JP5002408B2 - Lighting device - Google Patents

Description

  The present invention relates to a lighting device using a light-emitting diode lamp, particularly a white light-emitting diode lamp, and more particularly, to improve the luminous efficiency of general indoor lighting by utilizing heat generated in the lamp for light emission using a thermoelectric conversion element. It is an improvement. In the present invention, loss energy that has been discarded as heat in a lighting fixture using a white light-emitting diode lamp is extracted as electric power using a thermoelectric conversion element, and converted into light to increase the amount of light emission. At this time, a conventionally known technique requires a complicated power supply circuit such as using a battery, but in the present invention, the circuit is simplified by separately preparing an additional light emitting diode element for connection to the thermoelectric conversion element. I was able to.

  In recent years, solid-state lighting has been in the limelight. Among them, lighting fixtures using white light-emitting diode lamps have rapidly improved their luminous efficiency, and are expected to be the favorite of energy-saving lighting fixtures. Currently, a research level of 150 lm / W is also announced. However, many products still remain at several tens of lm / W at the mass production level, and further improvement in luminous efficiency is demanded.

  The mainstream of white light-emitting diode lamps for illumination currently uses blue semiconductor light-emitting diode elements and blue-light-excited visible-light-emitting phosphor powder, but the main causes are scattering caused by the phosphor powder, resulting in white light emission. The light extraction efficiency from the diode lamp package is low, and in many products, it is only about a few percent to a dozen percent. Incandescent bulbs and fluorescent lamps that are the mainstream of conventional lighting fixtures, most of the energy that is not converted to visible light is radiated as infrared rays or ultraviolet rays. In the case of white light-emitting diode lamps, most of the loss is converted to heat. When the semiconductor light emitting diode element is heated to a high temperature, the life is shortened and the reliability is lowered. Therefore, it is preferable to use a heat transfer substrate with high heat dissipation as a member on which the semiconductor light emitting diode element is mounted.

Up to now, there has been an idea to generate heat from a light-emitting diode element by a thermoelectric conversion element, extract it as electric power, and use it effectively, for example, disclosed in Patent Document 1 and Patent Document 2. A thermoelectric conversion module using a thermoelectric conversion element is usually a module in which an n-type semiconductor block and a p-type semiconductor block are alternately connected in series and configured in a flat plate shape. Power is generated by the temperature difference. In using this thermoelectric conversion module, when the heat source is a conductive material on the surface in contact with the heat source, a plurality of electrodes connecting the n-type semiconductor block and the p-type semiconductor block at their respective parts. In order to prevent a short circuit from occurring, it is common to connect the surface of the thermoelectric conversion module and a heat source via an insulating plate. On the other hand, in order to increase the thermoelectric conversion efficiency, it is preferable that the thermal resistance between the heat source and the thermoelectric conversion element is low and the heat transfer characteristics are excellent.
JP 2004-193031 A JP 2004-296989 A JP 2006-147865 A

In Patent Document 1, the paragraph number 0040 only includes “a portion where heat generated in the LED light emitting unit 3 is transferred, for example, thermally coupled to the substrate 7, the reflection member 11, and the heat transfer member 20”. No mention is made of the insulating structure, and there is no description of the specific mode of thermal coupling.
In Patent Document 2, regarding thermal connection, paragraph No. 0015 states that “the joining between the thermoelectric module and the substrate is preferably soldering or silver paste.” There is no mention, and it is presumed that the heat absorbing plate of FIG. 1 is made of an insulating material. A method of using the power generated by the thermoelectric change element, that is, a supply circuit of the generated power to the light emitting element is also a problem.
Further, in Patent Document 1, paragraph number 0040 states that “the power generated by the thermoelectric conversion element 26 is input to the control unit 8 of the LED light emitting unit 3”, and that the control unit 8 is necessary. In this case, of course, the cost is high.
In Patent Document 2, no technical disclosure is made regarding electrical connection for extracting electric power from the thermoelectric conversion element, and it is unclear. In the A-A ′ cross-sectional view of FIG. 2, it is as if the lead wires referred to in paragraph number 0013 and FIG. 1 are connected to the wiring pattern. In that case, it is clear and problematic that the thermoelectric conversion element will function as a Peltier cooling element, not as a power generation element. Accordingly, there has been a demand for a supply circuit that uses the power generated by the thermoelectric conversion element at low cost.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an illuminating device that can improve luminous efficiency by using heat generated in a light-emitting diode lamp for light emission by a simple circuit configuration using a thermoelectric conversion element. .

