200826320 九、發明說明: 【發明所屬之技術領域】 本發明係有關於一種發光裝置,尤指一種具有、、w产、甫 償、電壓修正以及突波吸收功效之發光裝置。 【先前技術】 按,照明燈具一直是現代人生 1 而口口 ’全世界 用於照明的電力,約為總用電量的40%,可見人們對於辟 明的需求。近年,以光電半導體技術製造的白色發光二極 體(LED)燈泡,其因具體積小、用電量省、壽命長優點, 支可王在一十一世紀取代鎢絲燈和水銀燈,成為兼具省電 及環保概念的照明光源。而過去2〇多年來,對於發光2 極體的開發,已使我國的發光二極體產值,僅次於日本, 居於世界第二’由此可知’發光二極體實在光電領域中佔 有舉足輕重的地位。 、 以現今所開發之交流發光二極體(acled)為例,其係 多數發光微晶粒所組成(約4 3〇i 1〇〇顆發光微晶 =)’而在施予電源後之點亮過程中,其會因所發出之光 能’進而使得溫度昇高,致使該交流發光二極體 =的笔壓電流OM)特性曲線產生偏移現象,如第^ 户:1係為溫度在T1時之電壓電流特性曲線,而當溫 2 :ΘΤ2時,會使電壓電流特性曲線偏移至如L2之位 H造成㈣降低,而在 使得操作功率卜显苴石达y ^文曰 之晶教制4 4 為一此外,因交流發光二極體 控制良率較低,會使得所製作出之各交流發光 19825 5 200826320 二極體應用之電源多為 成發光光源不均的問題而在疋電壓使用時,則會造 下,會產生—脈衝抑、::者,當電源在瞬間供給的狀況 之情事。 進而易發生交流發光二極體燒毀 職是,如何提彳it —链g ㈣- 有溫度補償、電壓修正以及突 問題。"―極體結構’實成為光電產業中亟待解決之 【發明内容】 且右^以上所述習知技術之問題’本發明係在提供-種 度補償、電壓修正以及突波吸收中之至少一者的功 效之發光裝置。 我力 以接Ϊ:卜=發明係揭露一種發光裝置,其包括-設有用 上且^ ^二導電體之承載元件,—設置於該承載元件 芥来Vi—電體電性連接之發光元件,以及至少-盘該 發先τΜ牛電性連接之修正元件。 一% 之、、^^f知技術,本發明提供至少-修正元件所具有 果度制員、電壓修正以及突波吸收中之至少一者的效 【實施方式】 以下係藉由特定的具體實施例說明本 式’熟習此技藝之人士可由本說明書所揭示之内之二方 瞭解本發明之其他優點與功效。本發明 1地 的具體實施例加以施行或應用,本說明書中=他:同 可基於不同觀點與應用,在不悖離本發明之精‘下 19825 6 200826320 種修飾與變更。 如第 2、3(A)及 3(B)、3 (C)及 3 (D) 、3 (E)及 3 (F) 、4、5 (A)及 5 (b、6、7 (A)至 7 (c) 、8、9 (A)及9(B)、10(A)A10(B)圖所示,係為本發明 發光裝置之相關圖式,將以此些圖式配合詳細說明,^述 本發明發光裝置的較佳實施例。其中,須注意的是,該等 圖式均為簡化之示意圖,僅以示意方式說明本發明之實乂施 例結構。因此’在該等圖式中僅顯示與本發明有關之元 件,且所顯示之元件並非以實際實施時之數目、形狀、及 尺寸比例等加以繪製,其實際實施時之數目、形狀及尺 =例為-種選擇性之設計,且其元件佈局形態可能更為複 雜,於此合先敘明。 百先,如第2圖所示,係為本發明發光裝置1之 一實施例結構示意圖,其包括-承載元件10、一發光元 件11以及至少一修下分杜〗ο x 光-署…以下即分別針對本發明發 先衣置1所揭之前述各物件作詳細說明。 心t載元件10係設有二導電體⑽及101,該二導 :: 幻01係用以接置電源,而該承載元件10之較 优貫施方式係為載具;該二導 (Lead Frame)形成。¥电脰100及⑻係由導線架 該發光元件n係設置於該承載元件1〇 101電性連接,並用以於該二導電請 t ==賴提供光源,而該發光元件η係可實施 i固乂*發光二極體(Ac LED)晶粒或複數個直流發 19825 7 200826320 體(DC _晶粒,如第3⑷圖所示,係以一單 11〇=·光,極體晶粒U°為例,該直峨 元件為早層發光元件結構,但亦可為雙層發光 。此外,該發光元件u係具單一波長或至少二 再:亥發光元件之發光顏色係可為單色或多色。 於A丌::&件11於接置電源後所提供之光源係可實 知為可見光或不可見光(如紫外光或紅外光)。 、 並用:=:Γ元件12係與該發光元件11電性連接, 溫度補=二元:11接置電源後,提供該發光元件11 由第2圖中可知,兮至及收中之至少一者的效果, 與該發光元件U電性隸兀件12細—特定方式 券#罢你# 、眭連接,該特定方式係該修正元件12 =;〇承載兀件1〇所設之導電體1⑽上, 線方式將該發光元件u與 猎由打 成串聯狀態(如第3 ίιη同 凡件12在电〜迴路上形 源供應時,二:=圖之等效電路所示),藉以於電 及突波吸收二 產生溫度補償、電壓修正以 少一者的效果。而該修正元件12之較 收-"、為,麗度補償兀件或電壓修正元件或突波吸 收兀件或具溫度補償、帝 干飞大波及 少二者之元件。4修正以及突波吸收功能中之至 光-:二’如第3(C)及3(D)圖所示,係為W發 先-極體晶粒為例之等效電路圖。 以乂_ 其中,若該修正元件12 θ遥 時,則可提供該發光元心/咖4補償元件 先兀件11 一溫度補償之效果 19825 8 200826320 補償元件所具溫度係數之極性係視所欲補償之實際狀況 而定;若該發光元件11在溫度昇高時在定電壓電源下, 會因電壓電流特性曲線往左偏移造成電流上昇(由11上 昇至12,如第1圖所示),則可實施為正溫度係數阻抗補 償元件阻抗上昇可修正電壓電流特性曲線往左偏移現 象,若該發光元件11在溫度降低時,會因電壓電流特性 _ 曲線往右偏移造成電流降低,實施為正溫度係數阻抗補償 . 元件阻抗下降可修正電壓電流特性曲線往右偏移現象。 其中,若該修正元件12實施為單一電壓修正元件 時,則可提供該發光元件11 一電壓修正之效果,該電壓 修正之效果係在於避免因該發光元件11之晶粒製程控制 良率較低而使得所製作出之應用電源多為不同(發光元件 11之驅動偏壓),若在定電壓使用時,所造成同批元件之 間電流差異產生發光光源不均的問題。而該電壓修正元件 - 可實施為電阻、電容、電感或其他可吸收壓降之元件。 ^ 其中,若該修正元件12實施為單一突波吸收元件 時,則可提供該發光元件11 一突波吸收之效果,該突波 吸收之效果係在於避免電源在瞬間供給的狀況下,會因所 產生之脈衝訊號,導致發光元件11被燒毀之情事,此時 該發光元件11與該修正元件12在電流迴路上形成並聯狀 態,其等效電路圖如第3 ( E)圖所示。而該電壓修正元 件可貫施為壓敏電阻、電容、背納二極體(Z e n e r)或壓敏 電阻材料(如ZnO)所製成之元件。 其中,若該修正元件12實施為具溫度補償、電壓修 9 19825 200826320 正以及突波吸收功能中之至少二者 效果係如同上述,且其盥該發光八斤產生之 士丄 /、/、先兀件11之電性連接可同 =具串聯及並聯狀態’如第3 (F)圖所示,於此不復賢 ,外二如第4及5 (A)圖所示’係為本發明發光裂 置之第二實施例結構示意圖 _ 口此乐一貫施例係如同第一實 例包括一承載元件10、-發光元件11以及至少一佟正 =12’且該些元件之仙與實施方式係 _ 於此不復資述;其中,如第5⑷圖所:,? =弟二實施例與第-實施例之差職在於電性連接之 (第;實施例中所指之特定方式),第二實施例中 光元件η上後,再經打^後Λ 方式設置於該發 _封叙方式)。其等效電路如第5⑴圖所示。 再圖所示’係為本發明發光裝置之第三實施 3=此第三實施例係如同第-及二實施例包括- —發光元件11以及至少一修正元件12,且 ^牛之作用與實施方式係如第一及二實施例中所 :::=復贅述;如圖所示’.可看出第三實施例與第一 13 —二= 列之差別係在於該第三實施例復包括一基板 施例接置該發光元件11(覆晶),而此實 定ΠΓ修正元件12之電性連接方式(前指之特 Γ:,別I實施如第7(Α)及7⑴圖所示。 ,、如昂7 (Α)圖所示,該至少一修正元件12之 10 19825 200826320 該至少,元件12接合於該基板 :二Γ:Γ 示與該發光元件11封|為-體(圖,, ^板13上係形成有複數條導電線路⑷。 圖所示’該至少一修正元件12之 少-修正元件12先製作於該基板13再如第=為= ^:0件11封裝為-體。上述之等效電路如第7⑷圖 再如第8圖所示,係為本發 ⑼示意圖,此第四實施例係如同第之置 :一承載元件1〇、-發光元…及至二; ’且該些元件之作用與實施方式係如第一二 例中所述’於此不復贅述;如圖所示二鈀 與第一、-努二垂 看出弟四貫施例 〜用时— 置^二1 之差別係在於該第四實施例除包括 用4置_光兀件η(覆晶)之基板13夕卜,該 二元:牛12之電性連接方式(前指之特定方式)亦為不同 (如弟9(A)及ι〇(Α)圖所示)。 其中,如第9⑴圖所示,該至少一修正元件以之 广:生連接方式係為該至少一修正元件12先形成於 _上之導電線路(如標號⑷,再如第8圖所示與該二光 :件11封裝為一體,而第9⑴圖之等效電路如第: :所示。如第10(Α)圖所示,該至少—修正元件 =性連接方式係為該至少—修正元件12以|晶方π 於該發光元件11上’再設置於該基板13上並°又 _所示封裝為一體,而第10⑴圖之等效電路 19825 11 200826320 (1\圖、所7^ °而刚相有之封裝中所使用之封裝材料係 可只施為金屬或非金屬,如陶瓷玻璃樹脂或透明塑膠 將前述元件封裝為一體之材料。 ^、 /山由:述及圖5U勺表現,可清楚的了解本發明之技術特 敛及其貫施的方式,主要係透過至少一與該發光元件電性 連接之仏正元件,提供该發光元件於本發明發光装置接置 電源後,具有溫度補償、電壓修正以及突波吸收中之至少 一 2的效果,若同時間,三者效果兼具,不僅可避免因溫 度變化造成電流電壓偏移所導致之電流與功率上昇之問 =(功率控制在一定安全範圍),更可解決因發光元件晶粒 製程控制良率較低,而在定電壓使用時,所造成發光光源 不均的問4,相對地,對於廠商而言則可達到偏壓不同之 晶粒修正曲線可同級出貨以提升出貨良率之功效,此外, 更可在電源瞬間供給的狀況下,吸收電源所產生之脈衝訊 -號(抵抗電源突波),使本發明發光裝置不致被燒毀。 • 上述之實施例僅為例示性說明本發明之原理及其功 V效,而非用於限制本發明。任何熟習此技藝之人士均可在 不違背本發明之精神及範疇下,對上述實施例進行修娜與 變化。因此,本發明之權利保護範圍,應如後述之申請專 利範圍所列。 【圖式簡單說明】 第1圖係為一曲線示意圖,係表示習知高壓發光二極 體電壓電流(V-I)特性曲線之偏移現象; 第2圖係為一結構示意圖,係表示本發明發光裝置 19825 200826320 之第一實施例之結構態樣,· 第3(A)圖係為一结構立 置中之第一麻' 、思0,係表示本發明發光裝 弟仏例之發光元件之結構態樣; Π二施例之發光元件之等效電路; 圖係為一等效電路示意圖,係200826320 IX. Description of the Invention: [Technical Field] The present invention relates to a light-emitting device, and more particularly to a light-emitting device having the effects of producing, compensating, compensating, voltage correcting, and swell absorption. [Prior Art] According to the lighting, lighting has always been a modern life 1 and the mouth of the world's electricity for lighting, about 40% of the total electricity consumption, showing the demand for people. In recent years, white light-emitting diode (LED) bulbs manufactured by optoelectronic semiconductor technology have been replaced by tungsten filament lamps and mercury lamps in the 11th century due to their specific small size, low power consumption and long life. Lighting source with power saving and environmental protection concepts. In the past two years, the development of light-emitting diodes has made China's LED output value second only to Japan, and it is the second in the world. It is known that the light-emitting diodes play an important role in the field of optoelectronics. Status. For example, the AC LEDs (acled) developed today are composed of a plurality of luminescent microcrystals (about 4 3 〇i 1 发光 luminescent crystallites =)' and after the power is applied. During the brightening process, it will cause the temperature to rise due to the emitted light energy, causing the AC light-emitting diode = pen pressure current OM) characteristic curve to shift, such as the first: 1 is the temperature The voltage and current characteristic curve at T1, and when the temperature is 2: ΘΤ2, the voltage current characteristic curve is shifted to the position H such as L2 to cause (4) lowering, and in the operation power, the crystal is 苴 达 曰 曰 曰 曰 晶In addition, because of the low control yield of the AC light-emitting diode, the power supply of the AC 198225 5 200826320 diodes produced is mostly a problem of uneven illumination source. When the voltage is used, it will be created, and it will produce - pulse suppression, ::, when the power supply is instantaneously supplied. In turn, it is prone to AC light-emitting diode burnout. How to