M352134 八、新型說明: 【新型所屬之技術領域】 本創作關於一種用於發光二極骰 遐之可S周控式震動散熱 器,特指一種利用震動及控制震動時 ^^ ^ 機達到節能及增加 散熱效率之雙重功效的結構。 【先前技術】 如第1圖所示’早期之發光二極體燈具L1,為了纤 :發光二極體D所產生的高熱大多會裝設大面積的散熱鰭 片組C ’此種發光二極_專用之鰭片组,大致上可區分 為散熱侧C1以及燈光安裝侧C2,其中該散熱侧以則 是排除各發光二極體D所產生的高熱,惟,該等散熱縛片 組C十分容易因為重量㉟重或體積過大等種種因素導致 燈具所能安裝的場合受到限制。 如第2圖所示,現今業界為解決上述鰭片組體積過大 …、法裝《又於小型空間的問題,發展出一種類似燈泡形狀 的小型燈具L 2,該燈具L 2主要特色在於,燈具外殼是 乂多片薄片散熱鑛片C 3排列而成,對於燈具l 2内之發 光二極體D所產生之高熱予以排除,並解決前述鰭片組過 大或重量過重的窘境; 惟’别述該等籍片組表面上具有增加了與空氣接觸的 面積’長期使用下熱交換率卻十分有限,其原因在於,位 在韓片周圍的空氣流動率並不高,導致鰭片與空氣之接觸 5 M352134 • 面積雖然增加,但單位體積的空氣續熱量卻有十分限以 致燈具内部容易因空氣熱飽和而升高溫度,影響散熱器組 之散熱效能,若在散熱器上增設一風扇來解決此一問題, 除了增加額外重量及體積外,亦容易增加多於耗電,抵銷 了發光二極體產生之高節能特性。 為此,如何有效解決上述散熱器之各項散熱問題,乃 為本創作所鑽研的課題。 φ 【新型内容】 本創作之主要目的在提供一種用於發光二極體之調控 式震動散熱器,係包含: w二 一散熱器組,係由熱傳導材質所構成,且該散熱器組 具有至少一散熱侧以及燈光裝設侧;以及, ' 力; 至少一震動單元,係設於該散熱器組之任—位置上, 用以控制該散熱n組間定震幅或非固定震幅來產生震動 如此一來,即能有效地增加熱能與周圍空氣之 率’進而提升散熱器之散熱效率。 依據前述之主要特徵,其中該震動單元係利 多個控制器’控制該震動單元之震動時機及 t 而達到有效節能及增加散熱效率之雙重功效。 X,進 依據前述之主要特徵,其中該控制器可為 度調節器, ―器或^ 6 M352134 當前述之控制器為溫度感應器時,其主要是感應散熱器 且之皿度’當其超過第!溫度值時即啟動該震動單元, 々散熱器組產生震動,而提升熱交換率。M352134 VIII. New Description: [New Technology Field] This creation is about a S-controlled vibration radiator for light-emitting diodes, especially when using vibration and vibration control to achieve energy saving and A structure that increases the dual efficiency of heat dissipation efficiency. [Prior Art] As shown in Fig. 1 'Early light-emitting diode lamp L1, for the fiber: the high heat generated by the light-emitting diode D is mostly equipped with a large-area heat-dissipating fin group C' such a light-emitting diode _Special fin group can be roughly divided into heat-dissipating side C1 and light-mounting side C2, wherein the heat-dissipating side is to exclude the high heat generated by each of the light-emitting diodes D, but the heat-dissipating set C is very It is easy to limit the installation of the luminaire due to various factors such as weight 35 or excessive volume. As shown in Fig. 2, in the industry today, in order to solve the problem that the above-mentioned fin group is too large... and the method is small space, a small lamp L 2 similar to a bulb shape is developed, and the main feature of the lamp L 2 is that the lamp The outer casing is formed by arranging a plurality of thin-plate heat-dissipating pieces C 3 , which excludes the high heat generated by the light-emitting diode D in the lamp 12 and solves the problem that the fin group is too large or too heavy; The surface of the group has increased contact with air. The heat exchange rate under long-term use is very limited. The reason is that the air flow rate around the Korean film is not high, resulting in the contact of the fin with the air. 5 M352134 • Although the area is increased, the continuous heat per unit volume of air is very limited, so that the inside of the lamp is easily heated by air heat saturation, which affects the heat dissipation performance of the radiator group. If a fan is added to the radiator to solve this problem One problem, besides adding extra weight and volume, it is also easy to increase more than power consumption, which offsets the high energy-saving characteristics produced by the light-emitting diode. To this end, how to effectively solve the various heat dissipation problems of the above-mentioned radiators is