In order to achieve the above object, the present invention provides a semiconductor light emitting diode element electrically connected to a power source, a heat transfer board on which the semiconductor light emitting diode element is mounted, a heat transfer board electrically connected to the heat transfer board and a thermoelectric conversion element that is insulated manner, saw including a semiconductor light emitting diode element connected to the thermoelectric conversion element, electrically connected to the relay to the power supply is connected to the thermoelectric conversion element and the thermoelectric conversion element Illumination characterized in that the thermoelectric conversion element and the semiconductor light-emitting diode element are electrically connected only when power is supplied from a power source, disposed in the middle of the semiconductor light-emitting diode. Providing equipment.

  In the illuminating device of the present invention, the heat transfer substrate is preferably a hollow substrate.

  In the illuminating device of the present invention, the electrode connecting the p-type semiconductor and the n-type semiconductor exposed on one surface of the thermoelectric conversion element is in close contact with the enamel layer of the enamel substrate, either directly or through only thermal conductive grease. It is preferable.

  In the lighting device of the present invention, the heat transfer substrate is preferably an insulating material.

  In the lighting device of the present invention, it is preferable that the semiconductor light emitting diode element is disposed at a position corresponding to the thermoelectric conversion element.

  In the lighting device of the present invention, the semiconductor light emitting diode element is mounted on the bottom surface of the recess formed in the heat transfer substrate, and the thickness of the substrate on the bottom surface of the recess is less than half the thickness of other portions of the substrate. It is preferable.

The lighting device of the present invention includes a semiconductor light-emitting diode element electrically connected to a power source, a heat transfer board on which the semiconductor light-emitting diode element is mounted, and is thermally connected to and electrically insulated from the heat transfer board. The thermoelectric conversion element and the semiconductor light-emitting diode element connected to the thermoelectric conversion element are used to generate electric power using energy that has been discarded as waste heat, and use the electric power to generate the illumination device. Therefore, the light emission efficiency can be improved by using heat generated in the light emitting diode lamp for light emission with a simple circuit configuration using a thermoelectric conversion element.
In addition, by using a hollow substrate having excellent heat dissipation, the heat dissipation of the lighting device can be improved, and the lifetime of the element can be extended.
In addition, by using the enamel layer of the enamel substrate as the insulating material, the heat transfer characteristics can be improved and the cost can be reduced because the insulating plate can be omitted when ensuring insulation.
In addition, the enamel layer of the enamel substrate is used as the insulating material, the arrangement of the thermoelectric conversion element and the arrangement of the semiconductor light emitting diode element are made to correspond to each other, and the thickness of the recess of the enamel substrate is reduced. The heat transfer characteristics to the conversion module can be improved.
Further, by additionally preparing a semiconductor light emitting diode element that is directly connected to the thermoelectric conversion element, it is possible to realize an illumination device that uses the thermoelectric conversion element without using equipment such as a control unit and a battery.
Further, since the insulating plate can be omitted and the control unit, the battery, and the like can be omitted, the cost can be reduced by reducing the number of equipment used.
In addition, by providing the light emitting element connected to the thermoelectric conversion element independently of the light emitting element connected to the power source, the light emitting element connected to the thermoelectric conversion element remains for a while after the power switch is turned off. It is possible to obtain an afterglow effect that light emission is continued for a period of time.
When this afterglow effect is unnecessary, a relay for turning on / off the circuit between the thermoelectric conversion element and the semiconductor light emitting diode element connected to the thermoelectric conversion element is inserted in conjunction with the supply of power. Thus, the afterglow effect can be prevented.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[First Embodiment]
FIG. 1 is a cross-sectional view showing a first embodiment of a lighting device according to the present invention. In FIG. 1, reference numeral 1 denotes a lighting device, 2 denotes an n-type semiconductor of a thermoelectric conversion element, 3 denotes a p-type semiconductor of a thermoelectric conversion element, 4 denotes a heat insulating layer, 5 denotes an electrode, 6 denotes a hollow layer of a hollow substrate, and 7 denotes a hollow A steel plate of the substrate, 8 is a semiconductor blue light emitting diode element, 9 is a phosphor powder, 10 is a transparent sealing resin, 11 is an insulating plate, and 12 is a heat sink.

The illuminating device 1 of this embodiment consists of a white light emitting diode illumination module, a thermoelectric conversion module, and a heat sink.
In the thermoelectric conversion module, a plurality of thermoelectric conversion elements in which an n-type semiconductor 2 and a p-type semiconductor 3 are connected by an electrode 5 are arranged in series or in parallel, one surface being a heat source side and the other surface being a cooling side. Thus, the module generates power using an electromotive force due to the Seebeck effect based on the temperature difference. Various materials are known as the n-type semiconductor 2 and the p-type semiconductor 3, but here, a bismuth-tellurium-based material having a high conversion efficiency even in a relatively low temperature range is preferable.

