JP5716630B2 - Organic EL lighting device - Google Patents

Description

  The present invention relates to an organic EL lighting device including an organic EL panel (EL: Electro Luminescence).

  As disclosed in Japanese Patent Application Laid-Open No. 2010-232286 (Patent Document 1), an organic EL lighting device including an organic EL panel is known.

JP 2010-232286 A

  The organic EL lighting device disclosed in Japanese Patent Application Laid-Open No. 2010-232286 (Patent Document 1) is limited to enabling the entire light emitting surface to emit light uniformly.

  In the present invention, for example, the organic EL panel is turned on so that the central portion in the light emitting surface becomes brighter and slower than the peripheral portion in the light emitting surface, or the light emitting surface in the light emitting surface is compared with the peripheral portion in the light emitting surface. An object of the present invention is to provide an organic EL lighting device capable of exhibiting a special effect on illumination such as turning off the organic EL panel so that the central portion becomes darker earlier.

An organic EL lighting device according to an aspect of the present invention generates a direct current or pulsed drive waveform, outputs a drive voltage corresponding to the drive waveform, an anode, a cathode, and the anode and the cathode An organic layer provided between the light emitting surface , a light emitting surface from which light generated in the organic layer is extracted , and a plurality of power feeding units provided on the peripheral side of the light emitting surface , and output from the driving circuit. And an organic EL panel in which the driving voltage is supplied to the organic layer through the plurality of power feeding units , the anode, and the cathode, and a central portion of the light emitting surface of the anode from the power feeding unit The resistance of the path leading to the organic layer through the part corresponding to is higher than the resistance of the path reaching the organic layer from the power feeding part through the part corresponding to the peripheral edge part of the light emitting surface of the anode, The organic layer is Has a capacitor component, when turning on the organic EL panel by the driving circuit in the organic EL panel in the off state to supply the drive voltage, the drive circuit turns on the organic EL panel By supplying the driving voltage having the first frequency to the organic EL panel for a predetermined time from the time when the instruction signal for receiving the instruction signal is received, the inside of the light emitting surface is compared with the periphery of the light emitting surface. The organic EL panel is turned on so that the central portion side becomes brighter and slower, and the driving circuit supplies the driving voltage having the first frequency to the organic EL panel for the predetermined time. by supplying the driving voltage having a second frequency lower than the first frequency to the organic EL panel, a uniform lighting condition of the above organic EL panel That.

  Preferably, during the predetermined time, the drive circuit changes the frequency value of the first frequency so as to gradually decrease. Preferably, the drive circuit includes a PWM control unit that controls the duty of the drive waveform, and the PWM control unit changes the duty of the drive waveform during the predetermined time.

  Preferably, the drive circuit includes a voltage control unit that controls a voltage value of the drive voltage, and the voltage control unit changes the voltage value of the drive voltage during the predetermined time. Preferably, the organic EL lighting device according to an aspect of the present invention further includes a switch unit disposed between the drive circuit and the plurality of power feeding units, and the switch for the predetermined time. The means reduces the number of the power supply units that supply the drive voltage to the organic EL panel by disconnecting an electrical connection between the drive circuit and a part of the power supply units.

An organic EL lighting device according to another aspect of the present invention generates a direct current or pulsed drive waveform and outputs a drive voltage corresponding to the drive waveform, an anode, a cathode, and the anode and the cathode An organic layer provided between the light emitting surface , a light emitting surface from which light generated in the organic layer is extracted , and a plurality of power feeding units provided on the peripheral side of the light emitting surface , and output from the driving circuit. And an organic EL panel in which the driving voltage is supplied to the organic layer through the plurality of power feeding units , the anode, and the cathode, and a central portion of the light emitting surface of the anode from the power feeding unit The resistance of the path leading to the organic layer through the part corresponding to is higher than the resistance of the path reaching the organic layer from the power feeding part through the part corresponding to the peripheral edge part of the light emitting surface of the anode, The organic layer is Has a capacitor component, the organic EL panel is a uniform lighting state by being supplied with the driving voltage having a third frequency from the driving circuit, the organic EL panel in which said uniform lighting state When the organic EL panel is extinguished by stopping the supply of the driving voltage to the organic EL panel, the driving circuit receives the instruction signal for extinguishing the organic EL panel. by the driving voltage supplied for a predetermined time to the organic EL panel having a fourth frequency higher than towards the center side in the light-emitting surface in comparison with the peripheral portion within the emission surface The organic EL panel is extinguished so that the darkness quickly becomes dark, and the drive circuit applies the drive voltage having the fourth frequency to the organic EL panel at the predetermined time. After feeding for, by stopping the supply of the drive voltage to the organic EL panel, it is unlit the organic EL panel.

  Preferably, during the predetermined time, the drive circuit changes the frequency value of the fourth frequency so as to gradually increase. Preferably, the drive circuit includes a PWM control unit that controls the duty of the drive waveform, and the PWM control unit changes the duty of the drive waveform during the predetermined time.

  Preferably, the drive circuit includes a voltage control unit that controls a voltage value of the drive voltage, and the voltage control unit changes the voltage value of the drive voltage during the predetermined time. Preferably, the organic EL lighting device according to another aspect of the present invention further includes a switch unit disposed between the drive circuit and the plurality of power feeding units, and the switch for the predetermined time. The means reduces the number of the power supply units that supply the drive voltage to the organic EL panel by disconnecting an electrical connection between the drive circuit and a part of the power supply units.

  According to the present invention, for example, the organic EL panel is turned on so that the central portion in the light emitting surface becomes brighter and slower than the peripheral portion in the light emitting surface, or the light emitting surface is compared with the peripheral portion in the light emitting surface. It is possible to obtain an organic EL lighting device capable of exhibiting a special effect on lighting, such as turning off the organic EL panel so that the central portion of the inside becomes darker earlier.

