TW201246528A - A light emitting device - Google Patents

Abstract

There is disclosed a light emitting device including a substrate; a first electrode part provided on the substrate; a light emitting part provided in the first electrode part, the light emitting part configured of an organic light emitting material; and a second electrode part provided in the light emitting part, wherein a plurality of regions separated and insulated from each other are provided in at least one of the first and second electrode parts, and voltages having a different polarity from each other are supplied to the plurality of the regions, respectively, to suppress brightness difference generated in the light emitting part. The light emitting device according to the embodiments of the invention can enhance brightness uniformity by controlling a driving of a panel based on a value of a voltage or current measured after applied to an auxiliary electrode part of a region where brightness deterioration is generated.

Description

201246528 VI. Description of the Invention: [Technical Field] The present invention relates to a light-emitting device including an organic light-emitting portion, and more particularly to a light-emitting device capable of controlling brightness, thereby reducing a local brightness difference generated in the light-emitting portion. [Prior Art] The $' organic light emitting diode (OLED) includes an anode, an organic light-emitting portion on the anode, and a cathode 0 on the organic light-emitting portion. When electric power is applied to the organic light-emitting diode When the anode and the cathode are in the body, a hole is injected from the anode into the organic light-emitting portion, and electrons are injected from the cathode into the organic light-emitting portion. The holes and electrons injected into the organic light-emitting portion are recombined in the organic light-emitting portion to form excitons. When such excitons migrate from the excitation state into the groundstate, the light is emitted. When the anode, the cathode, and the organic light-emitting portion are in contact with moisture, oxygen, nitrogen oxides (NOx), and the like contained in the air, the properties and service life of the anode, the cathode, and the organic light-emitting portion are remarkably deteriorated. Therefore, a protective layer is formed on the anode, the cathode, and the organic light-emitting portion. The organic light-emitting diode can be fabricated as a thin film and can artificially reduce the thickness of the light source. Therefore, less temperature increase tendency and low power drive can be achieved in the organic light emitting diode. In addition, the organic light-emitting diode uses a variety of different types of organic light-emitting materials 201246528, and the organic light-emitting diode can be used as a panel of a display device. The polar body has been widely used in liquid crystal display devices and various backlight units. x(10), Displaying the Sparks Figure 1 is a schematic diagram of the I1 Xing negative Ray 供应 supply process in a conventional organic light-emitting device. In the conventional organic light-emitting device 10 of the electric & (+) voltage is supplied to the placed electrode pad along the right side of the organic light-emitting portion buckle, and (a) the voltage is supplied to the placed electrode pad along the left side and the side of the organic light-emitting portion buckle. On the other hand side and the bottom side, the charge is high in the vicinity of the side and the edge of the organic light-emitting portion 2'. As a result of the electric resistance indicated by the arrow in the "first figure", X' is gradually lowered. A is toward the center because the edge region of the organic light-emitting portion 2 has the highest positive and negative voltage with the highest voltage and brightness. Further, the central portion of the organic light-emitting portion 20 has the lowest positive voltage and brightness. , °T & degree' For example, in the 25G mm X25G mm size organic light-emitting portion 2 (), if the brightness of the edge region is 500 turbid light (cd), the brightness of the central region will be 25 turbid light, the brightness difference exceed. Such a difference in luminance makes it difficult to generate high luminance, and the negative life of the organic light-emitting portion 20 can be adversely affected. In the meantime, another light-emitting diode disclosed in the Korean patent Να 10_20_05〇95〇 uses an auxiliary electrode. Because of the electrical resistance of the material normally used for the anode, there is a significant difference between the brightness of the central region of the edge of the organic hairline. 201246528 In other words, the charge density in each side region and edge region of the organic light-emitting portion is south, and the charge density gradually decreases toward the center due to the resistance. Therefore, the organic light-emitting portion has the highest voltage and the highest brightness. The field /, in addition, the organic light-emitting portion 'has a central low voltage and a minimum brightness with a minimum positive charge density. w. Most If this brightness difference is generated, _ to achieve high brightness and adversely affect the service life of the organic light-emitting diode. In order to solve this defect, the lake has an auxiliary electrode on the anode, and the auxiliary electrode has a lower resistance value than the anode. Therefore, the current is actually transmitted to the central region of the organic light-emitting diode. However, even in this case, in the auxiliary electrode, the resistance value at the center is turned off against the resistance of the external region. This problem is not completely solved because of the difference in the current that is turned to the per-area. SUMMARY OF THE INVENTION Accordingly, an embodiment of the present invention provides an organic light-emitting device. In order to solve these problems, the purpose of the embodiment is to provide an organic light-emitting diode device having a novel current supply method' which reduces the difference in luminance between the edge and the center of the organic light-emitting diode. . Another object of the present invention is to provide a light-emitting device which is capable of shutting off an electrode bank in an area where luminance degradation occurs, and which enhances uniformity of brightness according to the measured voltage or current value through driving of the control panel. It is still another object of the present invention to provide a light-emitting device capable of accurately and efficiently controlling a panel through a measuring panel such as a voltage, a current, and a four-product characteristic after forming a sensing resistor in the auxiliary electrode. Another object of the present invention is to provide a light-emitting device which can simplify the production process and reduce the complexity of the external circuit by providing a sensing resistor integrally formed with the auxiliary electrode to omit an additional process of providing an additional sensing resistor externally. In order to achieve these and other advantages of the present invention, the present invention will be embodied and broadly described. A light-emitting device includes a substrate; a first electrode portion is provided on the substrate; and a light-emitting portion is provided. In an electrode portion, the light emitting portion includes an organic light emitting material; the second electrode portion is provided in the light emitting portion, wherein the surfaces separated from each other and insulated are at least one of the cake electrode portion and the second electrode portion, and include each other Power supplies of different polarities are supplied to the plurality of regions, respectively, to suppress the luminance difference generated in the light-emitting portion. The first region and the second region insulated from each other are formed in the first electrode portion alternately along the vicinity of the predetermined region of the first electrode portion. A first power supply having a predetermined polarity is supplied to the first area and a second power supply having a reduced polarity is supplied to the second area. The light-emitting portion ' in the first electrode portion contacting the first region does not contact the second electrode portion. The first electrode portion contacts the two electrode portions in the two regions without contacting the light portion. The 〃 illuminating device also contains (4) bribes and electricity (four) on the Ministry. The first electrode portion in the boundary between the first region and the first interval is removed, and the insulating portion is placed on the boundary where the first electrode portion is removed. When the first power source is in polarity, the second power source is (i) polarity, and when the first power source is (-) polarity, the second power source is (+) polarity. The first electrode portion has a first region and a second region. 201246528 The second district is electrically isolated from each other. The edge of the first electrode portion includes a blank region in which the first region and the second region are not arranged. The same area of the first area and the second area are arranged adjacent to the blank area. According to another aspect of the present invention, a light-emitting device includes a substrate; an electrode portion is provided on the substrate; a light-emitting portion is provided in the first electrode portion, the light-emitting portion includes organic light-emitting (four); and the second electrode portion is Provided in the light emitting portion; and a current supply device for supplying power to at least one of the first and second electrode portions. At least the first and second electrode portions provide a plurality of faces that are separated from each other and insulated. The current supply means includes a remaining tool for controlling the current value to be applied to the first electrode portion or the second electrode portion, thereby suppressing the difference in luminance generated in the light-emitting portion. The current supply means includes a first and a second connection pad, the first connection pad is for supplying power to the predetermined ones of the zones, and the second connection is for supplying a power source having a reverse polarity to the other zone. The resistance tool controls the current value supplied to the connection port or the second port. The k regions include a first region and a second region insulated from and spaced apart from the first region. Current

201246528 Power supply line branch. Λ 歧 置 包含 包含 包含 包含 包含 包含 , , , , , , , , , , , , , , , , , , , , , 杂 杂 杂 杂 杂 杂 杂 杂 杂 杂 杂 杂 杂 杂 杂 杂The current value of the connection pad or the second electrode pad. The first electrode portion includes a plurality of side faces, and each of the regions and the second region possessed by the first electrode portion. The closer the resistance tool is to the edge of the first power supply line, the greater the resistance value. A resistance tool connects each of the - connection pads or each of the second ports. Two or more first ports or two or more second ports are branched from a single resistance tool. The first connection pad extends along the bottom of the insulating frame and passes through the insulating frame. The first power source is a (+) voltage, the second power source is a (a) voltage, and the resistor is arranged between the first power supply line and the first connection pad. According to still another aspect of the present invention, a light-emitting device includes a substrate, a first electrode port is disposed on the substrate, an auxiliary electrode portion is disposed in the first electrode portion, and a light-emitting portion is disposed in the auxiliary electrode portion. And the second electrode portion is provided in the light source J5 in the 'power supply portion' for supplying power to the light emitting portion via the first electrode portion, the second electrode portion, and the auxiliary electrode portion; and the control portion, the connection auxiliary The electrode portion measures the current or voltage applied to the auxiliary electrode, and controls the power supply of the power supply portion according to the measurement result to suppress the luminance difference generated in the light-emitting portion. The auxiliary electrode portion includes a power receiving portion 'for forming an external periphery; the wiring portion, the connected power receiving portion' wiring portion is closed by the power receiving portion, and the sensing is provided in the power receiving portion. Breaking S. 9 201246528 The power receiving portion includes an outwardly extending (four)-extension portion; the second extending portion extends from the end of the second extending portion; and the electrode exposed portion is formed by the first and second extending portions. The sensing resistors are arranged from the side of the exposed portion of the electrode to the second extension. One end of the sense resistor is spaced from the second extension. A plurality of sensing details are provided which are expected to be at a predetermined edge of the power receiving portion and at another opposite edge. A plurality of electrical measurements are provided, and these resistances are spaced apart from each other along the periphery of the power reduction. The hairline further includes an insulating portion provided on the auxiliary electrode portion to assist the electrode portion and the light emitting portion at the edges. Control the source of supply by comparing the current flowing to the set resistor containing the _ resistor or applying it to the set resistor = explicit reference or reference micro. The resistance value of the set resistor is the sum of the resistance value of the sense resistor pair formed in the different edges and the resistance value of one of the equivalent resistance or the sense resistor of the sense resistor. Two of the sensing resistors formed in the different edges are paired with the best known distance between them. The = part is the current (four) part or the overcurrent circuit, and the rib control is applied to the first electric (four), the auxiliary electrode part, the light emitting part, and the first current value. | Wang Shao, the control department is provided for each pair of sense resistors. The control unit connects at least one of the pair of sensing resistors. The current control part includes a reference supply circuit for generating a reference voltage through an input crane 201246528, and a calibration mirror circuit connected to the other end of the set resistance of the ground connection to ground according to the reference and setting control And a current control circuit for controlling at least one of the current flow of the first electrode portion, the auxiliary electrode portion, the light emitting portion, and the second electrode portion according to the control signal. The current control unit includes a comparator, including a first input terminal connected to one end of the set resistor and another terminal connected to the current source; and a switch component, including a collector terminal connected to the other end of the set resistor and an output terminal connected to the comparator The base terminal, wherein the emitter terminal is connected to the ground terminal (the GND^ current control unit includes a first resistor, one end is connected to the input power source, the other end is connected to the set resistor - the rail and the comparator - the input terminal; the comparator, The first input terminal is connected to the end of the set resistor and the first resistor; and the switching element, the terminal of the terminal is connected to the output terminal of the comparator, and the source terminal or the drain terminal is connected to the first electrode portion, the auxiliary electrode portion, the light emitting portion, and the first The two electrode portions are at least one of them, and the other of the two is connected to the terminal. The resistance value of the sensing resistor is variable based on the temperature. The overcurrent protection circuit includes a switching element, the collector terminal is connected to the power source, and the emitter terminal is connected to each of the drain terminals. a comparator, the output terminal is connected to a base terminal of the switching element, one of the input terminals is connected to the emitter terminal; and the second resistor is The other end of the comparator is connected to the input terminal of the comparator, and the other end is connected to the end of the set resistor. The set resistor is connected between the second resistor and the collector. The light emitting device further comprises a protective cover, which is provided on the second electrode portion. And a conductor provided in the protective cover opposite to the second electrode portion. The control portion is connected to the conductor, and the control portion controls the power source opposite to the polarity of the power source applied to the second electrode portion to the 201246528 body. The electrode (4) of the electrode portion has a charge of opposite polarity, so that the charge having a predetermined polarity together with the charge having the opposite polarity generates light in the light-emitting portion. 3'' Consistently has the advantage of being buckled. According to the present invention, the organic light-emitting two-homing device having the new current supply method can reduce the luminance difference between the edge and the center of the light-emitting diode. Further, after the auxiliary electrode portion is applied in the region where the pocket is deteriorated, according to the measurement The voltage flow value of the present invention (4) provides a hairline that can enhance the brightness uniformity through the driving of the panel. In addition, a sensing resistor is integrally formed in the auxiliary electrode. After that, by measuring, for example, voltage, electric heating and warm red panel miscellaneous, this (4) provides reading and setting of the wire to achieve accurate and effective panel control. In addition, by providing a whole-powered electric lion electrode, it is omitted to provide extra ❹ externally. At the age of 彳, the illuminating device provided by the present invention can simplify the production process and reduce the complexity of the external circuit. It is understood that the outline of the present invention as described above and the details of the invention described later are all substituted. 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 The same reference numerals are used to refer to the same or like parts. The "Fig. 2" shows a plurality of layers provided in the light-emitting device of the embodiment of the present invention.