  The heat insulating layer 4 is an air layer, or is preferably filled with an inert gas such as nitrogen or sealed in a vacuum because of high heat insulating properties, but may have a structure filled with a heat insulating material with an emphasis on mechanical strength. .

  The power generation amount of the thermoelectric conversion module is a value obtained by multiplying the heat flux from the heat source side surface to the cooling side surface by the conversion efficiency. It is possible to set appropriately by taking into consideration the dimensions of the element and the number of series / parallel connections. The surface on the heat source side of the thermoelectric conversion module is in close contact with the back surface of the enamel substrate, which is the heat transfer substrate of the white light emitting diode illumination module, with the electrode 5 exposed through thermally conductive silicone grease (not shown).

  The enamel substrate is composed of a steel plate 7 and an enamel layer 6. In this embodiment, the thermoelectric conversion module should be connected to a heat source via an insulating plate in order to prevent a short circuit of the electrodes. Since the enamel layer 6 of the enamel substrate serves as an insulation, the insulating plate can be omitted, thereby reducing the cost and increasing the heat transfer efficiency from the enamel substrate of the heat source to the thermoelectric conversion module. it can. If it is possible to sufficiently adhere, heat conductive silicone grease can be omitted.

  A recess is provided on the surface of the hollow substrate, and a white light emitting diode is mounted thereon. On the surface of the enamel substrate, an electrode (not shown) is formed on the enamel layer 6 by printing or sputtering, and the blue semiconductor light emitting diode element 8 is mounted on the electrode on the bottom of the recess. A transparent sealing resin 10 kneaded with the phosphor powder 9 is mounted so as to cover the blue light-emitting diode element 8, and a part of the blue light emitted from the blue light-emitting diode element 8 and a part of the blue light. Is absorbed by the phosphor powder 9 and white light is emitted by color mixing with the light whose wavelength is converted to visible light.

As the phosphor powder 9, various phosphor materials that can be excited by blue light and emit visible light can be used. Among them, a highly efficient YAG: Ce-based phosphor or a mixed color with blue can be used. A europium activated α-sialon phosphor capable of emitting a warm bulb color with a low color temperature is preferred. Alternatively, a blue excited green phosphor such as europium activated β sialon and a blue excited red phosphor such as Ca ₂ Si ₅ N ₈ : Eu or CaAlSiN ₃ : Eu may be mixed and used.

  As the transparent sealing resin 10, a silicone resin or the like is suitable. Further, as shown in FIG. 1, it is desirable to have a convex lens structure in consideration of light extraction efficiency and light distribution characteristics.

  The surface on the cooling side of the thermoelectric conversion module is in close contact with the heat sink 12 via the insulating plate 11 in order to prevent a short circuit of the electrodes. Thermally conductive silicone grease (not shown) is used between the thermoelectric conversion module and the insulating plate 11 and between the insulating plate 11 and the heat sink 12. However, in the case where sufficient adhesion is possible, the heat conductive silicone grease can be omitted. When the temperature on the cooling side of the thermoelectric conversion module is sufficiently low, such as when the environmental temperature is sufficiently low or there is a sufficient air volume, the insulating plate 11 may be exposed without using the heat sink 12. Further, when the short circuit is prevented, the electrode 5 can be exposed.

  As an important feature of the present invention, most of the individual white light-emitting diode lamps mounted on the white light-emitting diode lighting module are electrically connected to a power source and supplied with power from the outside, and some white light-emitting diode lamps Is connected to the generated power lead of the thermoelectric conversion module. FIG. 2 shows an energy transmission path. In FIG. 2, reference numeral 20 denotes a white light emitting diode lamp, and 21 denotes a thermoelectric conversion element.

As described above, according to the present embodiment, in the white light emitting diode illumination module, part of the energy that has been lost as heat in the past can be extracted as white light, and the luminous efficiency of the entire illumination device is improved. be able to.
Moreover, since the control part and battery which were conventionally required in the lighting fixture containing the thermoelectric conversion element were made unnecessary and this was able to be achieved, it succeeded in simplifying an apparatus and restraining cost low.
In addition, since the enamel substrate 6 is used as the insulating layer and the connection structure between the illumination module, which is a heat source, and the thermoelectric conversion module is devised, heat can be transferred efficiently and waste heat is converted into electricity. Efficiency can be improved. In addition, this makes it possible to omit the insulating plate and reduce costs.
Furthermore, according to the configuration of the present embodiment, when the power switch is turned off, the semiconductor light-emitting diode element connected to the thermoelectric conversion element cools the heat transfer substrate of the illumination module, and the front and back surfaces of the thermoelectric conversion module And the afterglow effect of continuing to shine for a period until the temperature difference falls below a certain threshold value. This is a function and effect peculiar to the present invention which has not been anticipated by those skilled in the art in Patent Document 1 and Patent Document 2 and the like. Usually, in the indoor lighting of a general house, a nightlight with a small amount of light such as a jujube sphere is used together with a fluorescent lamp, and it is obvious that this afterglow effect of the present invention is useful.

