JP2005191520A - Lighting device, power supply device for light-emitting diode, and conductive board used for the power supply device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To simply, easily, and freely change the connecting position of a light-emitting diode. <P>SOLUTION: The lighting device is provided with a plurality of light-emitting diodes 1 and a power supply device 3 connected, in such a state that leads 2 of the light emitting diodes 1 are electrically connected. The lighting device makes the plurality of light-emitting diodes 1 connect to the power supply device 3, to emit light by applying a current from the power supply device 3 to the light-emitting diodes 1. The power supply device 3 is provided with a connection part 5 for connecting the leads 2 of the light-emitting diodes 1. The connection part 5 has elasticity, capable of inserting and holding the leads 2 of the light-emitting diodes 1 and the conductivity for energizing the leads 2 in a holding state. The lighting device inserts the leads 2 of the light-emitting diodes 1 into the connection part 5 and energizes from the connection part 5, to be turned on. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an illuminating device using a light emitting diode, and more particularly, an illuminating device capable of emitting light by connecting a number of light emitting diodes at arbitrary positions, a power supply device for the light emitting diode used in the illuminating device, and the power supply device. The present invention relates to a conductive board to be used for

There is no light emitting diode corresponding to a filament of a light bulb, and light is emitted from a semiconductor pn junction. For this reason, it has a feature that it has a long life that is incomparable with a light bulb and has a high luminous efficiency. However, the light emitting diode has a small light emission output, and it is necessary to use a large number of light emitting diodes in order to emit light brightly. In order to realize this, a lighting device in which a large number of light emitting diodes are arranged side by side has been developed (see Patent Documents 1 to 3).
JP-A-6-291940 JP 2003-141906 A JP 2003-059335 A

  These publications describe a lighting device in which a large number of light emitting diodes are fixed in a straight line or in a region surrounded by a circle. In this way, in the lighting device having a large number of light emitting diodes arranged in a specific arrangement, the leads of each light emitting diode are fixed by soldering to the printed circuit board, and all the light emitting diodes are energized to emit light. ing.

  As described above, the lighting device including a large number of light emitting diodes has a drawback that it takes time to assemble because the leads of all the light emitting diodes are connected to the power supply line by a method such as soldering. In addition, since the leads are connected by a method such as soldering, there is a disadvantage that a device without specialized technology cannot be assembled. Furthermore, since the light emitting diodes are fixed at a fixed position, it is difficult to change the fixing positions of a large number of light emitting diodes to various forms so as to be optimal for the application. In particular, in the structure where the lead of the light emitting diode is soldered and fixed to the printed circuit board, the fixing position of the light emitting diode is specified on the printed circuit board, so the light emitting diode is specified by using a specially designed printed circuit board. It is necessary to fix in the position. For this reason, if it is going to arrange a light emitting diode in various forms, it is necessary to use the printed circuit board designed exclusively for each form. For this reason, there is a drawback that the arrangement of the light emitting diodes can be freely changed to make the arrangement optimal for various applications.

  The present invention has been developed for the purpose of solving such drawbacks. An important object of the present invention is to provide an illuminating device, a power supply device for the light emitting diode, and a conductive board used in the power supply device, in which the connection position of the light emitting diode can be easily and easily changed.

  The illuminating device of the present invention includes a plurality of light emitting diodes 1 and a power supply device 3 that connects the leads 2 of the light emitting diodes 1 in an electrically connected state. In the lighting device, a plurality of light-emitting diodes 1 connected to the power supply device 3 are energized from the power supply device 3 to the light-emitting diodes 1 to emit light. The power supply device 3 includes a connecting portion 5 that connects the leads 2 of the light emitting diodes 1. The connecting portion 5 has elasticity that allows the lead 2 of the light-emitting diode 1 to be inserted and held, and conductivity that energizes the lead 2 in the holding state. The illuminating device is turned on by inserting the lead 2 of the light emitting diode 1 into the connecting portion 5 and energizing the connecting portion 5.

  The lighting device according to claim 2 of the present invention includes a plurality of light emitting diodes 1 projecting a pair of leads 2 and a power supply device 3 that connects the leads 2 of the plurality of light emitting diodes 1 in an electrically connected state. . In the power supply device 3, connecting portions 5 that connect the pair of leads 2 are arranged on both sides of the insulating portion 4. The connecting portion 5 includes an elastic holding portion 6 that can be inserted and held through the lead 2 of the light emitting diode 1, and the elastic holding portion 6 includes a conductive portion 7 that is electrically connected to the inserted lead 2. In this illuminating device, the leads 2 of the plurality of light emitting diodes 1 are inserted into the elastic holding portions 6 of the connecting portions 5 along the insulating portion 4, the light emitting diodes 1 are held by the elastic holding portions 6, and are turned on when energized. .

  In the illumination device according to claim 3 of the present invention, the elastic holding portion 6 is a synthetic resin foam or a rubber-like elastic body containing a conductive substance.

  According to a fourth aspect of the present invention, there is provided a lighting device according to a fourth aspect of the present invention, in which the power supply device 3 has a surface-side elastic holding layer 16 that can hold the connecting portion 5 connecting the lead 2 of the light emitting diode 1 through the lead 2 of the light emitting diode 1. The back side elastic holding layer 17 is provided. The power supply device 3 has a structure in which a front-side elastic holding layer 16 and a back-side elastic holding layer 17 that can be inserted and held through the lead 2 of the light-emitting diode 1 are laminated with an insulating layer 18. The front-side elastic holding layer 16 and the back-side elastic holding layer 17 are synthetic resin foams or rubber-like elastic bodies containing a conductive substance, and have conductivity that can be electrically connected to the leads 2 of the light-emitting diodes 1 inserted therethrough. . In the light emitting diode 1, one lead 2 is an insulating lead 2 </ b> A that insulates a penetrating portion of the surface-side elastic holding layer 16. In this illuminating device, the insulating lead 2A of the light emitting diode 1 is passed through the front-side elastic holding layer 16 and inserted into the back-side elastic holding layer 17 without being electrically connected to the front-side elastic holding layer 16, and the other lead 2 Is inserted into the front side elastic holding layer 16 and the light emitting diode 1 is energized by the front side elastic holding layer 16 and the back side elastic holding layer 17 to emit light.

  In the illumination device according to claim 5 of the present invention, the metal wire 24 is disposed in contact with the front-side elastic holding layer 16 and the back-side elastic holding layer 17, and the front-side elastic holding is performed via the metal wire 24. The layer 16 and the back side elastic holding layer 17 are energized.

  The lighting device according to claim 6 of the present invention includes a surface-side elastic holding layer 16 that allows the power supply device 3 to hold the connection portion 5 connecting the lead 2 of the light-emitting diode 1 through the lead 2 of the light-emitting diode 1. The back side elastic holding layer 17 is provided. The power supply device 3 has a structure in which a front-side elastic holding layer 16 and a back-side elastic holding layer 17 that can be inserted and held through the lead 2 of the light-emitting diode 1 are laminated with an insulating layer 18. The front-side elastic holding layer 16 and the back-side elastic holding layer 17 have conductivity that can be electrically connected to the lead 2 of the light-emitting diode 1 inserted therethrough. Further, the front-side elastic holding layer 16 and the back-side elastic holding layer 17 have a metal wire 24 sewn and fixed to the surface, and the front-side elastic holding layer 16 and the back-side elastic holding layer 17 are fixed via the metal wire 24. The layer 17 is energized. In the light emitting diode 1, one lead 2 is an insulating lead 2 </ b> A that insulates a penetrating portion of the surface-side elastic holding layer 16. In this illuminating device, the insulating lead 2A of the light emitting diode 1 is passed through the front-side elastic holding layer 16 and inserted into the back-side elastic holding layer 17 without being electrically connected to the front-side elastic holding layer 16, and the other lead 2 Is inserted into the front side elastic holding layer 16 and the light emitting diode 1 is energized by the front side elastic holding layer 16 and the back side elastic holding layer 17 to emit light.

  The lighting device according to claim 7 of the present invention includes a surface-side elastic holding layer 16 that allows the power supply device 3 to hold the connecting portion 5 connecting the lead 2 of the light emitting diode 1 through the lead 2 of the light emitting diode 1. The back side elastic holding layer 17 is provided. The power supply device 3 has a structure in which a front-side elastic holding layer 16 and a back-side elastic holding layer 17 that can be inserted and held through the lead 2 of the light-emitting diode 1 are laminated with an insulating layer 18. The front-side elastic holding layer 16 and the back-side elastic holding layer 17 are synthetic resin foams or rubber-like elastic bodies containing a conductive substance, and have conductivity that can be electrically connected to the leads 2 of the light-emitting diodes 1 inserted therethrough. . Further, the front-side elastic holding layer 16 and the back-side elastic holding layer 17 have a metal wire 24 sewn and fixed to the surface, and the front-side elastic holding layer 16 and the back-side elastic holding layer 17 are fixed via the metal wire 24. The layer 17 is energized. In the light emitting diode 1, one lead 2 is an insulating lead 2 </ b> A that insulates a penetrating portion of the surface-side elastic holding layer 16. In this illuminating device, the insulating lead 2A of the light emitting diode 1 is passed through the front-side elastic holding layer 16 and inserted into the back-side elastic holding layer 17 without being electrically connected to the front-side elastic holding layer 16, and the other lead 2 Is inserted into the front side elastic holding layer 16 and the light emitting diode 1 is energized by the front side elastic holding layer 16 and the back side elastic holding layer 17 to emit light.

  In the lighting device according to claim 8 of the present invention, the conductive material is used as a conductive paint, and the conductive paint is applied to a synthetic resin foam or a rubber-like elastic body to form the front-side elastic holding layer 16 and the back-side elastic holding layer 17. .