Schematic of 12 S 201246528. The "figure 3" is a plan view showing the first electrode portion of the light-emitting device shown in "Fig. 2". The "figure 4" is a plan view showing the insulating portion of the light-emitting device shown in "Fig. 2". The light-emitting device 200 includes a substrate 210, a first electrode portion 220, an insulating portion 230, a light-emitting portion 240 formed of an organic light-emitting material, and a second electrode portion 250. The substrate 210 is a transparent substrate or an opaque substrate. Further, the substrate 21A may be formed of a flexible material. For example, the substrate 21A may be a glass substrate and may be formed in a polygonal, circular, elliptical, star or curved shape. The first electrode portion 220 is formed on the substrate 210' and the first electrode portion 220 is formed by depositing or coating a conductive material on the substrate 210. The first electrode portion 220 may be formed of an opaque material such as calcium (Ca), barium (Ba), magnesium (Mg), silver (Ag), copper (Cu), slag (A1) or an alloy of these materials. Further, the first electrode portion 220 may be formed of a transparent conductor, for example, formed of indium tin oxide (ITO) or indium zinc oxide (IZ0). For example, the first electrode portion 22 is formed of indium bismuth oxide. Referring to "Fig. 3", the first electrode portion 220 is removed along line 220a. For example, laser scribing is used as a method of removing the first electrode portion 22A along the line 220a. When the first electrode portion 220 is removed along the line 220a, the first electrode portion 22A is divided into a first region 221 and a second region 222 which are insulated from each other. The first region 22! is alternately formed with the second region 222 along a region in the vicinity of the first electrode portion 22A.曰 In the drawings, 'the third-different and four second regions 222 are formed in each short side of the first electrode portion 22'. Further, five first regions 221 and six second regions 222 are formed in each of the long sides 13 201246528 of the first pole portion 22A. == One zone 221 is electrically connected to each other, and the second zone 222 is electrically isolated from each other. The first power source is connected to the second cell 222. For example, when a positive voltage is connected to the first region, a 22% negative voltage is connected to the second region. Otherwise, a positive voltage is connected to the second region 222 when a negative voltage is connected to the first region 221. A blank area η3 is arranged at each edge of the first electrode portion 22, wherein the first region 221 and the second region are not formed. For example, the same area of the first zone milk or the second zone 222 is aligned next to each blank zone 223. In the drawing, the second area 222 is arranged next to the blank area 223. The insulating portion 230 is formed on the first electrode portion 220 (refer to "Fig. 4"). The insulating portion 230 is, for example, annular, and has a non-uniform pattern of a plurality of projections and recesses 232. The insulating portion 230 is formed, for example, by applying a photoresist. Referring to "Fig. 2", the projections 231 of the insulating portion 230 are mostly located on the first region 221 of the first turtle portion 220. This is because the first electrode portion 220 must be isolated from the second electrode portion 250 through the insulating portion 230, which will be described later. The light emitting portion 240 is located on the first electrode portion 220 and the insulating portion 23A. The light-emitting portion 24A is formed inwardly with respect to the insulating portion 230 to partially overlap the insulating portion 23A and is not laminated on the second region 222. The light emitting portion 240 includes a red light emitting material, a green light emitting material, or a blue light emitting material. The light-emitting portion 240 includes a light-emitting layer that emits light by the result of recombination of the electron-hole pairs. Further, the light-emitting portion 240 further includes at least one of a hole injection layer, an electron injection layer, a hole transport layer, and an electron transport layer. The second electrode portion 250 is formed on the light emitting portion 240. In the first region 221, the second electrode portion 25G is laminated on the insulating portion 23G, and the protruding portion 23 of the insulating portion 23 is not exceeded. The second region 222 is formed by the second electrode portion 25〇. The electrode portion 22 is beyond the insulating portion 230. The second electrode portion 250 may be formed of an opaque material such as a mother (four), a pin (four), a terracotta, a silver (Ag), a copper (Cu), a dimension or an alloy of these materials. Further, the second electrode portion may be formed of a turned material, for example, a tin oxide (yttrium oxide) or indium zinc oxide. For example, the second electrode portion is made of Nacheng. When the light-emitting device is completed and emits light, both the first pole portion (four) and the second electrode portion 250 are formed of a transparent electrode. When the green material is placed to complete the two-side material, both the first electrode portion 220 and the second electrode portion 25 are formed of transparent electrodes. The "figure 5" is a plan view showing the connection process between the first electrode portion and the power source shown in "Fig. 3". "After Figure 6" is the AA of the illuminating device shown in "Figure 2". The section 1 "Figure 7" of the line is shown as the record shown in "Figure 2". B_B, the cross-section of the line touch. Please refer to "Fig. 5"' (+) voltage connection to the -region 221, and the negative voltage to the second region 222. This voltage connection enables the (+) and (i) voltages to be alternately supplied to the side of the first electrode portion 220. (6) The voltage supplied to the first electrode portion 220 located at the outer periphery of the light-emitting device is transmitted to the light-emitting portion contacting the first electrode portion 22 along the inner first electrode portion 22A. . In this case, the first electrode portion 220 to which the (1) voltage is supplied may be the first region 221. In the first region, the first electrode portion 220 contacts the light emitting portion 240 and does not contact the second electrode portion because the insulating portion 230 is located between the first electrode portion 22A and the second electrode 15 201246528 pole portion 250. Referring to "FIG. 7", the voltage supplied to the first electrode portion 220 located at the outer periphery of the light-emitting device is transmitted to the second electrode portion 250 contacting the first electrode portion 22A. The (a) voltage transmitted to the second electrode portion 250 is transmitted to the light emitting portion 240 contacting the second electrode portion 250. The first electrode portion 220 at the both ends of the "Fig. 7" towel is electrically isolated from the first electrode portion 220 located at the center. In conjunction with the content of "Fig. 3", the first electrode portion 22A corresponding to the boundary between the first region 221 and the second region 222 is removed along the line 22()a to electrically isolate the first region 221 and the second region 222 from each other. . The insulating portion 230 is laminated on the region where the first electrode portion 22 is removed to enhance the insulation. Therefore, in the "Fig. 7", the first electrode portion 22 at both ends is the second region, and the first electrode portion at the center portion may be the first region 22 ΐ the first electrode 22 〇. Therefore, the first region 221 and the second region 222 are electrically isolated from each other. In the second region 222, the first electrode portion 22A contacts the second electrode portion 25'' without contacting the light-emitting portion 24A. The (+) and (1) voltages transmitted to the first electrode portion 22A are supplied along the first electrode portion 22 and the second electrode portion (10), respectively, so that current flows along the first electrode portion 22, the light emitting portion 240, and the The two electrode portions 250 flow. The "Fig. 8" is a schematic diagram of the charge distribution of the supply. In the luminescence of the embodiment, the (+) voltage and (·) are alternately arranged and supplied to, for example, the side surface of the rectangular first electrode portion 220. 201246528 Please refer to "i-th picture", the distance between (+) voltage and (_) voltage is closer at the edge of the traditional hairline 10, and further away from the center, so that the center and the edge are free. The degree difference is relatively large. However, in the illuminating device according to the embodiment of the present invention, (+) and (_) galvanic are alternately arranged and supplied, and Wei maintains close proximity regardless of position (+) and (1) cake _ turn. When it is close to (1), the area affected by the t-charge is effectively amplified, as indicated by the dotted line. Therefore, the charge density can be significantly reduced as compared with the case where the (+) and (a) voltages are farther away. The difference in brightness between the edge and the center of the light-emitting device (or organic light-emitting material). For example, in an organic light-emitting material having a size of 25 mm × 250 mm, when the edge of the party is 500 turbid (cd), the brightness of the center Keep it in a turbid light. In addition, there is no row in the edge of the electrode portion 220. (+) and (a) the blank area 223 of the voltage, the charge of the edge is higher than that of the other areas. Therefore, it is possible to avoid excessively enhancing the brightness. Further, the same voltage such as (+) or (a) voltage is arranged next to the blank area 223. The '(+) and (1) voltages are effectively spaced apart from each other. This avoids excessively increasing the charge at the edges and reduces the difference in brightness between the center and the edge of the illuminating device. - Each side of the rectangular illuminating device is alternately arranged (+ And (a) the voltage supply process is described. However, compared with the conventional hair-domain rib, at least one of the (+) and (a) voltage arrangement methods on the side of the light-emitting device can bring about efficacy. This can be applied to the round rise ^ , elliptical or curved light-emitting device. In the meantime, with "1st picture", "2nd picture", "3rd picture", "4th picture", "5th

Compared with the examples shown in Figure 7 and Figure 6 and Figure 7 and Figure 8, the combination of "Figure 9," "10th," and "nth" 12th, 13th, 14th, 15th, 16th, 17th, 18th, Wth, 20th The embodiments described in Figure 21, Figure 21, Figure 22, Figure 23, Figure 24, Figure 25, and Figure 26 use different methods to control brightness Q. The same reference numerals are used to describe the embodiment and "1", "2", "3", "4", "5", "6", "7" The same elements as in the above embodiment are shown in Fig. 8 and Fig. 8 . Fig. 9 is a plan view showing a current supply device 1 according to an embodiment of the present invention. The current supply device 100 includes a first power supply portion m, a second power supply portion 112, a first power supply 120, a second power supply 13A, a resistance tool 14A, and an insulating frame 150. The first power supply portion 111 supplies the first power source 120 with a first power source, such as a (+) voltage. The second power supply portion 112 supplies a second power source, for example, a (-) voltage, to the second power supply 13A. The first power supply line (121, 122: 120) includes a first power supply line 121 and a plurality of (four)_connected 122', wherein the first-f source supply line 121 is electrically connected to the first power supply unit 1U, and the first power supply unit 1U Divide a number of first-connections (2). As shown in "Fig. 9," the (+) voltage is supplied to these first ports (2). The insulating frame (apply, 150b: 150) is formed in a thin plate shape, and includes a central portion applied to the peripheral portion 150b, wherein the central portion is hidden in the central portion of the insulating frame 15〇, and the circumference 201246528 is disposed along the central portion i5〇a. . The central portion 150a may be a polygon. In Fig. 9, the central portion is rectangular, and the peripheral portion 150b has a rectangular shape along the central portion i5〇a. The central portion 150a is formed of a predetermined material which is the same as or different from the material used for the peripheral portion 150b. Further, the central portion 15A may be a blank space. "9th drawing" shows that the central portion 150a is a blank space. The first power supply line m is hidden and arranged on the peripheral portion. For example, the first power supply line 121 is circular, elliptical or polygonal in a ring shape. Fig. 9 shows that the first power supply line 丨21 is approximately rectangular. In Fig. 9, the first power supply line 121 forms a closed pattern and can form a closed loop pattern. The first-connected 122 branches along the first power supply line 121. A plurality of first-connecting ports 122 are provided, and the first connecting pads 122 are branched toward the central portion 15Qa or in opposite directions. The "Fig. 9" indicates that the first connection pad 122 branches toward the central portion 15A. One end of the first connection pad 122 protrudes from the peripheral portion i5〇b to extend in the direction of the central portion 15〇a. One end of the first connection pad 122 is formed with a contact portion. The second power supply (131, 132: 130) includes a second power supply line 131 and a plurality of second connection pads 132', wherein the second power supply line 131 is electrically connected to the second power supply 112, and the plurality of second connection pads 132 branches along the second power supply line 131. The voltage of (1) is supplied to the second connection pad 132 as shown in Fig. 9. The second power supply lines 131 are arranged along the peripheral portion 150b and arranged thereon. The second power supply line 131 is arranged along the first power supply line 121 and insulated from the first power supply line 121 through the peripheral portion 19 201246528 portion 150b. The second power supply line (3) may be circular, elliptical or polygonal. The second pattern power supply line 131 is approximately rectangular in shape. "9th, the first-electro-secret 131 is a closed figure, and may be an open loop second power supply line 131 arranged along the first power supply line 121 and arranged below it. 'The peripheral portion 15Gb is located at the second power supply, the line Between 131 and the first power supply line (2), since the second power supply line 131 overlaps with the first power supply line (2), a part of the second power supply line 131 is shown in "Fig. 9". The second port 132 branches along the second power supply line 131. A plurality of first-connected ports 132 are provided, and the plurality of second ports 132 are branched toward the central portion 15 or in the opposite direction. In the "fifth diagram", the second connection pad 132 is branched to the central portion 15. The end of each of the second connection pads 132 protrudes from the peripheral portion 150b to extend toward the central portion 15. One end of the second connection pad 132 is formed with a contact portion. The first connection pads 122 and the second connection pads 132 are alternately arranged. The (+) voltage is supplied to the first connection pad 122, and (a) the voltage is supplied to the second connection pad 132, so that the (+) and (1) voltages are alternately supplied in the ring shape. The resistance tool 140 is connected between the first power supply line 121 and the first connection pad 122 or between the second power supply line 131 and the second connection pad 132 to adjust the supply to the first connection pad 122 or the first The current value of the second port 132. In Fig. 9, the resistance tool 14 is formed between the first power supply line 121 to which the (+) voltage is supplied and the first connection pad 122. 20 201246528 Resistance tool 14G is connected one by one. In other words, each of the resistance tools 140 is connected to each of the first connections. ^A's two or more first connection pads/9th" wipes from a single resistance tool, and three first ports 122 branched from a single resistance tool 14 are provided to the first power supply line 121. Left and right side. Therefore, the (+) electric power supplied to the first power supply portion 111 is supplied to each of the first connection pads 122 by the first power supply supply 121 and the resistance tool 140. The resistance values of the resistance tool 140 are different from each other such that the current values supplied to the first port 122 are different from each other. The first power supply line 121 has a polygonal ring shape, and as the resistance tool 14 turns closer to the edge of the polygonal ring, the electric resistance of the resistor 1 becomes larger. For example, the first power supply line (2) has a rectangular ring shape, and as the resistance tool 14 turns closer to the edge of the rectangle, the resistance value of the resistance tool gradually becomes larger. The resistance value of the resistance tool 140 is (R1#3 and R7 to R9)>(R2£=R8) or R(four)paper)> (10). For example, the resistance value is ri = ohm ohm, R2 = l00 ohm, R3, 〇 ohm, R4 = 4 〇〇 ohm, R5 = 〇 ohm, then, 〇 ohm, chest 00 ohm, R8 = 100 ohm, R9 = 4 〇 〇 ohm, Ri 〇 = 働 ohm or R11 = 0 ohm, R12 = 400 ohm. The resistance value of the resistor tool 14〇 includes a 〇 ohm resistor. When the current supply device 100 is used to supply power to the illuminating device, by applying a resistance value of the resistance tool 14G closer to the rectangular edge, a smaller current is applied to each of the connection pads to listen to the center and the edge of the illuminating device. A difference in brightness is produced. "Figure 10" is shown in the current supply device shown in Figure 9.

