DE102014115981A1 - lighting device - Google Patents

Abstract

A lighting device comprises a light source, which in turn comprises a red light emitting element group, a green light emitting element group, a blue light emitting element group, a cyan light emitting element group and a yellow light emitting element group, and a lighting circuit having a control unit configured to selectively turn on the red, green, blue, cyan, and yellow light-emitting element groups. When either the cyan light emitting element group or the yellow light emitting element group is turned on, the controller turns off the other group.

Description

TECHNICAL AREA

The present invention relates to a lighting apparatus having a semiconductor light-emitting element such as a light-emitting diode (LED) as a light source.

STATE OF THE ART

Conventionally, a light source having LEDs of the three RGB primary colors has been developed. For example, Japanese Unexamined Patent Application Publication No. Hei. 2012-64888 and 2006-120860 a light emitting module with LED groups of RGB colors. Furthermore, various lighting devices are known, such as lighting for color rendering and ceiling lights, which are made using the light-emitting module as a light source. In the lighting device having LED groups of the three RGB primary colors in the light emitting module, light of various colors such as white, red, green, blue, yellow, aquamarine blue and purple can be synthesized by adjusting the amount of light of the LED group for each emission color.

Further, a light-emitting module having LEDs of other emission colors such as cyan and white is disclosed in addition to the LED groups of the three RGB primary colors. With such a light-emitting module, it is possible to expand the range of emission colors of light emitted from the light source and to increase the emission intensity for a particular color.

However, as described above, in the lighting device in which the light-emitting element groups of plural colors are arranged as the light source, a plurality of light-emitting elements are generally attached as the light source. Accordingly, the temperature tends to increase due to heat generated when the light source is turned on. Thus, it is a challenge to suppress this temperature increase.

BRIEF SUMMARY OF THE INVENTION

In view of the above, the present invention provides a lighting apparatus in which light emitting element groups of plural colors including the three RGB primary colors are arranged as a light source capable of expanding a range of emission colors and raising the temperature of the light source to suppress.

In accordance with an aspect of the present invention, there is provided a lighting apparatus having a light source comprising a red light emitting element group, a green light emitting element group, a blue light emitting element group, a cyan light emitting element group, and a yellow light emitting element group A lighting circuit is provided which includes a control unit configured to selectively turn on the red, green, blue, cyan and yellow light emitting element groups. When either the cyan light-emitting element group or the yellow light-emitting element group is turned on, the control unit turns off the other one. Further, the illumination device is configured to emit a color blend light by turning on at least two of the red, the green, the blue, the cyan, and the yellow light emitting element groups.

Here, "cyan" means aquamarine blue, which is almost blue-green. "Yellow" includes orange and amber in addition to yellow. The lighting device may be configured as follows.

Each of the red, the green, the blue, the cyan, and the yellow light emitting element groups may be configured by connecting a plurality of semiconductor light emitting elements of the same emission color. Preferably, the lighting circuit comprises power supply units for supplying the red light emitting element group, the green light emitting element group and the blue light emitting element group, a common power supply unit for supplying the yellow light emitting element group and the cyan light emitting element group, and a switch for switching a target is to be supplied with power from the common power supply unit between the cyan light-emitting element group and the yellow light-emitting element group. The switch can be controlled by the control unit.

The light source may further comprise a substrate on which the red, green, blue, cyan, and yellow light-emitting element groups are mounted, and the red, green, blue, cyan, and yellow light-emitting element groups may be so be arranged such that the light-emitting elements of the light-emitting element group having the lowest quantum efficiency among the red light-emitting element group, the green light-emitting element group and the blue light-emitting element group between the light-emitting elements of the yellow light-emitting Element group and the light-emitting elements of the cyan light-emitting element group are arranged.

Further, the light source may further comprise a substrate on which the red, green, blue, cyan, and yellow light-emitting element groups are mounted, and which may include red, green, blue, cyan, and yellow light-emitting element groups be arranged so that the light-emitting elements of the light-emitting element group having the highest luminous flux reduction rate among the red light-emitting element group, the green light-emitting element group and the blue light-emitting element group between the light-emitting elements of the yellow light-emitting element group and the light-emitting elements the cyan light emitting element group are arranged.

According to the above configuration, since the cyan and yellow light emitting element groups are provided as the light source in addition to the light emitting element groups of the three RGB primary colors, it is possible to use cyan or yellow light, both of which are not limited only by a combination of light three RGB primary colors can be synthesized to emit. Therefore, it is possible to expand the range of emission colors of the lighting device. Also, since the control unit turns on either the yellow light-emitting element group or the cyan light-emitting element group and turns off the other one, even when the lighting device is operated, the light-emitting element group that is turned off generates no heat. Thus, during the operation of the lighting device, an area that does not generate heat is formed in the light source and the temperature rise of the light source is suppressed.

In general, a plurality of the emission colors are synthesized by turning on the light emitting element groups of the emission colors, such as the three primary colors R, G and B at the same time, whereas the yellow light emitting element group and the cyan light emitting element group are not turned on at the same time mainly used to emit cyan or yellow light as described above. Therefore, even if either the cyan or the yellow light-emitting element group is turned on and the other is turned off, a function of emitting desired light from the lighting device is not affected.

BRIEF DESCRIPTION OF THE DRAWINGS

The figures show one or more embodiments according to the present teachings, but only by way of example, not limitation. In the figures, like reference numerals designate the same or similar elements.

1 FIG. 10 is a block diagram showing the entire configuration of a lighting apparatus according to a first embodiment. FIG.

2 Fig. 10 is a diagram showing an example of a correspondence table stored in a memory of a control circuit unit 27 is stored.

3 Fig. 10 is a flowchart for explaining a control operation of the control circuit unit 27 ,

4 is a diagram showing a specific example of the lighting device 1 shows.