  In the lighting device according to claim 9 of the present invention, the distance (D) between the metal wire 24 provided on the front surface side elastic holding layer 16 and the metal wire 24 provided on the back surface side elastic holding layer 17 is set at the light emitting diode 1. The distance (d) between the pair of leads 2 is larger.

  The illumination device according to claim 10 of the present invention is such that the power supply device 3 has a surface-side elastic holding layer 16 that can hold the connecting portion 5 connecting the lead 2 of the light emitting diode 1 through the lead 2 of the light emitting diode 1. The back side elastic holding layer 17 is provided. The power supply device 3 has a structure in which a front-side elastic holding layer 16 and a back-side elastic holding layer 17 that can be inserted and held through the lead 2 of the light-emitting diode 1 are laminated with an insulating layer 18. The front-side elastic holding layer 16 and the back-side elastic holding layer 17 have conductivity that can be electrically connected to the lead 2 of the light-emitting diode 1 inserted therethrough. In the light emitting diode 1, one lead 2 is an insulating lead 2 </ b> A that insulates a penetrating portion of the surface-side elastic holding layer 16. The light emitting diode 1 is provided with an insulating lead 2A by fixing an insulating tube to the lead 2 by inserting an insulating tube that is thermally contracted into one lead 2 and heating it. In this illuminating device, the insulating lead 2A of the light emitting diode 1 is passed through the front-side elastic holding layer 16 and inserted into the back-side elastic holding layer 17 without being electrically connected to the front-side elastic holding layer 16, and the other lead 2 Is inserted into the front side elastic holding layer 16 and the light emitting diode 1 is energized by the front side elastic holding layer 16 and the back side elastic holding layer 17 to emit light.

  In the illumination device according to an eleventh aspect of the present invention, a surface layer 21 made of silicon rubber is provided on one or both surfaces of the surface-side elastic holding layer 16 and the back-side elastic holding layer 17, and the surface layer 21 is provided on the surface side. The surfaces of the elastic holding layer 16 and the back side elastic holding layer 17 are insulated.

  In the illuminating device according to a twelfth aspect of the present invention, the power supply device 3 includes an auxiliary electrode 27 that supplies power to the connecting portion 5. In the power supply device 3, the auxiliary electrode 27 is connected to the connection portion 5, and the connection portion 5 is energized from the auxiliary electrode 27.

  The power supply device for a light emitting diode of the present invention is connected in a state where the light emitting diode 1 is electrically connected, and the light emitting diode 1 is energized to emit light. The power supply device includes a connection portion 5 that connects the leads 2 of the light emitting diodes 1. The connecting portion 5 has elasticity that allows the lead 2 of the light-emitting diode 1 to be inserted and held, and conductivity that energizes the lead 2 in the holding state. The power supply device inserts the lead 2 of the light emitting diode 1 into the connection portion 5, energizes the connection portion 5, and lights up.

  In a power supply device according to a fourteenth aspect of the present invention, the connecting portions 5 for connecting the pair of leads 2 of the light emitting diode 1 are disposed on both sides of the insulating portion 4. The connecting portion 5 includes an elastic holding portion 6 that can be inserted and held through the lead 2 of the light emitting diode 1, and the elastic holding portion 6 includes a conductive portion 7 that is electrically connected to the inserted lead 2. In this power supply device, the pair of leads 2 of the light emitting diode 1 are inserted into the elastic holding portions 6 of the connecting portions 5 arranged on both sides of the insulating portion 4 in a posture straddling the insulating portion 4, and the light emitting diode 1 is inserted. It is held by the elastic holding part 6 and turned on when energized.

  In a power supply device according to a fifteenth aspect of the present invention, the elastic holding portion 6 is a synthetic resin foam or rubber-like elastic body containing a conductive material.

  In the power supply device according to claim 16 of the present invention, the front-side elastic holding layer 16 and the back-side elastic holding layer which can hold the connecting portion 5 connecting the lead 2 of the light-emitting diode 1 through the lead 2 of the light-emitting diode 1. 17 and so on. In the power supply device 3, a front-side elastic holding layer 16 and a back-side elastic holding layer 17 that can be inserted and held through the leads 2 of the light-emitting diode 1 are laminated with an insulating layer 18 through which the leads 2 can be inserted. The front-side elastic holding layer 16 and the back-side elastic holding layer 17 are synthetic resin foams or rubber-like elastic bodies containing a conductive substance, and have conductivity that can be electrically connected to the leads 2 of the light-emitting diodes 1 inserted therethrough. . In this power supply device, a light emitting diode 1 is mounted which has one lead 2 as an insulating lead 2A and insulates the penetrating portion of the surface side elastic holding layer 16. The power supply device passes the insulating lead 2A through the front-side elastic holding layer 16 and passes through the back-side elastic holding layer 17 without being electrically connected to the front-side elastic holding layer 16, and holds the other lead 2 with the front-side elastic holding. The light-emitting diode 1 is passed through the layer 16 and caused to emit light by the front-side elastic holding layer 16 and the back-side elastic holding layer 17.

  According to a seventeenth aspect of the present invention, the metal wire 24 is disposed in contact with the front-side elastic holding layer 16 and the back-side elastic holding layer 17, and the surface-side elastic is provided via the metal wire 24. The holding layer 16 and the back side elastic holding layer 17 are energized.

  In the power supply device according to claim 18 of the present invention, the front-side elastic holding layer 16 and the back-side elastic holding layer which can hold the connecting portion 5 connecting the lead 2 of the light-emitting diode 1 through the lead 2 of the light-emitting diode 1. 17 and so on. In the power supply device 3, a front-side elastic holding layer 16 and a back-side elastic holding layer 17 that can be inserted and held through the leads 2 of the light-emitting diode 1 are laminated with an insulating layer 18 through which the leads 2 can be inserted. The front-side elastic holding layer 16 and the back-side elastic holding layer 17 have conductivity that can be electrically connected to the lead 2 of the light-emitting diode 1 inserted therethrough. Further, a metal wire 24 is sewn and fixed to the surface of the front-side elastic holding layer 16 and the back-side elastic holding layer 17, and the front-side elastic holding layer 16 and the back-side elastic holding layer 17 are interposed via the metal wire 24. And are energized. In this power supply device, a light emitting diode 1 is mounted which has one lead 2 as an insulating lead 2A and insulates the penetrating portion of the surface side elastic holding layer 16. The power supply device passes the insulating lead 2A through the front-side elastic holding layer 16 and passes through the back-side elastic holding layer 17 without being electrically connected to the front-side elastic holding layer 16, and holds the other lead 2 with the front-side elastic holding. The light-emitting diode 1 is passed through the layer 16 and caused to emit light by the front-side elastic holding layer 16 and the back-side elastic holding layer 17.

  According to a nineteenth aspect of the present invention, in the power supply device, the front-side elastic holding layer 16 and the back-side elastic holding layer that can hold the connecting portion 5 for connecting the lead 2 of the light-emitting diode 1 through the lead 2 of the light-emitting diode 1. 17 and so on. In the power supply device 3, a front-side elastic holding layer 16 and a back-side elastic holding layer 17 that can be inserted and held through the leads 2 of the light-emitting diode 1 are laminated with an insulating layer 18 through which the leads 2 can be inserted. The front-side elastic holding layer 16 and the back-side elastic holding layer 17 are synthetic resin foams or rubber-like elastic bodies containing a conductive substance, and have conductivity that can be electrically connected to the leads 2 of the light-emitting diodes 1 inserted therethrough. . Further, a metal wire 24 is sewn and fixed to the surface of the front-side elastic holding layer 16 and the back-side elastic holding layer 17, and the front-side elastic holding layer 16 and the back-side elastic holding layer 17 are interposed via the metal wire 24. And are energized. In this power supply device, a light emitting diode 1 is mounted which has one lead 2 as an insulating lead 2A and insulates the penetrating portion of the surface side elastic holding layer 16. The power supply device passes the insulating lead 2A through the front-side elastic holding layer 16 and passes through the back-side elastic holding layer 17 without being electrically connected to the front-side elastic holding layer 16, and holds the other lead 2 with the front-side elastic holding. The light-emitting diode 1 is passed through the layer 16 and caused to emit light by the front-side elastic holding layer 16 and the back-side elastic holding layer 17.

  The power supply device according to the twentieth aspect of the present invention is that the conductive material is used as a conductive paint, and the conductive paint is applied to a synthetic resin foam or a rubber-like elastic body as the front-side elastic holding layer 16 and the back-side elastic holding layer 17. Yes.

  According to the power supply device of claim 21 of the present invention, the distance (D) between the metal wire 24 provided on the front surface side elastic holding layer 16 and the metal line 24 provided on the back surface side elastic holding layer 17 is set to a light emitting diode. It is larger than the interval (d) between one pair of leads 2.

  In a power supply device according to a twenty-second aspect of the present invention, a surface layer 21 made of silicon rubber is provided on one or both surfaces of the surface-side elastic holding layer 16 and the back-side elastic holding layer 17. The surfaces of the side elastic holding layer 16 and the back side elastic holding layer 17 are insulated.

  A power supply device according to a twenty-third aspect of the present invention includes an auxiliary electrode 27 that supplies electric power to the connecting portion 5. The power supply device connects the auxiliary electrode 27 to the connection portion 5 and energizes the connection portion 5 from the auxiliary electrode 27.

  Furthermore, a conductive board according to a twenty-fourth aspect of the present invention is a board for forming a conductive layer of a power supply device for a light emitting diode. This conductive board is made of a synthetic resin foam or a rubber-like elastic body that contains a conductive material almost uniformly on the entire surface, so that a current that can light up the light emitting diode 1 can be supplied at an arbitrary position of the conductive board. Yes.

  The illumination device and the power supply device for the light emitting diode according to the present invention have a feature that the connection position of the light emitting diode can be easily and easily changed. That is, the present invention is provided with a power supply device for connecting and energizing light-emitting diode leads in a state of being electrically connected to each other, and the connection portion for connecting the light-emitting diode leads is inserted into the power supply device. This is because it has elasticity that can be held and conductivity that conducts electricity to the lead in the held state.