S 21 201246528 Cross-sectional view taken along line C-C. The peripheral portion 15Gb of the insulating frame 15G is located between the first electric secret line 121 and the second power supply line 131. The first coating layer 1〇 is located on the first power supply line (2) to protect the first power supply line 121. The second coating layer 102 is located on the second power supply line 131 τ to protect the second power supply line (3). Fig. 5 is a cross-sectional view taken along the line D-D' in the current supply device shown in Fig. 9. The peripheral portion 150b of the insulating frame 150 is located between the first power supply line (2) and the: power supply line 131. The through hole 151 is formed in the peripheral portion, and the through hole 15 is an extending path connecting the electric 14g (four)-seam 122. The resistance tool 140 connects the first power supply, the line 121 and the first connection pad 122. When the resistance tool is passed, the current supplied to the first power supply line ΐ2 is reduced to be supplied to the first port 122. The first connection port 122 extends through the bottom hole of the insulation 150 through the through hole (5) formed in the peripheral portion 15B. The coating layer 101 is located on the first power supply line 121 to protect the first genus. Please apply the coating on the second power supply line 131 below the power supply line 131. The cross section of the overburden layer 101 and the peripheral portion is shown as the current supply in the "Fig. 9" (4) around the insulating frame U0.卩1郷 is located in the first - power supply wire (2) and

22 201246528 Power supply line 131. The second connection I32 is connected to the second power supply line (3), and current is supplied from the second power supply line 131 to the second connection pad I%. The first coating layer 101 is located above the first power supply line 121 to protect the first power supply line 12. The second coating layer 102 is located below the second power supply line 131 to protect the second power supply, the line 131. . The second coating layer 1〇2 is shorter than the first coating layer 1〇1 and the peripheral portion to expose the bottom surface of the second connection pad. As described above, in the current supply device 100 of the embodiment of the present invention, the first connection port 122 and the second connection port 132 are alternately formed, and the first connection pad 122 is supplied along the peripheral portion 150b of the insulating frame 15A. The second port 132 supplies (a) voltage. Therefore, the current supply device of the present invention can be supplied with a voltage (.). Further, in the current supply device 100 of the embodiment of the present invention, the first connection pad 122 or the second connection pad 132 is connected. The resistance value of the resistance tool 14A is adjusted. Therefore, the current value supplied to the first connection pad 122 or the second connection port 132 can be adjusted according to the user's expectation. "Fig. 13" is the use of " Figure 9 shows an example of the current for the practice. The current supply device 100 is located on the object i to which the current is supplied. The current supply device 100 is an object in accordance with a simple method! Supply alternating (1) and (a) voltages. For this reason, even (+) terminals and (1) terminals are alternately formed in the object 1. Fig. 14 is a view showing a current supply device according to another embodiment of the present invention. The same elements as those provided in the embodiment shown in Fig. 9 are given the same reference numerals, and the detailed description of the same elements is omitted accordingly. The rim frame 〇5〇a, hidden: ISO) is formed in a thin plate shape, and the insulating frame 15A includes a central portion 150a and a peripheral portion 150b. The central portion is hidden in the center of the insulating frame mo, and the peripheral portion 150b is arranged at the central portion 15 In the surrounding area of 〇a. The central portion 150a is formed of a predetermined material which is the same as or different from the material used for the peripheral portion 15〇b. In addition, the central part can be used as a blank space. In "Fig. 14", the central portion 15〇a is a blank space. According to this embodiment, the first connection pad 122' and the second connection pad 132 do not protrude from the peripheral portion i5〇b of the insulating frame 150. Therefore, the peripheral portion 15〇1) supports the ends of the first connection pad 122' and the second connection pad 132. Fig. 15 is a view showing a plurality of layers provided in a light-emitting device according to another embodiment of the present invention. Fig. 16 is a plan view showing the first electrode portion of the light-emitting device shown in Fig. 15. Fig. 17 is a plan view showing the insulating frame of the light-emitting device shown in Fig. 15. The light-emitting device 200 includes a substrate 210, a first electrode portion 220, an insulating frame 230, a light-emitting portion 240 formed of an organic light-emitting material, and a second electrode portion 250. The substrate 210 is a transparent substrate or an opaque substrate. Further, the substrate is formed of a flexible material. For example, the substrate 21 is a glass substrate, and the substrate 21 can be formed in a polygonal shape, a circular shape, an elliptical shape, a star shape, or a curved shape. The first electrode portion 220 is formed on the substrate 210, and the first electrode portion 220 is formed by depositing or coating a conductive material on the substrate 210. The first electrode portion 220 may be formed of an opaque material such as calcium (Ca), barium (Ba), magnesium (Mg), silver (Ag), copper.

24 201246528 (Cu), aluminum (A1) or alloys of these materials. Further, the first electrode portion 220 may be formed of a transparent conductor, for example, formed of indium tin oxide or indium zinc oxide (IZ0). For example, the first electrode portion 22 is formed of a samarium oxide. In conjunction with "Fig. 16," the first electrode portion 22A is removed along the line 220a. For example, laser cutting is used as a method of clearing the first electrode portion 22A along the line 220a. When the first electrode portion 22A is removed along the line 220a, the first electrode portion 22'' is divided into the first region 221 and the second region 222 which are insulated from each other. The first region 221 and the first region 222 are alternately formed along a region in the vicinity of the first electrode portion 220. In these figures, three first regions 22 and four second regions 222 are formed in each short side of the first electrode portion 22A. Further, five first regions 221 and six second regions 222 are formed in each of the long sides of the first electrode portion 22A. The first regions 221 are electrically connected to each other, and the second regions 222 are electrically isolated from each other. The first power source is connected to the first zone 221, and the second power source is connected to the second zone 222. For example, when a positive voltage is connected to the first region 221, a negative voltage is connected to the second region. Otherwise, when a negative voltage is connected to the first region 221, a positive voltage is connected to the second region. ^第. A blank area is arranged at each edge of the electrode portion 22, wherein the first area 221 and the second area 222 are not formed. The same area, for example, the first area 221 or the second area a is arranged adjacent to each blank area 223. In Fig. 16, the second area 222 is arranged adjacent to the blank area 223. The insulating portion 230 is formed on the first electrode portion 22A (please refer to "Fig. 17"). For example, the insulating portion 23 is annular, and has a non-uniform pattern of a plurality of convex portions and recess portions η2. The insulating portion 23G is formed by, for example, applying a photoresist. 25 201246528 Referring to FIG. 15, the protruding portion 231 of the insulating portion 230 is mostly located on the first region 221 of the first electrode portion 220. This is because the first electrode portion 220 must be isolated from the second electrode portion 25A through the insulating portion 230, which will be described later. The light emitting portion 240 is located on the first electrode portion 220 and the insulating portion 230. The light-emitting portion 24 is formed inwardly with respect to the insulating portion 230 so as to partially overlap the insulating portion 23 and is not laminated on the second region 222. The light-emitting portion 24A includes a red light-emitting material, a green light-emitting material, or a blue light-emitting material. The light-emitting portion 240 includes a light-emitting layer that emits light by the result of recombination of electron-hole pairs. In addition, the light emitting portion 240 further includes at least one of a hole injection layer, an electron injection layer, a hole transport layer, and an electron transport layer. The second electrode portion 250 is formed on the light emitting portion 240. In the first region 221, the second electrode portion 250 is laminated on the insulating portion 23, and does not extend beyond the protruding portion 23 of the insulating portion 23, and the second portion is similar to the second electrode portion. Above, the insulating portion 230 is exceeded. The second electrode portion 250 may be formed of an opaque material, such as a mother (four), a lock, a magnesium (Mg), a g), a copper (Cu), a tantalum, or an alloy of these materials. Further, the second electrode portion 250 may also be formed of a coffee material such as indium tin oxide or indium zinc oxide oxidizer Z0). For example, the second electrode portion 25 is formed. When the light-emitting device completes the light emission on one side, both the first electrode portion 220 and the second electrode portion 25 are thinly formed. Both the slit electrode portion 22G and the second electrode portion (10) are formed of a transparent electrode. (4) Schematic diagram of the connection process shown in Figure 8 of the “Development of the County”. "Picture No. 19" is the "Picture 9" and the current supply device of 201246528 is layered on the "18th plane diagram. Figure 20" shows the state of the first electrode section. For the "figure 15"

The cross-sectional view of the line cut-off, and the FF Han Han map of the 21st (5) 7th 7th device are not the GG of the record, and the line is cut. 〇S" is not the 2nd 18th Figure "' (+) voltage is connected to the - area 221, (a) negative voltage connection. The connection is made such that (+) and (slack can be touched to the side of the first electrode portion 220. Please refer to "FIG. 19" to be placed on the first electrode portion 220 221 and the second region 222. Fig. 9 The current supply device 100 is not supplied with current to the first region of the first electrode portion 220, the first connection & 122 is connected to the first region 221 of the first electrode portion 22, and the (+) voltage is supplied to the first - Zone 221. The second connection pad 132 is connected to the second portion 222 of the first portion, and the (-) voltage is supplied to the second region 222. - The current supply device shown in "Fig. 9" can be simple The method realizes a structure in which the (+) and (1) voltages are alternately supplied to the first region 221 and the second region 222. Please refer to "20th drawing" for supplying to the first electrode portion 220 located in the periphery of the periphery of the light emitting device (+ The voltage is transmitted to the light-emitting portion 240 that is in contact with the first electrode portion 220 along the inside of the first electrode portion 22A. In this case, the first electrode portion 22 that is supplied with the (+) voltage is the first region 221. In the first region 221, the first electrode portion 220 contacts the light emitting portion 240 and does not contact the second electrode portion 250. This is because the insulating portion 230 is located at the first electrode portion 22. Between 0 and the second electrode portion 250. 3 27 201246528 In the meantime, referring to "21", the voltage supplied to the first electrode portion 220 located outside the periphery of the light-emitting device is transmitted to the contact first electrode portion 220. The second electrode portion 250. The voltage transmitted to the second electrode portion 25 is transmitted to the light emitting portion 240 that is in contact with the second electrode portion 250. The pole portion 220 is electrically isolated from the first electro-electrode portion 220 at both ends in the "21st" in the middle portion. Referring to the "Fig. 16", the first electrode corresponding to the boundary between the first region 221 and the second region 222 is removed along the line to electrically isolate the first region and the second region 222 from each other. The insulating portion 230 is laminated on the region where the first electrode portion 220 is removed. In the second figure, the first electrode portion at the both ends is moved to the second region 222'. The first electrode portion 22 in the middle portion is the first region η. Therefore, the second and second regions 222 are electrically isolated from each other. The electrode portion 250 is not in contact with the second region 222, and the first electrode portion 22 is in contact with the second light emitting portion 240. The (+) and (_) secret phases of the coffee_22G are supplied along the first electrode portion 4 pole portion 250, so that current can flow along the first electrode portion 发光, the light emitting portion 24A, and the second electrode portion 25〇. Figure 22 is a schematic diagram of the charge distribution supplied by Figure 15. The (+) and (_) voltages in the illuminating device shown are

S 201246528 Please refer to "1st picture", (+) the distance between the ink and the (the distance between the lazy and the illuminating device is close to the edge of the traditional light-emitting device ίο), so that the brightness difference between the center and the edge is However, in the light-emitting device according to the embodiment of the present invention, (+) and (gamma are alternately arranged and supplied, so that (+) and (a) sugar_disconnected when (1) and (a) voltage are close, regardless of the position, It will effectively enlarge the area affected by the charge, as shown by the dotted line. Therefore, compared with the case where the (+) and (1) voltages are farther, the charge density can be increased, and the edge of the light-emitting device (or organic light-emitting material) can be considerably reduced. The difference in brightness between the centers of the discs. ' ' For example, in an organic light-emitting material having a size of 15 filaments (10), when the brightness of the edge is 5GG®, the brightness of the light is held in the candle. Further, the first electrode portion 22〇 A blank area 223 is provided in the edge without arranging (+) and (a) voltages, and the charge of the edge is relatively higher than that of other areas. Therefore, the brightness is prevented from increasing too much. In addition, the same voltage system of (+) or (a) voltage is used. Adjacent blank area 223 is arranged Therefore, the (+) and (_) voltages are effectively isolated from each other. This avoids excessive charge increase at the edges and reduces the luminance difference between the center and the edge in the illuminating shock. Alternately arranged (+) and (i) voltage supply systems are described. However, compared to conventional illumination devices, the method of arranging (+) and (a) voltages in at least one of the sides of the hairline can produce efficacy. It is applied to a light-emitting device having a circular, elliptical or curved shape. 29 201246528 "23rd picture" is the test between the center and the edge of the test light-emitting device in which the current supply device shown in "Fig. 9" is not arranged with a resistance tool. Schematic diagram of the difference in brightness. Figure 24 shows the percentage of the difference in brightness between the center and the edge in the test in Figure 23. The test shown in Figure 23 indicates that when applying 4 volts, 44 〇 安 安 发光 ' ' ' ' ' ' 尺寸 尺寸 尺寸 尺寸 150 150 150 150 150 150 150 150 150 150 150 150 150 150 150 150 150 150 150 150 150 150 150 150 150 150 150 150 150 。 。 。 。 。 。 。 The resistance value of the resistance tool 140 is 〇 ohm. According to the test result, the central brightness is 5 〇〇 candle light, and the edge brightness is approximately (four) candle I. When this result is converted into a percentage, the central brightness is employed, the edge is The brightness is approximately 17 〇〇/0. Fig. 25 is not a difference between the center and the edge of the field in which the resistance values of the different electrical values of the central resistance value and the edge are arranged. Schematic. "Figure 26 is the comparison of the difference in brightness between the center and the edge in the test of Figure 25. The test of Figure 25 shows the illuminating of the size of 15 mm. When the device is made of 4 volts and 44 mA, the brightness difference between the center and the edge is different. In this case, the resistance value of the central resistance tool 140 is different from the resistance value of the edge of the current supply device 1 。. In the rectangular current supply device, the "A" resistance tool is arranged at the edge, and the % resistance tool is arranged at the edge and is arranged in the middle of the short side. 8 Figure 25 "In" the resistance value of "A" is 4 〇 0 ohm, the resistance value of "B"