It is a figure which shows typically the whole structure of the organic electroluminescent illuminating device in Embodiment 1. FIG. 2 is a plan view showing an organic EL panel used in the organic EL lighting device in Embodiment 1. FIG. It is arrow sectional drawing along the III-III line in FIG. It is arrow sectional drawing along the IV-IV line in FIG. It is a figure which shows typically the state by which the organic electroluminescent panel used for the organic electroluminescent illuminating device in Embodiment 1 and the drive circuit were mutually connected. It is a figure which shows the relationship between the drive voltage supplied from a drive circuit with respect to the organic electroluminescent panel used for the organic electroluminescent illuminating device in Embodiment 1, and time. FIG. 2 is a diagram equivalently showing a light emitting unit of an organic EL panel used in the organic EL lighting device according to Embodiment 1. When a voltage having a drive waveform having a relatively wide pulse width is supplied to the organic EL panel used in the organic EL lighting device according to Embodiment 1, it is actually applied to each position in the light emitting section of the organic EL panel. It is a figure which shows the relationship between a drive voltage and time. When a voltage having a drive waveform with a relatively narrow pulse width is supplied to the organic EL panel used in the organic EL lighting device according to the first embodiment, the voltage is actually applied to each position in the light emitting section of the organic EL panel. It is a figure which shows the relationship between a drive voltage and time. FIG. 6 is another plan view showing an organic EL panel used in the organic EL lighting device in the first embodiment. It is a figure which shows the time change of the luminance distribution in the light emission surface of the organic electroluminescent panel used for the organic electroluminescent illuminating device in Embodiment 1. FIG. It is a figure which shows the relationship between the drive voltage supplied from a drive circuit with respect to the organic electroluminescent panel used for the organic electroluminescent illuminating device in the 1st modification of Embodiment 1, and time. It is a figure which shows the relationship between the drive voltage supplied from a drive circuit with respect to the organic electroluminescent panel used for the organic electroluminescent illuminating device in the 2nd modification of Embodiment 1, and time. It is a figure which shows the time change of the luminance distribution in the light emission surface of the organic electroluminescent panel used for the organic electroluminescent illuminating device in the 2nd modification of Embodiment 1. FIG. It is a figure which shows typically the whole structure of the organic electroluminescent illuminating device in the 3rd modification of Embodiment 1. FIG. It is a figure which shows typically the whole structure of the organic electroluminescent illuminating device in Embodiment 2. FIG. It is a figure which shows the relationship between the drive voltage supplied from a drive circuit with respect to the organic electroluminescent panel used for the organic electroluminescent illuminating device in Embodiment 2, and time. It is a figure which shows the time change of the luminance distribution in the light emission surface of the organic electroluminescent panel used for the organic electroluminescent illuminating device in Embodiment 2. FIG. It is a figure which shows the relationship between the other drive voltage supplied from a drive circuit with respect to the organic electroluminescent panel used for the organic electroluminescent illuminating device in Embodiment 2, and time. It is a figure which shows the time change of the other luminance distribution in the light emission surface of the organic electroluminescent panel used for the organic electroluminescent illuminating device in Embodiment 2. FIG. It is a figure which shows the relationship between the drive voltage supplied from a drive circuit with respect to the organic electroluminescent panel used for the organic electroluminescent illuminating device in Embodiment 3, and time. It is a figure which shows the time change of the luminance distribution in the light emission surface of the organic electroluminescent panel used for the organic electroluminescent illuminating device in Embodiment 3. FIG. It is a figure which shows the relationship between the drive voltage supplied from a drive circuit with respect to the organic electroluminescent panel used for the organic electroluminescent illuminating device in the 1st modification of Embodiment 3, and time. It is a figure which shows the time change of the luminance distribution in the light emission surface of the organic electroluminescent panel used for the organic electroluminescent illuminating device in the 1st modification of Embodiment 3. FIG. It is a figure which shows the relationship between the drive voltage supplied from a drive circuit with respect to the organic electroluminescent panel used for the organic electroluminescent illuminating device in the 2nd modification of Embodiment 3, and time. It is a figure which shows the time change of the luminance distribution in the light emission surface of the organic electroluminescent panel used for the organic electroluminescent illuminating device in the 2nd modification of Embodiment 3. FIG. It is a figure which shows the relationship between the drive voltage supplied from a drive circuit with respect to the organic electroluminescent panel used for the organic electroluminescent illuminating device in the 3rd modification of Embodiment 3, and time. It is a figure which shows the time change of the luminance distribution in the light emission surface of the organic electroluminescent panel used for the organic electroluminescent illuminating device in the 3rd modification of Embodiment 3. FIG. It is a figure which shows the relationship between the drive voltage supplied from a drive circuit with respect to the organic electroluminescent panel used for the organic electroluminescent illuminating device in Embodiment 4, and time. It is a figure which shows the time change of the luminance distribution in the light emission surface of the organic electroluminescent panel used for the organic electroluminescent illuminating device in Embodiment 4. FIG. It is a figure which shows typically the whole structure of the organic electroluminescent illuminating device in Embodiment 5. FIG. It is a figure which shows typically the whole structure of the organic electroluminescent illuminating device in Embodiment 6. FIG. It is a figure which shows typically the whole structure of the organic electroluminescent illuminating device in Embodiment 7. FIG. It is a figure which shows typically the whole structure of the organic electroluminescent illuminating device in Embodiment 8. FIG. It is a figure which shows the relationship between the drive voltage supplied from a drive circuit with respect to the organic electroluminescent panel used for the organic electroluminescent illuminating device in Embodiment 8, and time, and the relationship between the operation | movement of a transistor, and time. It is a figure which shows the relationship between the drive voltage supplied from a drive circuit with respect to the organic electroluminescent panel used for the organic electroluminescent illuminating device in the modification of Embodiment 8, and time, and the relationship between the operation | movement of a transistor, and time.

  Embodiments based on the present invention will be described below with reference to the drawings. In the description of each embodiment, when referring to the number, amount, or the like, the scope of the present invention is not necessarily limited to the number, amount, or the like unless otherwise specified. In the description of each embodiment, the same parts and corresponding parts are denoted by the same reference numerals, and redundant description may not be repeated.

[Embodiment 1]
With reference to FIG. 1, the whole structure of the organic electroluminescent illuminating device 100 in this Embodiment is demonstrated. The organic EL lighting device 100 includes an organic EL panel 10, a drive circuit 20 for driving the organic EL panel 10, and a power supply 30 for supplying power to the organic EL panel 10.

  As shown in FIG. 1, the drive circuit 20 includes a microcomputer 21, a memory 22, a transistor 23, and a constant voltage circuit 24. The microcomputer 21, the transistor 23, the constant voltage circuit 24, and the organic EL panel 10 are connected in series. The transistor 23 is a field effect transistor (FET), for example, and is connected to the output port of the microcomputer 21. The transistor 23 switches ON / OFF of a current flowing through the organic EL panel 10.

  The microcomputer 21 is connected to an instruction signal input means arranged outside such as the operation unit 40. The microcomputer 21 changes, for example, an instruction signal for turning on the organic EL panel 10 (lighting instruction signal), an instruction signal for turning off the organic EL panel 10 (light-off instruction signal), or the luminance of the organic EL panel 10 An instruction signal (a dimming instruction signal) is received from the operation unit 40.

  The microcomputer 21 executes a predetermined program stored in the memory 22 in accordance with the instruction signal received from the operation unit 40. The microcomputer 21 controls the transistor 23 and the constant voltage circuit 24 according to the contents of the program. In the present embodiment, a direct current or pulsed drive waveform is generated under the control of the microcomputer 21, and a drive voltage corresponding to the drive waveform is output from the drive circuit 20. The drive voltage output from the drive circuit 20 is supplied to the organic EL panel 10.

(Organic EL panel 10)
The organic EL panel 10 will be described with reference to FIGS. The organic EL panel 10 has a light emitting surface 18. FIG. 2 is a plan view showing the organic EL panel 10 viewed from the light emitting surface 18 side. In FIG. 2, the transparent substrate 11 is transparently illustrated using a one-dot chain line. In FIG. 2, the anode 12, the organic layer 13, and the like are shown through through the transparent substrate 11. 3 is a cross-sectional view taken along the line III-III in FIG. 4 is a cross-sectional view taken along the line IV-IV in FIG.

  As shown in FIGS. 2 to 4, the organic EL panel 10 is a light emitting means including an organic EL. The organic EL panel 10 includes a transparent substrate 11 (cover layer), an anode 12, an organic layer 13, a cathode 14, an insulating layer 15, a sealing layer 16, and a light emitting surface 18. The anode 12, the organic layer 13, and the cathode 14 are sequentially stacked on the surface of the transparent substrate 11.

  The transparent substrate 11 is composed of various glass substrates, for example. As a member constituting the transparent substrate 11, a film substrate such as PET (Polyethylene Terephthalate) or polycarbonate may be used. The light emitting surface 18 is formed on the lower surface of the transparent substrate 11.

  The anode 12 is a conductive film having transparency. In order to form the anode 12, ITO (Indium Tin Oxide) or the like is formed on the transparent substrate 11 by sputtering or the like. The anode 12 is formed by patterning the ITO film into a predetermined shape by photolithography or the like.

  The organic layer 13 (light emitting unit) can generate light (visible light) by being supplied with electric power. The organic layer 13 may be composed of a single light emitting layer, or may be composed of a hole transporting layer, a light emitting layer, a hole blocking layer, an electron transporting layer, and the like that are sequentially laminated.

  The cathode 14 is, for example, aluminum (AL). The cathode 14 is formed so as to cover the organic layer 13 by a vacuum deposition method or the like. In order to pattern the cathode 14 into a predetermined shape, a mask may be used during vacuum deposition.

The insulating layer 15 is provided to electrically insulate between the anode 12 and the cathode 14. The insulating layer 15 is formed by depositing SiO ₂ or the like on the anode 12 and in the vicinity of the outer periphery of the anode 12 by using, for example, a sputtering method. The insulating layer 15 formed on the anode 12 and in the vicinity of the outer periphery of the anode 12 is formed by using a photolithography method or the like so as to surround an outer edge of the anode 12 (a place where the anode 12 and the cathode 14 are separated from each other). Formed into a pattern.

  The sealing layer 16 has an insulating property. The sealing layer 16 is formed to protect the organic layer 13 from moisture and the like. The sealing layer 16 is formed by, for example, using a glass substrate and adhering the periphery with an epoxy-based photocurable adhesive. The sealing layer 16 seals substantially the entire anode 12, organic layer 13, and cathode 14 on the transparent substrate 11. A part of the anode 12 and a part of the cathode 14 are exposed from the sealing layer 16 for electrical connection.