[Second Embodiment]
FIG. 3 is a cross-sectional view showing a second embodiment of the illumination device of the present invention. In FIG. 3, reference numeral 101 denotes a lighting device, 102 denotes an n-type semiconductor of a thermoelectric conversion element, 103 denotes a p-type semiconductor of a thermoelectric conversion element, 104 denotes a heat insulating layer, 105 denotes an electrode, 108 denotes a semiconductor blue light emitting diode element, and 109 denotes fluorescence. Body powder, 110 is a transparent sealing resin, 111A and 111B are insulating plates, and 12 is a heat sink. The illuminating device 101 of this embodiment is comprised substantially the same as the illuminating device 1 of 1st Embodiment mentioned above, and consists of a white light emitting diode illumination module, a thermoelectric conversion module, and a heat sink.

  The thermoelectric conversion module is not limited to the configuration in which the electrode 5 shown in the first embodiment is exposed, and may be in contact with a heat source via the insulating plate 111B of FIG. In this case, as the heat transfer substrate, it is possible to use a single-sided enamel substrate in which a hollow layer is applied only to the surface on which the white light emitting diode is mounted and the steel plate is exposed on the back surface. Various other metal-based heat transfer substrates can be used. Moreover, by making it the procedure which fixes the insulating board 111B to a thermoelectric conversion module previously, the mechanical strength of the thermoelectric conversion module in the middle of a manufacturing process is ensured, and manufacture can be made easy. In this case, there is a concern that the thermal resistance from the heat transfer substrate to the thermoelectric conversion module slightly increases, and the conversion efficiency is lower than in the case of the first embodiment. In addition, it is necessary to add an insulating plate 111B. Other functions and effects are the same as those of the first embodiment.

[Third Embodiment]
FIG. 4 is a cross-sectional view showing a third embodiment of the illumination device of the present invention. In FIG. 4, reference numeral 201 denotes a lighting device, 202 denotes an n-type semiconductor of a thermoelectric conversion element, 203 denotes a p-type semiconductor of a thermoelectric conversion element, 204 denotes a heat insulating layer, 205 denotes an electrode, 208 denotes a semiconductor blue light-emitting diode element, and 209 denotes fluorescence. Body powder, 210 is a transparent sealing resin, 211 is an insulating plate, 212 is a heat sink, and 214 is an insulating heat transfer substrate. The lighting device 201 of the present embodiment is configured in substantially the same manner as the lighting device 1 of the first embodiment described above, and includes a white light emitting diode lighting module, a thermoelectric conversion module, and a heat sink.

  The present embodiment is characterized in that an insulating heat transfer substrate 214 made of an insulating material having high thermal conductivity is used as the heat transfer substrate instead of the enamel substrate. By using the insulating heat transfer substrate 214, the substrate on which the semiconductor blue light emitting diode element 208 is mounted and the thermoelectric conversion module can be directly connected, heat transfer efficiency can be further improved, and the structure can be simplified.

[Fourth Embodiment]
FIG. 5 is a cross-sectional view showing a fourth embodiment of the illumination device of the present invention. In FIG. 5, reference numeral 301 denotes an illumination device, 302 denotes an n-type semiconductor of a thermoelectric conversion element, 303 denotes a p-type semiconductor of a thermoelectric conversion element, 304 denotes a heat insulating layer, 305 denotes an electrode, 306 denotes a hollow layer of a hollow substrate, and 307 denotes a hollow. A steel plate of the substrate, 308 is a semiconductor blue light emitting diode element, 309 is a phosphor powder, 310 is a transparent sealing resin, 311 is an insulating plate, and 312 is a heat sink. The lighting device 201 of the present embodiment is configured in substantially the same manner as the lighting device 1 of the first embodiment described above, and includes a white light emitting diode lighting module, a thermoelectric conversion module, and a heat sink.