30 S 201246528 is 100 ohms, and the resistance value of "C" is 〇 ohm. In order to reduce the difference in shell between the center and the edge, a resistance tool 14 having a large resistance value is arranged at the edge. According to the test results, the central brightness is 570 candelas and the edge brightness is approximately 720 candelas. When this result is converted to a percentage, the central brightness is 丨(8)% and the edge brightness is approximately 125%. And the "Glowing Farms and "" in Figure 2, "3", "4", "5", "6", "7" and "8" Figure 9 ", "1", "11", "12", "13", "14", "15", "16", " 17, "18", "19th", "20th", "21st", "22nd", "23rd", "24th", "25th" Compared with the light-emitting devices shown in Figure 26, "27th", "28th", "29th", "30th", "31st" and "32" "33", "34", "35", "36", "37", "38", "38", "38C", " Figure 39, Figure 40, Figure 41, Figure 42, Figure 43, Figure 44, Figure 45, Figure 46, page 47 The illuminating device shown in Fig., "48th" and "Fig. 49" can control the brightness of the illuminating portion by different methods. In this embodiment, "2", "3", "4", "5", "6", "7", "8", "9" Figure, "1", "11th", "12th", "13th", "Nth", "15th", "16th", "17th" "18", "19th", "20th", "21st", "22nd", "23rd", "24th", "25th" and The same elements of the illuminating device shown in Fig. 26 are denoted by the same reference numerals. 31 201246528 The light-emitting device of this embodiment is an organic light-emitting diode. As shown in Fig. 27, the light-emitting device 200 of this embodiment includes a substrate 210, a first electrode portion 220, an auxiliary electrode portion 330, an insulating portion 230, a light-emitting portion 240, and a second electrode portion 250. The light-emitting portion 240 is an organic light-emitting portion, and the light-emitting portion 240 constituted by the organic light-emitting portion will be described below. The substrate 210 is a transparent substrate or an opaque substrate. Further, the substrate 21 is formed of a flexible material. The substrate 210 is an insulating substrate formed of glass, quartz, ceramic or plastic, and the substrate 210 may include light-emitting regions and pad regions separated from each other. The substrate 210 is formed in a polygonal shape, a circular shape, an elliptical shape, a star shape, or a curved shape. The first electrode portion 220 is formed on the substrate 210. The first electrode portion 220 is formed by depositing or coating a conductive material on the substrate 210. The first electrode portion 220 may be formed of an opaque material such as calcium (Ca), barium (Ba), magnesium (Mg), silver (Ag), copper (Cu), or (A1) or an alloy of these materials. Further, the first electrode portion 220 may be formed of a transparent conductor, for example, indium tin oxide (ITO), indium zinc oxide (ITO), zinc oxide (Zn0), or oxidized (In2〇3). For example, the first electrode portion 220 is formed of indium tin oxide. The first electrode portion 220 has a (+) polarity and is a hole injection electrode. In the meantime, the second electrode portion 250 has (a) polarity and is an electron injecting electrode. The light-emitting portion 240 includes a light-emitting layer that is completed by recombination of electron-hole pairs.

32 S 201246528 In addition, the light emitting portion 240 may be a plurality of layers including at least one of a maker layer, an electron injection layer, a hole transport layer, and an electron transport layer. The light-emitting portion 240 includes all of the trees and one hole of the hole in the first electrode portion 220 of the positive polarity. The hole transport layer, the light-emitting layer, the electron transport layer, and the electron injection layer sequentially form a plurality of layers on the hole injection layer. In the meantime, the second electrode portion 250 is formed on the light-emitting portion 24A. The first electrode portion 221 t ' of the first electrode portion of the first electrode portion is laminated on the insulating portion and does not extend beyond the protruding portion 231 of the insulating portion 230. The second electrode portion 250 is laminated on the first electrode portion 22A and extends beyond the insulating portion 23A. The second electrode portion 250 may be formed of an opaque material, for example, by about (4), lock (Ba) > ^(Mg). m(Ag) ^ ^(Cu) ^ 〇 In addition, the second electrode portion 250 may be formed of a transparent material , for example, formed of copper tin oxide or indium zinc oxide. For example, the second electrode portion 25 is made of Na. When the light-emitting device completes the side-emitting light, both the first electrode portion 22 and the second electrode portion 250 are formed by the transparent electrode. When the illuminating is completed to emit light on both sides, both the first electrode portion 220 and the second electrode portion 25 are formed of transparent electrodes. Meanwhile, the auxiliary electrode portion 300 is arranged on the first electrode portion 22A, and the first electrode portion 220 is divided into predetermined blocks. As shown in Fig. 27, the auxiliary electrode portion 3 is composed of a wire which enables supply of a current. As shown in Fig. 27, the auxiliary electrode portions are arranged in a mesh type on the first electrode portion 22A. The auxiliary electrode portion 300 may be of a belt type rather than a mesh type or a plurality of geometric figures 33 201246528. In addition, the lion can be called a wealth or a ship, a character or a flower pattern or other design. According to the shape of the auxiliary electrode portion 300, the light-emitting or non-light-emitting area of the light-emitting device 200 indicates an image, a character or a number. The auxiliary electrode portion 300 is electrically connected to the first electrode portion 22A, and is formed of a predetermined material having a relatively low non-resistance value as compared with the first electrode portion 22A. The auxiliary electrode portion may be formed of a reflective material. In particular, the auxiliary electrode portion 3〇〇, (fluorith^calc^;

LiF/Ca) > 13⁄4 ^ (fiuorinated lithium/aluminum . ^ } ^ A predetermined material of aluminum, silver, magnesium or gold is formed. However, the present invention is not limited thereto, and has a relatively high electrical conductivity than the first electrode portion 22A. And the reflected light is arbitrarily applied to the _ electrode portion 3 〇〇. The auxiliary electrode portion of various shapes is formed in the first electrode portion. A specific symbol or pattern can be displayed, and the aesthetic feeling can be enhanced. Meanwhile, the auxiliary electrode portion can be The current is facilitated to flow to the first electrode portion 220 to achieve overall uniformity. In other words, the galvanic electrode 3GG compensates for the low conductivity, and the brightness of the light emitted by the illuminating portion 240 of the illuminating device 200 is completely uniform. The transparent conductive material used for the electrode portion 22 has a relatively non-resistance. Therefore, as the region of the first electrode portion 220 is larger, the current flowing to the first electrode portion 22 is more difficult to be completely uniform. If the light-emitting portion 240 formed between the first electrode portion 22 and the second electrode portion 25b emits light, there is no auxiliary electrode portion, and the first light emission is relatively low.

S 34 201246528 ^ The light-emitting portion corresponding to the edge of 22 发射 emits high-intensity light, and the light emitted from the first electrode portion of the relatively low-brightness light by the resistor emits low-intensity light. Further, the area of the first electrode portion 22 is enlarged, and the overall brightness is more uniform. The auxiliary electrode portions _ are wired or connected in a plurality of directions. The insulating portion 230 ft covers the auxiliary electrode portion 3A to prevent communication between the auxiliary electrode portions and the second electrode portion 250. For this reason, the insulating portion 230 appears corresponding to the appearance of the auxiliary electrode portion 300. As shown in "Different 28*" and "Fig. 29", the first electrode portion 220 arranged on the substrate 210 is removed along the line. For example, laser cutting is used as a method of partially removing the first pole portion 22 from the line 2. When the first electrode portion 22A is partially removed along the line 220a, the first electrode portion 22'' is divided into the first region 221 and the second region 222 which are insulated from each other. The first region 2 222 is alternately formed along a region in the vicinity of the first electrode portion 220. These patterns cause three first regions 221 and four second regions 222 to be formed in each of the short sides of the first electrode portion 22'. Further, five first zone work and six second zones 222 are formed in each of the long sides of the first electrode portion 22'. The first regions 221 are electrically connected to each other, the second regions 222 are electrically separated from each other by a second power supply to the second region 35 201246528, for example, when a positive voltage is connected to the first region 221, the negative voltage is connected to the second region. Area 222. Conversely, when the negative voltage is connected to the first region 221, the positive voltage is connected to the second region 222. The blank area 223 is arranged at each edge of the first electrode portion 220, and the first area 221 and the second area 222 are not formed in the blank area 223. Further, the same area such as the first area 221 or the second area 222 is arranged adjacent to each of the blank areas 223. In "28th picture", the second area 222 is arranged adjacent to the blank area 223. The "Fig. 29" indicates that the (+) voltage (the current supply device 1 〇〇, which will be described later, the reference numeral 30) is supplied to the first region 221 and the voltage is supplied to the second region 222. Fig. 30 is a plan view showing the above-described current supply device used as a power supply unit. The current supply device 100 includes a first power supply portion η1, a second power supply portion 112, a first power supply 120, a second power supply 13A, a resistance tool, and an insulating frame 150. The first power supply section 111 supplies a first power source such as a (+) voltage to the first power source supplier 120. The second power supply unit 112 supplies a second power source such as a (1) voltage to the second power supply 130. The first power supply (m, m: 120) includes a first power supply line m and a plurality of first connection ports 122' of the first power supply line 121 electrically connected to the first power supply portion 111' from the first power supply line 121 A plurality of first connection pads are paid out. As shown in Figure 27, (+) is supplied to the first connection 塾I]:.

36 201246528 The insulating frame (150a, 150b: 150) is formed in a thin plate shape, and the insulating frame includes a central portion i5 〇 and a peripheral portion 15Gb, the central portion 15Ga is located at the center of the insulating (four), and the peripheral portion 2 is arranged along the central portion 150a. b The central part can be a polygon. In the "Fig. 9" +, the central portion of the dirty portion peripheral portion 150b has a rectangular shape along the central portion 150a. The central portion l5〇a is made of a predetermined material shape force. This predetermined material is the same as or different from the material used for the peripheral portion. Further, the central portion 15a may also be a blank space. "9th drawing" indicates that the central portion i5〇a is a blank space. The first power supply line 121 is arranged along the peripheral portion (10) and arranged thereon. For example, the first power supply line 121 is a circular, elliptical or polygonal ring f' "30th view" indicating that the first power supply line 121 is approximately rectangular. The "first-power supply line 121" in the "Fig. 9" is formed in a closed pattern, and the annular pattern can be closed.乂 ^ The first connection bridge 122 branches along the first power supply line 121. A plurality of first-connecting ports 122 are provided, and the direction of the (four) central portion 15Ga or the branching direction is reduced. "Thirtyth diagram" indicates a branch in which the first port 122 is torn toward the center portion. The end of the first port 122 protrudes from the peripheral portion (10) to extend toward the central portion (10). One end of the first connection pad 122 is formed with a contact portion. The second power supply unit (131, 132: 130) includes a second power supply line 131 and a plurality of ports 132. The second power supply line 131 is electrically connected to the second power supply unit 112, and the plurality of connection pads 132 are branched along the second power supply line 131. As shown in "Fig. 30", (a) the voltage is supplied to the second connection pad 132. The second power supply lines 131 are arranged along the peripheral portion 150b and arranged thereon. 37 201246528 The first power supply line 131 is arranged along the first power supply line 121, and is insulated from the first power supply line 121 through the peripheral portion 150b. The second power supply line 131 is circular, elliptical or polygonal. The "30th drawing" indicates that the second power supply line 131 is approximately rectangular. The "second picture" power supply line 131 is a closed figure and may be an open ring pattern. The second power supply line 131 is arranged along the first power supply line 121 and arranged below it. The peripheral portion 1 is located between the second supply line 131 and the power supply line (2). Since the second power supply line 131 overlaps with the first power supply line 12, a part of the second power supply line 131 is shown in "Fig. 30". The second port 132 branches along the second power supply line 131. A plurality of first-connecting ports 132' are provided to the plurality of second joints 132 to branch in the hidden or opposite directions of the central portion. The "30th drawing" shows that the second connection pad 132 is branched in the direction toward the center portion 15. The end of each of the second connecting jaws 132 protrudes from the peripheral portion by 15% to extend in the tearing direction of the central portion. One end of the second connection pad 132 is formed with a contact portion. The first port 122 and the second port 132 are alternately arranged. The (+) voltage is supplied to the first-connector 122, and the voltage is supplied to the second port 132 so that the voltage is alternately supplied in the ring shape. 'Fig. 31' is a cross-sectional view taken along the line H-H' in the current supply device shown in Fig. 3. The peripheral portion 150b of the insulating frame 150 is located between the first power supply line ΐ2ι and the second power supply line 131.