  The portions of the anode 12 exposed from the sealing layer 16 (see FIG. 3) constitute the anode connection portion 12L and the anode connection portion 12R. The anode connecting portions 12L and 12R and the anode 12 are made of the same material. The anode connecting portion 12L and the anode connecting portion 12R are located on the peripheral edge side of the light emitting surface 18, and are located on the opposite sides of the light emitting surface 18.

  The portions of the cathode 14 exposed from the sealing layer 16 (see FIG. 4) constitute the cathode connection portion 14L and the cathode connection portion 14R. The cathode connecting portions 14L and 14R and the cathode 14 are made of the same material. The cathode connection portion 14L and the cathode connection portion 14R are located on the peripheral edge side of the light emitting surface 18, and are located on the opposite sides of the light emitting surface 18.

  The transparent substrate 11, the anode 12, the organic layer 13, the cathode 14, the insulating layer 15, the sealing layer 16, and the like configured as described above are held by a frame body or a housing (not shown) and are attached to a ceiling or a wall surface. Fixed.

  As shown in FIG. 5, in a state where the organic EL panel 10 and the drive circuit 20 are connected to each other, the drive is performed at a substantially central position of the anode connection portion 12L and a substantially central position in the anode connection portion 12R. The OLED + terminals of the circuit 20 are connected in parallel. A power feeding portion 12L1 is formed at a portion where the anode connecting portion 12L and the OLED + terminal of the drive circuit 20 are connected. A power feeding portion 12R1 is formed at a portion where the anode connecting portion 12R and the OLED + terminal of the drive circuit 20 are connected.

  Similarly, in a state where the organic EL panel 10 and the drive circuit 20 are connected to each other, the OLED of the drive circuit 20 is located at a substantially central position of the cathode connection portion 14L and a substantially central position in the cathode connection portion 14R. -Terminals are connected in parallel. A power feeding portion 14L1 is formed at a portion where the cathode connecting portion 14L and the OLED-terminal of the drive circuit 20 are connected. A power feeding portion 14R1 is formed at a portion where the cathode connecting portion 14R and the OLED-terminal of the drive circuit 20 are connected.

  As the organic EL panel 10, the organic layer 13 emits light when the driving voltage output from the driving circuit 20 is supplied through the power feeding units 12L1, 12R1, 14L1, and 14R1. The light generated in the organic layer 13 is extracted outside from the transparent substrate 11 (light emitting surface 18) side. 2 to 4, the light emitting surface 18 is illustrated as being formed in a part of the lower surface of the transparent substrate 11. In practice, however, the light generated in the organic layer 13 is transmitted through the transparent substrate 11. 11 is taken out from the entire lower surface. Therefore, the organic EL panel 10 emits light also from the outer peripheral portion of the light emitting surface 18 shown in FIGS.

(Operation of the organic EL lighting device 100)
The operation of the organic EL lighting device 100 will be described with reference to FIG. FIG. 6 is a diagram showing the relationship between time T when the organic EL panel 10 of the organic EL lighting device 100 is turned on and the drive voltage V supplied from the drive circuit 20 to the organic EL panel 10.

  In the organic EL lighting device 100, the organic EL panel 10 is turned on when the drive circuit 20 supplies a drive voltage to the organic EL panel 10 that is turned off. As shown in FIG. 6, it is assumed that the organic EL panel 10 is turned off when T0 ≦ time T <T1. At this time, the value of the drive voltage V supplied from the drive circuit 20 to the organic EL panel 10 is 0, and the organic EL panel 10 is in a light-off state.

  When the organic EL panel 10 is turned on, the drive circuit 20 applies a predetermined drive voltage having the first frequency F1 from the time (time T = T1) when the instruction signal for turning on the organic EL panel 10 is received. The organic EL panel 10 is supplied for a predetermined time (T1 ≦ time T <T2). In T1 ≦ time T <T2, the organic EL panel 10 forms a transition state (details will be described later).

  The drive circuit 20 supplies the drive voltage having the first frequency F1 to the organic EL panel 10 for the predetermined time (T1 ≦ time T <T2), and then starts the second frequency F2 from T2 ≦ time T. A predetermined driving voltage is supplied to the organic EL panel 10. Here, the value of the second frequency F2 is lower than the value of the first frequency F1.

  The second frequency F2 is, for example, 100 Hz, and the first frequency F1 is, for example, 450 KHz. At T2 ≦ time T, a predetermined drive voltage having the second frequency F2 is supplied to the organic EL panel 10, whereby the organic EL panel 10 forms a normal lighting state, and an object or the like has a desired brightness. It becomes possible to illuminate with.

  As described above, the light emitting surface 18 of the organic EL panel 10 (see FIG. 2 and the like) includes the organic layer 13 (light emitting unit) sandwiched between the anode 12 and the cathode 14. For this reason, the light emitting section in the organic EL panel 10 can be regarded as equivalent to a plurality of diodes and capacitors connected in parallel to each other arranged in a predetermined direction.

  Referring to FIG. 7, if a diode and a capacitor connected in parallel to each other are OLED1, OLED2,... OLEDn, the light emitting portion of the organic EL panel 10 in the light emitting surface 18 is OLED1 as shown in FIG. , OLED2, OLEDn, OLED2, OLED1 are connected in parallel.

  In FIG. 7, only OLED1, OLED2,..., OLEDn,. To strictly explain the operation of the organic EL lighting device 100, it is necessary to consider the distribution in the two-dimensional direction. However, the distribution in the two-dimensional direction and the distribution in one direction have the same characteristics in principle. The operation of the organic EL lighting device 100 will be described below based on OLED1, OLED2,..., OLEDn,. In addition, since the resistance of the cathode 14 made of Ag or the like is extremely smaller than the resistance of the anode 12 made of ITO or the like, the resistance of the cathode 14 is not shown in FIG.

  Assume that a pulsed drive voltage is supplied from the drive circuit 20 to the equivalent circuit shown in FIG. FIG. 8A shows the relationship between the drive voltage V actually applied to the OLED 1 and the time T when a predetermined voltage higher than the threshold voltage V1 is supplied to the OLED 1 when the time T = TA ( It is a figure which shows typically a voltage waveform.

  As shown in FIG. 8 (A), the OLED 1 closest to the peripheral portion of the light emitting surface 18 is hardly affected by the anode resistance of the anode 12 and the capacitor component in the light emitting portion. When a predetermined voltage is supplied at this time, the drive voltage V2 (V2> V1) is applied to the OLED 1 almost simultaneously with the supply (time T = TA). When the supply of voltage is stopped at time T = TB, the drive voltage applied to the OLED 1 becomes 0 almost simultaneously with the stop (time T = TB).

  FIG. 8B shows the relationship between the drive voltage V actually applied to the OLED 2 and the time T when a predetermined voltage higher than the threshold voltage V1 is supplied to the OLED 2 when the time T = TA ( It is a figure which shows typically a voltage waveform.

  As shown in FIG. 8B, in the OLED 2 away from the peripheral portion of the light emitting surface 18, due to the influence of the anode resistance of the anode 12 and the influence of the capacitor component in the light emitting portion, at time T = TA. When a predetermined voltage is supplied, the driving voltage V2 (V2> V1) is applied to the OLED 2 at time T = TA1 (TA <TA1). When the supply of voltage is stopped at time T = TB, the driving voltage applied to the OLED 2 is 0 at time T = TB1 (TB <TB1).

  FIG. 8C shows the relationship between the drive voltage V actually applied to OLEDn and time T when a predetermined voltage higher than the threshold voltage V1 is supplied to OLEDn at time T = TA ( It is a figure which shows typically a voltage waveform.

  As shown in FIG. 8 (C), in the OLED n located substantially at the center of the light emitting surface 18, when the time T = TA, the influence of the anode resistance of the anode 12 and the influence of the capacitor component in the light emitting portion are large. When a predetermined voltage is supplied, the driving voltage V2 (V2> V1) is applied to OLEDn at time T = TA2 (TA <TA1 <TA2). When the supply of voltage is stopped at time T = TB, the driving voltage applied to OLEDn is 0 at time T = TB2 (TB <TB1 <TB2).