raise it - chain g (4) - There are temperature compensation, voltage correction and sudden problems. ""Polar Body Structure" has become an urgent need to be solved in the optoelectronic industry. [Inventive content] and right above. The problem of the prior art described above is that the present invention provides at least - degree compensation, voltage correction, and surge absorption. A luminaire for the efficacy of one. I am trying to connect: Bu=Invention discloses a light-emitting device, which comprises: a carrier member provided with a second electrical conductor, and a light-emitting component disposed on the carrier member and electrically connected to the Vi-electric body. And at least the correction element of the electric connection of the τ Μ 。. The present invention provides at least one of the effects of at least one of the modifier component, the voltage correction, and the surge absorption. [Embodiment] The following is by specific implementation. EXAMPLES Those skilled in the art can understand the other advantages and effects of the present invention from the two aspects disclosed herein. The specific embodiments of the present invention are applied or applied, and in the present specification, the following can be modified and changed according to the different viewpoints and applications without departing from the essence of the present invention. Such as 2, 3 (A) and 3 (B), 3 (C) and 3 (D), 3 (E) and 3 (F), 4, 5 (A) and 5 (b, 6, 7 (A ) to 7 (c), 8, 9 (A) and 9 (B), 10 (A) A10 (B), is the relevant diagram of the illuminating device of the present invention, and will be combined with the details DESCRIPTION OF THE PREFERRED EMBODIMENT(S) The preferred embodiment of the illuminating device of the present invention is described. It is to be noted that the drawings are simplified schematic diagrams, and only the schematic structure of the present invention is illustrated in a schematic manner. Only components related to the present invention are shown in the drawings, and the components shown are not drawn in the actual number, shape, and size ratio, etc., and the number, shape, and rule of the actual implementation are as follows. The design of the nature, and the layout of the components may be more complicated, which is described in the following. First, as shown in FIG. 2, it is a schematic structural view of an embodiment of the light-emitting device 1 of the present invention, which includes a carrier element. 10. A light-emitting element 11 and at least one repaired component. The following is a detailed description of each of the above-mentioned articles disclosed in the present invention. There are two conductors (10) and 101, the two guides:: The magical 01 is used to connect the power supply, and the preferred embodiment of the load-bearing component 10 is a carrier; the two-lead (Lead Frame) is formed. 