5A FIG. 15 is an exploded perspective view of a device main body. FIG 50 , and 5B is an exploded perspective view of a modular unit 51 ,

6 is a plan view of a light emitting module 10 ,

7A shows the arrangement of light-emitting element fields in the light-emitting module 10 and 7B Fig. 10 shows the shape of a wiring portion of each emission color in the light-emitting module 10 ,

8th is a color chart according to the International Commission on Illumination CIE for explaining the effect of the lighting device 1 ,

9 is a plan view of a light emitting module 110 according to a second embodiment.

DETAILED DESCRIPTION

[History of the Invention]

The present inventors have paid attention to the fact that in light emitting elements of the three RGB primary colors, the cyan spectrum and the yellow spectrum are insufficient, and it is difficult to obtain cyan or yellow light only by the combination of light of the three Primary colors RGB to synthesize. Through increased effort, the inventors of the present invention have a lighting device in which cyan and yellow light emitting element groups are additionally provided to light emitting element groups of the three RGB primary colors which is capable of emitting cyan or yellow light which can not be synthesized by a mere combination of light of the three primary colors RGB, whereby a color range of the emitted light is increased.

Further, the present inventors have found that the frequency of simultaneously switching on light emitting elements of the three RGB primary colors is higher than those of the cyan and yellow light emitting element groups, whereas the range of colors of emitted light without simultaneously switching on the cyan light emitting element group and the yellow light-emitting element group can be extended. Thus, the inventors of the present invention invented the lighting apparatus in which the cyan light emitting element group and the yellow light emitting element group can not be turned on at the same time.

Hereinafter, a lighting apparatus and a light emitting module according to an embodiment of the present invention will be described with reference to the accompanying drawings.

<First Embodiment>

(Whole configuration of the lighting device)

1 is a block diagram illustrating the entire configuration of a lighting device 1 and also a connection state of a light-emitting module 10 and a circuit unit 20 shows.

The lighting device 1 includes the light emitting module 10 which serves as a light source in which a plurality of light-emitting element groups 120R . 120G . 120B . 120W . 120C and 120Y which are different in emission color from each other, and the circuit unit 20 for selectively driving the light-emitting element groups 120 ,

The red light-emitting element group 120R includes a plurality of red LEDs connected in series. The green light emitting element group 120G includes a plurality of green LEDs connected in series. Also the blue light emitting element group 120B , the white light-emitting element group 120W , the cyan light-emitting element group 120C and the yellow light-emitting element group 120Y include a plurality of blue LEDs, a plurality of white LEDs, a plurality of cyan LEDs, and a plurality of yellow LEDs connected in series, respectively.

Further, a plurality of LEDs are included in each of the light-emitting element groups 120R . 120G . 120B . 120W . 120C and 120Y in 1 are connected in series, however, a parallel connection or a series-parallel connection can be used without being limited to series connection. The lighting device 1 emits a mixture of light having a desired mixed color and amount of light by changing a combination of amounts of light output from the light-emitting elements of the respective emission colors, based on a user's instruction.

(Circuit unit 20 )

The circuit unit 20 is electrically connected to an external commercial AC power source (not shown) and converts energy input from the external commercial AC power source and provides the converted power to the light emitting module 10 , Also, the circuit unit performs 20 a light control of the light-emitting element groups 120R . 120G . 120B . 120W . 120C and 120Y by.

The circuit unit 20 includes an AC-DC converter (not shown), constant current circuits 21 to 25 , a switch 26 and a control circuit unit 27 , As an AC-DC converter, for example, a diode bridge is used. The AC-to-DC converter converts the AC power coming from the commercial AC power source into DC power and supplies the DC power to each of the constant current circuits 21 and 25 , Each of the constant current circuits 21 to 25 For example, a down-chopper circuit or step-up / down circuit, which is well-known, includes direct current for each of the light-emitting element groups 120R . 120G . 120B . 120W . 120C and 120Y While it regulates the current, it supplies a current value supplied by the control circuit unit 27 instructed to exhibit.

The constant current circuits 21 to 24 are in one-to-one correspondence to the anode sides of the light-emitting element groups 120R . 120G . 120B and 120W via power lines 33R . 33G . 33B and 33W connected. Meanwhile, the constant current circuit 25 with the anode sides of the light-emitting element group 120C and the light-emitting element group 120Y through a common power supply line 31 , the switch 26 and the branch lines 32C and 32Y connected.

Each cathode side of the light-emitting element groups 120R . 120G . 120B . 120W . 120C and 120Y is with a common power line 34 connected. The desk 26 performs the process of switching between a connection state C and connection state V based on the instructions from the control circuit unit 27 , out. In this case, the C-connection state is a state in which the common power line 31 not with the branch line 32Y but with the branch line 32C is connected, and the V-connection state is a state in which the common power line 31 not with the branch line 32C but with the branch line 32Y connected is.

The control circuit unit 27 includes a microprocessor and a memory. The memory stores a correspondence table in which a plurality of color numbers having output values Ur, Ug, Ub, Uw, Uc and Uy of the light-emitting element groups 120R . 120G . 120B . 120W . 120C and 120Y associated with it. 2 Fig. 10 is a diagram showing an example of the correspondence table.

The initial values Ur, Ug, Ub, Uw, Uc and Uy of the light-emitting element groups 120R . 120G . 120B . 120W . 120C and 120Y range from 0 to 100. However, at least either the output value Uc of cyan or the output value Uy of yellow is 0. An input unit 27a is a device to allow the user to adjust the color of the light emitted by the lighting device 1 to be broadcast. Specifically, the user specifies the color to be emitted by inputting one of the color numbers listed in the table, and the designated color number is sent to the control circuit unit 27 Posted.

3 FIG. 10 is a flowchart illustrating an operation in which the control circuit unit. FIG 27 the constant current circuits 21 to 25 and the switch 26 controls. The operation of the circuit unit 20 is described based on the drawing. The control circuit unit 27 Waiting for the color number from the input unit 27a is entered. If the color number is input (Yes in step S1), the control circuit unit reads 27 the output values Ur, Ug, Ub, Uw, Uc and Uy of the respective colors corresponding to the color number by referring to the table (step S2).