  As shown in FIG. 8A, FIG. 8B, and FIG. 8C, the voltage waveform in the light emitting surface 18 of the organic EL panel 10 supplied with the pulse-shaped drive voltage is the power feeding unit 12L1. , 12R1, 14L1, and 14R1 (see FIG. 5), the distance becomes smaller.

  As shown in FIG. 8C, here, the drive voltage actually applied to OLEDn is higher than the threshold voltage V1 with respect to the voltage supplied to the organic EL panel 10 during TA ≦ time T <TB. Thus, the pulse width of the drive voltage (time difference between time TA and time TB) is set. Although the voltage waveform of the drive voltage applied to OLEDn is distorted, OLEDn has the same brightness as OLED1 and OLED2 while the drive voltage actually applied to OLEDn exceeds the threshold voltage V1. The light is emitted with the brightness (luminance).

  On the other hand, compared to the equivalent circuit shown in FIG. 7, the drive circuit 20 has a pulse-like drive voltage whose pulse width is narrower than that shown in FIGS. 8A, 8B, and 8C. Is supplied. FIG. 9A shows the relationship between the drive voltage V actually applied to the OLED 1 and the time T when a predetermined voltage higher than the threshold voltage V1 is supplied to the OLED 1 at the time T = TC ( It is a figure which shows typically a voltage waveform.

  As shown in FIG. 9 (A), the OLED 1 closest to the peripheral portion of the light emitting surface 18 is hardly affected by the anode resistance of the anode 12 and the capacitor component in the light emitting portion. When a predetermined voltage is supplied at this time, the drive voltage V2 (V2> V1) is applied to the OLED 1 almost simultaneously with the supply (time T = TC). When the supply of voltage is stopped at time T = TD, the driving voltage applied to the OLED 1 becomes 0 almost simultaneously with the stop (time T = TD).

  FIG. 9B shows the relationship between the drive voltage V actually applied to the OLED 2 and the time T when a predetermined voltage higher than the threshold voltage V 1 is supplied to the OLED 2 at the time T = TC ( It is a figure which shows typically a voltage waveform.

  As shown in FIG. 9B, in the OLED 2 away from the peripheral portion of the light emitting surface 18, due to the influence of the anode resistance of the anode 12 and the influence of the capacitor component in the light emitting portion, at time T = TC. When a predetermined voltage is supplied, the driving voltage V2 (V2> V1) is applied to the OLED 2 at time T = TC1 (TC <TC1). When the supply of voltage is stopped at time T = TD, the driving voltage applied to the OLED 2 is 0 at time T = TD1 (TD <TD1).

  FIG. 9C shows the relationship between the drive voltage V actually applied to OLEDn and time T when a predetermined voltage higher than the threshold voltage V1 is supplied to OLEDn at time T = TC ( It is a figure which shows typically a voltage waveform.

  As shown in FIG. 9C, in the OLEDn located at the approximate center of the light emitting surface 18, the influence of the anode resistance of the anode 12 and the influence of the capacitor component in the light emitting part is large, so that the time T = TC. When a predetermined voltage is supplied, the driving voltage V3 (V2> V3> V1) is applied to OLEDn at time T = TC2 (TC <TC1 <TC2). When the supply of voltage is stopped at time T = TD, the driving voltage applied to OLEDn is 0 at time T = TD2 (TD <TD1 <TD2).

  As shown in FIG. 9A, FIG. 9B, and FIG. 9C, the voltage in the light emitting surface 18 of the organic EL panel 10 supplied with a pulse-shaped drive voltage having a relatively narrow pulse width. Also as a waveform, as it leaves | separates from electric power feeding part 12L1, 12R1, 14L1, 14R1 (refer FIG. 5), it becomes a thing which became round.

  Furthermore, in the case shown in FIG. 9C, the time during which the drive voltage actually applied to OLEDn exceeds the threshold voltage V1 is shorter than in the case of FIG. OLEDn in the case shown in FIG. 9C emits light with darker brightness (luminance) than OLED1 and OLED2. As described above, when the pulse width is narrow, the ratio of occurrence of the luminance distribution in the light emitting surface 18 increases.

  The organic EL lighting device 100 of the present embodiment uses this principle. When a normal lighting state (see FIG. 6) is formed on the organic EL panel 10, a relatively wide pulse width as shown in FIGS. 8A, 8B, and 8C. Is supplied to the organic EL panel 10 at a second frequency F2 (see FIG. 6). In the lighting state, the organic EL panel 10 is lit so that the light emitting surface 18 emits light uniformly.

  On the other hand, when the organic EL lighting device 100 transitions the organic EL panel 10 from the unlit state to the lit state (in the transition state), FIG. 9 (A), FIG. 9 (B), and FIG. A drive voltage of the first frequency F1 (see FIG. 6) having a relatively narrow pulse width as shown in C) is supplied to the organic EL panel 10. As described above, the value of the first frequency F1 is higher than the value of the second frequency F2. That is, in the transition state, the driving voltage having the first frequency F1 that causes the luminance distribution as shown in FIGS. 9A, 9B, and 9C is applied to the organic EL panel 10. Supplied against.

  As shown in FIGS. 10 and 11, the luminance distribution between the position X1 and the position X2 along the line XX in the light emitting surface 18 of the organic EL panel 10 is in a light-off state (T0 ≦ time T <T1). Becomes uniform at luminance L = 0. In the transition state (T1 ≦ time T <T2), the central portion of the light emitting surface 18 is darker than the peripheral portion of the light emitting surface 18. In the lighting state (T2 ≦ time T), it becomes uniform at a predetermined luminance. Here, the time interval of the transition state (T1 ≦ time T <T2) is preferably about 1 second ≦ (T2−T1) ≦ 10 seconds, for example.

(Action / Effect)
As described above, in the organic EL lighting device 100, when the organic EL panel 10 is turned on, the organic EL panel 10 sequentially forms a light-off state, a transition state, and a light-on state, thereby forming a peripheral edge in the light emitting surface 18. Compared with the part, the central part in the light emitting surface 18 becomes slower and brighter. Therefore, according to the organic EL lighting device 100, it is possible to exhibit a special effect on lighting.

  In the present embodiment, the organic EL panel 10 is driven to emit light uniformly in the lighting state (T2 ≦ time T). However, in the lighting state (T2 ≦ time T), the organic EL panel 10 is driven. The panel 10 does not necessarily have to emit light uniformly, may emit light in a substantially uniform state, or may emit light in a state where some luminance unevenness exists.

(First modification)
As described above with reference to FIG. 6, in the first embodiment, the value of the first frequency F1 of the drive voltage supplied to the organic EL panel 10 in the transition state is the organic EL panel in the lighting state. 10 is set to be higher than the value of the second frequency F <b> 2 of the drive voltage supplied to 10.

  As shown in FIG. 12, as the drive voltage supplied to the organic EL panel 10 in the lighting state, a drive voltage corresponding to direct current may be supplied to the organic EL panel 10. Also in this case, the value of the first frequency F1 is higher than the value of the second frequency F2 (frequency = 0). That is, when the value of the first frequency F1 is higher than the value of the second frequency F2, the case where a driving voltage corresponding to direct current is supplied to the organic EL panel 10 in the lighting state is included. .

  Also in the organic EL lighting device according to the present modification, the organic EL panel 10 is sequentially formed with a light-off state, a transition state, and a lighting state when the organic EL panel 10 is turned on, thereby comparing with the peripheral portion in the light emitting surface 18. Thus, the central part in the light emitting surface 18 becomes brighter and slower. Therefore, even with the organic EL lighting device in this modification, it is possible to exhibit a special effect on lighting.

(Second modification)
As shown in FIG. 13, in the transition state of the present modification, the drive circuit 20 starts with the first frequencies F1A and F1B from the time when the instruction signal for turning on the organic EL panel 10 is received (time T = T1). , F1C are sequentially supplied to the organic EL panel 10 during a predetermined time (T1 ≦ time T <T2). The drive circuit 20 of the present modification changes the frequency values of the first frequencies F1A, F1B, and F1C so as to decrease in order.