100 and (8) are electrically connected by the light-emitting element n, and the light-emitting element n is electrically connected to the light-carrying element, and is used to provide a light source for the two-conducting light, and the light-emitting element η can be implemented. Light-emitting diode (Ac LED) grain or a plurality of DC-transmitted 19825 7 200826320 bodies (DC _ die, as shown in Figure 3 (4), with a single 11 〇 = · light, polar body grain U ° as an example The straight element is an early layer light emitting element structure, but may also be a double layer light emitting. In addition, the light emitting element u has a single wavelength or at least two colors: the light emitting color of the light emitting element may be monochromatic or multicolor. The light source provided by the A::& 11 after the power is connected can be known as visible light or invisible light (such as ultraviolet light or infrared light), and: =: Γ element 12 is connected to the light-emitting element 11 Electrical connection, temperature compensation = binary: 11 after the power is connected, the light-emitting element 11 is provided. As can be seen from the second figure, The effect of at least one of the illuminating elements U is electrically connected to the illuminating element 12, and the specific mode is the connection of the correcting element 12 = On the conductor 1 (10), the light-emitting element u and the hunting element are connected in series in a line manner (for example, when the third 同 同 12 12 在 在 在 在 在 形 回路 回路 回路 回路 回路 , , , , , , , , , , , , By means of electricity and surge absorption, the effect of temperature compensation and voltage correction is less. The correction component 12 is more than -", is a Lithium compensation component or a voltage correction component or a surge absorption component. Or components with temperature compensation, emperor flying waves and less. 4 Correction and the oscillating absorption function to the light-:2' as shown in the 3rd (C) and 3(D) diagrams, which is the equivalent circuit diagram of the W-first-polar dies.乂 _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ Depending on the actual condition of the compensation; if the light-emitting element 11 is under constant voltage supply when the temperature rises, the current will rise due to the voltage-current characteristic curve shifting to the left (from 11 to 12, as shown in Figure 1). , the positive temperature coefficient impedance compensating element impedance rise can be corrected to correct the voltage current characteristic curve to the left shift phenomenon. If the light emitting element 11 is lowered in temperature, the current is reduced due to the voltage current characteristic _ curve shifting to the right. Implemented as positive temperature coefficient impedance compensation. The component impedance drop can correct the voltage-current characteristic curve to the right. Wherein, if the correcting element 12 is implemented as a single voltage correcting element, the effect of the voltage correcting of the light emitting element 11 can be provided, and the effect of the voltage correcting is to avoid the low yield control of the crystallizing process by the light emitting element 11. Therefore, the applied power sources are different (the driving bias of the light-emitting element 11), and when used at a constant voltage, the current difference between the same batch of components causes a problem that the light source is uneven. The voltage correction component - can be implemented as a resistor, capacitor, inductor or other component that absorbs voltage drop. Wherein, if the correcting element 12 is implemented as a single surge absorbing element, the effect of the swell absorption of the illuminating element 11 can be provided, and the effect of the absorbing wave is to prevent the power supply