S 201246528 The first coating layer HH is located on the first power supply line 121 to protect the first power supply line 121. The second coating layer 102 is located on the second power supply line (3). The second power supply line 13 is shown in Fig. 32, which is a section along the μ line in the current supply of the county shown in Fig. 9. Figure. The peripheral portion (10) of the insulating frame 15 is located between the first power supply line ΐ2ΐ and the second power supply line 131. The hole (5) is formed in the peripheral portion (10), and the through hole (5) is an extending path connecting the first connection pads 122 of the resistance tool 14A. The first connection (four) 2 extends along the bottom of the insulating frame 150 via the through hole ΐ5ι formed in the peripheral portion 15Qb. The first coating layer κη is located on the first power supply line 121 to protect the first power source, and the upper line 12L·the second coating layer 1() 2 is located below the second power supply line (3) to protect the first power supply line 131. The first coating layer 1〇2 extends shorter than the first coating layer 1〇1 and the peripheral lion to expose the bottom surface of the first connection pad 122. Figure 33 is a cross-sectional view taken along the line j_j in the current supply device shown in Figure 3. The peripheral portion 15% of the insulating frame 15 is located between the first power supply line ΐ2ΐ and the second power supply line 131. The first connection 132 is connected to the second power supply line 131, and current is supplied from the second power supply line 131 to the second connection pad 132. The first coating layer ιοί is located on the first power supply line 121 to protect the first power source 39 201246528 supply line 121. The second coating layer 1〇2 is located below the second power supply line 131 to protect the second power supply line 1M. The second coating layer 102 is shorter than the first coating layer 1〇1 and the peripheral portion 15 to expose the bottom surface of the second connection pad. As described above, in the current supply device 1 of the embodiment of the present invention, the first connection (four) supplying the (+) voltage and the second connection pad supplying the (_) voltage are alternately formed along the peripheral portion 150b of the insulating frame 150. Therefore, the simple structure realized by the current supply device of the embodiment of the present invention can alternately supply the (+) and (1) voltages. I denotes a current supply device trace placed on the first electrode portion 22A. In the wide example, the first port 122 is placed to connect the first power supply line (2) in the first region 221 of the first electrode portion 220. The second port 132 of the solid supply line 131 is placed in the first-second region 222 of the first electric (four) 22 。. Therefore, the (+) voltage is applied to the first region 221, and the voltage is applied to the second 222. Fig. 35 is a view showing an example of an auxiliary electrode portion formed in the light-emitting device of the embodiment of the invention. Reference numeral π is referred to as "the 35th drawing". The auxiliary electrode unit 300 provided in the light-emitting device according to the embodiment of the present invention includes a power receiving portion (10), a wiring portion 320, and a sensing resistor portion 340. The power receiving unit 310 is connected to the transparent electrode, and the power receiving unit 31 is configured to transmit the power supplied from the external power source to the wiring unit 320. Further, as shown in Fig. 35, at least one sensing resistor portion 340 is formed in the power receiving portion 310. The power receiving portion 31 〇 forms a closed square, approximately flat 201246528 每 on each side of the transparent electrode and spaced from each side. Specifically, the power receiving section 310 constitutes first to fourth power receiving lines 311 (3Ua to 311d). The first power source receiving line 3Ua and the third power receiving line 3ΐ. Parallelly formed on the transparent repair, the second electric wire 3Ub and the thin power receiving wire are formed on the transparent electrode. The two long end portions of each of the power receiving lines 311 are physically connected to the two long end portions of the power receiving line. Further, as shown in the drawing, the power receiving line 311 is formed with a projection 331 and a recess IW 332. The projections 331 and the recesses 332 are formed, and the side faces of the transparent electrodes, in other words, are located on the side of the power receiving line in the non-wiring area. Power reception. The projection 331 formed in the P 310 is connected to the recess to receive the power receiving 4 310 to the external power supply line. The projection % i is directly connected to the power supply line of the first power source together with the transparent electrode. In the case of k, the recessed portion 332 is connected to the external power source for the lining or the bulging portion and the bulging portion are not formed. However, the invention is not limited thereto. It is assumed that the protruding portion 331 is connected to the first power source to the power supply line, wherein the first power source is mainly (+) 赖. Further, the power receiving portion _ is formed of a predetermined metal material and has a relatively high electrical conductivity, for example, gold or silver, and the power receiving portion 310 is formed on the transparent electrode through a photoresist or a printing process. . . The wiring portion 320 is formed in a mesh form in the internal region 415 of the power receiving portion 31_ to be connected to the power receiving portion 31A. The wiring portion 320 that is supplied to the transparent electrode by the wiring portion 320 and supplied to the transparent electrode via the power receiving portion 310 includes the first wiring 321 and the second wiring 322 for connecting the first power receiving lines 311a and the third to each other. The power receiving line 311c, the second wiring 322 is used to connect the second power receiving line 3Ub and the fourth power receiving line 311d to each other. The first wiring 321 and the second wiring 322 are physically connected to each other at an intersection. In this case, "fifth figure" indicates that the wiring portion 320 is formed in the inner region 415 by a vertical pattern (first wiring) and a horizontal line (second wiring) in a grid pattern. However, the embodiments of the present invention are not limited thereto, and may be formed in various forms. Further, the wiring portion 320 together with the sensing resistor portion 34 can also be used as a measurement variable of the circuit portion. Specifically, a predetermined portion of the wiring portion 320 arranged between each of the sensing resistors 341a to 343b of the sensing resistor portion 340, together with the sensing resistors 341a to 343b, is equal to a measurement variable for controlling the circuit portion. The following will be described in detail in conjunction with another drawing. The sensing resistor portion 340 is formed in the power receiving portion 31A, and the sensing resistor portion 340 serves as a terminal for connecting the circuit portion. For example, the sensing resistor portion 34 is used to provide a measurement variable such as a resistance value. In particular, the control unit solves the electrical balance by measuring the resistance value of the sensing resistor portion 34 and the resistance, current, and voltage of the wiring portion 320 connecting the sensing resistors 341a to 343b to each other (in accordance with an embodiment of the present invention, Electrical balance includes electric field, potential, charge density, voltage, and power 'these are all referred to as 〃 electric balance 〃). The control unit completes the control according to the electrical balance of the wiring portion 320 to control the brightness of the panel to be uniform. The method of using the control portion of the control and the sense resistor will be described in detail below. To this end, the sensing resistor portion 340 includes one or more sensing resistors 34ia to 343b, and each of the sensing resistors 341a to 343b is formed on a predetermined area of the power receiving portion 31,

42 S 201246528 The electrical characteristics of the shortest turn of a certain - expected thief. + For s, "Fig. 35" indicates the first to third pairs of sense resistors. Connect each part of the sense resistor to the _ shortest lining item _ resistance 3 to 343b imaginary _ field of view electrical interference to reflect the electrical characteristics of the control. In particular, the control unit controls the lining of the panel by detecting the temperature of the panel or the current flowing to the panel. In this case, the controlling officer makes (4) a resistor to detect the current or temperature. The preset resistance may be the value of the sense resistors 341a to 鸠 or may be the sum of the equivalents of the sense resistor pair, the sensed pair of the two transparent electrodes, and the auxiliary electrode pair 300. The town will describe this in detail with examples of the control. The panel control realized by the preset resistor can be completed by independent operation of the circuit portion connected to the sense resistors 3 4 i a to 343b, or can be completed by the connection operation of the circuit portions connected to the sense resistors 341a to 343b. The control unit is connected to the sense resistor pair thereof or each pair of sense resistors. The circuit portions connected to the sense resistors respectively contain different circuit dies and operation characteristics. However, the embodiments of the present invention are not limited thereto. In addition, the set resistance represents the sum of the resistance value of the single sense resistor or the sense resistor pair and the equivalent resistance value. However, it may also be considered as a single resistor in circuit conversion, as will be described below, assuming that the preset resistance is a single resistor. Therefore, the pair of sensing resistors are formed on the power receiving portion 31A so that the distance between the sensing resistors constituting the pair is the shortest. α 43 201246528 Specifically, as shown in FIG. 35, the sensing resistor is formed in the first power receiving line 311a and the second power receiving line 3Uc, and the distance between the power receiving lines 3ι is the most f. The embodiment of the invention does not limit the position of the sense resistor at the first power receiving line Μh and the second power receiving line 311c. The sensing resistor is formed on the second power receiving line 311b and the fourth power receiving line 3. In this case, the measured value may be incorrect. As shown in FIG. 35, the sensing resistor portion 340 is formed in the protruding portion 331 of the power receiving portion 310, and the appearance of the protruding portion 331a at the sensing resistors 341a to 343b and other projections are formed. The appearance of the 331 is different. Fig. 36 is an enlarged view of "κ/' shown in "Fig. 35", and "37th" is a schematic diagram showing an example of a connection circuit portion. In addition, "38A", "38b" and "38C" are another examples of types and configurations of sensing resistors. Please refer to "36th", "37th", "38A", "38B" and "38C". The appearance of the protrusions 331 & The appearance of the projections 331. The respective appearances of the other projections 331 are formed such that the width of the power receiving line 311 is wider. In contrast, the projection 331a formed with the sensing resistor 342 includes a first extension 333 and a second extension 334. The first extension portion 333 extends toward one side of the panel, and the second extension portion 334 extends from the longitudinal end portion of the first extension portion 333 and is parallel to the power receiving line 311. The first extension 333 and the second extension 334 are physically and continuously connected to each other. The electrode exposure portion (or a space 335) is formed between the first extension portion 333 and the second extension portion 334 and the power receiving portion, unlike the other protrusion portions 331. In addition,

44 S 201246528 The area of the power receiving line 331 parallel to the second extension has a narrow line width compared to other areas of the power receiving line 311. Meanwhile, the longitudinal end portion of the sensing resistor 342 is formed in the electrode exposure portion 335 as shown. Further, as shown in "38A", "38B" and "38c", the type and number of the sense resistors 342 are variable. "38A", "38B" and "38C" represent one example of the sense resistor 3 illusion. According to the sense resistor, such as the required resistance value and the connection of the external circuit, _ remaining 342 can be provided. Embodiments of the invention are not limited to the examples shown in the drawings. /, Fig. 37 is not intended to be used to connect the power supply line 381 and the signal line 382 to which the circuit portion is soldered. As shown in Fig. 37, the power receiving unit 31 connects the power supply line through the power supply line 381 or a predetermined pattern. Further, the protruding portion 331a and the sensing resistor 3 are connected to each other through the signal line 382. Although the pattern t is not shown, the circuit part uses the on-board chip (chip〇n

Board, C0B) way to connect the sense resistor 342 'The embodiment of the present invention is not limited to the example of the portion of the electric material ▲ 0 figure "the field circuit and the panel of the equivalent circuit of the equivalent circuit, to Indicates the operation of the circuit portion generated by the sense resistor. "The first is not to use the sense resistor to control the electric power." A case of the control unit of an embodiment is not considered. Please refer to "Picture 39" and the current control section shown in the section "Fig. 41" and "41". The embodiment includes a regulator-mirror circuit 45 201246528 391, a current control circuit 392, and a reference. Voltage supply circuit 393. A preset resistance (RT) is connected to the calibration mirror circuit 391. Further, the current control unit 350 further includes a low voltage protection circuit 395 and a shutdown delay circuit 394. Embodiments of the present invention control the flow of current flowing near the shortest distance between pairs of sense resistors to uniformly maintain brightness while operating the panel. Therefore, the current control unit 350 shown in Fig. 39 connects the sensing resistors 341a to 343b as external circuit portions. The current control unit 350 controls the current flowing to the panel through a set value (rset) to maintain uniformity. In this case, the set value (rset) is determined by the setting resistor (RT) connected between the ground terminal (GND) and the input value of the set value (RSET). The set resistor (rt) is operated as a current source for the calibration mirror circuit 391. This current source enables calibration mirror circuit 391 to control current control circuit 352 to control the current flow to the panel. Therefore, the current control section 350 connects one of each of the sense resistor pairs. The current control unit 350 includes a low voltage protection circuit 395, a shutdown delay circuit 394, a reference voltage supply circuit 393, a calibration mirror circuit 391, and a current control circuit 392. The low voltage protection circuit 395 is supplied with a panel input voltage (VIN). When the panel input electric volt (VIN) is the operating limit voltage or lower, the low voltage is protected by the 395. (4) The current control circuit is not stopped. . Further, in accordance with the request to turn off the delay circuit 394, the low voltage protection circuit controls the current (four) circuit 392 to stop the operation of the panel. To this end, the low voltage _ 201246528 circuit 395 is connected to the panel power supply unit (not shown) to supply the panel input voltage (VIN), and the panel input voltage (VIN) is supplied to the reference voltage supply circuit 393 and the calibration mirror circuit 391. At this time, the low voltage protection circuit 395 is connected to the electric 1 control circuit 392. The shutdown delay circuit 394 determines the interruption of the externally supplied control woman (E-view). When the supply of the control signal (En/PWM) is interrupted, the state of the shutdown delay circuit is requested to stop the panel operation. The reference voltage supply circuit 393 supplies a reference voltage to the calibration mirror circuit 391 to control the current control circuit 392. To this end, the reference voltage supply circuit 393 is supplied with a panel input voltage (yjn) from the low voltage protection circuit 395. The calibration mirror circuit 391 controls the current control circuit 392 in accordance with the reference voltage supplied from the set resistance (RT) and the reference voltage supply circuit 393. To this end, the calibration mirror circuit 391 is connected to a set resistor (4), a reference voltage supply circuit 393, and a current control circuit 392. As the resistance value of the set resistance becomes larger, the calibrated mirror circuit 391 controls the amount of current flowing into the panel to decrease. When the resistance value of the set resistance (RT) is fixed, the calibration mirror circuit 391 controls the current control circuit 392' to supply a conventional current to the panel. + The current control circuit is operated according to at least the control of the external control signal (EN/pWM), the low voltage protection circuit 395, and the calibration mirror package 391. A current control circuit 392 is employed to control the current flowing in the panel. To this end, the current control circuit 392 is connected to the panel and the second power source (or sub- (_) voltage or the ground terminal G (four) for the current control circuit 392 to provide a reference value for the set resistance (RT) to use 201246528 for the standard The current control of the mirror circuit 391. The components of the current control unit omits the low voltage protection circuit 395 and the shutdown delay circuit 394. This kind of brother, through the sense resistor value or the sense resistor and the wiring resistance (R. R1 to R3) Set the resistance (foot). In the 40th figure, RS11, RS12, RS22, RS31, and RS32 are the resistance values of the sense resistors 341a to 343b, respectively, and ri to R3 are the sense resistor pairs.等效The equivalent resistance of the shortest distance. In this case, the set resistance (RT) can be the resistance of the sense resistor 341a~ island connected to the setpoint input terminal or the resistance set (349: 349c) In particular, when the current control unit is connected to the first sense resistor 341a of the first sense resistor pair, the set electrical value is the resistance value of the first sense resistor 341a or the first sense resistor, The second sense resistor is repeated The sum of the first wiring resistances R1. The following description will be further described in conjunction with "41." The transparent electrodes and the auxiliary electrode portions 300 are equivalent to each other having a resistance having different resistance values. This is because the transparent electrodes are used as the resistance elements. The current flow is irregular. The sum of the current flowing between the power supply (vCC) and the ground terminal (GND) in the equivalent circuit is at the power supply (VCC) and the terminal (GND) (5), at the measurement point Sl, illusion and illusion In particular, the sum of the currents n, 12, and 13 flowing along the imaginary line is different from each other, wherein the imaginary line is along S1-S1, S2-S2', and S3-S3'. This II, 12 and The same material and the sum result in the brightness of the panel. According to the embodiment of the invention, the values of the currents n, 12 and 13 are controlled by the sensing resistor and the current control unit 35 to be uniform 'this can reduce the brightness difference of the panel.