  During T1 ≦ time T <T1A, the drive circuit 20 supplies a drive voltage having the first frequency F1A to the organic EL panel 10. Next, during T1A ≦ time T <T1B, the drive circuit 20 supplies a drive voltage having the first frequency F1B to the organic EL panel 10. Here, the value of the first frequency F1B is lower than the value of the first frequency F1A. The first frequency F1A is, for example, 500 KHz, and the first frequency F1B is, for example, 450 KHz.

  When the drive voltage having the first frequency F1B lower than the first frequency F1A is supplied to the organic EL panel 10, the luminance distribution in the light emitting surface 18 is relaxed (the luminance of the light emitting surface 18 as a whole). Changes in a direction in which it approaches uniformly.

  Thereafter, during T1B ≦ time T <T2, the drive circuit 20 supplies a drive voltage having the first frequency F1C to the organic EL panel 10. The value of the first frequency F1C is lower than the value of the first frequency F1B. The first frequency F1C is, for example, 100 Hz. In this case, since the waveform rounding does not affect the luminance of the light emitting surface 18, the light emitting surface 18 emits light almost uniformly. If the frequency is about 100 Hz, switching loss hardly occurs in the drive circuit 20, and the user hardly feels flicker.

  In T2 ≦ time T, the organic EL panel 10 forms a normal lighting state by supplying a predetermined drive voltage (DC in this case) having the second frequency F2 to the organic EL panel 10.

  As shown in FIG. 14, the organic EL panel 10 of the present modified example is in the state of T1 ≦ time T <T1A, T1A ≦ time T <T1B, and T1B ≦ time T <T2 from the extinguished state of T0 ≦ time T <T1. A lighting state of T2 ≦ time T is formed through a transition state including three stages of luminance changes.

  When a plurality of luminance changes are obtained in the transition state, the organic EL panel 10 of the present modification has a lower brightness when the central portion in the light emitting surface 18 is brighter than the peripheral portion in the light emitting surface 18 (lights off). The brightness can be changed smoothly during the transition state from the state to the lighting state. Therefore, according to the organic EL lighting device of this modification, it is possible to exhibit a higher quality rendering effect on illumination.

(Third Modification)
As shown in FIG. 15, the organic EL lighting device 101 according to this modification further includes a transistor 25 for short-circuiting the anode 12 (anode) and the cathode 14 (cathode) of the organic EL panel 10. The transistor 25 is, for example, a field effect transistor (FET), and is connected to the anode 12 and the cathode 14 of the organic EL panel 10.

  As described above with reference to FIGS. 7 to 9, when a pulsed drive voltage is supplied to the organic EL panel 10, it is affected by the anode resistance of the anode 12 of the organic EL panel 10 and the capacitor component in the light emitting section. As a result, the voltage waveform in the organic EL panel 10 is rounded. In the drive circuit 20 (see FIG. 1) used in the organic EL lighting device 100 according to the first embodiment described above, the transistor 23 connected in series with the organic EL panel 10 is turned on or off, whereby the organic EL panel 10 is turned on. On the other hand, a pulsed drive voltage is supplied.

  In the organic EL panel 10 of the organic EL lighting device 100 of the above-described first embodiment, the drive voltage is sufficient due to the influence of the capacitor component of the organic EL panel 10 even when the transistor 23 is switched from ON to OFF. The drive voltage supplied to the organic EL panel 10 without being discharged is held near the light emission start voltage (threshold voltage).

  Therefore, in the organic EL panel 10 of the above-described first embodiment, when the transistor 23 is turned on next, the light emitting surface 18 is based on the waveform rounding starting from the voltage value near the light emission start voltage (threshold voltage). There is an effect in illumination that the central portion in the light emitting surface 18 becomes brighter later than the inner peripheral portion.

  On the other hand, in this modification, when the transistor 23 is switched from ON to OFF, the driving voltage remaining as the capacitor component of the organic EL panel 10 is returned to 0 by the operation of the transistor 25. The transistor 25 is turned ON alternately with the transistor 23, thereby discharging the electric charge charged in the capacitor component of the organic EL panel 10 when the transistor 23 is OFF.

  Even when the transistor 23 is switched from ON to OFF by the operation of the transistor 25, the voltage at both ends of the organic EL panel 10 becomes zero. In the organic EL panel 10 of the present modification, when the transistor 23 is turned on next, the inner surface of the light emitting surface 18 is compared with the peripheral portion of the light emitting surface 18 based on the waveform rounding starting from the voltage value of 0. There is a lighting effect in which the central area becomes brighter and slower.

  Therefore, according to the organic EL lighting device 101 of the present modified example, compared to the organic EL lighting device 100 of the first embodiment described above, a large amount of luminance unevenness is formed in the light emitting surface 18 in the transition state. It becomes possible to demonstrate the prominent effect of the above.

[Embodiment 2]
Like the organic EL lighting device 102 shown in FIG. 16, the drive circuit 20 may include a PWM control unit 21A (PWM: Pulse Width Modulation) and / or a voltage control unit 24A. In other words, the drive circuit 20 may include only the PWM control unit 21A, or may include only the voltage control unit 24A.

  When the drive circuit 20 includes the PWM control unit 21A, the PWM control unit 21A may be provided in the microcomputer 21. When the voltage control unit 24A is included in the drive circuit 20, the voltage control unit 24A may be provided in the constant voltage circuit 24. The organic EL lighting device 102 may further include the above-described transistor 25 (see FIG. 15).

  17 and 18, when drive circuit 20 includes PWM control unit 21A, PWM control unit 21A controls the duty of drive voltage (drive waveform) supplied to organic EL panel 10 in the transition state. To do. The PWM control unit 21A in the present embodiment sets the duty to 50% when T1 ≦ T <T1C, and sets the duty to 75% when T1C ≦ T <T2.

  Compared with T1B ≦ T <T1C, the overall luminance in the light emitting surface 18 becomes brighter when T1C ≦ T <T2. Luminance can be changed smoothly when the central portion in the light emitting surface 18 is brightened more slowly (in the transition state in which the light emitting surface transitions to the lighting state) than the peripheral edge in the light emitting surface 18. It becomes.

  19 and 20, when drive circuit 20 includes voltage control unit 24A, voltage control unit 24A controls the voltage value of the drive voltage supplied to organic EL panel 10 in the transition state. The voltage control unit 24A in the present embodiment sets the drive voltage to the voltage value VA when T1 ≦ T <T1A, and sets the drive voltage to the voltage value VB when T1A ≦ T <T2. The voltage value VA is about half of the voltage value VB.

  When transitioning from T1 ≦ T <T1A to T1A ≦ T <T1B, the luminance is unevenly formed in the light emitting surface 18 by changing the drive voltage as described above. According to the said structure, it becomes possible to exhibit the more outstanding production effect on illumination.

[Embodiment 3]
In the above-described embodiments and modifications, the operation when the organic EL panel 10 is turned on has been described. According to the organic EL lighting device of the present embodiment, when the organic EL panel 10 is turned off, the organic EL panel 10 is organic so that the central portion in the light emitting surface 18 becomes darker faster than the peripheral portion in the light emitting surface 18. A special lighting effect such as turning off the EL panel can be exhibited.

  Referring to FIG. 21 and FIG. 22, specifically, the organic EL panel 10 is supplied with a predetermined drive voltage having the third frequency F3 when T3 ≦ time T <T4. A lighting state is formed.

  When the organic EL panel 10 is turned off, the drive circuit 20 applies a predetermined drive voltage having the fourth frequency F4 from the time when the instruction signal for turning off the organic EL panel 10 is received (time T = T4). The organic EL panel 10 is supplied for a predetermined time (T4 ≦ time T <T5).

  Here, the value of the fourth frequency F4 is higher than the value of the third frequency F3. The third frequency F3 is, for example, 100 Hz, and the fourth frequency F4 is, for example, 450 KHz. In T4 ≦ time T <T5, the organic EL panel 10 forms a transition state.

  The drive circuit 20 supplies a drive voltage having the fourth frequency F4 to the organic EL panel 10 for the predetermined time (T4 ≦ time T <T5), and then from T5 ≦ time T to the organic EL panel 10. The supply of the driving voltage is stopped. The organic EL panel 10 is turned off.