a subject of research in this creation. φ [New content] The main purpose of this creation is to provide a controlled vibration heat sink for a light-emitting diode, comprising: a w-two heat sink set, which is composed of a heat conductive material, and the heat sink set has at least a heat-dissipating side and a lighting installation side; and, 'force; at least one vibration unit, disposed at the position of the heat sink group, for controlling the fixed amplitude or non-fixed amplitude of the heat-distributing n groups to generate As a result of the vibration, the heat energy and the surrounding air rate can be effectively increased, thereby improving the heat dissipation efficiency of the heat sink. According to the foregoing main features, the vibration unit is capable of controlling the vibration timing and the t of the vibration unit to achieve the dual functions of effective energy saving and increased heat dissipation efficiency. X, according to the main features mentioned above, wherein the controller can be a degree adjuster, or a device or a device. When the aforementioned controller is a temperature sensor, it is mainly an induction heat sink and the degree is 'when it exceeds The first! When the temperature value is reached, the vibration unit is activated, and the heat sink group generates vibration to increase the heat exchange rate.
又,溫度感應器亦可進一步地設定多個溫度值,來控 制該震動單元㈣幅度,例如,當溫度感應n感應散熱器王 組溫度超過第1溫度值時,即㈣震動單元產生第^震動 振幅’當溫度感應器感應散熱器組溫度超過第2溫度值 時,即控制震動單Μ生高於第1震動振㈣第2震動幅 度,依此_地_震料元財定頻方式產生震動。 ^前述之控制器為計時器時,係用以累計發光二極體 之點儿時間’當其累計超過—設定值時即啟動該震動單 凡,令散熱器組產生震動,而提升熱交換率。 又’计時器亦可進—步地設定累計時間,來控制該震 動單元震動幅度,例如,者眸 田0十時器累计發光二極體累計點 亮時間超過第1設定值 — 〜m即控制震動單7C產生第丨震動振 巾田4同地w σ十時器累計發光二極體點亮時間超過第2 «又疋值時即控制震動單元產生高於第^震動振幅的第2 震動幅度’依此類推地’控制震動單元以非定頻方式產生 震動。 依據月J述之主要特徵,其中該震動單元可為較常見的 ㈣震動馬達,該馬達係具有—偏心轉子,當該偏心轉子 偏心地在定子内旋轉,同時會產生—震動力。 7 M352134 依據前述之主要特徵,其中該散熱器組可為一體 成型的鋁擠型散熱器組,或是由多片散熱鰭片所組成的散 熱器組’於本創作並不加以侷限。 【實施方式】 有關本創作為上述之目的,所採用之技術手段及其餘 功效,茲舉多個較佳實施例,必配合圖示加以說明如下: 睛參閱第3至6圖,第3圖為本創作用於發光二極體 籲之調控式震動散熱器立體分解示意圖。第4圖為本創作用 於發光二極體之調控式震動散熱器剖面示意圖。第5圖為 本創作用於發光二極體之調控式震動散熱器之另一剖面示 意圖,係顯示該震動單元設於散熱器組的中央位置。第6 圖為本創作用於發光二極體之調控式震動散熱器之剖面示 思圖,係顯示震動單元平均分設於散熱器組周圍。 如該等圖所示,本創作提供一種用於發光二極體之調 馨控式震動散熱器,至少包含:一散熱器組1Q、至少一震動 單兀2〇以及至少一控制器3〇:其中該震動單元2〇平 均地设於該散熱器組i 〇上,而該控制器3 〇用以震動單 疋2 0震動時機及震動頻率’達到有效節能及增加散熱效 率之雙重功效 該散熱器組1 〇,其組成結構可為一體的鋁擠型散熱 器組(如第3至4圖所示)’或是由多片散熱鰭片1 〇 1所 組成(如第5圖所示),本創作中並不加以侷限但,散熱 M352134 器組1 0須為導熱材質所構成,如鋁或銅合金材質,且, 該散熱器組1〇至少具有一散熱侧i i以及燈光裝設側工 2 ’其中該散熱側1 1用以增加空氣接觸面積,而燈光裝 設侧12則是提供單顆或是多顆發光二極體4〇及其驅動 電路裝設之用途(如第4圖所示); 該震動單元2 0 ’係用以產生震動力給前述之散熱器 組1 0,該震動單元2 〇可設於散熱器組1 〇的中央位置 _ (如第5圖所示)或是平均分設於散熱器組周圍上(如 第6圖所示),本創作並不加以侷限,僅要是可令散熱器組 1 0平均地產生震動即可,該震動單元2 〇可為較常見的 微型震動馬達,該馬達具有一偏心轉子(圖中未示),當該 偏心轉子偏心地在馬達之定子内旋轉產生震動力,或是直 接在一般馬達前端裝設一偏心塊(圖中未示),透過偏心塊 旋轉所產生的震動力,令散熱器組i 〇產生震動; 馨該控制器30主要是控制震動單元2〇震動時機或是 震動幅度(如第5圖所示),本創作並不加以侷限,在本實 施例中該控制器20可為一溫度感應器或是一計時器;當 該控制器3 0為一溫度感應器時(圖中未示),用以感應散 熱器組溫度,該溫度感應器上並可預設多組溫度值,當散 熱器組10溫度超過第1溫度值時,即啟動該震動單元2 0產生震動,當散熱器組1〇溫度超過第2溫度值時即 控制震動單元2 0產生高於第χ震動振幅的第2震動幅 9 M352134 f,依此類推地,㈣震動單元2〇以非定頻 動,同理地,當前述之控制器3〇為一計時器時(圖中= 不,係累计發光二極體4〇之點亮時間,當計時器 過一時間值時’即啟動該震動單元2 0產生震動,二t 器並可預先設定多組時間值,用來控制該震動翠元 動^度,當計時器累計發光二極體4〇點亮的 過第1時間值時,即控制震動單元20產生第i震: 幅,相同地,當發光二極體40點亮時間累計超過第3 間值時,計時器即控制震動單元20產生高於第i震動振 幅的第2震動幅度,依此類推地控制震動單元2 〇 頻方式產生震動。 請再次參閱第5至6圖以及第7圖,第7圖為本創作用於發光 二極體之調控式震動散熱器另—立體分_,係顯示震動單元與散熱 Is組嵌合為一體。 