  The illumination device and the power supply device for the light emitting diode according to the present invention have a feature that the connection position of the light emitting diode can be easily and easily changed. In the present invention, the power supply device for connecting the pair of leads of the light emitting diode in an electrically connected state has a structure in which connecting portions for connecting the pair of leads are arranged on both sides of the insulating portion, or the leads are inserted. The front-side elastic holding layer and the back-side elastic holding layer that can be held together are insulated and laminated with an insulating layer, and a plurality of light-emitting diodes connected to the power supply device are energized from the power supply device and turned on. Because.

  In the illumination device according to claim 2 and the power supply device according to claim 14 of the present invention, the connecting portion includes an elastic holding portion that holds the lead of the light emitting diode through the plurality of light emitting diodes. The light emitting diode can be easily and easily held freely by inserting the lead.

  Furthermore, in the illumination device according to claims 4 to 10 and the power supply device according to claims 16 to 21, one lead of the light emitting diode is an insulating lead that insulates the penetrating portion of the surface side elastic holding layer. An insulating lead is passed through the front-side elastic holding layer through the front-side elastic holding layer, and the other lead is inserted into the front-side elastic holding layer. Can be held easily and easily.

  As described above, the lighting device and the power supply device of the present invention can easily and easily connect a large number of light emitting diodes and freely energize them. There is a feature that can be changed to form. In particular, unlike the prior art, there is no need to use a printed circuit board designed exclusively for specifying the fixed position of the light emitting diode, so that the manufacturing cost can be reduced. Furthermore, the illumination device and the power supply device of the present invention have an advantage that they can be assembled very easily because all the light emitting diodes can be electrically connected to the power supply line very easily. In particular, it has the feature that it can be easily assembled even if it does not have specialized technology, such as soldering.

  Furthermore, in the illumination device of claim 11 and the power supply device of claim 22 of the present invention, the surface layer made of silicon rubber is provided on one or both of the surface side elastic holding layer and the back surface side elastic holding layer. The surface layer has an advantage that it can be used safely by insulating the surfaces of the front-side elastic holding layer and the back-side elastic holding layer. In particular, since silicon rubber has excellent properties in waterproofness, heat resistance, and cold resistance, it has a feature that it can be used safely for a long period of time even in an application where the lighting device is used in a severe environment. Furthermore, the remarkable features of the lighting device and power supply device that use silicon rubber for the surface layer of the front side elastic holding layer and the back side elastic holding layer are that the lead can be removed even though it is easy to insert the LED lead. It is a difficult point. Silicone rubber has a small coefficient of friction with respect to the lead inserted through the silicon rubber, and the frictional force with the inserted lead can be reduced. For this reason, the lead of the light emitting diode can be smoothly inserted. Furthermore, since the silicon rubber is soft and has excellent elasticity, the inserted lead can be stably held so as not to come off. Therefore, the lighting device and the power supply device can stably hold the light emitting diode by effectively preventing the inserted lead from coming off while smoothly inserting the lead of the light emitting diode. Furthermore, since the surface layer made of silicon rubber can be formed thin to realize the above features, there is also a feature that the entire power supply device can be thinned.

  Furthermore, the illuminating device according to claim 12 and the power supply device according to claim 23 of the present invention are provided with an auxiliary electrode for supplying power to the connecting portion, and the auxiliary electrode is connected to the connecting portion and connected from the auxiliary electrode. Since power is supplied to the part, it is possible to supply power from the auxiliary electrode, effectively preventing partial differences in brightness, and to light up multiple light emitting diodes uniformly. Power can be supplied locally to the portion where the electrode is provided, and the light emitting diode near the auxiliary electrode can be lit brighter than the surroundings.

  Furthermore, the conductive board according to claim 24 of the present invention is made of a synthetic resin foam or a rubber-like elastic body containing the conductive material substantially uniformly in the entire surface, and a current capable of lighting the light emitting diode is obtained. Since it is possible to energize at any position on the conductive board, the extremely simple structure has the advantage that it can be stably lit regardless of the position where the light-emitting diode is mounted, while being mass-produced inexpensively.

  Embodiments of the present invention will be described below with reference to the drawings. However, the embodiment described below exemplifies a lighting device for embodying the technical idea of the present invention, and the present invention does not specify the lighting device as described below.

  Further, in this specification, in order to facilitate understanding of the scope of claims, the numbers corresponding to the members shown in the embodiments are referred to as “claims” and “means for solving the problems”. It is added to the member shown by. However, the members shown in the claims are not limited to the members in the embodiments.

  The illuminating device of the present invention includes a plurality of light emitting diodes 1 and a power supply device 3 that connects the leads 2 of the light emitting diodes 1 in an electrically connected state. The lighting device causes a plurality of light-emitting diodes 1 connected to the power supply device 3 to emit light by energizing the light-emitting diodes 1 from the power supply device 3. The power supply device 3 includes a connecting portion 5 that connects the leads 2 of the light emitting diodes 1. The connecting portion 5 has elasticity that allows the lead 2 of the light-emitting diode 1 to be inserted and held, and conductivity that energizes the lead 2 in the holding state. The illuminating device is turned on by inserting the lead 2 of the light emitting diode 1 into the connecting portion 5 and energizing the connecting portion 5.

  1 to 5 includes a plurality of light emitting diodes 1 projecting a pair of leads 2 and a power supply device 3 that connects the leads 2 of the plurality of light emitting diodes 1 in an electrically connected state. . In the illuminating device shown in these drawings, a plurality of light emitting diodes 1 connected to the power supply device 3 are energized from the power supply device 3 to the light emitting diodes 1 to emit light.

  In the power supply device 3 of the illuminating device in FIG. 1, connecting portions 5 that connect the pair of leads 2 are arranged on both sides of the insulating portion 4. The connecting portion 5 includes an elastic holding portion 6 that can be inserted and held through the lead 2 of the light emitting diode 1. The elastic holding portion 6 includes a conductive portion 7 that is electrically connected to the inserted lead 2. In this illuminating device, the leads 2 of the plurality of light emitting diodes 1 are inserted along the insulating portion 4 through the elastic holding portion 6 of the connecting portion 5 and connected to the power supply device 3, and the light emitting diode to which the power supply device 3 is connected. 1 is turned on.

  The insulating part 4 is disposed between the pair of leads 2 to prevent the lead 2 of the light emitting diode 1 from being short-circuited. The insulating part 4 shown in the figure is an insulating wall 4A. The insulating wall 4A is formed by molding an insulating material such as plastic into a plate shape. In the illustrated lighting device, a conductive wire 8 is fixed to both sides of an insulating wall 4A, and a conductive tape 9 having a predetermined width is fixed to the surface of the conductive wire 8 so as to be in contact with the conductive wire 8. A pair of conducting wires 8 fixed on both sides of the insulating wall 4 </ b> A are connected to a direct current or alternating current power source, and are connected to the conductive portion 7 of the elastic holding portion 6 via the conductive tape 9. The illuminating device that connects the conductive wire 8 to the DC power supply lights the light emitting diode 1 continuously. The illuminating device which connects the conducting wire 8 to the AC power supply lights up the light emitting diode 1 in an AC half cycle.

  The elastic holding part 6 is made of a synthetic resin foam or a rubber-like elastic body in order to insert and hold the lead 2 of the light emitting diode 1 therein. The synthetic resin foam can smoothly pass through the lead 2 of the light emitting diode 1. The rubber-like elastic body is inserted by cutting the insertion portion with the lead 2. In the illustrated lighting device, an intermediate groove 6A is provided in the elastic holding portion 6, and an insulating wall 4A is inserted therein.

  The elastic holding portion 6 shown in the figure is a conductive portion 7 provided with a conductive layer 19 that penetrates the inserted lead 2. The conductive layer 19 is a plated layer of a conductive metal such as nickel, aluminum, or copper. However, the conductive layer can also be composed of a metal foil. The elastic holding part 6 shown in the figure is provided with a conductive layer 19 which is a conductive part 7 inside. In this structure, since the conductive portion 7 does not appear on the surface of the elastic holding portion 6 through which the lead 2 is inserted, even if a conductor contacts the surface, there is no short circuit.

  The conductive portion of the synthetic resin foam or rubber-like elastic body can be provided by applying a conductive paint. The conductive paint is obtained by adding conductive powder to a binder and curing the binder to realize conductivity. The conductive powder added to the conductive paint is a metal powder or a carbon powder. The metal powder is a powder of nickel, aluminum, copper, shinchu or the like. The conductive paint can reduce the electrical resistance in the cured state by increasing the amount of metal powder or carbon powder added. The binder of the conductive paint is liquid or pasty in an uncured state. A conductive powder is added to a liquid or pasty binder and applied to the surface of a synthetic resin foam or rubber elastic body. The binder is solidified when cured, and has a low electrical resistance due to the conductive powder being added. The conductive portion provided by applying the conductive paint can reduce the electrical resistance by increasing the number of times of applying the conductive paint. Further, the electrical resistance in the cured state can be reduced by increasing the amount of conductive powder contained in the conductive paint.

  In the above embodiment, the insulating portion 4 is the insulating wall 4A. The power supply device 3 has an advantage that the pair of leads 2 can be reliably insulated by the insulating wall 4A. However, the insulating part does not necessarily need to be an insulating wall. Although not shown, the insulating part may be an insulating groove or a non-conductive part provided between conductive parts electrically connected to the pair of leads. In this power supply device, for example, the conductive layer provided inside the elastic holding part is divided into intermediate grooves to form insulating grooves, or a plurality of rows of conductive parts are provided inside the elastic holding part, The non-conductive part which is a part can be used as an insulating part.