  When the organic EL lighting device according to the present embodiment forms a normal lighting state (see FIG. 21) for the organic EL panel 10, the above-described FIG. 8A, FIG. 8B, and FIG. A drive voltage of the third frequency F3 (see FIG. 21) having a relatively wide pulse width as shown in FIG. 8C is supplied to the organic EL panel 10. In the lighting state, the organic EL panel 10 is lit so that the light emitting surface 18 emits light uniformly.

  On the other hand, in the organic EL lighting device of the present embodiment, when the organic EL panel 10 is transitioned from the lighting state to the extinguishing state (in the transition state), the above-described FIG. 9A and FIG. ) And a driving voltage of the fourth frequency F4 (see FIG. 21) having a relatively narrow pulse width as shown in FIG. 9C is supplied to the organic EL panel 10. As described above, the value of the fourth frequency F4 is higher than the value of the third frequency F3. That is, in the transition state, the drive voltage having the fourth frequency F4 that causes the luminance distribution as shown in FIGS. 9A, 9B, and 9C is applied to the organic EL panel 10. Supplied.

  As shown in FIG. 22, the luminance distribution between the position X1 and the position X2 is uniform at a predetermined luminance in the lighting state (T3 ≦ time T <T4). In the transition state (T4 ≦ time T <T5), the central portion of the light emitting surface 18 is darker than the peripheral portion in the light emitting surface 18. In the unlit state (T5 ≦ time T), the luminance L = 0.

(Action / Effect)
As described above, in the organic EL lighting device according to the present embodiment, when the organic EL panel 10 is turned off, the organic EL panel 10 sequentially forms a lighting state, a transition state, and a light-off state. Compared with the periphery of 18, the inside of the light emitting surface 18 becomes darker faster. Therefore, even with the organic EL lighting device of the present embodiment, it is possible to exhibit a special effect on lighting.

(First modification)
As shown in FIG. 23, in the transition state of the present modification, the drive circuit 20 starts with the fourth frequencies F4A and F4B from the time when the instruction signal for turning off the organic EL panel 10 is received (time T = T4). , F4C are sequentially supplied to the organic EL panel 10 during a predetermined time (T4 ≦ time T <T5). The drive circuit 20 of the present modification changes the frequency values of the fourth frequencies F4A, F4B, and F4C so as to increase in order.

  During T4 ≦ time T <T4A, the drive circuit 20 supplies a drive voltage having the fourth frequency F4A to the organic EL panel 10. Next, during T4A ≦ time T <T4B, the drive circuit 20 supplies a drive voltage having the fourth frequency F4B to the organic EL panel 10. Here, the value of the fourth frequency F4B is higher than the value of the fourth frequency F4A. The fourth frequency F4A is, for example, 100 Hz, and the fourth frequency F4B is, for example, 450 KHz.

  Thereafter, during T4B ≦ time T <T5, the drive circuit 20 supplies a drive voltage having the fourth frequency F4C to the organic EL panel 10. The value of the fourth frequency F4C is higher than the value of the fourth frequency F4B. The fourth frequency F4C is, for example, 500 KHz.

  The drive circuit 20 supplies the drive voltage having the fourth frequency F4C to the organic EL panel 10 for the predetermined time (T4B ≦ time T <T5), and then from T5 ≦ time T to the organic EL panel 10. The supply of the driving voltage is stopped. The organic EL panel 10 is turned off.

  As shown in FIG. 24, the organic EL panel 10 of the present modification example is in the lighting state of T3 ≦ time T <T4, T4 ≦ time T <T4A, T4A ≦ time T <T4B, and T4B ≦ time T <T5. A light-off state of T5 ≦ time T is formed through a transition state including three stages of luminance changes.

  By obtaining a plurality of luminance changes in the transition state, the organic EL panel 10 according to the present modified example is more rapidly darkened in the central portion in the light emitting surface 18 than in the peripheral portion in the light emitting surface 18 (lights up). The brightness can be changed smoothly during the transition state in which the state transitions to the extinguished state. Therefore, according to the organic EL lighting device of this modification, it is possible to exhibit a higher quality rendering effect on illumination.

(Second modification)
Referring to FIGS. 25 and 26, when drive circuit 20 includes PWM control unit 21A (see FIG. 16), PWM control unit 21A provides drive voltage (drive waveform) supplied to organic EL panel 10 in the transition state. ) To control the duty. The PWM control unit 21A in this modification sets the duty to 75% when T4 ≦ T <T4A, and sets the duty to 50% when T4A ≦ T <T5.

  When T4A ≦ T <T4B, the overall luminance in the light emitting surface 18 becomes darker than when T4 ≦ T <T4A. Luminance can be changed smoothly when the central portion of the light emitting surface 18 is darkened faster than the peripheral portion of the light emitting surface 18 (in the transition state from the lighting state to the extinguishing state). It becomes.

(Third Modification)
Referring to FIGS. 27 and 28, when drive circuit 20 includes voltage control unit 24A (see FIG. 16), voltage control unit 24A has a voltage value of the drive voltage supplied to organic EL panel 10 in the transition state. To control. The voltage control unit 24A in the present modification sets the drive voltage to the voltage value VB when T4 ≦ T <T4C, and sets the drive voltage to the voltage value VA when T4C ≦ T <T5. The voltage value VA is about half of the voltage value VB.

  When transitioning from T4B ≦ T <T4C to T4C ≦ T <T5, the luminance is unevenly formed in the light emitting surface 18 by changing the drive voltage as described above. It becomes possible to exhibit a more prominent effect on the lighting.

[Embodiment 4]
In the above-described first and second embodiments and the modifications, the operation when the organic EL panel 10 is turned on has been described. In the above-described third embodiment and each modification, the operation when the organic EL panel 10 is turned off has been described.

  In the organic EL lighting device according to the present embodiment, when the luminance of the organic EL panel 10 is changed (when the organic EL panel 10 is dimmed), the light emitting surface 18 is compared with the peripheral portion in the light emitting surface 18. It produces a special lighting effect such as dimming the organic EL panel so that the central part of the inside becomes brighter and slower.

  Referring to FIGS. 29 and 30, specifically, the organic EL panel 10 is supplied with a predetermined drive voltage having a sixth frequency F6 having a duty of 25% when T6 ≦ time T <T7. Thus, a lighting state having a luminance of 25% is formed.

  When the organic EL panel 10 is dimmed so that the luminance increases from 25% to 75%, the drive circuit 20 receives an instruction signal for dimming the organic EL panel 10 (time T = T7). ), A predetermined drive voltage having the seventh frequencies F7A, F7B, and F7C is sequentially supplied to the organic EL panel 10 during a predetermined time (T7 ≦ time T <T8). The drive circuit 20 of the present embodiment changes each duty and each frequency value of the seventh frequencies F7A, F7B, F7C as follows.

  During T7 ≦ time T <T7A, the drive circuit 20 supplies a drive voltage having the seventh frequency F7A to the organic EL panel 10. Here, the frequency value of the sixth frequency F6 is, for example, 100 Hz, and the duty of the sixth frequency F6 is, for example, 25%. The frequency value of the seventh frequency F7A is, for example, 500 KHz, and the duty of the seventh frequency F7A is, for example, 40%.

  Next, during T7A ≦ time T <T7B, the drive circuit 20 supplies a drive voltage having the seventh frequency F7B to the organic EL panel 10. The frequency value of the seventh frequency F7B is, for example, 450 KHz, and the duty of the seventh frequency F7B is, for example, 40%.

  Thereafter, during T7B ≦ time T <T8, the drive circuit 20 supplies a drive voltage having the seventh frequency F7C to the organic EL panel 10. The frequency value of the seventh frequency F7C is, for example, 100 Hz, and the duty of the seventh frequency F7C is, for example, 50%.

  The drive circuit 20 supplies the drive voltage having the seventh frequency F7C to the organic EL panel 10 for the predetermined time (T7B ≦ time T <T8), and then starts the eighth frequency F8 from T8 ≦ time T. A drive voltage having the same is supplied to the organic EL panel 10. The frequency value of the eighth frequency F8 is, for example, 100 Hz, and the duty of the eighth frequency F8 is, for example, 75%.