如該圖所示,本創作震動單元2 0並不限定必須設於 散熱器組1 〇的何處,原則上,僅要是可令散熱器組工〇 各處平均地產生震動即可,例如:設於散熱器組i 0内部中 央位置(如第5圖所示)、設於散熱器組之散熱韓片之間(如 第6圖所示)皆可;至於,震動單元2〇與散熱器組丄〇兩 者之結合方式’可選擇直接平貼在散熱器◦表面或背 面(如第6圖所示)、相互膠合為一體、相互嵌合為一體(如 第7圖所示)或是利用固定元件(如螺絲)相互固定為一體 M352134 皆可’视實際需求及散熱器組1 0的造型而定,本創作並 不加以侷限。 本創作已藉上述較佳實施例加以說明,以上所述者, =本創作之較佳的實施例,並非用來限定本創作之實施Moreover, the temperature sensor can further set a plurality of temperature values to control the amplitude of the vibration unit (4). For example, when the temperature sensing n senses that the temperature of the radiator group exceeds the first temperature value, that is, (4) the vibration unit generates the second vibration. Amplitude 'When the temperature sensor senses that the temperature of the radiator group exceeds the second temperature value, that is, the control vibration single is higher than the second vibration amplitude of the first vibration vibration (four), and accordingly, the vibration is generated by the frequency_frequency method. . ^When the aforementioned controller is a timer, it is used to accumulate the time of the light-emitting diode. When the cumulative value exceeds the set value, the vibration is started, and the heat sink group generates vibration, and the heat exchange rate is increased. . In addition, the timer can also set the cumulative time to control the vibration amplitude of the vibration unit. For example, the accumulated lighting time of the cumulative LED of the Putian 0 00 is over the first set value - ~m Control vibration single 7C produces the third vibration vibrating towel field 4 with the ground w σ ten-timer cumulative light-emitting diode lighting time exceeds the second «depreciation, that is, the control vibration unit produces a second vibration higher than the second vibration amplitude The amplitude 'and so on' controls the vibration unit to generate vibration in a non-fixed frequency manner. According to the main feature of the month J, wherein the vibration unit can be a more common (four) vibration motor, the motor has an eccentric rotor, and when the eccentric rotor rotates eccentrically in the stator, a vibration force is generated. 7 M352134 According to the above main features, the heat sink set may be an integrally formed aluminum extruded heat sink set, or a heat sink set composed of a plurality of heat sink fins, which is not limited in this creation. [Embodiment] For the above purposes, the technical means and other functions used for the above-mentioned purposes, the preferred embodiments will be described with reference to the following figures: See Figures 3 to 6, and Figure 3 This creation is used for the stereo decomposition of the control type vibration radiator of the light-emitting diode. Fig. 4 is a schematic cross-sectional view of a controlled vibration heat sink for creating a light-emitting diode. Fig. 5 is another cross-sectional view of the controlled vibration heat sink for the light-emitting diode, showing that the vibration unit is disposed at the center of the heat sink. Fig. 6 is a cross-sectional view of the control type vibration radiator for creating a light-emitting diode, showing that the vibration unit is equally distributed around the radiator group. As shown in the figures, the present invention provides a tuned vibration radiator for a light-emitting