  In the power supply device 3 of the lighting device in FIG. 2, connecting portions 5 for connecting the pair of leads 2 are arranged on both sides of the insulating wall 4 </ b> A. The connecting portion 5 includes an elastic clamping portion 10 that can be inserted and held through the lead 2 of the light emitting diode 1. The elastic clamping part 10 holds the light emitting diode 1 by elastically clamping the lead 2 inserted therethrough. Furthermore, the elastic clamping part 10 is equipped with the electroconductive part 7 electrically connected to the lead | read | reed 2 of the light emitting diode 1 penetrated here.

  The power supply device 3 shown in the figure has a side wall 11 made of an insulating plate on both sides of an insulating wall 4A, and the pair of side walls 11 and the insulating wall 4A are arranged in a continuous groove 12A of a groove material 12 that is elastically deformed. Yes. As with the insulating wall 4A of FIG. 1, the insulating wall 4A is provided with a conductive wire 8 and a conductive tape 9 on both sides. The side wall 11 is a surface of an insulating plate made of plastic or the like, and the conducting wire 8 and the conductive tape 9 are fixed to a surface facing the insulating wall 4A. In the power supply device 3, a conductive tape 9 fixed to the surfaces of the insulating wall 4 </ b> A and the side wall 11 is used as a conductive portion 7 connected to the lead 2.

  The groove member 12 is manufactured by molding a hard material that can be elastically deformed, such as plastic, or is formed by drawing a metal or the like, or press-molding it into a groove shape. The groove material 12 is integrally formed with an intermediate ridge 12B that contacts the surface of the side wall 11 and presses the side wall 11 on the opposing surface of the continuous groove 12A. Further, in the illustrated groove member 12, in order to sandwich and hold the light emitting diode 1 from both sides, a holding projection 12C for holding the light emitting diode 1 is also integrally formed at the opening of the continuous groove 12A. ing. The side wall 11 is fixed to the intermediate protrusion 12B, and the insulating wall 4A is fixed to the bottom of the continuous groove 12A.

  As shown in the drawing, the lighting device having this structure inserts the lead 2 of the light emitting diode 1 into the elastic sandwiching portion 10 so that the lead 2 of the light emitting diode 1 straddles both sides of the insulating wall 4A. In this way, the plurality of light emitting diodes 1 are connected along the insulating wall 4A. In the light emitting diode 1 to be connected, the lead 2 is inserted through the elastic clamping portion 10 of the connection portion 5. In this state, the light-emitting diode 1 connected to the power supply device 3 is sandwiched between the conductive portions 7 made of the conductive tape 9 provided on the opposing surfaces of the insulating wall 4A and the side wall 11, and is energized through the conductive portion 7. The The conducting wire 8 that contacts the conductive tape 9 disposed on both sides of the insulating wall 4A is connected to a DC or AC power source. The conducting wires 8 connected to the conductive tape 9 disposed on the opposing surfaces of the insulating wall 4A and the side wall 11 are electrically connected to each other and connected to a power source. Therefore, the light emitting diode 1 held by the elastic sandwiching portion 10 is lit by bringing the lead 2 into contact with the conductive tape 9 provided on both sides of the insulating wall 4A and energizing through the lead 2.

  The groove member 12 shown in FIG. 2 has a shape extending linearly, and a plurality of light emitting diodes 1 can be continuously mounted in the extending direction of the groove member 12. However, although the groove material is not illustrated, the groove material 12 shown in FIG. 2 can be cut into a short shape. This groove material holds, for example, one light emitting diode by one groove material. Since the groove material having a short overall length is easily elastically deformed on the side surface, when mounting a light emitting diode, the groove material has a feature that the elastic pinching portion can be opened wide and the lead can be easily inserted. Moreover, since this groove | channel material hold | maintains a light emitting diode individually, there exists the feature which can be mounted | worn without affecting the clamping state of an adjacent light emitting diode at the time of mounting | wearing of a light emitting diode. For this reason, a plurality of light emitting diodes can be efficiently mounted. The groove material for individually mounting the light emitting diodes can be connected to, for example, a linearly extending guide member to integrally connect a plurality of light emitting diodes. For example, the guide member can be connected by providing a linear elastic pinching portion and fitting the elastic pinching portion into a connecting groove provided in the groove member. This structure has a feature that the connecting position of the groove member and the guide member can be freely changed. However, the groove member and the guide member can be connected by another fitting structure or locking structure, or by bonding or screwing. Furthermore, a plurality of light emitting diodes can be arranged in a desired shape by making the guide member have a desired shape. Moreover, it is also possible to freely adjust the irradiation direction of the light emitting diode by changing the direction in which the groove member is connected to the guide member. However, two or more light emitting diodes can be mounted in one groove material.

  In the power supply device 3 of the lighting device shown in FIGS. 3 and 4, the connection portions 5 that connect the pair of leads 2 are arranged on both sides of the insulating wall 4 </ b> A, and the light emitting diode 1 is sandwiched between the connection portions 5. An elastic holding wall 14 is provided to be worn and held. Further, in the illustrated lighting device, another insulating wall 4B is provided outside the connecting portion 5 in parallel with the insulating wall 4A. Insulating walls 4A and 4B arranged in parallel with each other in an attitude facing each other are insulating plates made of plastic or the like, and are fixed in parallel to each other at a predetermined interval. Between the insulating walls 4A and 4B facing each other, an uneven plate 13 that is an elastic holding wall 14 that sandwiches and holds the light emitting diode 1 is disposed, and a conductive portion 7 through which the lead 2 can be inserted is provided. The lead 2 inserted through the connecting portion 5 is electrically connected to the conductive portion 7. In the illuminating device shown in FIG. 3, the power supply device 3 is provided with four rows of insulating walls 4A and 4B, and the connecting portions 5 are provided in three rows between the respective insulating walls 4A and 4B. The lighting device having this structure can mount the light emitting diodes 1 in two rows along the two rows of insulating walls 4A. However, although not shown, the power supply apparatus can be provided with two rows of connecting portions with three rows of insulating walls. In addition, it is possible to arrange the light-emitting diodes in three or more rows with five or more insulating walls and four or more connecting portions.

  The concavo-convex plate 13 that is the elastic holding wall 14 is a plastic plate or metal plate that can be elastically deformed and is press-molded so as to be corrugated or concavo-convex. In the power supply device 3 shown in FIG. 3, the concavo-convex plates 13 are arranged in three rows between the insulating walls 4A and 4B. The concavo-convex plate 13 disposed adjacent to each other is arranged in such a manner that the concave portions face each other, and the insertion portion 22 is formed by the opposed concave portions, and the light emitting diode 1 is inserted therein. The light emitting diode 1 inserted into the insertion portion 22 is sandwiched between the two concavo-convex plates 13 in contact therewith and held at a predetermined position. As shown in FIG. 4, the concavo-convex plate 13 has a lower portion inserted into the upper portion of the connecting portion 5 and an upper portion formed higher than the insulating walls 4A and 4B, and light is emitted from the portions protruding from the insulating walls 4A and 4B. The side surface of the diode 1 is sandwiched and held. The concave and convex plate 13 can be insulated from the surface by molding with an insulating material such as a plastic plate, so that it does not short-circuit even when a conductor comes into contact therewith. The uneven plate can also be a part of the conductive part as a metal plate. The concavo-convex plate, which is a metal plate, can insulate the front end portion that holds the light emitting diode and prevent a short circuit on the surface side.

  Further, the power supply device shown in the figure is provided with conductive portions 7 through which the leads 2 can be inserted in the three rows of connecting portions 5 provided between the four rows of insulating walls 4A, 4B, and leads that are inserted into the connecting portions 5. 2 is electrically connected to the conductive portion 7. The conductive portion 7 is a conductive synthetic resin foam, or a synthetic resin foam impregnated with metal powder or carbon powder that is conductive powder, or metal powder or carbon powder.

  A conductive synthetic resin foam can be coated with a conductive paint to reduce electrical resistance. This synthetic resin foam is a foam having open cells, and the applied conductive paint can penetrate into the inside by open cells to reduce the electrical resistance of the synthetic resin foam. As the conductive paint, the same conductive paint as that used for providing the conductive portion of FIG. 1 can be used. This synthetic resin foam can also reduce the electrical resistance of the synthetic resin foam by increasing the number of times the conductive paint is applied and impregnating more conductive paint into the open cells. Moreover, even if the addition amount of the conductive powder contained in the conductive paint is increased, the electrical resistance of the synthetic resin foam in the cured state can be reduced.

  The conductive portion 7 is provided with a lead wire 15 connected to a power source so as to be electrically connected to conductive synthetic resin foam or metal powder. The lead wire 15 is wired below the concavo-convex plate 13 inserted in the connection portion 5. When the uneven plate is a metal plate, the uneven plate can be used together with the lead wire. Furthermore, the power supply apparatus of the figure has connected the electroconductive part 7 to the terminal of DC power supply or AC power supply. In the power supply device 3 shown in the figure, the intermediate conductive portion 7 is connected to the + side terminal of the DC power source, and the conductive portions 7 on both sides are connected to the − side terminal of the DC power source. The power supply device 3 can turn on the light emitting diode 1 by inserting the lead 2 of the light emitting diode 1 across the insulating wall 4A. This is because both sides of the insulating wall 4A are connected to the +-power supply terminal. Although not shown, a power supply device including four or more rows of connection portions alternately connects + side terminals and − side terminals to conductive portions of connection portions adjacent to each other.

  In the power supply device 3, the light emitting diode 1 is inserted into the insertion portion 22 formed by the adjacent uneven plate 13, and the pair of leads 2 are inserted into the connection portion 5 in a state of straddling the insulating wall 4A. The power supply device 3 can connect a plurality of light emitting diodes 1 along the insulating wall 4A. The light emitting diode 1 inserted into the insertion portion 22 is sandwiched and held by the concave and convex plate 13. When the lead of the light emitting diode 1 is inserted into the connecting portion 5, the lead 2 is connected to the conductive portion 7 that is electrically connected to the power source. For this reason, the light emitting diode 1 is connected to a power source via the lead 2 and the conductive portion 7 and is turned on when energized.