  As shown in FIG. 30, the organic EL panel 10 according to the present embodiment starts from a lighting state of T6 ≦ time T <T7, and T7 ≦ time T <T7A, T7A ≦ time T <T7B, and T7B ≦ time T <T8. A lighting state of T8 ≦ time T is formed through the transition state including the three stages of luminance changes. The brightness of the organic EL panel 10 is brighter in the lighting state of T8 ≦ time T than in the lighting state of T6 ≦ time T <T7.

  The organic EL panel 10 of the present modified example has a central portion in the light emitting surface 18 that is closer to the central portion in the light emitting surface 18 than in the peripheral portion in the light emitting surface 18 in a transition state in which the lighting state changes to a lighting state brighter than the lighting state. It becomes possible to lighten up late. The organic EL panel 10 of the present modification can smoothly change the luminance by obtaining a plurality of luminance changes in the transition state. Therefore, even with the organic EL lighting device of the present modification, it is possible to exhibit a higher quality rendering effect on illumination.

  In the organic EL lighting device of the present embodiment, the organic EL panel 10 may be dimmed in the reverse order described above. According to the configuration, when the lighting state transitions to a darker lighting state than the lighting state, the central portion in the light emitting surface 18 can be darkened faster than the peripheral portion in the light emitting surface 18. The brightness can be changed smoothly. Even with this configuration, it is possible to achieve a higher quality rendering effect on the illumination.

[Embodiment 5]
Referring to FIG. 31, in organic EL lighting device 103 in the present embodiment, power supply unit 12L1 of anode 12 and drive circuit 20 are connected to each other, and power supply unit 12L1 is connected to organic EL panel 10. Power is supplied from 14L1 and 14R1.

  According to the organic EL lighting device 103 in the present embodiment, when a driving voltage having a driving waveform as in each of the above-described embodiments is supplied to the organic EL panel 10, the luminance distribution has an anode connection in the light emitting surface 18. The portion 12L side is brighter and the anode connecting portion 12R side in the light emitting surface 18 is darker. At the time of lighting, it is possible to exhibit an effect that the anode connection portion 12R side becomes brighter and slower than the anode connection portion 12L. When the light is extinguished, it is possible to produce an effect that the anode connection portion 12R side becomes darker faster than the anode connection portion 12L.

[Embodiment 6]
Referring to FIG. 32, organic EL lighting apparatus 104 in the present embodiment includes organic EL panel 10A and organic EL panel 10B. The organic EL panel 10A and the organic EL panel 10B have the same shape and are arranged adjacent to each other.

  In the organic EL panel 10A, the power feeding unit 12L1 of the anode 12 and the drive circuit 20 are connected to each other, and power is fed from the power feeding units 12L1, 14L1, and 14R1 to the organic EL panel 10A. In the organic EL panel 10B, the power supply unit 12R1 of the anode 12 and the drive circuit 20 are connected to each other, and power is supplied to the organic EL panel 10B from the power supply units 12R1, 14L1, and 14R1.

  According to the organic EL lighting device 104 in the present embodiment, when a driving voltage having a driving waveform as in each of the above-described embodiments is supplied to the organic EL panels 10A and 10B, the luminance distribution of the organic EL panel 10A is as follows. Regarding the light emitting surface 18, the anode connecting portion 12L side becomes brighter and the anode connecting portion 12R side becomes darker. With respect to the light emitting surface 18 of the organic EL panel 10B, the anode connecting portion 12L becomes darker and the anode connecting portion 12R becomes brighter.

  At the time of lighting, the central portion in the light emitting surface 18 as a whole of the organic EL panels 10A and 10B becomes brighter and slower than the peripheral portion in the light emitting surface 18 as a whole of the organic EL panels 10A and 10B. As a result, it is possible to produce a production effect that is lit. When the light is turned off, the central portion in the light emitting surface 18 as a whole of the organic EL panels 10A and 10B becomes darker faster than the peripheral edge portion in the light emitting surface 18 as a whole of the organic EL panels 10A and 10B. As a result, it is possible to produce a production effect that is turned off.

[Embodiment 7]
Referring to FIG. 33, organic EL lighting device 105 in the present embodiment includes organic EL panels 10A to 10C and drive circuits 20A and 20B. The organic EL panels 10A to 10C have the same shape and are disposed adjacent to each other.

  In the organic EL panel 10A, the power supply unit 12L1 of the anode 12 and the drive circuit 20B are connected to each other, and power is supplied to the organic EL panel 10A from the power supply units 12L1, 14L1, and 14R1. In the organic EL panel 10B, the power feeding units 12L1 and 12R1 of the anode 12 and the drive circuit 20A are connected to each other, and power is fed to the organic EL panel 10B from the power feeding units 12L1, 12R1, 14L1, and 14R1. In the organic EL panel 10C, the power supply unit 12R1 of the anode 12 and the drive circuit 20B are connected to each other, and power is supplied to the organic EL panel 10C from the power supply units 12R1, 14L1, and 14R1.

  According to the organic EL lighting device 105 in the present embodiment, when a driving voltage having a driving waveform as in each of the above-described embodiments is supplied to the organic EL panels 10A to 10C, the luminance distribution of the organic EL panel 10A is As for the light emitting surface 18, the anode connecting portion 12L side becomes bright and the anode connecting portion 12R side becomes dark. As for the light emitting surface 18 of the organic EL panel 10B, both the anode connecting portion 12L side and the anode connecting portion 12R side become bright. Regarding the light emitting surface 18 of the panel 10C, the anode connecting portion 12L side becomes dark and the anode connecting portion 12R side becomes bright.

  At the time of lighting, the central portion in the light emitting surface 18 becomes brighter and slower than the peripheral portion in the light emitting surface 18 by controlling the duty and voltage values of the organic EL panels 10A to 10C as a whole. It is possible to produce a production effect that is lit up. When the light is turned off, the organic EL panels 10 </ b> A to 10 </ b> C as a whole control the duty and voltage values so that the central portion in the light emitting surface 18 becomes darker faster than the peripheral portion in the light emitting surface 18. It is possible to produce a production effect that is turned off.

[Embodiment 8]
Referring to FIG. 34, in organic EL lighting device 106 in the present embodiment, power supply units 12L1, 12L2, and 12L3 are provided in anode connection unit 12L of anode 12. Similarly, power supply portions 12R1, 12R2, and 12R3 are provided in the anode connection portion 12R of the anode 12.

  The power feeding part 12L1 is located closer to the cathode connection part 14R in the anode connection part 12L than the power feeding part 12L2, and the power feeding part 12L3 is located closer to the cathode connection part 14L in the anode connection part 12L than the power feeding part 12L2. The power feeding part 12R1 is located closer to the cathode connection part 14R in the anode connection part 12R than the power feeding part 12R2, and the power feeding part 12R3 is located closer to the cathode connection part 14R in the anode connection part 12R than the power feeding part 12R2.

  The power supply from the drive circuit 20 to the organic EL panel 10 (anode connection part 12L) through the power supply parts 12L1 and 12L3 is switched between connection and non-connection by the operation of the transistor 28. Similarly, power supply from the drive circuit 20 to the organic EL panel 10 (anode connection part 12R) through the power supply parts 12R1 and 12R3 is switched between connection and non-connection by the operation of the transistor 28. The transistor 28 (switch means) is composed of, for example, a field effect transistor (FET).

  The transistor 28 is connected to the output port of the microcomputer in the drive circuit 20. The drive circuit 20 can control the transistor 28 in synchronization with the drive timing of the organic EL panel 10.

  As shown in FIGS. 35A and 35B, in the organic EL lighting device 106 of the present embodiment, the transistor 28 is OFF (not connected) when T1 ≦ time T <T1B in the transition state. ) State. In T1 ≦ time T <T1B in the transition state where the organic EL panel 10 transitions from the unlit state to the lit state, power is supplied to the organic EL panel 10 from the power feeding units 12L2, 12R2, 14L1, and 14R1.

  In T1B ≦ time T <T2 in the transition state in which the organic EL panel 10 transitions from the unlit state to the lit state, the transistor 28 is turned on (connected). In T1B ≦ time T <T2, the organic EL panel 10 is supplied with power from the power supply units 12L1, 12L2, 12L3, 12R1, 12R2, 12R3, 14L1, and 14R1.