48 S 201246528 A current control unit 35 is provided in each of the corresponding first to third resistance sets 349 in Sl-S1', S2_S2, and S3_S3. The current control unit 350 connected to each of the resistor sets 349 detects the flow to each of the resistor sets 349 by using a set resistance (RT).

The current, current control section 350 can control the current flowing to each resistor set 349 to 13). In other words, the current control section 350 controls a set of resistors 349 in which more current flows to less current (ι to 13) and a resistor set 349 that controls less current flowing to the excess current (n to 13). In particular, when the current detected by the set resistance (RT) increases, the current control circuit 392 operates to reduce the amount of current flowing to the panel. When the detected current is reduced, current control circuit 392 operates to increase the current flow to the panel. In particular, the current control section 350 connected to each of the resistor sets 349 independently controls the current flowing into each of the resistor sets 349 to maintain the luminance of the imaginary equivalent region to which each of the resistor sets 349 belongs. Therefore, the brightness of the entire panel can be uniformly controlled. Therefore, by controlling the amount of current flowing to the top surface of the panel, the brightness difference of the panel can be reduced and the brightness uniformity can be enhanced. To this end, the value of the set resistance (RT) in the current control unit 350 is defined as the equivalent resistance value of the wiring portion 320 connecting the pair of sense resistor values (RS11-RS12, RS21-RS22, and RS31-RS32). The sum of the sense resistors 341a to 343b. Alternatively, the setting resistance (RT) is the value of the sensing resistor 34 (RS 11, RS 12, RS2, RS22, RS31, and RS32) that is connected to the current control unit 350. In other words, three sets of current control units 350 are provided in the panel having the auxiliary electrode unit 300 shown in Fig. 35. The set resistance value of each current control unit 350

S 49 201246528 RS1 卜 RS2 卜 RS31 or RS12, RS22, RS32 or RS11+R1+RS12, RS21+R2+RS22, RS31+R3+R32. "42" is an example of a current control unit of the control unit of the second embodiment. Please refer to "42" "The control unit of the second embodiment includes switching elements (sw: SW1, SW2, and SW3), comparators (OP: OP1, 〇P2, and 〇p3), and ·|· mutual current sources ( IR) (or constant voltage source). The first input terminal of the comparator (OP) is connected to one end of the set resistor (RT), and is connected to the first input terminal IR of the first input terminal of the parent device (OP). Furthermore, the output terminal of the comparator (op) is connected to the base terminal (B) of the switching element. The collector terminal (C) of the switching element is connected to the output terminal of the panel (EL), and the base terminal (B) is connected to the output terminal of the comparator (〇p). The emitter terminal is connected to the ground terminal (GND). In this case, the panel (el) can be understood as a general term for the first electrode portion, the second electrode portion, the auxiliary electrode portion, and the light-emitting portion, and one of them can complete the connection. In addition, this point is also applied to the following description. One end of the setting resistor (RT) is connected to the input terminal of the comparator (0P), and the other end of the setting resistor (RT) is connected to the collector terminal of the output terminal and the panel (EL) (〇. Specifically, 'flow through the setting resistor (RT)) The current (irt) is the first input of the comparator (〇p). The reference current (8) supplied by the constant current source (IR) is the second input of the comparator (〇p). The comparator (OP) compares the first input with The second input 'comparator (〇p) controls the switching elements according to the comparison result such that currents (n, 12, and 13) flow along each equivalent region. As described above, the current control portion of the second embodiment is applied to the setting. The current of the resistor (RT) and the current of the constant current source, and the switching element according to the comparison value.

50 S 201246528 This can control the amount of current flowing through the switching element and the current applied to the auxiliary electrode portion 300. Fig. 43 is a view showing an example of the current control unit of the third embodiment provided in the control unit for controlling the current based on the temperature. Referring to "FIG. 43", the current control portion of the third embodiment includes a first resistor (RA), a set resistor (RT), a comparator (OP4), a constant voltage source (vr), and a switching element (SWM). The current control portion of the temperature is configured with a resistor having a variable value based on the temperature to control the current supplied to the panel. Therefore, the brightness of the panel can be controlled by controlling the current supplied to the panel. To this end, the current control unit using the temperature includes a first resistor (RA), a set resistor (RT) for each equivalent region, a comparator (〇P4), a constant voltage source (vr), and a switching element (SWM). ). One end of the first resistor (RA) is connected to the power source (VCC), and the other end of the first resistor (RA) is connected to one end of the set resistor (RT) and the input of the comparator (〇p). In this case, the first resistor (RA) and the end of the set resistor are input to the input of the comparator (0P). However, embodiments of the invention are not limited thereto. One end of the set resistor (RT) is connected to the ground terminal (GND), and the other end of the set resistor (RT) is connected to the other end of the first resistor (RA) and the input of the comparator (〇p). In addition, the other input of the comparator (OP), such as the main (1) input terminal, is connected to the (+) polarity of the constant voltage source (VR). The output terminal of the comparator (〇p) is connected to the gate terminal of the switching element (SWM). This comparator (OP) compares the two opposite end voltages of the set resistance (RT) with a constant voltage. The comparator (0P) controls the flow in the switching element (SWM) according to the comparison result. The current flows to the control panel (EL). The gate terminal (G) of the switching element (SWM) is connected to the output terminal of the comparator (〇p), and the source terminal (S) of the switching element (SWM) is connected to ground. The switching terminal (SWM) and the terminal (D) are connected to the output terminals of the panel. Similar to the current circuit described above, this current control unit is also connected to each resistor set to control the current (11 to 13) of each of the set resistors. Therefore, the current control unit can control the brightness of the panel. Fig. 44 is a view showing a current control unit having a protection circuit of the fourth embodiment provided in the control unit. Please refer to "Fig. 44". The protection circuit includes a set resistor (RT), a second resistor, a comparator (OP), and a switching element (SWM). Connect one end of the resistor (RT) to the power supply (VCC) together with the collector terminal of the switching element. The other end of the set resistor (RT) is connected to the input terminal of the panel (EL) and one end of the second resistor (RR). One end of the second resistor (RR) is connected to the input terminal of the panel (EL) and the set resistor (RT), and the other end of the second resistor (RR) is connected to the first input terminal of the comparator (〇p). The collector terminal (C) of the switching element (SWM) is connected to the power supply (VCC), and the base terminal (B) is connected to the output terminal of the comparator. The emitter terminal (E) returns to the ground terminal (GND) and the second input terminal of the comparator (0P). The comparator compares the current of the returned emitter terminal (E) with the current that has passed the set resistance (RT), and the comparator controls the switching element (SWM) according to the comparison result to protect the circuit from short-circuiting of the panel (EL), especially the light-emitting portion, Overvoltage

S 52 201246528 (over-voltages) or overcurrent (over_currents) is damaged. The "fifth figure" shows the insulating portion 23A arranged on the first electrode portion 22A. For example, the insulating portion 230 is formed in a frame shape and has a closed space. Further, the 'I-bar edge portion 230 & has a non-uniform pattern having a plurality of projections 231 and depressions 232 formed along the outer periphery thereof. The insulating portion 230 is formed by applying a photoresist liquid. The protruding portion of the insulating portion 230 is located on the first region of the first electrode portion 22A to insulate the first electrode portion 22A and the second electrode portion 25A in the first region 221 . The insulating portion 230 includes a first insulating portion 233 and a second insulating portion 234. The first insulating portion 233 covers the power receiving portion 31 of the auxiliary electrode 胄3〇〇, and the second insulating portion 234 covers the auxiliary electrode. The wiring portion is moved by the insulating wiring portion 320. The first, the squad, the squad, and the sputum (5, 233 s) are in the form of a frame corresponding to the shape of the power receiving unit 31 ,. The Jt condition T帛, the thickness of the insulating portion 233, and the thickness of the second insulating portion 234 are respectively larger than the thickness of the power receiving portion and the thickness of the wiring portion 32. This is because the complete insulation must be completed. The light emitting portion is located at the first electrode portion. (Refer to "Fig. 28" and "29th"), the auxiliary electrode portion is thin (please refer to "Picture"), and the insulating portion 230. For this reason, the outer periphery 4 of the light-emitting portion is arranged so as not to exceed the insulating portion 230. It

S 53 201246528 External surroundings. The light emitting unit 240 includes a red light emitting material, a green light emitting material, or a blue light emitting material. The light-emitting portion 240 is formed of a low-molecular organic material or a high-molecular organic material, and the light-emitting portion 240 includes a button, and is recombined through the electron-electron hole to complete the light emission. Further, the light emitting portion 240 further includes at least one of a hole injection layer, an electron injection layer, a hole transport layer, and an electron transport layer. The second electrode portion 250 is formed on the light emitting portion 240. In the first region 221, the second electrode portion 250 is laminated on the insulating portion 230 without exceeding the protruding portion 231 of the insulating portion 23A. In the second region 222, the second electrode portion 250 is laminated on the first electrode portion 22A and extends beyond the insulating portion 230. The second electrode portion 250 is formed on the light emitting portion 240. In the first region 221 (refer to "28th view" and "29th view"), the outermost edge portion of the second electrode portion 250 is laminated on the insulating portion 230, and the protruding portion 231 of the insulating portion 23 is not exceeded. The outermost edge. In the second area 222 (refer to "28th figure" and "29th figure"), the second electrode part 250 is laminated on the first electrode part 220 (refer to "28th figure" and "29th figure"). Exceeding the insulating portion 230. The second electrode portion 250 may be formed of an opaque material such as a handle (9), a lock (Ba), magnesium (Mg), silver (Ag), copper (Cu), aluminum (A1), or an alloy of these materials. Further, the second electrode portion 250$ is formed of a transparent material, for example, made of indium tin oxide (ITO) or indium zinc oxide (ITO). For example, the second electrode portion 25 is formed by 0

54 S 201246528 When the illuminating device is completed-side illuminating, both of the first electrode portion 22 〇 and the second electrode 2S0 are formed by a transparent electrode. When the light-emitting device completes the light emission on both sides, both the first electrode portion 220 and the second electrode portion 250 are formed of transparent electrodes. The second electrode portion 250 is formed on the light emitting portion 240. In the first region 221, the second electrode portion 250 is laminated on the insulating portion 23, and does not exceed the protruding portion 231 of the insulating portion 230. In the second region 222, the second electrode portion 250 is laminated on the first electrode portion 22A beyond the insulating portion 230. The second electrode portion 250 may be formed of an opaque material such as calcium (Ca), barium (Ba), silver (Ag), copper (Cu), or (A1) or an alloy of these materials. Further, the second electrode portion 250 may be formed of a transparent material such as indium tin oxide (ITO) or surface zinc oxide (IZO). For example, the second electrode portion 250 is formed of a chain. Fig. 46 is a cross-sectional view taken along line L-L' shown in Fig. 27, and Fig. 47 is a cross-sectional view taken along line M-Μ' shown in Fig. 27. Referring to "46" and "47", the auxiliary electrode portions 3 are arranged on the first electrode portion 220. In this case, the width of the wiring portion 320 constituting the auxiliary electrode portion 300 is approximately 50 to 250 μm. Further, the interval between one of the wiring portions 320 of the auxiliary electrode 300 and the other wiring portion 320 is 300 to 600 μm. If the interval between the wiring portions 320 is too narrow, the current density at the light-emitting portion 240 near the wiring portion 320 is too high, and the light-emitting portion 240 is overheated. Therefore, if possible, the interval between the two wiring portions is larger than the width of the wiring portion. 55 201246528 The sensing resistor portion 341a is protruded from both sides of the auxiliary electrode portion 3A, and is not shown (not shown). During the control, the auxiliary electrode portion 300 is covered by the insulating portion 23A. The insulating portion 23 is for insulating the auxiliary electrode portion 300 and the second electrode portion 25A from each other. The insulating portion 23 is formed of an inorganic material such as oxidized stone or nitrite. However, the embodiment of the present invention is not limited thereto, and the insulating portion is now formed of a plurality of inorganic materials or organic materials. If the insulation between the auxiliary two electrode portions 250 can be ensured even without the insulating portion 230, the insulating portion 23A can be omitted. For example, the auxiliary electrode portion 300 and the second electrode portion are arranged to be used as an insulating portion. In this case, the auxiliary insulating portion is not provided on the auxiliary electrode portion 300. As shown in the "figure 46", the (+) voltage supplied to the first electrode portion 220 placed in the outer peripheral region of the light-emitting device 2 is transmitted to the light-emitting portion of the contact first-electrode portion 220. . The first electrode portion 22 to which the voltage is supplied (1) is the first region function (refer to "Fig. 28" and "Fig. 29"). In the month > 221 (see "28" and "29"), the first electrode portion 220 contacts the light-emitting portion 240 and does not contact the second electrode portion 25A. This is because the insulating portion 230 is located between the first electrode portion 22A and the second electrode portion 25A. In the meantime, referring to "Fig. 47", the (a) voltage supplied to the first electrode portion 220 placed on the outer periphery of the light-emitting device is transmitted to the first electrode portion.