  In the power supply device 3 of the lighting device of FIG. 5, the connection portions 5 that connect the pair of leads 2 are arranged on both sides of the insulating wall 4 </ b> A, and the light emitting diode 1 is sandwiched and held outside the connection portion 5. An elastic holding wall 14 is provided. Further, a conductive portion 7 through which the lead 2 can be inserted is provided between the elastic holding wall 14 and the insulating wall 4A, and the lead 2 inserted through the connection portion 5 is electrically connected to the conductive portion 7. The conductive portion 7 is a conductive synthetic resin foam, or a synthetic resin foam impregnated with metal powder or carbon powder that is conductive powder, or metal powder or carbon powder. The conductive portion 7 is provided with a lead wire 15 connected to a power source so as to be electrically connected to conductive synthetic resin foam or metal powder.

  The power supply device 3 in the figure is a plate material that can be elastically deformed, and the insulating wall 4A and the elastic holding wall 14 are integrally formed. The constituting plate material is a hard plastic plate that can be elastically deformed. The hard plastic plate is formed by drawing. However, an elastic metal plate whose inner surface is insulated can also be used.

  In this lighting device, a plurality of light emitting diodes 1 are mounted along the insulating wall 4A so as to straddle the insulating wall 4A. The light emitting diode 1 is held by inserting the lead 2 into the connecting portion 5 and sandwiching the lead 2 by the elastic holding wall 14. The lead 2 inserted into the connecting portion 5 is connected to the conductive portion 7, connected to the power source via the conductive portion 7, and turned on when energized.

  Furthermore, the power supply device 3 of the lighting device shown in FIGS. 6 to 21 has a surface-side elastic holding layer 16 that can hold the connecting portion 5 connecting the lead 2 of the light-emitting diode 1 through the lead 2 of the light-emitting diode 1. And a back-side elastic holding layer 17. The power supply device 3 shown in these drawings has a structure in which the front-side elastic holding layer 16 and the back-side elastic holding layer 17 which are the connecting portions 5 are insulated and laminated by an insulating layer 18 through which the lead 2 can be inserted. The front-side elastic holding layer 16 and the back-side elastic holding layer 17 have conductivity that can be electrically connected to the lead 2 of the light-emitting diode 1 inserted therethrough.

  6 and 7 includes a plurality of light emitting diodes 1 from which a pair of leads 2 protrudes, and a power supply device 3 that connects the leads 2 of the plurality of light emitting diodes 1 in an electrically connected state. The plurality of light emitting diodes 1 connected to the power supply device 3 are energized from the power supply device 3 to emit light.

  The power supply device 3 has a structure in which a front-side elastic holding layer 16 and a back-side elastic holding layer 17 that can be inserted and held through the leads 2 of the light-emitting diode 1 are laminated with an insulating layer 18 through which the leads 2 can be inserted. . The front-side elastic holding layer 16 and the back-side elastic holding layer 17 have conductivity that can be electrically connected to the lead 2 of the light-emitting diode 1 inserted therethrough.

  The front-side elastic holding layer 16 and the back-side elastic holding layer 17 can hold the light-emitting diode 1 by inserting the lead 2 of the light-emitting diode 1 here, and are a synthetic resin foam or a rubber-like elastic body. . The synthetic resin foam can smoothly pass through the lead 2 of the light emitting diode 1. The rubber-like elastic body is inserted through the lead 2 by cutting the insertion portion with the lead 2.

  The front-side elastic holding layer 16 and the back-side elastic holding layer 17 have conductivity that allows the lead 2 to be energized. The front-side elastic holding layer 16 and the back-side elastic holding layer 17 that are synthetic resin foams or rubber-like elastic bodies are conductive synthetic resin foams or rubber-like elastic bodies, or metal powders that are conductive powders. Or a synthetic resin foam or rubber-like elastic body impregnated with carbon powder. Furthermore, the front-side elastic holding layer and the back-side elastic holding layer can be made conductive by applying a conductive paint to a synthetic resin foam or rubber-like elastic material that is not conductive, or a conductive synthetic material. A conductive paint can also be applied to the resin foam or rubber-like elastic body. As the conductive paint, the same conductive paint as that used for providing the conductive portion of FIG. 1 can be used.

  For the front-side elastic holding layer 16 and the back-side elastic holding layer 17, a conductive board made of a synthetic resin foam containing a conductive substance or a rubber-like elastic body can be used. This conductive board contains a conductive material almost uniformly on the entire surface of the synthetic resin foam or rubber-like elastic body so that a current that can light up the light-emitting diode 1 can be applied at an arbitrary position of the conductive board. 3 conductive layers are formed. The conductive material can be contained in the entire interior of the synthetic resin foam or rubber-like elastic body, or can be contained only in the surface portion. The conductive board sets the overall electrical resistance by adjusting the electrical resistance and content of the conductive material contained therein. The resistance value of the conductive board is set to a value that allows the current emitted from the light emitting diode to flow through various light emitting diodes to be mounted. There are various types of light emitting diodes having a barrier voltage of 1.5 to 4.0 V depending on the light emission color and standard. As shown in the equivalent circuit of FIG. 22, this conductive board is set so that the resistance R0 of the conductive board is larger than the resistance RA of the light emitting diode 1, and this is applied to all the light emitting diodes 1 to be mounted. A current that can emit light can be applied. Therefore, the conductive board having this structure can stably supply current for causing various light emitting diodes 1 mounted at arbitrary positions to emit light without using an expensive constant current circuit. As shown in FIGS. 6 to 21, this conductive board is used as a front-side elastic holding layer 16 and a back-side elastic holding layer 17 which are stacked through an insulating layer 18 and are conductive layers of the power supply device 3. Can do. In addition, this conductive board can be cut into a predetermined width according to the application and used as a conductive portion of the power supply device 3 shown in FIGS.

  The front-side elastic holding layer and the back-side elastic holding layer for applying the conductive paint to the synthetic resin foam or rubber-like elastic body can be applied on both sides or only on one side. Furthermore, the conductive coating is applied to only one surface of the front-side elastic holding layer and the back-side elastic holding layer that achieve conductivity by applying a conductive paint to a non-conductive synthetic resin foam or rubber-like elastic body. Thus, the light-emitting diode can be energized, and the other surface can be a non-energized part to which no conductive paint is applied. The front-side elastic holding layer and the back-side elastic holding layer can be laminated to form a surface layer in a state where the non-current-carrying portion to which the conductive paint is not applied is located on the outside, and the surface side of the power supply device can have an insulating structure. .

  A conductive synthetic resin foam can be coated with a conductive paint to reduce electrical resistance. This synthetic resin foam is a foam having open cells, and the applied conductive paint can penetrate into the inside by open cells to reduce the electrical resistance of the synthetic resin foam. The same conductive paint as that described above can be used for this conductive paint. This synthetic resin foam can also reduce the electrical resistance of the synthetic resin foam by increasing the number of times the conductive paint is applied and impregnating more conductive paint into the open cells. Moreover, even if the addition amount of the conductive powder contained in the conductive paint is increased, the electrical resistance of the synthetic resin foam in the cured state can be reduced.

  The front-side elastic holding layer 16 and the back-side elastic holding layer 17 are provided with a conductive layer such as a metal foil or a metal plating layer in the same manner as the elastic holding portion 6 of the lighting device shown in FIG. It is also possible to energize through the lead. As shown in the cross-sectional view of FIG. 8, the front-side elastic holding layer 16 and the back-side elastic holding layer 17 have a conductive layer 19 laminated therein.

  Further, as shown in the cross-sectional view of FIG. 9, the power supply device 3 laminates and adheres conductive layers 19 on both surfaces of the insulating layer 18, and the surface of the conductive layer 19 is made of a synthetic resin foam, rubber-like elastic body, or the like. It can also be set as the structure which laminates | stacks and adhere | attaches the elastic holding | maintenance part 6. FIG. In the power supply device 3, the conductive layer 19 and the elastic holding unit 6 constitute a front surface side elastic holding layer 16, and the conductive layer 19 and the elastic holding unit 6 constitute a back side elastic holding layer 17.

  Further, as shown in the sectional view of FIG. 10, the power supply device 3 is a synthetic resin impregnated with conductive synthetic resin foam, rubber-like elastic body, or metal powder or carbon powder which is conductive powder. A conductive layer 19 may be laminated and adhered to the surface of the elastic holding portion 6 that is a resin foam or rubber-like elastic body to form a conductive front-side elastic holding layer 16 and back-side elastic holding layer 17. it can. This power supply device 3 has a structure in which the surface and boundary surfaces of the front-side elastic holding layer 16 and the back-side elastic holding layer 17 are laminated by insulating with an insulating layer 18. The front-side elastic holding layer 16 and the back-side elastic holding layer 17 shown in the drawing are provided with the conductive layer 19 only on one side of the elastic holding unit 6, but the conductive layer can also be provided on both sides of the elastic holding unit.

  Further, as shown in FIG. 11, a lead plate 23 is provided around the front surface side elastic holding layer 16 and the back side elastic holding layer 17 to energize the front side elastic holding layer 16 and the back side elastic holding layer 17. You can also. The lead plate 23 is in electrical contact with the periphery of the front-side elastic holding layer 16 and the back-side elastic holding layer 17 made of a conductive synthetic resin foam, so that the front-side elastic holding layer 16 and the back-side side are in contact with each other. The elastic holding layer 17 is energized.