from being supplied instantaneously. The generated pulse signal causes the light-emitting element 11 to be burnt. At this time, the light-emitting element 11 and the correction element 12 form a parallel state on the current loop, and the equivalent circuit diagram is as shown in FIG. 3(E). The voltage correcting element can be applied as a component of a varistor, a capacitor, a Zener diode (Z e n e r) or a varistor material (such as ZnO). Wherein, if the correcting element 12 is implemented with temperature compensation, voltage repair 9 19825 200826320 positive and at least two of the surge absorption functions, the effect is as described above, and the light-emitting eight pounds produces a morale /, /, first The electrical connection of the element 11 can be the same as that of the series and the parallel state, as shown in the figure 3 (F), which is not the case, and the second is as shown in the fourth and fifth (A) diagrams. STRUCTURAL STRUCTURE OF THE SECOND EMBODIMENT OF THE LIGHT LIGHTING _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ This is no longer a capital account; among them, as shown in Figure 5(4): The difference between the second embodiment and the first embodiment is electrically connected (the specific manner referred to in the embodiment), and after the optical element η is applied to the second embodiment, it is set by the method of pressing the Λ In the issue of the _ sealing method). The equivalent circuit is shown in Figure 5(1). 3 is a third embodiment of the illuminating device of the present invention. The third embodiment is like the first and second embodiments, including the illuminating element 11 and the at least one correcting element 12, and the function and implementation of the ox. The method is as follows in the first and second embodiments:::=re-description; as shown in the figure, it can be seen that the difference between the third embodiment and the first 13-two= column is that the third embodiment includes A substrate embodiment is connected to the light-emitting element 11 (flip-chip), and the actual connection mode of the correction element 12 is determined (the characteristics of the former refers to: the implementation of the other is shown in Figures 7 (Α) and 7 (1) As shown in the figure of ang 7 (Α), the at least one correction element 12 is 10 19825 200826320. At least, the element 12 is bonded to the substrate: the Γ: 与 and the illuminating element 11 are sealed into a body (Fig. , the board 13 is formed with a plurality of conductive lines (4). The figure shows that the at least one correction element 12 is small - the correction element 12 is first fabricated on the substrate 13 and then as = =0: 0 piece 11 is packaged as - The above equivalent circuit is as shown in Fig. 7 (4) and Fig. 8 is a schematic view of the present invention (9). The fourth embodiment is like the first one: a carrier member 1 〇, - illuminating elements ... and to two; 'and the role and implementation of these elements are as described in the first two examples, 'will not be repeated here; as shown in the figure, two palladium and the first, - The difference between the fourth embodiment of the younger brother and the use of the time - the difference between the two and the second is that the fourth embodiment includes the substrate 13 with the four-side photo-shield η (cladding), the binary: the electricity of the cattle 12 The sexual connection method (the specific method of the former refers to) is also different (as shown in the diagrams of the brothers 9(A) and ι〇(Α).) As shown in Figure 9(1), the at least one correction component is widely used: The connection mode is a conductive line formed by the at least one correction component 12 first on the _ (such as the reference numeral (4), and as shown in FIG. 8 and the two-light: the component 11 is packaged as one body, and the equivalent circuit of the ninth (1) diagram is as The first: is shown. As shown in FIG. 10(Α), the at least-correcting element=sexual connection is the at least—the correcting element 12 is disposed on the light-emitting element 11 on the light-emitting element 11 13 is the same as the package shown in Figure _, and the equivalent circuit of the 10th (1) figure is 19825 11 200826320 (1\图,7^°, and the package material used in the package) It is only used as a metal or non-metal, such as ceramic glass resin or transparent plastic to encapsulate the above components into a single material. ^, /Mountain: Referring to the performance of Figure 5U, the technology of the present invention can be clearly understood and its The method of applying the light-emitting element to at least one of temperature compensation, voltage correction, and surge absorption after the power supply of the light-emitting device of the present invention is provided through at least one of the positive-working elements electrically connected to the light-emitting element. The effect of the three, at the same time, the effect of the three, not only can avoid the current and power rise caused by temperature and voltage changes caused by the temperature = (power control in a certain safe range), can also solve the problem of light-emitting elements The grain process control yield is low, and when the constant voltage is used, the illuminating light source is uneven. 4, relatively, for the manufacturer, the grain correction curve with different bias voltage can be shipped in the same class to improve. The effect of the yield of the goods, in addition, in the case of the instantaneous supply of the power supply, the pulse signal generated by the power source is absorbed (resistance to the power surge), so that the light-emitting device of the present invention does not It was burned. The above-described embodiments are merely illustrative of the principles of the invention and its advantages, and are not intended to limit the invention. Any person skilled in the art can make modifications and variations to the above embodiments without departing from the spirit and scope of the invention. Therefore, the scope of protection of the present invention should be as set forth in the scope of the application patents described below. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram showing a shift phenomenon of a conventional high-voltage light-emitting diode voltage (VI) characteristic curve; FIG. 2 is a schematic structural view showing a light-emitting pattern of the present invention. The structural aspect of the first embodiment of the device 19825 200826320, the third (A) diagram is the first hemp of the structure standing, and the structure of the light-emitting element of the light-emitting device of the present invention is shown. The equivalent circuit of the light-emitting element of the second embodiment; the diagram is an equivalent circuit schematic diagram