diode, comprising at least: a radiator set 1Q, at least one vibration unit 2〇, and at least one controller 3〇: The vibration unit 2 is evenly disposed on the heat sink group i ,, and the controller 3 〇 is used to vibrate the single 疋 20 vibration timing and the vibration frequency ′ to achieve effective energy saving and increase heat dissipation efficiency. Group 1 〇, the composition of which can be an integrated aluminum extruded heat sink set (as shown in Figures 3 to 4)' or consists of multiple fins 1 〇1 (as shown in Figure 5), This creation is not limited. However, the heat dissipation M352134 group 10 must be made of a heat conductive material, such as aluminum or copper alloy, and the heat sink set 1〇 has at least one heat dissipation side ii and a lighting installation side 2 'The heat dissipation side 1 1 is used to increase the air contact area, and the light installation side 12 is to provide a single or multiple LEDs 4 and its driving circuit installation (as shown in FIG. 4). ); the vibration unit 20 0 ' is used to generate a shock force to the aforementioned Heater group 10, the vibration unit 2 〇 can be set at the center of the radiator group 1 _ (as shown in Fig. 5) or evenly distributed around the radiator group (as shown in Fig. 6) This creation is not limited. It is only necessary to cause the radiator group 10 to generate an average vibration. The vibration unit 2 can be a relatively common micro-vibration motor having an eccentric rotor (not shown). When the eccentric rotor rotates eccentrically in the stator of the motor to generate a vibration force, or directly installs an eccentric block (not shown) at the front end of the general motor, the shock force generated by the rotation of the eccentric block makes the radiator set i 〇 generates vibration; the controller 30 mainly controls the vibration unit 2 〇 vibration timing or vibration amplitude (as shown in FIG. 5 ), the creation is not limited, in the embodiment, the controller 20 can be a temperature sensor or a timer; when the controller 30 is a temperature sensor (not shown) for sensing the temperature of the radiator group, the temperature sensor can preset a plurality of sets of temperature values When the temperature of the radiator group 10 exceeds the first temperature When the vibration unit 20 is activated to generate vibration, when the temperature of the radiator group 1〇 exceeds the second temperature value, the vibration unit 20 is controlled to generate a second vibration amplitude 9 M352134 f higher than the amplitude of the second vibration, and so on. Ground, (4) The vibration unit 2〇 is not fixed, and similarly, when the aforementioned controller 3 is a timer (in the figure = no, it is the lighting time of the cumulative LED 2〇, when timing When the device passes a time value, the vibration unit 20 is activated to generate vibration, and the second device can set a plurality of sets of time values in advance to control the vibration level of the vibration element. When the timer accumulates the light-emitting diode 4〇 When the first time value is lit, that is, the control vibration unit 20 generates the ith vibration: the same, when the illumination LED cumulative time exceeds the third interval, the timer controls the vibration unit 20 