  Further, as shown in the exploded perspective view of FIG. 12, the power supply device 3 has a metal wire 24 disposed on the front-side elastic holding layer 16 and the back-side elastic holding layer 17, and the front-side elastic holding layer 16 and the back-side side. It is also possible to energize the elastic holding layer 17. The metal wire 24 can be a conductive metal wire such as a copper wire or a nickel wire, or a metal wire such as copper or iron whose surface is plated with nickel plating or the like. The metal wire 24 is in electrical contact with the front-side elastic holding layer 16 and the back-side elastic holding layer 17 made of a conductive synthetic resin foam, and the front-side elastic holding layer 16 and the back-side elastic holding layer 17 The layer 17 is energized.

  In the power supply device 3 of FIG. 12, metal wires 24 are sewn and fixed to the surfaces of the front-side elastic holding layer 16 and the back-side elastic holding layer 17. The structure in which the metal wire 24 is sewn can be fixed very easily by, for example, sewing the lower thread with the metal wire 24 and the upper thread with the insulating thread material 25 with a sewing machine. In particular, as shown in the figure, by making the tension of the metal wire 24 as the lower thread stronger than the thread material 25 as the upper thread, the metal wire 24 can be ideally wired without being disconnected. However, the structure in which the metal line is sewn can be such that the lower thread is an insulating thread material and the upper thread is a metal line, or both the lower thread and the upper thread are metal lines. For the insulating thread material 25, for example, natural fiber or plastic fiber can be used. As described above, the structure in which the metal wire 24 is sewn is characterized in that the metal wire 24 can be fixed to the predetermined positions of the front-side elastic holding layer 16 and the back-side elastic holding layer 17 very easily. However, the metal wire can be bonded and fixed to the surface of the front-side elastic holding layer and the back-side elastic holding layer, or can be fixed with a connector. As shown in the drawing, the front-side elastic holding layer 16 and the back-side elastic holding layer 17 having the metal wires 24 fixed on the surface are laminated on both sides of the insulating layer 18 and insulated from each other. The front-side elastic holding layer 16 and the back-side elastic holding layer 17 shown in the figure are arranged with the surface on which the metal wire 24 is arranged facing the insulating layer 18, and the metal wire 24 is on the surface side of the power supply device 3. To prevent it from appearing.

  Further, as shown in FIG. 13, the metal wire 24 disposed on the front surface side elastic holding layer 16 and the metal wire 24 disposed on the back surface side elastic holding layer 17 are disposed so as to be shifted from each other. This is to prevent the lead 2 of the light emitting diode 1 inserted through the front-side elastic holding layer 16 and the back-side elastic holding layer 17 from simultaneously contacting the metal wires 24 located on both sides of the insulating layer 18. For example, when the metal wires located on both sides of the insulating layer are in positions facing each other, the power supply is short-circuited when the leads of the light emitting diodes inserted to the back-side elastic holding layer simultaneously contact the two metal wires. In addition, when the distance between the metal wires located on both sides of the insulating layer is narrow, the pair of leads of the light emitting diode inserted through the front surface side elastic holding layer and the back surface side elastic holding layer are in contact with the metal wire. The light emitting diode may break down when energized. In order to prevent these adverse effects, the distance (D) between the metal wire 24 provided on the front surface side elastic holding layer 16 and the metal wire 24 provided on the back surface side elastic holding layer 17 is set to a pair of the light emitting diodes 1. It is made larger than the interval (d) of the leads 2.

  As shown in FIG. 14, the interval (D) between the metal wires 24 is an interval in a projected view from the insertion direction of the light-emitting diode 1, and as shown in this drawing, is disposed on the surface-side elastic holding layer 16. The distance between the metal wire 24 and the metal wire 24 disposed on the back-side elastic holding layer 17 is closest. In FIG. 14, the metal wire 24 provided on the front surface side elastic holding layer 16 is indicated by a chain line, and the metal wire 24 provided on the back surface side elastic holding layer 17 is indicated by a one-dot chain line. In a state in which the distance (D) between the metal wires 24 is larger than the distance (d) between the leads 2, as shown in FIG. 13, the lead 2 of the light-emitting diode 1 inserted through the back-side elastic holding layer 17 has two metals. The pair of leads 2 of the light-emitting diode 1 inserted through the front-side elastic holding layer 16 and the back-side elastic holding layer 17 are not in contact with the metal wire 24 at the same time. Therefore, it is possible to safely energize while protecting the power supply and the light emitting diode 1. The interval (D) between the metal wires 24 disposed on both sides of the insulating layer 18 is appropriately determined by the interval (d) between the leads 2. The interval (D) between the metal wires 24 is, for example, between the leads 2. The above-mentioned adverse effects can be effectively prevented by setting the interval (d) to 1.2 times or more, preferably 1.5 times or more, and more preferably 2 times or more.

  Furthermore, the power supply device 3 shown in FIG. The frame body 26 is disposed in a state in which the front-side elastic holding layer 16 and the back-side elastic holding layer 17 laminated on both sides of the laminated insulating layer 18 are insulated. The frame body 26 shown in the figure is disposed in a state of covering not only the outer peripheral surfaces of the front surface side elastic holding layer 16 and the back surface side elastic holding layer 17 but also the peripheral edge portion. As described above, the power supply device 3 that covers the peripheral edge portion with the frame body 26 is provided on the metal wire 24 and the back surface side elastic holding layer 17 provided on the front surface side elastic holding layer 16 as shown in the figure. The metal wires 24 can be arranged at positions facing each other. This is because the lead 2 of the light emitting diode 1 cannot be inserted into the frame body 26, so that the lead 2 of the light emitting diode 1 inserted into the back-side elastic holding layer 17 is located on both sides of the insulating layer 18. It is because it does not touch simultaneously. Further, the power supply device including the frame body 26 at the peripheral edge has an advantage that the appearance can be improved because the thread material 25 which is the upper thread can be prevented from appearing when the metal wire 24 is sewn.

  Further, as shown in FIGS. 16 and 17, the power supply device 3 connects the auxiliary electrode 27 and supplies power from the auxiliary electrode 27 to the front-side elastic holding layer 16 and the back-side elastic holding layer 17. Can do. As shown in FIG. 17, the auxiliary electrode 27 can be inserted from the back surface side and disposed without improving the appearance without being exposed to the front surface side. However, the auxiliary electrode can be inserted and disposed from the surface side. Since the power supply device 3 including the auxiliary electrode 27 can supply electric power from the auxiliary electrode 27 to the light emitting diode 1 mounted in the vicinity of the auxiliary electrode 27, the current flowing through these light emitting diodes 1 can be increased to light up brightly. There are features. In particular, the lighting device may partially differ in brightness depending on the number and arrangement of light emitting diodes to be mounted. At this time, by connecting the auxiliary electrode to the portion that is lit dark, this portion can be effectively lit brightly.

  The auxiliary electrode 27 in the figure includes a pair of electrodes. This electrode is a conductive rod or plate and is connected to a power source via a lead wire 28. The pair of electrodes are electrically connected to the front-side elastic holding layer 16 and the back-side elastic holding layer 17, respectively. In the auxiliary electrode 27, one electrode that penetrates the back-side elastic holding layer 17 and is connected to the front-side elastic holding layer 16 is an insulating electrode 27A. The insulating electrode 27 </ b> A insulates the penetrating portion of the back-side elastic holding layer 17 as an insulating portion 27 a and does not insulate the tip portion inserted through the front-side elastic holding layer 16. The insulating electrode 27A is provided with an insulating portion 27a by covering the surface of the electrode with an insulator such as plastic, applying an insulating material to the surface of the electrode, or inserting an insulating tube through the electrode. The insulating electrode 27 </ b> A can be electrically connected to the front-side elastic holding layer 16 while being insulated from the back-side elastic holding layer 17 by the insulating portion 27 a. The insulating electrode 27A that passes through the back-side elastic holding layer 17 and is inserted into the front-side elastic holding layer 16 is electrically connected to the front-side elastic holding layer 16 and the other electrode 27B inserted into the back-side elastic holding layer 17. Are electrically connected to the backside elastic holding layer 17. The auxiliary electrode 27 energizes the front-side elastic holding layer 16 and the back-side elastic holding layer 17 and energizes the light-emitting diode 1 attached thereto.

  However, the auxiliary electrode does not necessarily need to be a conductive rod or plate. As shown in FIGS. 18 and 19, the conductive portion of the electric wire 29 whose surface is insulated and coated is exposed, and this conductive portion is used as an electrode. Can be substituted. A wiring cable is suitable for the electric wire 29. As the wiring cable, for example, a two-core cable or a coaxial cable can be used. As shown in FIG. 18, in the two-core cable, one core wire 29A is passed through the back-side elastic holding layer 17 in an insulated state and electrically connected to the front-side elastic holding layer 16, and the other core wire 29B is held back-side elastically. Connect to layer 17. The core wire 29 </ b> A connected to the front-side elastic holding layer 16 is insulated from the back-side elastic holding layer 17 by the covering portion 29 a so as not to be electrically connected to the back-side elastic holding layer 17. As shown in FIG. 19, the coaxial cable has a central core wire 29 </ b> C inserted into the front-side elastic holding layer 17 to be electrically connected, and the outer outer conductor 29 </ b> D is exposed to be electrically connected to the back-side elastic holding layer 17. The center core wire 29C is insulated from the back surface side elastic holding layer 17 by the inner covering portion 29c so as not to be electrically connected to the back surface side elastic holding layer. As described above, the electric wire having the core wire insulated and coated can be ideally electrically connected to the front-side elastic holding layer and the back-side elastic holding layer by adjusting the length of the portion where the core wire is exposed and the insulating portion. However, as the electric wire for providing the auxiliary electrode, a cable for wiring other than a two-core cable or a coaxial cable can be used, or an electric wire other than a cable for wiring can be used.