S 56 201246528 Two electrode portion 250. The (_) voltage transmitted to the second electrode portion 250 is transmitted to the light emitting portion 240 contacting the second electrode portion 250. In "Fig. 47", the first electrode portion 22'' at both ends is electrically isolated from the first electrode portion 220 located at the center. As described in connection with "Fig. 28", the first electrode portion DO corresponding to the boundary between the first region 221 and the second region 222 is removed along the line 220a to electrically isolate the first region 221 and the second region 222 from each other. The insulating insulating portion 230 is laminated on the region where the first electrode portion 220 is removed, and as a result of the reluctance, in the "47th drawing", the first electrode portion 22 located at both ends is the second region 222, and the _ electrode located at the middle portion The Ministry is now the first district 22μ. Therefore, the second regions 222 are electrically isolated from each other. In the u, the first electrode portion 220 is in contact with the second electrode portion, and the first electrode portion 22 and the second electrode portion (4) respectively supply (+) and (1) voltages which are transmitted to the first and the 220, thereby causing current The first electrode (four) light portion 240 and the second electrode portion 25 are flowed. The outer peripheral region of the object, the low current of the auxiliary electrode portion 300, the _____== ground drop

S 57 201246528 Therefore, the brightness between the peripheral region and the central region in the light-emitting portion can be remarkably reduced to ° "" and "FIG. 49" are structures for controlling the brightness at a specific region in the light-emitting device of the present invention. A detailed description of the Thunder I· n power supply unit 1 and the panel shown in Fig. 48 and Fig. 49. Related information. Therefore, a conductor 4〇〇 is provided on the panel shown in the omitted T diagram, and this conductor is raised =. The second electrode portion 25 is opposed to each other and has a polarity opposite to that applied to the second electrode portion. The conductor is made in the center of the panel and in the center of the panel, and the center of the sub-panel is spaced a predetermined distance. In this case, the conductors arranged in the center of the panel are called Na, and the conductors arranged next to the center are called 4〇〇a and 4〇〇c. The conductor 40G supplies a charge having a polarity opposite to that of the charge emitted by the second electrode portion (4), and is used to enhance the brightness of the corresponding region in which the conductor is located, as will be described below. In contrast to the current flowing along other regions, the amount of current flowing along the center of the panel or immediately adjacent to the center of the panel is smaller, and accordingly, the luminance is deteriorated. In order to avoid degradation of the party degree and to reduce the entire luminance difference of the panel, the conductors 400 are arranged in a region where luminance degradation may occur. The detailed operation of the conductor will be described below. The control unit connects the first power supply unit (1) and the second power supply unit m to control

58 S 201246528 The electric power they supply In addition, as mentioned above, the control is connected to the ground, and the current is applied to the current connected to the position of the ❹m resistance 341a (the side of the secret). Immediately adjacent to the middle part of the system, the control unit guides the part of the power supplied by the power supply unit 111 and the second power supply unit 112. In other words, when the power supplied to the second electrode portion 250 is a negative voltage, a positive voltage is supplied to the conductor 4G0. When the power supplied to the second electrode portion 25G is a positive voltage, a negative voltage is supplied to the conductor 4A. When it is determined by the control of the control unit 350 that the current applied to a specific area (for example, the center of the panel) is lower than the preset reference, the additional ray is supplied to the conductor 400 recorded in the corresponding area to minimize or avoid the brightness with respect to other areas. difference. As shown in Fig. 49, a cover member 27A is provided on the second electrode portion 25, and the conductor 400 is arranged on the cover member 27''. The back surface of the conductor is exposed in the direction of the second electrode portion 25A. A blank space is formed between the cover member 270 and the second electrode portion 250, and a seal assembly 280 is arranged in the space. Conductor 400 can have a predetermined appearance and volume. The conductor 4 is formed of a metal material such as zinc (Zn), indium (In), cadmium (Cd), gallium (Ga), nickel (Ni), iron (Fe), cobalt (Co), and town (W). , titanium (Ti), complex (Cr), indium (Mo), gold, (Au),! 6(Pt) '#5(Ca), barium (Ba), magnesium (Mg), silver (Ag), copper (Cu), aluminum (A1) or alloys of these materials. Further, the conductor 400 is formed of, for example, indium tin oxide (yttrium oxide) or indium zinc oxide (IZO). 59 201246528 When the negative voltage is connected to the second electrode portion 250, the electrons (6) emitted by the second electrode portion 250 encounter a hole illuminating at the pass-through sublayer and the electron transport layer. 30% of the electrons are secreted through the hole transport layer and the hole injection layer, and they cannot encounter holes in the illuminator and contribute to luminescence. According to this embodiment, the conductor 400 is placed adjacent to the second electrode portion 25, and the conductor 400 can reduce the loss of electrons which cannot contribute to light emission. The conductor 40 (H is transmitted through a polarity opposite to the polarity possessed by the second electrode portion 25A. Therefore, electrons depleted through the hole transport layer and the hole injection layer are trapped in a region in which the conductor is completely adjacent. The possibility of electrons reacting after encountering a hole at the illuminant is improved. As a result, the region in which the conductor turns are placed in the embodiment of the present invention can enhance the luminous efficiency of the illuminating device. In particular, when the conductor 400 is placed on a panel whose brightness may be deteriorated At the center of the center, the brightness of the center can be enhanced. The conductors are arranged at one or more positions where brightness enhancement is required, even at the center of the organic light-emitting device. The current control unit including the embodiment of the present invention will be described below. The operation principle of the illuminating device is provided with a current control unit in the towel detecting portion. The current control unit 350 of the first embodiment shown in "Fig. 39", "Fig. 4" and "41" is based on the preset The set resistance (RT) value keeps the current flowing uniformly to the auxiliary electrode portion for each set resistance set 349, and only controls the flow value to be uniform. In particular, even the electric power of the auxiliary electrode is When temporarily increasing, the setting resistor 201246528 (Ri) and the current control circuit 332 control the current having a normal value to flow to the auxiliary electrode portion. Therefore, the current is controlled by uniformly controlling the amount of current flowing to the front surface of the panel. The 卩350 can lower the panel. The brightness is poor, and only the brightness uniformity is enhanced. When the power comes to a constant current, the current control unit of the second embodiment shown in Fig. 42 controls the contact element (SW)' to supply a predetermined amount of current to the auxiliary electrode. Section 300. When the current supplied by the power supply increases, the current control unit receives the feedback 'and the down-flow current via the set resistance (10)). When the current is reduced, the current control unit increases the amount of current flowing to a certain small amount of current, and controls a predetermined amount of current to constantly flow through the set resistance (RT). In particular, a current control section is provided for each set of resistors, reducing the set of resistors (4) flowing to a large amount of current flow, and increasing the amount of current flowing to a set of resistors flowing a small amount of money. Therefore, the amount of current flowing in each area of the control panel is uniform. As described above, the current control unit of the third embodiment shown in Fig. 43 has a variable resistance value according to the temperature control setting resistance (RT). The switching element can be controlled by comparing the voltage applied to the set resistor (r) and the voltage of the constant voltage source (VR). Therefore, the current flowing through the switching element can be controlled. As a result, when the temperature of the set resistance (RT) is increased by the overcurrent supplied to the panel or the auxiliary electrode 300, the current control portion of the third embodiment lowers the temperature by lowering the current of the switching element (SWM). When the temperature of the set resistance (RT) is lowered, the electric purchase increases the current flowing through the open element (SWM). The second current control unit uses a current flow control method to keep the current applied to the auxiliary electrode 201246528 portion 300 constant and uniform while maintaining the temperature of the panel or auxiliary electrode portion 300 uniform. The current control unit of the fourth embodiment shown in Fig. 44 includes a short circuit protection circuit. When an overvoltage or overcurrent or short circuit current is supplied to the panel, the short circuit protection circuit controls the switching element (SWM) to form a bypass (B). Therefore, the overcurrent or the short-circuit current is branched, and the panel (EL) can be prevented from being deteriorated by the overcurrent or the short-circuit current. As described above, when the current flows through the set resistance, the current control portion of the fourth embodiment minimizes the current passing through the switching element (SWM) before the current flows to the panel or the auxiliary electrode portion 300. In contrast, when the voltage or current applied to the set resistance increases, the protection circuit causes current to flow to the switching element and accordingly forms a bypass. Thereafter, the protection = path branches this overcurrent via the bypass. a When the voltage or current applied to the set resistance (RT) is lowered, the protection circuit reduces the current flowing through the switching element and controls the current supplied from the electric rotation to the panel or the auxiliary electrode portion 300. Control units (current control unit 35〇图图) and "control unit shown in Fig. 49" in the first to fourth embodiments. 』至4 In the state in which the sensing resistor is connected, the sensing is arranged. The wiring portion provided in the auxiliary electrode portion corresponding to the region of the resistor, the control portion measures the current applied to one of the currents. The field determines whether the amount of current at the specific region is smaller than the preset reference control. Supplying a positive or positive power source to the corresponding conductor of the area. In other words, when the second electrode portion is connected to a negative voltage, the control unit supplies positive power.

S 62 201246528 Pressing body. When the second electrode portion 25G is connected to the positive voltage, the control portion supplies a negative voltage to the conductor 400. The conductors 4 are arranged in any area of the hair strand that needs to be enhanced in brightness. Further, when a plurality of conductors 400 are arranged, the voltages supplied to these conductors are different from each other. As described above, the conductor of the present invention is spaced apart from each other on the second electrode portion 25, and has a polarity opposite to that of the voltage supplied to the second electrode portion 250, so that the luminance of the region of the conductor 4GG is transmitted through the electric field effect. Was added. Therefore, the conductors 400 are correspondingly arranged in the region of the light-emitting portion having deteriorated brightness. This simple method improves the uniformity of brightness. Further, the conductors 400 are arranged in various orientations and forms in the region of the light-emitting device where brightness is desired to be enhanced. Even if the appearance of the hair is changed, the conductors are arranged at the desired position and the brightness uniformity can be easily and effectively ensured. When a plurality of conductors 400 are arranged, the voltages or currents supplied to the conductors 4〇〇 are different from each other, and desired luminance characteristics can be achieved. Although the present invention has been disclosed above in the foregoing embodiments, it is not intended to limit the invention. Modifications and modifications are intended to be included within the scope of the present invention without departing from the spirit and scope of the invention. In particular, various modifications and adaptations are possible in the component parts and/or arrangements of the subject combinations disclosed herein. Other methods of use will be apparent to those skilled in the art, in addition to variations and modifications in the component parts and/or arrangements. [Simple description of the diagram] Figure 1 shows the pattern of positive and negative voltages in a conventional illuminating device. 63 201246528 Intent; not intended, the second figure is set in the green setting of the present invention. A plan view of a plurality of layers; a third plan view showing a first pole portion of the light-emitting device shown in Fig. 2; and a plan view showing an insulating portion of the light-emitting device shown in Fig. 2; Figure 5 shows the connection between the first electrode and the power supply. The figure 6 is read as the 发光·Α of the illuminating device shown in Fig. 2, and the line cut is not shown in Fig. 7. A schematic cross-sectional view taken along line (4) of the light-emitting device shown in FIG. 2; FIG. 8 is a charge distribution for supplying (+) and (a) voltages. FIG. 9 is an embodiment of the present invention. The plane for current supply is shown in Figure C-C'. Figure 10 is a cross-sectional view of the current provided in Figure 9 along the current diagram shown in Figure 9. Figure 11 is shown in Figure 9. A cross-sectional view of the line D of the current supply device; ° Fig. 12 is a cross-sectional view taken along the line of the current supply device shown in Fig. 9; Example of a system using a current _ 9 illustrates the apparatus of FIG supply section turned

64 S 201246528 Intent; FIG. 14 is a schematic diagram showing a plurality of layers of the hair supply of the present invention according to another embodiment of the present invention; ° ' Figure 16 is the first schematic view; Figure 17 is the first intention; 15 shows the flat surface of the insulating frame of the light-emitting device shown in Figure 15 of the first electrode portion of the light-emitting device Fig. 18 is a plan view showing the connection process between the first electrode portion and the power source shown in Fig. 16; and Fig. 9 is a view showing the current supply device shown in Fig. 9 being stacked on the πth figure. A schematic plan view of the state on the first electrode portion; Fig. 20 is a cross-sectional view taken along line F_F of the light-emitting device shown in Fig. 15; FIG. 21 is a view along the line 15 In the illuminating device, GG, a cross-sectional view taken along the line; Fig. 22 is a schematic diagram showing the charge distribution (+) and (a) voltage supply in the illuminating device shown in Fig. 15; In the current supply device shown in Fig. 1, there is no centering and edge in the illuminating device in the measurement of the arranging resistance tool Schematic diagram of the difference in brightness; 65 201246528 Figure 24 is not intended to be a percentage of the difference in brightness between the center and the edge of the test shown in Figure 23; Figure 25 is a view of the arrangement of the red scarf The center of the wire and the edge _ brightness difference, and the towel (four) Chen and the edge material with the same resistance value; Figure 26 is a schematic diagram of the percentage of the brightness difference between the center and the edge in the test of Figure 25; Figure 27 The tf is a schematic plan view of the hairline of the re-embodiment of the invention; the 28th and 29th is a plan view of the first electrode of the illumination device; and the power supply of the surface illumination device shown in FIG. Fig. 31 is a cross-sectional view taken along line H_H' of Fig. 3; Fig. 32 is a cross-sectional view taken along line w of Fig. 3; The figure shows a cross-sectional view taken along the Μ of the third figure; the figure 34 shows a schematic diagram of the power supply unit arranged on the first electrode; the 35th _ shows the actual situation of the invention Schematic diagram of an example of an auxiliary electrode formed by a field towel; Figure 36 is an enlarged view of κ shown in Fig. 25. Schematic diagram; Fig. 37 is a schematic diagram showing an example of a connection circuit portion; the second diagram, the second diagram, and the figure are schematic diagrams showing examples of types and structures of the sense resistors;