to generate The second vibration amplitude is higher than the amplitude of the i-th vibration, and the vibration unit 2 is controlled to generate vibration in the frequency mode. Please refer to the 5th to 6th and 7th drawings again. The 7th figure is the control type vibration radiator for the light-emitting diode. The three-dimensional sub-section shows that the vibration unit is integrated with the heat-dissisting Is group. As shown in the figure, the present vibrating unit 20 does not limit where it is necessary to be disposed in the radiator group 1 . In principle, it is only necessary to cause the radiator group to generate vibrations evenly everywhere, for example: It is located in the inner center position of the heat sink group i 0 (as shown in Fig. 5) and between the heat sinks of the heat sink group (as shown in Fig. 6); as for the vibration unit 2〇 and the heat sink The combination of the two can be selected as follows: directly on the surface or back of the heat sink (as shown in Figure 6), glued together and integrated into each other (as shown in Figure 7) or The M352134 can be fixed to each other by means of fixing elements (such as screws). The creation is not limited by the actual needs and the shape of the radiator set 10 . The present invention has been described in terms of the preferred embodiments described above, and the preferred embodiment of the present invention is not intended to limit the implementation of the present invention.
II M352134 【圖式簡單說明】 第1圖為習用之散熱器組之結構示意圖。 第2圖為鰭片式散熱器組之結構示意圖。 第3圖為本創作用於發光二極體之調控式震動散熱器立體 分解示意圖。 第4圖為本創作用於發光二極體之調控式震動散熱器剖面 示意圖。 籲第5圖為本創作用於發光二極體之調控式震動散熱器之另 一剖面示意圖’係顯示該震動單元設於散熱器組的中央位 置。 第6圖為本創作用於發光二極體之調控式震動散熱器之剖 面示意圖,係顯示震動單元平均分設於散熱器組周圍。 第7圖為本創作用於發光二極體之調控式震動散熱器另一 立體分解圖’係顯示震動單元與散熱器組嵌合為一體。 【主要元件符號說明】 先前技術: L 1 燈具 L 2 燈具 c 散熱鰭片組 C 1 散熱侧 C 2 燈光安裝侧 12 M352134 c 3 散熱鰭片 D 本創作 發光二極體 1 0 散熱器組 1 0 1 散熱鰭片 1 1 散熱侧 1 2 燈光裝設侧 2 0 震動單元 3 0 控制器 4 0 發光二極體II M352134 [Simple description of the diagram] Figure 1 is a schematic diagram of the structure of the conventional radiator group. Figure 2 is a schematic view of the structure of the finned heat sink set. The third figure is a three-dimensional exploded view of the control type vibration radiator for creating a light-emitting diode. Fig. 4 is a schematic view showing the profile of a controlled vibration radiator for a light-emitting diode. Referring to Fig. 5, another schematic cross-sectional view of the control type vibration radiator for creating a light-emitting diode shows that the vibration unit is disposed at the center of the radiator group. Fig. 6 is a schematic cross-sectional view showing the control type vibration heat sink for the light-emitting diode, showing that the vibration unit is equally distributed around the heat sink group. Fig. 7 is another perspective exploded view of the control type vibration heat sink for the light-emitting diode. The vibration unit is integrated with the heat sink unit. [Main component symbol description] Prior art: L 1 Luminaire L 2 Luminaire c Heat sink fin set C 1 Heat sink side C 2 Light mount side 12 M352134 c 3 Heat sink fin D This light-emitting diode 1 0 Heat sink set 1 0 1 Heat sink fin 1 1 Heat sink side 1 2 Light installation side 2 0 Vibration unit 3 0 Controller 4 0 Light-emitting diode