  Furthermore, as shown in the plan view of FIG. 20, the power supply device 3 can also divide the whole into a plurality of regions and connect the auxiliary electrode 27 to each of these regions. Auxiliary electrode 27 is connected to each region through lead wire 28 to supply power. As the auxiliary electrode 27 disposed in each region, one having the above-described structure can be used. Furthermore, the power supply device 3 shown in the figure controls the power supply to the auxiliary electrode 27 connected to each region by the control circuit 30 so that the lighting of the light emitting diodes mounted in each region can be controlled. . The power supply device 3 shown in the figure is divided into a plurality of regions (six regions in the figure), and the power supplied to each region is controlled by the control circuit 30. In the power supply device 3 having this structure, the control circuit 30 controls the energization of the auxiliary electrode 27 connected to each region, so that the light emitting diodes mounted in a desired region can be lit brightly. Therefore, the power supply device 3 can light up the light emitting diodes mounted in each region in units of regions and display different information in units of regions. Furthermore, the power supply device 3 can also control the blinking of the light emitting diodes for each region, and display them in different lighting states for each region. Furthermore, this power supply device can display moving images by increasing the number of areas to be divided and controlling the blinking of the light emitting diodes disposed in each area.

  As described above, the power supply device 3 including the auxiliary electrode 27 has a partial difference in brightness by supplying power from the auxiliary electrode 27 according to the number and arrangement of the light emitting diodes to be mounted. Can be effectively turned on and the whole can be lit uniformly, and power is intentionally supplied to a portion where the auxiliary electrode 27 is intentionally disposed, so that the light emitting diodes in the vicinity of the auxiliary electrode 27 can be seen from the surroundings. It can also be lit brightly to enter various display states.

  The insulating layer 18 prevents the laminated front side elastic holding layer 16 and back side elastic holding layer 17 from short-circuiting. The insulating layer 18 needs to penetrate one lead 2 of the light emitting diode 1. Therefore, the insulating layer 18 is made of a synthetic resin foam or a rubber-like elastic body so that the lead 2 can be inserted.

  The surface side elastic holding layer 16 of FIG. 6 is provided with a through portion 20 through which one lead 2 of the light emitting diode 1 can be inserted. The through portion 20 can be a dot-like through hole or a belt-like slit hole. The through portions, which are through holes, are opened at a predetermined interval to ideally connect a plurality of light emitting diodes. The through portion, which is a slit hole, can freely determine the vertical connection position of the light emitting diode. The front-side elastic holding layer 16 is inserted through the back-side elastic holding layer 17 without passing through one lead 2 of the light-emitting diode 1 through the penetrating portion 20 and contacting the front-side elastic holding layer 16. The penetration part 20 preferably insulates the inner surface. The penetrating portion 20 can be insulated by inserting an insulating tube on the inner surface or by applying an insulating material on the inner surface. The surface-side elastic holding layer 16 is not energized even if the lead 2 inserted through the through portion 20 contacts the inner surface. The other lead 2 of the light emitting diode 1 is inserted into the front side elastic holding layer 16 so that the light emitting diode 1 is energized by the front side elastic holding layer 16 and the back side elastic holding layer 17 to emit light.

  The power supply device 3 in FIG. 7 insulates one lead 2 of the light-emitting diode 1 without providing a through portion in the surface-side elastic holding layer 16. In this light-emitting diode 1, one lead 2 that penetrates and is connected to the back-side elastic holding layer 17 through the front-side elastic holding layer 16 is an insulating lead 2A. The insulating lead 2 </ b> A insulates the penetrating part of the front surface side elastic holding layer 16 and does not insulate the tip part inserted through the back side elastic holding layer 17. The insulating lead 2A can be provided with an insulating portion on the surface of the lead 2 by inserting an insulating tube into the lead 2 or applying an insulating material to the surface. The insulating tube inserted into the lead 2 can be a heat-shrinkable plastic tube, for example. The light emitting diode 1 can be formed as an insulating lead having a surface insulated by inserting an insulating tube into one lead 2 and heating the insulating tube with a dryer or the like to cause heat shrinkage. In the light emitting diode 1, the insulating lead 2 </ b> A can be inserted into the front surface side elastic holding layer 16 in an insulating state, and the tip can be connected to the back side elastic holding layer 17. The power supply device 3 that connects the light emitting diodes 1 does not need to be provided with a penetrating portion in the surface side elastic holding layer 16. This is because it is not necessary to insulate the insulating lead 2A at the penetrating portion. However, a light-emitting diode having one lead as an insulating lead can be connected to the back-side elastic holding layer by inserting the light-emitting diode into the penetrating portion of the front-side elastic holding layer.

  The power supply device 3 shown in FIGS. 6 to 10, 12, 13, 15, and 17 to 19 has a surface layer 21 laminated on the surface of the front-side elastic holding layer 16 and the back-side elastic holding layer 17. Yes. The surface layer 21 is an insulating layer and insulates the surfaces of the front-side elastic holding layer 16 and the back-side elastic holding layer 17. The power supply device 3 having the surface layer 21 can be used safely and conveniently because the surface is insulated. However, the lighting device of the present invention does not necessarily require a surface layer, and the surface layer can be omitted. In the power supply device 3 shown in FIG. 6, the penetrating portion 20 is opened in one surface layer 21 laminated on the surface of the surface-side elastic holding layer 16 in accordance with the position of the penetrating portion 20 provided in the surface-side elastic holding layer 16. doing.

  The surface layer 21 provided on the surface of the surface side elastic holding layer 16 is made of, for example, synthetic resin foam or rubber elastic body so that the lead 2 can be inserted because the lead 2 of the light emitting diode 1 is inserted. Since the surface layer 21 provided on the surface of the back-side elastic holding layer 17 does not need to be inserted through the lead 2 of the light emitting diode 1, it may be a synthetic resin plate or a rubber-like elastic plate through which the lead 2 cannot be inserted. it can. However, both of the surface layers laminated on the surface of the front-side elastic holding layer and the back-side elastic holding layer can be inserted through the lead of the light emitting diode. This power supply device can connect light emitting diodes on both sides.

  Furthermore, the surface layer 21 can be made of silicon rubber. Silicone rubber has excellent properties such as waterproofness, heat resistance, and cold resistance. Therefore, the structure in which the surface layer 21 is made of silicon rubber has a feature that it can be used safely over a long period of time even when the lighting device is used in a severe environment. The surface layer 21 made of silicon rubber can be provided by applying liquid or gel-like silicon rubber on the surface of the front-side elastic holding layer 16 or the back-side elastic holding layer 17. The method of applying a liquid or gel-like silicon rubber has good compatibility with the surface of the synthetic resin foam and the rubber-like elastic body forming the front-side elastic holding layer 16 and the back-side elastic holding layer 17, and is peeled off from these surfaces. The surface layer 21 can be provided so as not to adhere. In particular, the overall thickness can be reduced by forming the surface layer 21 thinly on the surface of a synthetic resin foam or rubber-like elastic body. Furthermore, since the surface layer 21 of silicon rubber can be attached in a state of covering the entire surface of the front-side elastic holding layer 16 and the back-side elastic holding layer 17, there is an advantage that an excellent waterproof property can be realized. However, the surface layer made of silicon rubber can be provided by adhering sheet-like silicon rubber.

  Further, the surface layer 21 made of silicon rubber has a feature that the lead 2 of the light emitting diode 1 can be smoothly inserted and the lead 2 cannot be easily pulled out. Since the silicone rubber has a small coefficient of friction with respect to the lead 2 inserted through the silicone rubber, the frictional force with the inserted lead 2 can be reduced. For this reason, the lead 2 of the light emitting diode 1 can be smoothly inserted. In particular, it is possible to comfortably feel when the lead 2 is inserted through the surface layer 21. Further, since silicon rubber is soft and has excellent elasticity, it can be stably held so as not to come out of the inserted lead 2. Therefore, while smoothly inserting the lead 2 of the light emitting diode 1, it is possible to effectively prevent the inserted lead 2 from being pulled out, and to stably hold the light emitting diode 1. Thus, the power supply device 3 that holds the lead 2 of the inserted light-emitting diode 1 with the surface layer 21 has an advantage that an excellent holding force can be realized while making the whole thin.

  The surface layer made of silicon rubber can be provided on both surfaces of the front-side elastic holding layer and the back-side elastic holding layer, or can be provided only on the surface of the front-side elastic holding layer. Furthermore, the surface layer of silicon rubber can be provided on both surfaces of the front-side elastic holding layer and the back-side elastic holding layer. In this power supply device, the insulating layer can be formed by the surface layers provided on the mutually opposing surfaces of the front surface side elastic holding layer and the back surface side elastic holding layer. The power supply device 3 shown in FIG. 21 is provided with a surface layer 21 on both surfaces of the front-side elastic holding layer 16 and the back-side elastic holding layer 17, and is insulated by interposing an insulating material 31 between the opposing surface layers 21. Layer 18 is assumed. For this insulating material 31, for example, paper, plastic film, non-woven fabric or the like can be used. The insulating layer 18 has a three-layer structure including a surface layer 21 and an insulating material 31, and has an advantage that the entire thickness can be reduced while realizing excellent insulating properties. However, this insulating material can be omitted, and the surface layers of the front-side elastic holding layer and the back-side elastic holding layer can be provided only on one of the opposing surfaces.

  Furthermore, since the insulating layer 18 is formed of silicon rubber, the power supply device 3 of FIG. 21 can hold the lead 2 penetrating the insulating layer 18 smoothly while being smoothly inserted. That is, the power supply device 3 having this structure has the front-side elastic elasticity in addition to elastically holding the lead 2 of the light-emitting diode 1 inserted by the front-side elastic holding layer 16 and the back-side elastic holding layer 17. Since the surface layer 21 on both sides of the holding layer 16 and the surface layer 21 on the inner surface side of the back side elastic holding layer 17 are also held, they can be held firmly so as not to come off. In particular, it is possible to effectively prevent the light emitting diode 1 from coming off while making the entire power supply device 3 thin.