The control circuit unit 27 put the switch 26 on the C connection, if Uy is zero (Uy = 0), and sets the switch 26 to the V-connection if Uy is not zero (steps S3 to S5). Further, the control circuit unit controls 27 the constant current circuits 21 to 24 to obtain powers corresponding to the output values Ur, Ug, Ub and Uw of the light-emitting element groups 120R . 120G . 120B and 120W issue. Further, the control circuit unit controls 27 the constant current circuit 25 to power corresponding to the sum Uc + Uy of the output value Uc of the light-emitting element group 120C and the output value Uy of the light-emitting element group 120Y (Step S6).

Then the control circuit unit waits 27 to the next color number, which from the input unit 27a (Step S1) is input. In the meantime, enter the constant current circuits 21 to 25 continuously evaluates the services, which are based on the instructions from the control circuit unit 27 result. In particular, each of the constant current circuits 21 to 25 is driven by a PWM method and outputs the power with an ON duty ratio (ratio of the ON time duration in one cycle) corresponding to an output value output from the control circuit unit 27 is sent.

By the above-described operation of the circuit unit 20 become the benefits of the constant current circuits 21 to 24 to the light-emitting element groups 120R . 120G . 120B and 120W with the ON-duty ratios, which correspond to the output values Ur, Ug, Ub and Uw supplied. Further, the current from the constant current circuit 25 to the light-emitting element group 120C or the light-emitting element group 120Y supplied with the ON duty corresponding to the sum of the output values Uc and Uy.

By the control process of the circuit unit 20 For example, the amount of current corresponding to the color specified by the user is given to each of the light-emitting element groups 120R . 120G . 120B . 120W . 120C and 120Y fed. Thus, the light intensity for each color corresponds to that of the light emitting module 10 is emitted, the initial value of each color by the user in the table of 2 specified color number. Further, even if any color number is given in the table, at least one of the light-emitting element group becomes 120C and the light-emitting element group 120Y set to a non-luminous state (off state).

(Specific example of the lighting device)

4 is a diagram showing a specific example of the lighting device 1 shows. For example, the lighting device 1 used as a light for an indoor stage production or as a light for an outdoor stage production to illuminate a floor or a wall. As in 4 shown includes the lighting device 1 a device main body 50 for receiving the light-emitting module 10 and the circuit unit 20 for supplying power to the device main body 50 , The light emitting module 10 and the circuit unit 20 are with each other via a wire group 30 connected.

The wire group 30 corresponds to the power lines 33R . 33G . 338 . 33W . 32C and 32Y and the power line 34 , shown in 1 , 5A FIG. 15 is an exploded perspective view of the device main body. FIG 50 , In the device main body 50 is a module unit 51 on a heat sink 52 attached and a mounting metal part 54 is on an upper surface and two opposite side surfaces of the assembled module unit 51 appropriate. The two side surfaces of the module unit 51 are with the mounting metal element 54 through the metal elements 53 , which are attached to the side, fixed.

The side plates 55 are at both ends of the mounting metal part 54 attached and the heat sink 52 is between the side plates 55 interposed. 5B is a perspective, exploded view of the module unit 51 , In the module unit 51 is the light emitting module 10 on a module basis 511 attached, which on a module housing 512 is attached.

The module housing 512 has an opening 512a on to with a mounting surface 101 of the light emitting module 10 in which the elements are mounted to correspond. A translucent front panel 513 is at the opening 512a appropriate. Also is an opening 54a in the fastening metal part 54 intended. In the device main body 50 gets the light from the mounting surface 101 of the light emitting module 10 from the device main body 50 after passing through the opening 512a and the front panel 513 and the opening 54a issued in this order.

(Light emitting module 10 )

6 is a plan view of the light-emitting module 10 ,

The light emitting module 10 includes a module substrate 11 and light-emitting elements 12R . 12G . 12B . 12W . 12C and 12Y from a variety of colors, on the module substrate 11 are attached. The module substrate 11 has a polygonal shape in plan view and a two-layer structure including an insulating layer formed of a thermally conductive resin or a ceramic substrate and a wiring pattern layer formed on the upper surface side thereof. Furthermore, a connection section 14 and a wiring section 15 on an upper surface 11a of the module substrate 11 formed and the light-emitting elements 12R . 12G . 12B . 12W . 12C and 12Y are in the wiring part 15 appropriate.

The wiring section 15 has wiring patterns for the respective emission colors and is on the upper surface 11a educated. Accordingly, the with the connection section 14 supplied power to each of the light-emitting elements 12 delivered. The light-emitting elements 12R . 12G . 12B . 12W . 12C and 12Y are on the upper surface 11a of the module substrate 11 appropriate to spread two-dimensionally. As in 7A shown has the mounting surface 101 on which the light-emitting elements 12 are attached, a circular shape.

The arrangement of the light-emitting elements 12R . 12G . 12B . 12W . 12C and 12Y the respective colors on the upper surface 11a of the module substrate 11 As will be described later, it is achieved that light emitted from the emitting elements of different emission colors is uniformly mixed to form a color mixing light. In addition, the white light emitting element can 12W emit white light by turning it on by itself.

However, as in the color number 101 . 102 or the like of 2 , this can be the white light emitting element 12W be switched on in combination with light-emitting elements of the other emission colors, which allows the amount of light emitted by the lighting device 1 is emitted, increase.

Each of the light-emitting elements 12R . 12G . 12B . 12W . 12C and 12Y is a surface mount device (SMD) type LED. The red light emitting element 12R , the green light emitting element 12G , the blue light emitting element 12B and the cyan light emitting element 12C emit red, green, blue and cyan light from their respective light-emitting layers. The white light emitting element 12W and the yellow light-emitting element 12Y are configured to emit white light and yellow light by using, for example, the blue light emitting element. Specifically, the light emitted from the blue light emitting element is converted to the white light or the yellow light via the wavelength conversion by a phosphor.

(Arrangement of the light-emitting elements of each emission color in the light-emitting module 10 )

In the light emitting module 10 , shown in 6 and 7A , are light-emitting element fields 121R . 121G . 121B . 121W . 121C and 121Y formed radially in such a manner that the light-emitting elements 12 arranged in each radial line having the same emission color. Furthermore, the light-emitting element fields 121R . 121G . 121B . 121W . 121C and 121Y arranged in a circumferential direction. Thus, the light-emitting element arrays become 121R . 121G . 121B . 121W . 121Y and 121C radially as a whole on the upper surface 11a of the module substrate 11 arranged.