=置中之發光元件以交流發光二極體為例轉:明 件串聯之第一等效電路; 勹灼舁知正7L 第3 ( D)圖係為一等效雷立 發光,置中之私η 思圖’係表示本發明 2衣置中之I先讀以交流發光二= The light-emitting element with centering is taken as an example of the alternating current light-emitting diode: the first equivalent circuit of the series connected with the bright part; the L 舁 舁 7 7 7L The third (D) picture is an equivalent ray light, the private η思图' indicates that the first reading of the second garment of the present invention is preceded by an alternating light
件串聯之第二等效電路; 勺正7C 發光:二E) ^為一等效電路示意圖,係表示本發明 I先衣置中之發光元件與修正元件並聯之等 . J 3⑴圖係為一等效電路示意圖,係表示本發明 :光裝置中之發光元件與修正元件串聯及並聯之=電 ' ^目係為-結心意圖,係表示本發明 弟二貫施例之結構態樣; i < 第5(A)圖係為一結構示意圖,係表 置中:第二實施例之發光元件與修正元件電性連接後 結構態樣; 第5(B)®係為-等效電路示意圖’係表示本發明發 光裝置中之第二實施例之發光元件與修正元件電接 後之等效電路; 19825 13 200826320 第-: = =示意圖,係表示本發明發光裝置之 弟二貫施例之結構態樣; 〜 第7(A)及7(B)圖係為結構示咅 光裝置中之第三實_之發、表示本發明發 性連接方式; ’…件、修正元件與基板之電 茫置圖二為^效電路示意圖,係表示本發明發光 連發光元件、修正元件與基板之電性 第四實第』=構意圖’係表示本發明發繼之 光^中9(^mA)圖係為結構示意圖,係表示本發明發 :置中之弟四貫施例之發光元件、 性連接方式;以及 兀仟/、基极之電 第9(B)圖及1〇(Β)圖係為等效電路示意圖,係 第四實施例之發光元件、修正元娜 ^之免性連接方式之等效電路。 『主要元件符號說明】 1 10 100 11 110 12 13 14 發光裝置 承載元件 101 導電體 發光元件 交流發光二極體晶粒 修正元件 基板 導電線路 19825 14The second equivalent circuit of the series is connected; the scoop positive 7C illuminating: two E) ^ is an equivalent circuit schematic diagram showing the illuminating element and the correcting element in the first garment of the present invention in parallel. The J 3 (1) system is a The equivalent circuit diagram shows the invention: the light-emitting element and the correction element in the optical device are connected in series and in parallel with each other, and the electric field is the same as the structure of the second embodiment of the present invention; < 5(A) is a schematic structural view showing the structure of the light-emitting element of the second embodiment electrically connected to the correcting element; 5(B)® is an equivalent circuit schematic ' is an equivalent circuit after the light-emitting element of the second embodiment of the present invention is electrically connected to the correcting element; 19825 13 200826320 The first: - = = schematic diagram showing the second embodiment of the light-emitting device of the present invention Structures; ~ 7(A) and 7(B) are the third embodiment of the structure of the neon device, indicating the hair connection method of the present invention; '...piece, correction component and substrate Figure 2 is a schematic diagram of the circuit of the effect, showing the luminous unit of the invention The correction of the electrical properties of the component and the substrate is the fourth embodiment of the present invention. The representation of the present invention is shown in the schematic diagram of the structure of the present invention. The light-emitting element and the sexual connection method of the embodiment; and the ninth (B) and the first (Β) diagrams of the 兀仟/, the base are equivalent circuit diagrams, and are the light-emitting elements and correction elements of the fourth embodiment. The equivalent circuit of the free connection method. 『Main component symbol description】 1 10 100 11 110 12 13 14 Light-emitting device Carrier element 101 Conductor Light-emitting element AC light-emitting diode die Correction element Substrate Conductive line 19825 14