  The present embodiment is characterized in that the arrangement of the semiconductor light emitting diode elements is made to correspond to the thermoelectric conversion elements. In the configurations of the first to third embodiments described above, the position of each element in the thermoelectric conversion module and each semiconductor light-emitting diode element in the white light-emitting diode illumination module, which is the heat source, correspond one-to-one. Therefore, the lateral heat conduction by the heat transfer board greatly affects the heat transfer characteristics from the white light emitting diode illumination module to the thermoelectric conversion module, and it is necessary to make the heat transfer board thick to some extent. However, with the configuration of the fourth embodiment, the influence of heat conduction in the lateral direction is sufficiently small. In this configuration, the thickness of the heat transfer substrate at the mounting position of the semiconductor light emitting diode element is preferably as thin as possible within a range in which the mechanical strength necessary for ensuring reliability can be ensured. For example, in the first embodiment, the enamel substrate In this embodiment, the depth of the recess is 0.4 mm and the thickness of the substrate at the bottom of the recess is 0.6 mm, whereas the thickness of the substrate at the bottom of the recess is 0.6 mm. It is preferable that the thickness of the substrate on the bottom surface of the recess is not more than half the thickness of other portions of the substrate, such as 4 mm. Of course, when the mechanical strength is not affected, the entire heat transfer substrate can be made thin.

[Fifth Embodiment]
FIG. 6 is a circuit diagram showing a fifth embodiment of the illumination device of the present invention. The illuminating device of this embodiment can employ | adopt the structure of the illuminating device in 1st Embodiment mentioned above-4th Embodiment except having employ | adopted the circuit shown in FIG.

  In the first to fourth embodiments described above, the afterglow effect is obtained even after the power switch is turned off by the circuit shown in FIG. 2, but there are applications where this afterglow effect is unnecessary. In such a case, as shown in FIG. 6, a relay that turns on / off the circuit between the thermoelectric conversion element 321 and the semiconductor light emitting diode element 320 connected to the thermoelectric conversion element 321 in conjunction with the supply of power. By inserting 322, it can be set as the structure which an afterglow effect does not arise.

It is sectional drawing which shows 1st Embodiment of the illuminating device of this invention. It is a circuit diagram which shows 1st thru | or 4th embodiment of the illuminating device of this invention. It is sectional drawing which shows 2nd Embodiment of the illuminating device of this invention. It is sectional drawing which shows 3rd Embodiment of the illuminating device of this invention. It is sectional drawing which shows 4th Embodiment of the illuminating device of this invention. It is a circuit diagram which shows 5th Embodiment of the illuminating device of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1,101,201,301 ... Illuminating device, 2,102,202,302 ... n-type semiconductor, 3,103,203,303 ... p-type semiconductor, 4,104,204,304 ... Heat insulation layer, 5,105, 205,305 ... electrode, 6,306 ... hollow layer, 7,307 ... steel plate, 8,108,208,308 ... semiconductor blue light emitting diode element, 9,109,209,309 ... phosphor powder, 10,110,210 , 310 ... Transparent sealing resin, 11, 111A, 111B, 211, 311 ... Insulating plate, 12, 112, 212, 312 ... Heat sink, 20 ... White light emitting diode lamp, 21 ... Thermoelectric conversion element, 214 ... Insulating heat transfer substrate 320, semiconductor light emitting diode elements, 321, thermoelectric conversion elements, 322, relays.

Claims (6)

A semiconductor light emitting diode element electrically connected to a power source, a heat transfer board on which the semiconductor light emitting diode element is mounted, a thermoelectric conversion element thermally connected to the heat transfer board and electrically insulated; a semiconductor light emitting diode element connected to the thermoelectric conversion element seen including,
The relay electrically connected to the power source is disposed between the thermoelectric conversion element and the semiconductor light emitting diode connected to the thermoelectric conversion element, and only when power is supplied from the power source, the relay An illumination device configured to be electrically connected to a semiconductor light emitting diode element .  The lighting device according to claim 1, wherein the heat transfer substrate is a hollow substrate.  The electrode that connects the p-type semiconductor and the n-type semiconductor exposed on one surface of the thermoelectric conversion element is in close contact with the enamel layer of the enamel substrate directly or through only thermal conductive grease. The lighting device according to claim 1.  The lighting device according to claim 1, wherein the heat transfer substrate is made of an insulating material.  The lighting device according to claim 1, wherein the semiconductor light emitting diode element is disposed at a position corresponding to the thermoelectric conversion element. The semiconductor light-emitting diode element is mounted on a bottom surface of a recess formed in the heat transfer substrate, and the thickness of the substrate on the bottom surface of the recess is less than half of the thickness of other portions of the substrate. 5. The lighting device according to 5 .

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