In particular, on the upper surface 11a of the module substrate 11 four light-emitting element fields 121 for each emission color formed and twenty-four light-emitting element fields 121 in a total of six colors are arranged radially. Thus, for the red color, there are four light-emitting element arrays 121R arranged in a cross shape at intervals of 90 ° in the circumferential direction. Each of the light-emitting element fields 121R is provided so that a plurality of light-emitting elements 12R is arranged in the radial direction. Also for the green color are four light-emitting element fields 121G arranged in a cross shape at intervals of 90 ° in the circumferential direction. Each of the light-emitting element fields 121G is provided so that a plurality of light-emitting elements 12G is arranged in the radial direction. The same applies to the blue, the white, the cyane and the yellow color.

Further, a temperature sensor S is on the upper surface 11a attached to allow the temperature measurement, but the description thereof is omitted. As described above, in the light emitting module 10 by radially arranging the light-emitting element arrays 121R , ..., 121Y That is, the lights of the light-emitting elements having different emission colors are advantageously mixed, and the mixed color light is uniformly obtained.

That is, the light-emitting elements of each of the light-emitting element arrays 121 are arranged in the radial direction and the light-emitting element fields 121 are arranged to be adjacent to each other in the circumferential direction (in the direction of arrow C in FIG 7A ). Accordingly, the light-emitting element arrays 121 arranged with a plurality of emission colors annularly in the circumferential direction. Thus, the light emitting element field 121 each emission color between the light-emitting element fields 121 arranged by different colors adjacent to its two sides. For example, each of the four red light emitting element fields 121R between the yellow light emitting element field 121Y and the blue light emitting element field 121B arranged.

Thus, the light rays emitted by the light-emitting element arrays become 121 emitted from a variety of emission colors, advantageously mixed. Especially in the light emitting module 10 , as in 6 and 7A shown are the light-emitting element fields 121 of the respective colors repeatedly arranged in a certain color sequence in the circumferential direction. That is, the light-emitting element arrays 121 are repeated in the order red light emitting element field 121R , yellow light-emitting element field 121Y , green light emitting element field 121G , cyan light emitting element field 121C , white light-emitting element field 121W and blue light emitting element field 121B arranged in a counterclockwise direction (arrow C) extending direction. Accordingly, the color mixing light can be obtained more uniformly.

(Shape of the wiring section 15 in the light emitting module 10 )

The connection section 14 and the wiring section 15 are as conductor patterns on the insulating layer on the upper surface 11a of the module substrate 11 educated. For ease of explanation, as in 7A shown is in the upper surface 11a of the module substrate 11 an annular surface on which the light-emitting elements 12 are attached, as the attachment area 101 denotes the inside of the attachment area 101 is considered a central section 102 and the outside of the mounting surface 101 is considered an outdoor area 103 designated.

The connection section 14 is used as connections for external power supply 103 on the upper surface 11a , as in 6 shown, trained. The connection section 14 includes a pair of positive and negative terminals for each emission color. The connection section 14 is electric with the wire group 30 , shown in 2 , through a connector 19 connected. 7B shows patterns of the wiring section 15 for the respective emission colors in the light emitting module 10 , shown in 6 , In 7B For example, a direction of the current flowing through the wiring is indicated by an arrow. Also, for simplicity, there are only pictures for red, green, blue and cyan, and the illustration for yellow and white is omitted.

The connection of the light-emitting elements 12 through the wiring section 15 becomes now described. As shown below, the wiring portion becomes 15 on the upper surface 11a formed to the light-emitting elements 12 to switch in the same color in series connection or series-parallel connection. The red wiring section 15R is designed to have twenty four light emitting elements 12R the red light emitting element group 120R such that six sets of four light-emitting elements are connected in series, each set comprising four light-emitting elements 12R includes, each of which two light-emitting elements 12R connected in series, being parallel to the other two light emitting elements 12R , which are connected in series, are connected.

The green wiring section 15G is formed to ten light-emitting elements 12G the green light emitting element group 120G to connect in series. The blue wiring section 15B is also designed to be ten light-emitting elements 12B the blue light emitting element group 120B to connect in series. Although not shown, the white wiring section 15W also designed to be ten light-emitting elements 12W the white light-emitting element group 120W to connect in series. The cyan wiring section 15C is also designed to be ten light-emitting elements 12C the cyan light-emitting element group 120C to connect in series.

Although not shown, the yellow wiring section 15Y designed to be twenty light-emitting elements 12Y the yellow light-emitting element group 120Y in a way to connect that four sets of light-emitting elements 12Y are connected in series, each with two sets thereof, which six light-emitting elements 12Y comprising, wherein three light emitting elements 12J connected in series, in parallel with the other three light-emitting elements 12Y , which are connected in series, are connected, each of the other two sets, the four light-emitting elements 12Y include, of which two light emitting elements 12Y , which are connected in series, in parallel with the other two light-emitting elements 12Y , which are connected in series, are connected.

The wiring section 15 Each emission color includes perimeter sections 16 in which the flow in the circumferential direction in the outdoor area 103 flows, inward sections 17 , in which the current in the direction of the central portion 102 from the outside surface 103 flows forth, and outward sections 18 in which the flow towards the outer surface 103 from the central section 102 flows forth, with the outward-facing section 18 from the inward section 17 extends out.

The light-emitting elements 12 each emission color are on the inward facing section 17 or the outward-facing section 18 fixed by soldering or the like, whereby the light-emitting element fields 121 be formed. In the example of 6 to 7B has the wiring section 15 each emission color four pairs of the inward section 17 and the outward-facing section 18 and the light-emitting element array 121 each emission color is on the inward facing section 17 or the outward-facing section 18 each pair provided. Accordingly, as described above, four light-emitting element arrays 121 for each emission color formed and twenty-four light-emitting element fields 121 in six colors are arranged in total.

