包括旋轉扇葉組24外圍所產生之氣流 中央所產生之氣流W2,且氣流W1強度大於氣流W2 (僅 於第4圖),係本創作之散熱模組鰭片10係呈橫向設 - 且各單元出風通道12之外側部121高度係大於内側部 . 之結構型態,(參第6圖所揭H1大於H2 ),即各單元 通道12外側部121可通過之氣流量相對較内側部122 ® 俾可使該氣流W1通過散熱模組鰭片10各單元出風通道 側部121時能大量增加出風量,以提昇散熱風扇20之 效率。 如第6圖所示,為該散熱模組鰭片10平面側視放 ,所述各單元片體11兩側可一體結合呈向上曲折延伸 接片16,各單元片體11藉由該連接片16相互抵靠結合 令對應單元出風通道12外側部121之連接片16高度大 應單元出風通道12内側部122之連接片16高度,藉此 單元片體11之橫面向傾斜型態。 ® 如第3 、4圖所示,其中該散熱模組鰭片10之單 ,體11内端係更形成有一凸伸緣部15向内延伸至該外殼 部,使該散熱模組鰭片10散熱面積擴大,藉此以提升 風扇20之散熱效率。 補充'說明的一點是,該出風口 22相對於散熱風扇 殼21可為外徑内縮之縮口式結構型態(如第1至5圖 ),但不侷限於此種型態。 功效說明: 本創作功效增進之事實如下: 本創作所揭「可提昇散熱效益之散熱模組鰭片配 6 M425315 100. 12. 2 6 造」主要是藉由散熱模組鰭片之各單元片體係成橫面向配 置型態,且各橫向配置的單元片體係呈傾斜設置型態,並 構成各單元出風通道之外側部高度係大於内側部之空間型 態,使本創作對照【先前技術】所提各單元鰭片之間隔均 為等分設置型態而言,俾可令該散熱風扇外圍所產生之氣 流,於通過各單元通道外側部時能大量增加出風量,而能 達到大幅提昇散熱風扇散熱效率之實用進步性。 上述實施例所揭示者係藉以具體說明本創作,且文中 雖透過特定的術語進行說明,當不能以此限定本新型創作 之專利範圍;熟悉此項技術領域之人士當可在瞭解本創作 之精神與原則後對其進行變更與修改而達到等效目的,而 此等變更與修改,皆應涵蓋於如后所述申請專利範圍所界 定之範疇中。 M425315 卜圖圖圖圖圖圖 ® 1 2 3 4 5 6 第第第第第 100. 12. 2 6 單說明】 本創作結構較佳實施例之組合立體圖。 本創作結構較佳實施例之分解立體圖一。 本創作結構較佳實施例之分解立體圖二。 本創作之使用狀態示意圖。 本創作結構較佳實施例之平面側視圖。 本創作之散熱模組鰭片平面側視放大示意圖。 【主要元件符號說明 散熱模組鰭片 單元片體 單元出風通道 外側部 内側部 &伸緣部 連接片 散熱風扇 外殼 出風口 葉片 旋轉扇葉組 入風口 導熱管 〇 2 2 2 2 0 2 1 2 2 2 3 2 4 2 5 冷卻端 箭號The patent application of the configuration of 3 and 4 is set in the heat dissipation embodiment, which is provided with a plurality of blades, and the outer end 31 is connected to the module fin 10 yuan piece 11 'there is a unit outwind wind 20 is in the piece The body 11 is formed into a unit body 11 and is interlaced with the unit air outlets of the unit element body 11 and the relatively wind direction arrangement of the single air passages 12 [for the implementation, please refer to the thermal efficiency of the embodiment. Corresponding to 22), the outer casing 21 is provided with a tube 30, the guiding side 'to design the phase between the heat including the spacing ligand 丨1, which is mainly in the state of the thermal module fin diagram, and the vertical angle 12 of the vertical facing surface 23 For example, the interior 121 of the tea group 24; and the type, and the first and second heat module fins are used for the purpose of the group fin 10 series (the inside of the 21 is provided with the air inlet 25 phase heat pipe 30) The majority of the single pair of cold conduction to heat dissipation is defined by: each unit of heat dissipation 10, such that the mutual vertical or degree), as shown in each of the six figures, the side portion 122, wherein each of the horizontal units is presented , the preferred embodiment of the present invention is not subject to the casing of the junction fan 20 One of the air outlets 22 23 is externally coupled to the rotating shell 21 and is combined with the heat radiating mold, each of the channels 12; the horizontally disposed state strip is disposed laterally and the cooling fan system (note: the relative formation of the $ 12 includes rotation The fan blade element body 11 is outside the wall 121 can be lifted up, but these physical constraints are limited. 21 - The side of the fan blade group 24 in the inner space is arranged with the heat conduction air outlet 22 - the group of fins 10 is adjacent For the core piece of the creation of the die, the scatter state (the 222th blade 23 depends on the blade unit, and the wind direction is adjacent to the outer side of the rotating fan group 24, and the south side is larger than M425315. 100. 12. 2 6 • the inner side The spatial pattern of 122 (only shown in Figures 5 and 6). When operating, push W1 and the standard are not set, 122 is more windy, 12 is connected to the larger image, and the heat is 20 in the constituent element 21. The illustrated structure is designed by the above-mentioned structural composition. When the cooling fan of the present invention is .20, as shown in FIG. 4, the blade 23 of the rotating blade group 24 is rotated (as indicated by the arrow R1), that is, The heat dissipation module fin 10 of the air outlet 22 outputs airflow, The airflow includes the airflow W2 generated by the center of the airflow generated by the periphery of the rotating