  During the time when the driving frequency in the transition state is relatively high (T1 ≦ time T <T1B), the transistor 28 is connected to the driving circuit 20 and some of the power feeding units (power feeding units 12L1, 12L3, 12R1, 12R3) is cut off, the number of power supply units that supply the drive voltage from the drive circuit 20 to the organic EL panel 10 is reduced.

  During T1 ≦ time T <T1B, the amount of drive voltage supplied to the anode 12 is low, so that a large amount of luminance unevenness is formed in the light emitting surface 18. When a lighting effect is performed such that the central portion of the light emitting surface 18 becomes brighter and slower than the peripheral edge portion of the light emitting surface 18, a more prominent effect can be exhibited.

  At T1B ≦ time T, the transistor 28 is turned on (connected), so that the number of power supply units increases. The drive circuit 20 can emit light uniformly within the light emitting surface 18 of the organic EL panel 10.

  In the present embodiment, the description has been made based on the mode in which the organic EL panel 10 transitions from the unlit state to the lit state. However, the transistor 28 is also used when the organic EL panel 10 transitions from the lit state to the unlit state. An operation similar to the above may be performed.

  For example, when T4B ≦ time T <T5 shown in FIG. 25, the transistor 28 is turned off (not connected), so that the amount of drive voltage supplied to the anode 12 during T4B ≦ time T <T5. Therefore, a large amount of luminance unevenness is formed in the light emitting surface 18. When a lighting effect is performed such that the central portion in the light emitting surface 18 becomes darker faster than the peripheral portion in the light emitting surface 18, a more prominent effect can be exhibited.

(Modification)
In the above-described eighth embodiment, when the organic EL panel 10 transitions from the lit state to the unlit state, the transistor 28 is turned off (not connected) over substantially the first half of the transition state.

  Referring to FIGS. 36A and 36B, the transistor 28 may be in an OFF (non-connected) state throughout the transition state. Even with this configuration, when a lighting effect is performed such that the central portion in the light emitting surface 18 becomes brighter later than the peripheral portion in the light emitting surface 18, a more prominent effect can be exhibited. It becomes.

  The transistor 28 may perform the same operation as described above even when the organic EL panel 10 transitions from the lit state to the unlit state.

  For example, when T4 ≦ time T <T5 shown in FIG. 25, the transistor 28 is turned off (not connected), so that the amount of drive voltage supplied to the anode 12 during T4 ≦ time T <T5. Therefore, a large amount of luminance unevenness is formed in the light emitting surface 18. When a lighting effect is performed such that the central portion in the light emitting surface 18 becomes darker faster than the peripheral portion in the light emitting surface 18, a more prominent effect can be exhibited.

  As mentioned above, although each embodiment and each modification based on this invention were described, each embodiment and each modification disclosed this time are illustrations in all points, and are not restrictive. The technical scope of the present invention is defined by the terms of the claims, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  10, 10A, 10B, 10C Organic EL panel, 11 transparent substrate, 12 anode, 12L, 12R anode connection part, 12L1, 12L2, 12L3, 12R1, 12R2, 12R3, 14L1, 14R1 power feeding part, 13 organic layer, 14 cathode, 14L, 14R Cathode connection part, 15 insulation layer, 16 sealing layer, 18 light emitting surface, 20, 20A, 20B drive circuit, 21 microcomputer, 21A control part, 22 memory, 23, 25, 28 transistor, 24 constant voltage circuit, 24A voltage control unit, 30 power supply, 40 operation unit, 100, 101, 102, 103, 104, 105, 106 lighting device, F1, F1A, F1B, F1C first frequency, F2 second frequency, F3 third frequency, F4 , F4A, F4B, F4C 4th frequency, F6 6th frequency, F7A, F7B, F 7C 7th frequency, F8 8th frequency.

Claims (10)

A drive circuit that generates a drive waveform in a DC or pulse form and outputs a drive voltage according to the drive waveform;
An anode, a cathode, an organic layer provided between the anode and the cathode, a light emitting surface from which light generated in the organic layer is extracted , and a plurality of power supplies provided on a peripheral edge side of the light emitting surface An organic EL panel in which the driving voltage output from the driving circuit is supplied to the organic layer via the plurality of power feeding units , the anode, and the cathode ,
The resistance of the path from the power feeding portion to the organic layer through the portion corresponding to the central portion of the light emitting surface of the anode corresponds to the peripheral portion of the light emitting surface of the anode from the power feeding portion. Higher than the resistance of the path through the part to the organic layer,
The organic layer has a capacitor component,
When the drive circuit turns on the organic EL panel by supplying the drive voltage to the organic EL panel in a light-off state, the drive circuit receives an instruction signal for turning on the organic EL panel by the driving voltage having a first frequency is supplied for a predetermined time to the organic EL panel from slower toward the center side in the light-emitting surface in comparison with the peripheral portion of the light emitting surface Turn on the organic EL panel so that it is bright,
The driving circuit supplies the driving voltage having the first frequency to the organic EL panel for the predetermined time, and then applies the driving voltage having a second frequency lower than the first frequency to the organic EL panel. An organic EL lighting device that causes the organic EL panel to be in a uniform lighting state by being supplied to. During the predetermined time, the drive circuit changes the frequency value of the first frequency so as to gradually decrease.
The organic EL lighting device according to claim 1. The drive circuit includes a PWM control unit that controls the duty of the drive waveform,
During the predetermined time, the PWM control unit changes the duty of the drive waveform.
The organic EL lighting device according to claim 1 or 2. The drive circuit includes a voltage control unit that controls a voltage value of the drive voltage;
During the predetermined time, the voltage control unit changes the voltage value of the drive voltage.
The organic EL lighting device according to claim 1. Further comprising switch means arranged between the drive circuit and the plurality of power feeding units,
During the predetermined time, the switch means supplies the drive voltage to the organic EL panel by disconnecting an electrical connection between the drive circuit and a part of the plurality of the power supply units. Reducing the number of power feeding units,
The organic EL lighting device according to claim 1. A drive circuit that generates a drive waveform in a DC or pulse form and outputs a drive voltage according to the drive waveform;
An anode, a cathode, an organic layer provided between the anode and the cathode, a light emitting surface from which light generated in the organic layer is extracted , and a plurality of power supplies provided on a peripheral edge side of the light emitting surface An organic EL panel in which the driving voltage output from the driving circuit is supplied to the organic layer via the plurality of power feeding units , the anode, and the cathode ,
The resistance of the path from the power feeding portion to the organic layer through the portion corresponding to the central portion of the light emitting surface of the anode corresponds to the peripheral portion of the light emitting surface of the anode from the power feeding portion. Higher than the resistance of the path through the part to the organic layer,
The organic layer has a capacitor component,
The organic EL panel is in a uniform lighting state by being supplied with the driving voltage having a third frequency from the driving circuit,
When the organic EL panel is turned off by stopping the supply of the driving voltage to the organic EL panel in the uniform lighting state, the driving circuit is used to turn off the organic EL panel. By supplying the drive voltage having a fourth frequency higher than the third frequency to the organic EL panel for a predetermined time from the time when the instruction signal is received, compared with the peripheral side in the light emitting surface. turns off the organic EL panel as towards the central portion in the light emitting surface becomes dark quickly,
The drive circuit supplies the drive voltage having the fourth frequency to the organic EL panel for the predetermined time, and then stops supplying the drive voltage to the organic EL panel, whereby the organic EL panel is stopped. Turn off the panel,
Organic EL lighting device. During the predetermined time, the drive circuit changes the frequency value of the fourth frequency so as to gradually increase.
The organic EL lighting device according to claim 6. The drive circuit includes a PWM control unit that controls the duty of the drive waveform,
During the predetermined time, the PWM control unit changes the duty of the drive waveform.
The organic EL lighting device according to claim 6 or 7. The drive circuit includes a voltage control unit that controls a voltage value of the drive voltage;
During the predetermined time, the voltage control unit changes the voltage value of the drive voltage.
The organic EL lighting device according to claim 6. Further comprising switch means arranged between the drive circuit and the plurality of power feeding units,
During the predetermined time, the switch means supplies the drive voltage to the organic EL panel by disconnecting an electrical connection between the drive circuit and a part of the plurality of the power supply units. Reducing the number of power feeding units,
The organic EL lighting device according to claim 6.

Images