The wiring section 15 Each emission color forms a current path in which the current from the corresponding positive terminal back to the corresponding negative terminal through a plurality of light-emitting element fields 121 flows according to each emission color. For example, the red color wiring portion forms a current path in which the current from the positive terminal 14R + back to the negative connection 14R through a plurality of peripheral sections 16R and to several pairs of the inboard section 17R and the outward-facing section 18R flows. The green color wiring section forms a current path in which the current from the positive terminal 14G + back to the negative connection 14G- through a plurality of peripheral sections 16G and several pairs of the inward section 17G and outward-facing section 18G flows.

Further, in the light emitting module 10 In the present embodiment, the wiring portions 15 formed according to the respective emission colors in a wiring pattern in which the wiring portions 15 that have different emission colors, not mutually on the top surface 11a to cut. This will be described below. As in the 6 to 7B Shown is the wiring section 15 each emission color a current path, in which the current back to the negative electrode of the terminal section 14 flows in one direction (counterclockwise) around the central section 102 from the positive electrode of the terminal section 14 flowed. The current paths through the six wiring sections 15 are trained are designed to sequentially the central section 102 from the circumference of the central section 102 to surround radially outward. In other words, shows a structure in which a plurality of annular line sections 15 the central section 102 surrounded in turn in the form of an onion.

In particular, the green wiring section forms 15G a current path which is circulated on the innermost side, and the yellow wiring portion 15Y , the red wiring section 15R , the blue wiring section 15B , the white wiring section 15W and the cyan wiring section 15C form current paths, which are out in the order outward in a circle. Furthermore, the terminals of the respective colors are in the terminal section 14 arranged in this order. That is, the positive connection 14G + and the negative connection 14G- which with the green wiring section 15G are in the middle of the terminal section are connected, which comes to lie on the innermost side orbiting 14 arranged and the positive connection 14Y + and the negative connection 14Y- of the yellow wiring section are arranged on both sides thereof. The positive terminals and the negative terminals of the red, blue, white and cyan wiring portions are sequentially arranged on the outside thereof.

Thus, the wiring sections 15 for multiple colors set up the rungs sequentially around the central section 102 to put around, and the wiring sections 15 with different emission colors are arranged, not each other on the upper surface 11a to cut. In the wiring section 15 each emission color are the light-emitting elements 12 in one of a pair of the inboard section 17 and the outward-facing section 18 arranged to the light-emitting element field 121 to form, and the light-emitting elements 12 are not arranged in each other. This configuration is based on the fact that the light-emitting element fields 121 of six colors are arranged in the specific order in the circumferential direction as described above.

Especially in the red wiring section 15R is the light-emitting element field 121R so formed that the light-emitting elements 12R not in the inward section 17R but in the outward-facing section 18R are arranged. In the green wiring section 15G , in the blue wiring section 15B , in the white wiring section 15W and in the yellow wiring section 15Y are the same light emitting elements 12 only in the outward-facing section 18G , in the outward-facing section 18B , in the outward-facing section 18W and in the outward-facing section 18Y arranged to the light-emitting element fields 121 to build. On the other side are in the cyan wiring section 15C on the outermost side the light-emitting elements 12C not in the outward-facing section 18C arranged but in the inward section 17C to the light-emitting element field 121C to build.

(Effect of the shape of the wiring section 15 and the arrangement of the light-emitting elements 12 in the light emitting module 10 )

As described above, according to the lighting device 1 For example, since the light-emitting element arrays of the respective emission colors are arranged radially, a good color mixing light can be obtained by synthesizing the light of the respective emission colors. In particular, the light-emitting element fields 121 the respective colors are arranged in the determined color order in the circumferential direction, wherein the number of light-emitting element fields 121 four is, in the same way for each color of red, yellow, green, cyan, white and blue, and the light-emitting element fields 121 are arranged symmetrically at intervals of 90 °. Therefore, a uniformly mixed color light with less color deviation can be synthesized.

Further, the wiring sections 15 the respective emission colors are formed such that the wiring sections 15 in different emission colors are not mutually exclusive on the upper surface 11a to cut. Thus, since the wiring sections 15 the respective emission colors not on the back of the module substrate 11 but on the upper surface 11a of the module substrate 11 are provided, the insulating layer are exposed on the entire back. Therefore, the light emitting module 10 directly on the module base 511 be attached while a good insulation between them is achieved.

Further, since the light-emitting element array 121 each emission color either in the inboard section 17 or the outward-facing section 18 each wiring section 15 is formed, the wiring pattern is easy.

Further, in the light emitting module 10 , shown in 6 , the light-emitting element fields 121 of the respective emission colors repeats in the specific order in the circumferential direction in the wiring portions 15 arranged the respective emission colors and the light emitting elements 12 be either in the inward-facing section 17 or in the outward-facing section 18 attached.

However, the number of light emitting element fields 121 of each color, arrangement order, and the like, and if necessary, the light-emitting elements can be changed 12 both in the inward-facing section 17 as well as in the outward-facing section 18 to be assembled.

(Comparison of the light emitting module 10 with comparative examples)

Comparative Example 1

As Comparative Example 1, the light-emitting elements of the same color are arranged in the circumferential direction to form the light-emitting element array, and the light-emitting element arrays of a plurality of emission colors are arranged radially.

In this case, the wiring portion can be formed along the ring-shaped light-emitting element array, and a relatively simple wiring pattern can be achieved. However, since the light-emitting element arrays having different emission colors are arranged in the radial direction instead of the circumferential direction, there are no light-emitting element arrays on the inside of the light-emitting element field of the emission color disposed on the innermost side. Further, there are no light-emitting element arrays on the outside of the light-emitting element field of the emission color disposed on the outermost side.

Thus, in the case of Comparative Example 1, the light of the light-emitting elements of each emission color tends to deviate in the radial direction, and the light emissions of the respective emission colors are difficult to uniformly mix.