blade group 24, and the airflow W1 intensity is greater than the airflow W2 (only in FIG. 4), and the heat dissipation module fins 10 of the present invention are horizontally disposed - and The height of the outer side portion 121 of each unit outlet passage 12 is greater than that of the inner portion. (refer to FIG. 6 that H1 is greater than H2), that is, the air flow of the outer portion 121 of each unit passage 12 can be relatively relatively inner side. The 122 ® 俾 can increase the air volume when the airflow W1 passes through the air outlet passage side 121 of each unit of the heat dissipation module fin 10 to improve the efficiency of the cooling fan 20. As shown in FIG. 6 , the heat dissipation module fins 10 are arranged in a plane view, and the two sides of the unit body 11 can be integrally combined to form an upward zigzag extension piece 16 , and each unit piece 11 is connected by the connecting piece. The mutual abutment 16 causes the height of the connecting piece 16 of the outer portion 121 of the corresponding unit air outlet passage 12 to be the height of the connecting piece 16 of the inner portion 122 of the unit air outlet passage 12, whereby the lateral direction of the unit piece body 11 is inclined. As shown in Figures 3 and 4, wherein the heat dissipation module fin 10 is formed, the inner end of the body 11 is further formed with a convex edge portion 15 extending inwardly to the outer casing portion, so that the heat dissipation module fin 10 The heat dissipation area is enlarged to thereby increase the heat dissipation efficiency of the fan 20. It is to be noted that the air outlet 22 may be a shrink-type structure in which the outer diameter is retracted relative to the heat dissipation fan case 21 (as shown in Figs. 1 to 5), but is not limited to this type. Efficacy Description: The facts of this creation enhancement are as follows: The heat dissipation module fins that can improve the heat dissipation efficiency are 6 M425315 100. 12. 2 6 made mainly by the fins of the heat dissipation module fins. The system is arranged in a laterally facing configuration, and the laterally arranged unit piece systems are in an inclined setting configuration, and constitute a spatial pattern in which the height of the side of the outlet passage of each unit is larger than that of the inner portion, so that the creation is compared with the prior art. In the case where the spacing of the fins of each unit is equally divided, the airflow generated by the periphery of the cooling fan can greatly increase the airflow when passing through the outer portion of each unit passage, thereby achieving a substantial increase in heat dissipation. Practical advancement of fan cooling efficiency. The disclosures of the above embodiments are used to specifically explain the present creation, and although the descriptions are made through specific terms, the scope of patents of the novel creation cannot be limited thereby; those skilled in the art can understand the spirit of the creation. Changes and modifications are made to the equivalent purpose, and such changes and modifications are to be included in the scope defined by the scope of the patent application as described later. M425315 卜图图图图图 1 1 3 3 4 5 6 No. 100. 12. 2 6 Single explanation] A combined perspective view of a preferred embodiment of the authoring structure. An exploded perspective view of the preferred embodiment of the present construction. An exploded perspective view of the preferred embodiment of the present construction. A schematic diagram of the state of use of this creation. A plan side view of a preferred embodiment of the present authoring structure. The planar view of the fin of the heat dissipation module of the present invention is enlarged. [Main component symbol description Heat dissipation module Fin unit Unit body Outlet channel Outer side Inner part & Extension edge connection piece Cooling fan case Outlet port Blade Rotating fan blade inlet air inlet Heat pipe 〇 2 2 2 2 0 2 1 2 2 2 3 2 4 2 5 Cooling arrow
W W 2 8W W 2 8