S 201246528; Fig. 39 is a schematic diagram showing an example of the current control unit as an external circuit unit. 11=^_Observation of the circuit of the resistance circuit, the operation of the circuit portion generated by the non-inductive resistance; Control of the resistance control current Fig. 41 is not a schematic diagram of an example of the use of the sensing unit of the first embodiment; the figure is not shown as an example of the current control unit of the control unit of the second embodiment; Department (10) _ flow current control: 料 控 料 愤 愤 实 实 实 实 实 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图 示意图A schematic view of the electrode; a drawing of FIG. 46 is not a cross-sectional view taken along the [Fig. 3]; FIG. 47 is not a MM as shown in FIG. ; f 48 is not intended to be a schematic representation of the hairline in which the conductor is mounted, and FIG. 49 is not a cross-sectional view of the n_n shown in FIG. [Main component symbol description] 1〇.............................. Organic light-emitting device 100 ........... ................ Current supply device 67 5 201246528 20 ........................... Organic light-emitting portion 200 .....................Light-emitting device 210 ................ ...........substrate 220 ...........................first electrode portion 220a..... ......................line 221 .......................... .1st District 222 ...........................Second Zone 223 .............. .............Blank area 230 ...........................Insulation 231 .... .......................protrusion 232 ..................... .... recessed portion 233 ...........................first insulating portion 234 ........... ................second insulating portion 240 ...........................lighting portion 250 ...........................Second electrode portion 270 ........... .......... Covering assembly 280 ........................... Sealing assembly 100....... .................... Current supply device 101 .......................... .The first coating layer 102 .......................... .Second Coating Layer 111 ........................... First Power Supply Department

S 68 201246528 112 ...........................second power supply unit 120 ............. ..............The first power supply 121 ...........................the first power supply Supply line 122 ...........................first connection pad 122' .............. .............first connection pad 130 ...........................second power supply 131 ...........................second power supply line 132 ................ ...........the second connection pad 132' ...........................the second connection pad 140, A, B, C.........resistive tools

Rl, R2, R3, R4, R5, R6, R7, R8, R9, R10, R11, R12 ........................... Resistor RS11, RS2, RS31, RS12, RS22, RS32 resistance value 150 ...........................Insulation frame 150a..... ......................Central Department 150b......................... .. Peripheral 151 ...........................through hole 1 ............... ............object 300 ...........................Auxiliary electrode portion 310 ..... ......................Power receiving unit 311a........................ ...the first power receiving line s 69 201246528 311b...........................the second power receiving line 311c ..... ...................... Third power receiving line 311d..................... ..... fourth power receiving line 311 ........................... power receiving line 320 ........ ...................Wiring section 321 ........................... a wiring 322 ...........................second wiring 331 ................ ........... bulging portion 331a ........................... bulging portion 332 .... .......................Depression 333 ........................ ...the first Extension 334 ........................... second extension 335 ............... ............electrode exposed portion 340 ..................... sensing resistance portions 341a, 341b , 342, 342a, 342b, 343a, 343b sense resistors 349, 349a, 349b, 349c resistance set 350 ..................... Control unit 392 ...................... Current control circuit 381 ................ ...........Power supply line 382 ...........................Signal line 391 ..... ...................... Calibration mirror circuit 201246528 393 ....................... .... reference voltage supply circuit 394 ...........................turn off delay circuit 395 .......... .................low voltage protection circuit 400, 400a, 400b, 400c conductor 415 .................... .......Internal area SI, S2, S3, SI', S2', S3, measuring point current panel input voltage control signal setting value setting resistance grounding terminal

II '12 '13 > IRT VIN .................... EN/PWM.......... RSET....... ............RT .................... GND................ .... VCC........................... Power OP, OP1, OP2, OP3, OP4 Comparator SWM ..... ...................Switching element SW > SW1 ' SW2 ' SW3 Switching element RA .................. .........first resistance RR ...........................second resistance VR ...... ..................... Constant voltage source IR ......................... ..Constant current source ir ...........................Reference current 71 201246528 EL ............ ...............Panel C ........................... Collector terminal B .. .........................base terminal E ..................... ...the emitter terminal BB ...........................bypass G .......... .................gate terminal D ...........................bungee Terminal S ...........................source terminal

Claims (1)

201246528 VII. The scope of the patent application: 1. A light-emitting device comprising: a substrate; a first electrode portion provided on the substrate; a light-emitting portion provided in the first electrode portion, the light-emitting portion An organic light-emitting material is included; and a second electrode portion is provided in the light-emitting portion, and at least one of the first electrode portion and the second electrode portion of the middle portion 4 provides a plurality of regions separated and insulated from each other, and Power sources including mutually different polarities are respectively supplied to the regions to suppress the luminance difference generated in the light-emitting portion. The illuminating device according to Item 1, wherein the first region and the first region are alternately formed along a peripheral portion of the first electrode portion, and the first electrode portion and the first power source have a a predetermined polarity, supplied to the first region, and a first power source having an opposite polarity, supplied to the second region, and the first electrode portion contacting the light emitting portion in the first region without contacting the first portion The second electrode portion and the electrode portion are not in contact with the second light-emitting portion of the second electrode portion. The illuminating device of claim 2, further comprising: 73 201246528 an insulating portion arranged on the first electrode portion, wherein the reading is performed. ^ The first electrode portion in the interval boundary is removed, and the insulation is at the boundary of the first electrode portion. i is cleared 4. As requested in item 2, where the first -, ,, 兮 - - 帝, 広 4 /, ι pen source is (+) polarity: brother first secret is (a) Polarity, and when the first source is (·) New, the first power source is (+) polarity. , wherein the item is in the form of a forest, wherein the first electrode and the second region are included in the first electrode portion. According to the illuminating device of item 2, the sputum 7-zone is electrically isolated from each other. The greening device of item 2, wherein one of the edges of the first electrode portion includes a blank region in which the first and second regions are not arranged. 8·= please _ 7_ describe the hairpin, its + _ the first and second zones (four) phase. </ RTI> </ RTI> </ RTI> </ RTI> </ RTI> </ RTI> </ RTI> </ RTI> </ RTI> </ RTI> </ RTI> </ RTI> </ RTI> </ RTI> </ RTI> </ RTI> </ RTI> </ RTI> </ RTI> The current supply device 'supplied to at least -, to the first and second electrode portions S 74 201246528, wherein the second electrode portion provides at least a plurality of regions that are isolated and insulated from each other - and The current supply device includes a resistance tool to control a current value supplied to the first electrode portion or the second electrode portion to suppress a luminance difference generated in the light emitting portion. 10. The illuminating device of claim 9, wherein the current supply device comprises a first connection pad and a second connection pad, the first connection pad is for supplying a power source to the one of the predetermined ones The second connection pad is for supplying a power source having a reverse polarity to another area, and the X resistance tool controls a current value supplied to the first connection port or the second connection pad. The illuminating device of claim 10, wherein the regions include a -th region and a second region insulated from and spaced apart from the first region, and the current supply device comprises, - a first power supply portion For supplying a first power source having a predetermined polarity; a second power supply portion for supplying a second power source having a reverse polarity; a space, the insulating frame, including a central portion and a peripheral portion, the central portion a portion of the blank portion is arranged along the central portion; the first power supply portion includes a first power supply line and a plurality of first connections 75 201246528. The first source supply line is arranged along the steel edge portion at the periphery. On the department, connect. The first source supply unit, the first connection port is branched along the first power supply line; and the second power supply unit includes a second power supply line and a plurality of second connection pads. The first power supply line is arranged along the first power supply line below the peripheral portion to electrically connect to the second power supply portion, and the second connection pads are branched along the second power supply line. 12. The illuminating device of claim 11, further comprising: a resistance tool 'connected between the first power supply and the first connection port or the second power supply line and the second connection For controlling the current value supplied to the first connection pad or the second electrode pad. 13. If the hairline of item 12 is requested, the terminal portion includes a plurality of sides, and . Each side of the Haidi Dipole contains the first zone and the second zone, as well as . The closer the resistance tool is to the edge of the first power supply line, the greater the resistance value. R. The hair strand of claim 11 wherein the remaining tool connects each of the first port or each of the second ports. The illuminating device of claim 11, wherein two or more first connection pads or two or more second connection ports are dispensed from a single resistance tool. 76 S 201246528. The hairline of claim 11, wherein the first connecting pad extends along the bottom of the insulating frame and passes through the insulating frame. The illuminating device of claim 11, wherein the first power source is a (+) voltage, the second power source is a (1) voltage, and a 6 Hz resistance tool is arranged on the first power supply line and the first - between the ports. 18. A light-emitting device comprising: a substrate; a first electrode portion arranged on the substrate; an auxiliary electrode portion arranged in the first electrode portion; a light-emitting portion 'arranged in the auxiliary electrode portion and the first portion a first electrode portion; a second electrode portion is provided in the light emitting portion; (4) a power supply portion for supplying a Wei to a matte portion via the first electrode portion, the second electrode portion, and the auxiliary electrode portion; And a control unit that connects the auxiliary electrode portion to measure an electric scratch or a force applied to the auxiliary electrode, and controls a brightness difference generated in the power supply light-emitting portion of the power supply portion according to the measurement result. The illuminating device of claim 18, wherein the auxiliary electrode portion includes a power receiving portion for forming an outer periphery thereof; and a wiring portion 'connecting the power receiving portion, the wiring portion being connected by the power Closing; and 77 201246528 - a sensing resistor provided in the power receiving portion. The illuminating device of claim 19, wherein the power receiving portion comprises, - a first extension, extending outwardly; - a second extension portion extending from one end of the first extension portion; and - an electrode The exposed portion is formed by the first and second extension portions, and the side surface of the exposed portion of the sensing resistor (10) is aligned in the direction of the second extension portion. The illuminating device according to Item 2G, wherein one end of the sensing resistor is spaced apart from the second extending portion. For example, the illuminating skirt of claim 19, wherein a plurality of sensing resistors are provided, the sensing sensations being aligned with the power receiving 敎-predetermined edge and the other opposite edge. 23. The hairline of claim 19, which provides a complex _ resistance, and a sensing resistor such as a hai, is spaced apart from each other along the periphery of the power receiving portion. 24. The illuminating device of claim 17, further comprising: an insulating portion ???a (10) gamma electrode portion ± insulating the auxiliary electrode portion and the illuminating portion from each other. The illuminating device of claim 22, wherein the current flowing to one of the set resistances of one of the sensing resistors or one of the set resistors is compared with a reference voltage or a reference current The control unit controls the power supply. 〃 S 201246528 26. If the green setting is as described in the 2S item, the resistance value of the shooting resistor is two: 'The sensing resistor formed in the same edge has the resistance value of the pair of lion electrodes. The sum of the resistance values of the effective resistance or the resistance of the towel. -. = widely described illuminating device in which the sensations formed in different edges, with the shortest of the two being in pairs. The illuminating device of item 26, wherein the control unit is a current system. The P or - overcurrent protection circuit ' is controlled to apply to the first electrode portion, the auxiliary electrode portion, the light emitting portion, and the second electrode portion by at least one value. A light-emitting device according to claim 28, wherein the control portion is provided corresponding to each pair of sense resistors. The illuminating device of item 29, wherein the control unit is connected to at least one of the measuring resistors. The illuminating device of item 28, wherein the current control unit comprises: a voltage; 'to generate a reference calibrator circuit through an input voltage, and connect the one of the set terminals connected to a ground terminal at one end thereof One end for generating a control number according to the reference voltage and the set resistor; and a current control circuit for controlling the first power S 79 201246528, the auxiliary electrode portion, the light emitting portion, and the current control circuit according to the control signal At least one of the currents of the second electrode portion flows. 32. The hair current control unit of claim 28, wherein the current control unit comprises: - a comparator comprising a first input terminal connected to the slave resistor end and another terminal connected to a constant current source; The switching element 'includes a collector terminal connected to the other end of the set resistor and a base terminal connected to the output of the comparator, and the emitter terminal is connected to the ground terminal (GND). 33. The hairspring of claim 28, wherein the towel (four) portion comprises: a first resistor, one end connected to an input power source, and the other end connected to one end of the set resistor and one of the comparators first An input terminal; the first input terminal is connected to the end of the set resistor and the first resistor; and a switching element, a gate terminal is connected to the output terminal of the comparator, a source terminal or a The pole terminal is connected to at least one of the first electrode portion, the auxiliary electrode portion, the light emitting portion, and the second electrode portion, and the other of the source terminal or the drain terminal is connected to the terminal. The illuminating device of claim 33, wherein the resistance value of the sensing resistor is variable based on temperature. The illuminating device of claim 28, wherein the overcurrent protection circuit comprises: 201246528 a switching element, a collector terminal is connected to a power source, and an emitter terminal is connected to each collector terminal, a comparator, An output terminal is connected to one of the base terminals of the switching element, one of the wheeled terminals is connected to the emitter terminal; and a second resistor is connected at one end to the other input terminal of the comparator, and the other end is connected to one end of the set resistor And the set resistor is connected between the second resistor and the collector terminal. The illuminating device of claim 28, further comprising: a protective cover provided on the second electrode portion; and a conductor provided in the protective cover opposite to the second electrode portion The control unit is connected to the conductor, and the control unit controls a power source to the conductor, the polarity of the power source being opposite to a polarity applied to one of the power sources of the second electrode portion to capture a predetermined polarity emitted by the second electrode portion The charge together with the charge having the opposite polarity, from the secret surface, has a predetermined recorded charge along with a charge having the opposite polarity to generate light in the light-emitting portion. 〃