Comparative Example 2:

In Comparative Example 2, a plurality of light-emitting elements in the light-emitting element group for each emission color are scattered on each other on the module substrate and arranged so that the light-emitting elements in different emission colors are adjacent to each other.

In this case, the light of the light-emitting element groups of the respective emission colors can be uniformly mixed. However, in order to individually drive and control the light-emitting element groups of the respective emission colors, the wiring pattern on the module substrate tends to be complicated. Accordingly, it is necessary to construct a wiring structure such as a multilayer wiring structure. Thus, in the light emitting module of Comparative Example 2, it is difficult to form the wiring portions only on the upper surface of the module substrate and to achieve a simple wiring pattern.

(Effect obtained by providing the cyan light-emitting element group and the yellow light-emitting element group)

In the lighting device 1 are the cyan light emitting element group 120C and the yellow light-emitting element group 120Y in the light emitting module 10 in addition to the red light-emitting element group 120R , in addition to the green light emitting element group 120G and in addition to the blue light-emitting element group 1208 provided. The effect of this is made with reference to a color chart according to the International Commission on Illumination CIE 8th described.

Red, green and blue are three additive primary colors. Thus, all colors within a triangle C (hatched area in 8th ), whose vertices are red, green and blue in the color chart according to the International Commission on Illumination CIE 8th are synthesized by varying an emission ratio of the red, green and blue light-emitting element groups. However, since cyan and yellow are outside the triangle, they can not be synthesized by using only the light of the red, green and blue light-emitting element groups. In addition, the color within a triangle (arrow A) whose corners are green, blue and cyan, and the color in a triangle (arrow B) whose corners are green, red and yellow in 8th are not synthesized using only the red, green and blue light-emitting element groups.

As the lighting device 1 the cyan light emitting element group 120C and the yellow light-emitting element group 120Y it is by switching on the cyan light emitting element group 120C or the yellow light-emitting element group 120Y possible to emit yellow or cyan light. Further, by combining the light emissions of the green light emitting element group 120G , the blue light-emitting element group 120B and the cyan light-emitting element group 120C , all colors within the triangle (arrow A) whose corners are green, blue and cyan in 8th are, be synthesized. For example, the color No. 205 corresponds to 2 this case.

Further, by combining the light emissions from the green light emitting element group 120G , the red light-emitting element group 120R and the yellow light-emitting element group 120Y all colors within the triangle (arrow B) whose corners are green, red and yellow in 8th are to be synthesized. For example, the color No. 305 corresponds to 2 this case. In the lighting device 1 For example, by providing the cyan and yellow light emitting element groups, it is possible to emit cyan or yellow light which can not be obtained by using only the light emissions of the red, green and blue light emitting element groups. Since a range of color light that can be output is greatly expanded, it is possible to improve a stage effect using lighting.

(Effect of the lighting control method of the lighting device 1 )

In general, in the light-emitting module in which a large number of light-emitting elements are arranged on the substrate, when all the light-emitting elements are turned on at the same time, the substrate is liable to raise its temperature due to the accumulation of heat from each of the light-emitting elements Light emitting elements is generated increase. In the lighting device 1 is located even if any color number of 2 is selected, at least one of the light-emitting element group 120C and the light-emitting element group 120Y not in the light condition.

This configuration can achieve the following effect. Since the light-emitting elements generate no heat in the non-illuminated state, the light-emitting elements in the non-illuminated state, which are on the mounting surface 101 of the light emitting module 10 , which serves as a light source, are arranged to regions which do not generate heat. Thus, because areas that do not generate heat are formed to be on the mounting surface 101 of the light emitting module 10 to be scattered, the module substrate 11 prevented from high temperature during operation of the lighting device 1 to be raised.

Further, as described above, the red, green and blue light emitting element groups corresponding to the three primary colors RGB must be turned on at the same time most of the time to turn each color within the triangle C of FIG 8th to synthesize. On the contrary, the yellow light-emitting element group 120Y and the cyan light emitting element group 120C used to extend the color range by emitting light that can not be synthesized by using only red, green and blue light. Therefore, there is no problem even if the cyan light emitting element group 120C and the yellow light-emitting element group 120Y are not turned on at the same time.

For the above reason, by performing the control such that either the cyan light emitting element group 120C or the yellow light-emitting element group 120Y turned on and the other is turned off, as in the lighting device 1 , the effect of suppressing an increase in the temperature of the light source is achieved while emitting light in a wide range of colors. Furthermore, in the circuit unit 20 the power supply from the common constant current circuit 25 between the cyan light-emitting element group 120C and the yellow light-emitting element group 120Y through the switch 26 be switched. This makes it possible to configure the circuit unit 20 to simplify.

That is, since the cyan light-emitting element group 120C and the yellow light-emitting element group 120Y with power not from the individual constant current circuits, but from the common constant current circuit 25 is supplied, it is possible to control the number of constant circuits in the circuit unit 20 to reduce. By reducing the number of power supply circuits in this way, it is possible to change the configuration of the circuit unit 20 to simplify.

In the above description, the output of at least one of the cyan light-emitting element group becomes 120C or the yellow light-emitting element group 120Y set to zero. However, the output does not necessarily have to be zero, and the same effect can be obtained even by weak output power (for example, 10% or less of the maximum output power). Thus, when turning off at least one of the cyan light emitting element group 120C or the yellow light-emitting element group 120Y That is, the "OFF" means a case where the output is weak, and a case where the output is zero.

(Effect of the combination of the arrangement order of the light-emitting element arrays and the illumination method of the lighting device 1 )

In the arrangement according to 7A as described above are the red light-emitting element array 121R , the yellow light-emitting element field 121Y , the green light emitting element field 121G , the cyan light-emitting element field 121C , the white light-emitting element field 121W and the blue light emitting element field 121B repeatedly arranged counterclockwise. Therefore, the green light emitting element field 121G between the cyan light-emitting element field 121C and the yellow light-emitting element array 121Y arranged adjacent thereto. That is, the green light emitting elements 12G are between the cyan light emitting elements 12C and the yellow light emitting elements 12Y arranged adjacent thereto. By this arrangement of the light-emitting elements 12 The following effects can be obtained.

Generally, among the red light emitting elements 12R , the green light emitting elements 12G and the blue light emitting elements 12B the green light emitting elements 12G the lowest quantum efficiency. Since the quantum efficiency of the light-emitting elements is lower, the amount of heat generated becomes larger. Hence, the green light emitting elements come 12G easy on a high temperature. However, as described above, in the lighting device 1 even in the case of any color number at least either the cyan light-emitting element group 120C or the yellow light-emitting element group 120Y switched off.

Further, the green light emitting elements 12G which gives the lowest quantum efficiency among the light-emitting elements 12R . 12G and 12B of the three primary colors, between the cyan light emitting elements 12C and the yellow light emitting elements 12Y arranged. Accordingly, it is possible to cause excessive temperature rise of the green light-emitting elements 12G to suppress. In addition, it is because the heat generation of the red light emitting elements 12R and the blue light emitting elements 12B compared with the green light emitting elements 12G Small, even less likely, is an excessive temperature rise in the light-emitting elements 12R and 12B occurs.

In this way, it is by suppressing the temperature rise of the green light-emitting elements 12G , which have the lowest quantum efficiency, possible, the temperature of the parts that are likely to high temperature in the light-emitting module 10 have to decrease. Accordingly, a material having low heat resistance can be used as a material for each element in the lighting device 1 used, which leads to a reduction in the cost of the device.

Next, a description will be given of a modification example in which the positions of the red light emitting element array 121R and the green light emitting element array 121G to those from the arrangement, in 7A is shown are exchanged.

In this case, the red light emitting element field 121R between the cyan light-emitting element field 121C and the yellow light-emitting element array 121Y arranged adjacent thereto. That is, the red light emitting elements 12R are between the cyan light emitting elements 12C and the yellow light emitting elements 12Y arranged adjacent thereto. By this arrangement of the light-emitting elements 12 As described below, the effect of extending the life of the lighting device 1 achieved.

Generally, among the red light emitting elements 12R , the green light emitting elements 12G and the blue light emitting elements 12B the red light emitting elements 12R the highest luminous flux decline rate. The lifetime of the lighting device is essentially determined by the life of the light-emitting elements of the emission color having the highest luminous flux reduction rate. Thus, since the luminous flux reduction rate of the red light emitting elements 12R is high, the life of the lighting device 1 reduced.

As described above, in the lighting device 1 even if the light of any color number is selected, at least one of the cyan light emitting element group 120C or the yellow light-emitting element group 120Y switched off. Therefore, it is by arranging the red light-emitting elements 12R with the highest luminous flux decline rate among the light-emitting elements 12R . 12G and 12B the three primary colors between the cyan light emitting elements 12C and the yellow light emitting elements 12Y possible, the temperature of the red light emitting elements 12R to reduce. Further, because the luminous flux reduction rate of the red light emitting elements 12R decreases as the temperature of the red light emitting elements decreases 12R during operation is reduced extends the life of the lighting device.

<Second Embodiment>

9 is a plan view of a light emitting module 110 according to a second embodiment. As in 9 shown includes the light emitting module 110 a module substrate 111 with an elongated shape and the light-emitting elements 12 are in rows in the longitudinal direction of the module substrate 111 assembled.

Similar in the 1 shown lighting device 1 becomes the light emitting module 110 with the circuit unit 20 and is used as a light source of the lighting device. A lighting device comprising the light emitting module 110 can be used as a horizon light that illuminates a horizon curtain in the innermost portion of the stage. In the light emitting module 110 are the emission colors of the light-emitting elements which are on the module substrate 111 are arranged six colors, namely red, green, blue, white, cyan and yellow as in the first embodiment.

As for the arrangement of the light-emitting elements of each emission color, as in 9 5 rows are formed, each row comprising the light-emitting elements in the longitudinal direction of the module substrate 111 is arranged. To simplify the explanation, they are used as first to fifth row from top to bottom in 9 designated. Both the first row and the fifth row comprise ten yellow light-emitting elements 12Y ,

In the second line are eleven red light emitting elements 12R and ten green light emitting elements 12G alternately arranged and a red light emitting element 12R is additionally on the side of the connection section 14 arranged. In the third row are ten white light emitting elements 12W and nine cyan light emitting elements 12C arranged alternately. In the fourth line are eleven red light emitting elements 12R and ten blue light emitting elements 12B alternately arranged and a red light emitting element 12R is also on the to the connection section 14 arranged opposite side.

For each emission color, the light-emitting elements 12 in series with each other or in series-parallel connection through the wiring part 15 which is on the module substrate 111 is formed, connected to the light-emitting element group 120 to build. Because the light-emitting elements 12 of a plurality of emission colors (six colors) substantially uniform in the longitudinal direction of the module substrate 111 are distributed, is also the color mixing light, which of the light emitting module 110 is emitted, uniform in the longitudinal direction.

Hereinafter, a particular shape of the wiring portion will be described 15 in the light-emitting element group for each emission color.

Red light emitting element group 120R :

The red wiring section 15R forms a current path in which the current from the positive terminal 14R + back to the negative connection 14R by twenty-four red light emitting elements 12R flows.

Through the wiring section 15R becomes the red light-emitting element group 120R so designed to be twenty four light-emitting elements 12R including six groups of light-emitting elements 12R are connected in series, each set having four light-emitting elements 12R includes, of which two light-emitting elements 12R connected in series, in parallel with two light-emitting elements 12R connected in series.

Green light emitting element group 120G :

The green wiring section 15G forms a current path in which the current from the positive terminal 14G + back to the negative connection 14G- by ten green light emitting elements 12G flows.

Through the wiring section 15G becomes the green light-emitting element group 120G designed to be ten green light emitting elements 12G to be included in series.

Blue light emitting element group 120B :

The blue wiring section 15B forms a current path, in which the current from the positive pole 14B + back to the negative connection 14B- by ten blue light emitting elements 12B flows.

Through the wiring section 15B becomes the blue light-emitting element group 120B designed to be ten blue light emitting elements 12b to be included in series.

White light-emitting element group 120W :

The white wiring section 15W forms a current path in which the current from positive connection 14W + back to the negative connection 14W- by ten white light emitting elements 12W flows.

Through the wiring section 15W becomes the white light-emitting element group 120W designed to contain ten white light emitting elements 12W to be included in series.

Cyan's light-emitting element group 1200 :

The cyane wiring section 15C forms a current path in which the current from the positive terminal 14C + back to the negative connection 14C by nine cyan light emitting elements 12C flows.

Through the wiring section 15C becomes the cyan light emitting element group 120C designed to contain nine cyan light emitting elements 12C to be included in series.

Yellow light-emitting element group 120Y :

The yellow wiring section 15Y forms a current path in which the current from the positive terminal 14Y + back to the negative connection 14Y- by twenty yellow light-emitting elements 12Y flows.

Through the wiring section 15Y becomes the yellow light-emitting element group 120Y so designed to be twenty light-emitting elements 12Y to include five sets of light-emitting elements 12Y are connected in series, each set having four light-emitting elements 12Y includes, of which two light-emitting elements 12R connected in series, in parallel with two light-emitting elements 12R , which are connected in series, are connected.

The operation of the circuit unit 20 This lighting device is the same as that of the first embodiment.

Therefore, an effect achieved by providing the cyan light-emitting element group and the yellow light-emitting element group and an effect achieved by the lighting method of the lighting device can be achieved similarly to those of the first embodiment. Further, in the arrangement of the light-emitting elements of each emission color in the light-emitting module 110 , as in 9 shown the red light emitting elements 12R and the green light emitting elements 12G between the yellow light emitting elements 12Y and the cyan light emitting elements 12C arranged.

That is, the red light emitting elements 12R which are present in the second row except the red light emitting elements 12R which are arranged at both ends of the row, are arranged so as to be between the yellow light-emitting elements 12Y which are present in the first row and the cyan light emitting elements 12C which are present in the third row to be inserted. Likewise, the red light emitting elements 12R that are in the fourth row, except those disposed at both ends thereof, arranged to be between the yellow light-emitting elements 12Y which are present in the fifth row and the cyan light emitting elements 12C which are present in the third row. to be arranged. The green light emitting elements 12G which are present in the second row are also arranged to be between the yellow light-emitting elements 12Y which are present in the first row and the cyan light emitting elements 12C located in the third row are arranged.

Therefore, an effect achieved by combining the arrangement order of the light-emitting element arrays and the lighting method of the lighting device can also be obtained similarly to the first embodiment.

<Modifications>

In the above embodiments, the light-emitting module includes light emitting elements of the six colors (red, green, blue, white, cyan, and yellow). However, lemon yellow, orange or amber light emitting elements may be used instead of the yellow light emitting elements. Also in this case, an embodiment can be similarly implemented and the same effect can be obtained.

In the above embodiments, the light-emitting elements of six colors are mounted on the light-emitting module. However, the white light emitting elements may be omitted, and the light emitting elements of the five colors (red, green, blue, cyan and yellow) may be provided. Also in this case, an embodiment can be similarly implemented and the same effect can be obtained. In the above embodiments, LEDs are used as the light-emitting elements which are mounted on the light-emitting module. However, as light emitting elements of any color, for example Laser diodes (LDs) or electroluminescent elements (EL elements), without being limited to the LEDs, find use.

The light-emitting module and the lighting device described in the above can be applied to headlights, downlights and the like.

While the foregoing has been described in terms of what may be considered to be the best mode and / or other examples, it will be understood that various modifications may be made and that the subject matter disclosed herein may be implemented in various forms and examples, and that these can also be used in numerous applications, only a few of which have been described here. It is intended by the following claims to claim any and all modifications and variations that fall within the true scope of the present teachings.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 2012-64888 [0002]
• JP 2006-120860 [0002]

Claims (6)

Lighting device comprising: a light source including a red light emitting element group, a green light emitting element group, a blue light emitting element group, a cyan light emitting element group, and a yellow light emitting element group; and a lighting circuit including a control unit configured to selectively turn on the red light emitting element group, the green light emitting element group, the blue light emitting element group, the cyan light emitting element group, and the yellow light emitting element group; wherein, when either the cyan light-emitting element group or the yellow light-emitting element group is turned on, the control unit turns off the other one. The lighting device according to claim 1, wherein each of the red, green, blue, cyan, and yellow light-emitting element groups is configured by connecting a plurality of semiconductor light-emitting elements of the same emission color. A lighting device according to claim 1 or 2, wherein the lighting circuit comprises: Power supply units for the power supply of the red light-emitting element group, the green light-emitting element group or the blue light-emitting element group; a common power supply unit for supplying power to the yellow light-emitting element group and the cyan light-emitting element group; and a switch for switching a target to be supplied with power from the common power supply unit between the cyan light emitting element group and the yellow light emitting element group, and wherein the switch is controlled by the control unit. The lighting device according to any one of claims 1 to 3, wherein the light source further comprises a substrate on which the red, green, blue, cyan, and yellow light-emitting element groups are mounted, and wherein the red, green, blue, cyan, and yellow light-emitting element groups are arranged so that the light-emitting elements of the lowest-quantum-efficiency light-emitting element group among the red light-emitting element group, the green light-emitting element group, and the blue light-emitting element group between Inserted light emitting elements of the yellow light emitting element group and light emitting elements of the cyan light emitting element group. The lighting device according to any one of claims 1 to 3, wherein the light source further comprises a substrate on which the red, green, blue, cyan, and yellow light-emitting element groups are mounted, and wherein the red, green, blue, cyan and yellow light emitting element groups are arranged so that the light emitting elements of the light emitting element group having the highest luminous flux decrease rate among the red light emitting element group, the green light emitting element group and the blue light emitting element group between Inserted light emitting elements of the yellow light emitting element group and light emitting elements of the cyan light emitting element group. A lighting device according to any one of claims 1 to 5, wherein the lighting device is configured to emit a color mixing light by turning on at least two of the red, green, blue, cyan, and yellow light emitting element groups.

Images