  The front-side elastic holding layer 16 and the back-side elastic holding layer 17 are connected to a power source. This lighting device is lit by connecting one lead 2 of the light emitting diode 1 to the front-side elastic holding layer 16 and connecting the other lead 2 to the back-side elastic holding layer 17. In the light emitting diode 1, the lead 2 inserted through the back side elastic holding layer 17 is inserted into the front side elastic holding layer 16 so that one can be inserted into the front side elastic holding layer 16 and the other through the back side elastic holding layer 17. It is longer than the lead 2 to be used. In other words, the lead 2 of the light emitting diode 1 is inserted into the power supply device 3 until the one lead 2 is connected to the front-side elastic holding layer 16, and the other lead 2 is inserted into the back-side elastic holding layer 17. Thus, the length of the pair of leads 2 is specified. The light emitting diode 1 is in a state where the other lead 2 is inserted through and connected to the back side elastic holding layer 17, and the one lead 2 does not reach the back side elastic holding layer 17 and is inserted into the front side elastic holding layer 16. Connected.

  As shown in FIGS. 6 to 21, the power supply device 3 in which the front-side elastic holding layer 16 and the back-side elastic holding layer 17 are stacked can illuminate the light-emitting diodes 1 by arranging them in arbitrary vertical and horizontal positions. The light emitting diode 1 can be fixed and lit at a position optimal for the application.

The disassembled perspective view of the illuminating device concerning one Example of this invention. The exploded perspective view of the illuminating device concerning the other Example of this invention. The top view of the illuminating device concerning the other Example of this invention. AA line sectional view of the lighting device shown in FIG. Sectional perspective view of the illuminating device concerning the other Example of this invention. The expanded sectional view of the illuminating device concerning the other Example of this invention. The expanded sectional view of the illuminating device concerning the other Example of this invention. Expanded sectional view showing another example of the power supply device Expanded sectional view showing another example of the power supply device Expanded sectional view showing another example of the power supply device Sectional perspective view of the illuminating device concerning the other Example of this invention. An exploded sectional perspective view showing another example of the power supply device FIG. 12 is an enlarged sectional view of the power supply device shown in FIG. The top view of the power supply device shown in FIG. Expanded sectional view showing another example of the power supply device A perspective view showing another example of a power supply device The expanded sectional view which shows the state which connects an auxiliary electrode to the power supply device shown in FIG. Expanded sectional view showing another example of auxiliary electrode Expanded sectional view showing another example of auxiliary electrode The top view which shows another example of a power supply device The top view which shows another example of a power supply device Circuit diagram showing equivalent circuit of power supply device

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Light emitting diode 2 ... Lead 2A ... Insulating lead 3 ... Power supply device 4 ... Insulating part 4A ... Insulating wall 4B ... Insulating wall 5 ... Connection part 6 ... Elastic holding part 6A ... Intermediate groove 7 ... Conductive part 8 ... Conductor 9 ... Conductive tape 10 ... Elastic sandwiching part 11 ... Side wall 12 ... Groove material 12A ... Continuous groove 12B ... Intermediate ridge
12C ... Holding convex strip 13 ... Concave and convex plate 14 ... Elastic holding wall 15 ... Lead wire 16 ... Front side elastic holding layer 17 ... Back side elastic holding layer 18 ... Insulating layer 19 ... Conductive layer 20 ... Penetration part 21 ... Surface layer 22 ... Insertion part 23 ... Lead plate 24 ... Metal wire 25 ... Yarn material 26 ... Frame material 27 ... Auxiliary electrode 27A ... Insulating electrode 27B ... Electrode
27a ... Insulating part 28 ... Lead wire 29 ... Electric wire 29A ... Core wire 29B ... Core wire
29C: Core wire 29D: External conductor
29a ... covering portion 29c ... inner covering portion 30 ... control circuit 31 ... insulating material

Claims (24)

A plurality of light emitting diodes (1) and a power supply device (3) connected in a state where the leads (2) of these light emitting diodes (1) are electrically connected, and a plurality of the light emitting diodes (1) connected to the power supply device (3) The light emitting diode (1) is a lighting device that emits light by energizing the light emitting diode (1) from the power supply device (3),
The power supply device (3) includes a connection part (5) for connecting the lead (2) of the light emitting diode (1), and the connection part (5) is inserted through the lead (2) of the light emitting diode (1). Elasticity that can be held in place and conductivity that conducts electricity to the lead (2) in the retained state, and the light-emitting diode (1) inserts the lead (2) into the connection part (5) and energizes from the connection part (5). A lighting device that is turned on. A plurality of light emitting diodes (1) projecting a pair of leads (2), and a power supply device (3) for connecting the leads (2) of the plurality of light emitting diodes (1) in an electrically connected state, A plurality of light emitting diodes (1) connected to a power supply device (3) is a lighting device that emits light by energizing the light emitting diode (1) from the power supply device (3),
The power supply device (3) has a connecting part (5) connecting the pair of leads (2) on both sides of the insulating part (4), and the connecting part (5) is a lead of the light emitting diode (1). (2) includes an elastic holding part (6) that can be inserted and held, and the elastic holding part (6) includes a conductive part (7) that is electrically connected to the lead (2) to be inserted;
The lead (2) of the plurality of light emitting diodes (1) is inserted into the elastic holding part (6) of the connection part (5) along the insulating part (4), and the light emitting diode (1) is inserted by the elastic holding part (6). The lighting device according to claim 1, wherein the lighting device is held and turned on when energized.   The lighting device according to claim 2, wherein the elastic holding portion (6) is a synthetic resin foam or a rubber-like elastic body containing a conductive substance. A plurality of light emitting diodes (1) projecting a pair of leads (2), and a power supply device (3) for connecting the leads (2) of the plurality of light emitting diodes (1) in an electrically connected state, A plurality of light emitting diodes (1) connected to a power supply device (3) is a lighting device that emits light by energizing the light emitting diode (1) from the power supply device (3),
The power supply device (3) is a surface-side elastic holding layer (5) that connects the lead (2) of the light emitting diode (1) and holds the connecting portion (5) through the lead (2) of the light emitting diode (1). 16) and the back side elastic holding layer (17), the front side elastic holding layer (16) and the back side elastic holding layer (17) that can be inserted and held through the lead (2) of the light emitting diode (1) It is a structure in which the insulating layer (18) through which (2) can be inserted is insulated and laminated, and the front-side elastic holding layer (16) and the back-side elastic holding layer (17) are synthetic resin foams containing a conductive substance. Or a rubber-like elastic body, and has conductivity that can be electrically connected to the lead (2) of the light emitting diode (1) inserted therethrough,
In the light emitting diode (1), one lead (2) is an insulating lead (2A) that insulates the penetrating part of the surface side elastic holding layer (16), and the light emitting diode (1) is an insulating lead (2A). Is inserted through the back side elastic holding layer (17) without being electrically connected to the front side elastic holding layer (16) through the front side elastic holding layer (16), and the other lead (2) is held elastically by the front side. The light-emitting diode (1) is energized by the front-side elastic holding layer (16) and the back-side elastic holding layer (17) through the layer (16) to emit light. Lighting device.   The metal wire (24) is disposed in contact with the front-side elastic holding layer (16) and the back-side elastic holding layer (17), and the front-side elastic holding layer (16 5) and the back side elastic holding layer (17). A plurality of light emitting diodes (1) projecting a pair of leads (2), and a power supply device (3) for connecting the leads (2) of the plurality of light emitting diodes (1) in an electrically connected state, A plurality of light emitting diodes (1) connected to a power supply device (3) is a lighting device that emits light by energizing the light emitting diode (1) from the power supply device (3),
The power supply device (3) is a surface-side elastic holding layer (5) that connects the lead (2) of the light emitting diode (1) and holds the connecting portion (5) through the lead (2) of the light emitting diode (1). 16) and the back side elastic holding layer (17), the front side elastic holding layer (16) and the back side elastic holding layer (17) that can be inserted and held through the lead (2) of the light emitting diode (1) (2) is an insulating layer (18) that can be inserted and laminated, and the front-side elastic holding layer (16) and the back-side elastic holding layer (17) are light-emitting diodes (1 ) Has electrical conductivity that can be electrically connected to the lead (2),
Further, a metal wire (24) is sewn and fixed to the surface of the front-side elastic holding layer (16) and the back-side elastic holding layer (17), and the front-side elastic holding layer is interposed via the metal wire (24). (16) and the back side elastic retaining layer (17) are energized,
In the light emitting diode (1), one lead (2) is an insulating lead (2A) that insulates the penetrating part of the surface side elastic holding layer (16), and the light emitting diode (1) is an insulating lead (2A). Is inserted through the back side elastic holding layer (17) without being electrically connected to the front side elastic holding layer (16) through the front side elastic holding layer (16), and the other lead (2) is held elastically by the front side. The light-emitting diode (1) is energized by the front-side elastic holding layer (16) and the back-side elastic holding layer (17) through the layer (16) to emit light. Lighting device. A plurality of light emitting diodes (1) projecting a pair of leads (2), and a power supply device (3) for connecting the leads (2) of the plurality of light emitting diodes (1) in an electrically connected state, A plurality of light emitting diodes (1) connected to a power supply device (3) is a lighting device that emits light by energizing the light emitting diode (1) from the power supply device (3),
The power supply device (3) is a surface-side elastic holding layer (5) that connects the lead (2) of the light emitting diode (1) and holds the connecting portion (5) through the lead (2) of the light emitting diode (1). 16) and the back side elastic holding layer (17), the front side elastic holding layer (16) and the back side elastic holding layer (17) that can be inserted and held through the lead (2) of the light emitting diode (1) It is a structure in which the insulating layer (18) through which (2) can be inserted is insulated and laminated, and the front-side elastic holding layer (16) and the back-side elastic holding layer (17) are synthetic resin foams containing a conductive substance. Or a rubber-like elastic body, and has conductivity that can be electrically connected to the lead (2) of the light emitting diode (1) inserted therethrough,
Further, a metal wire (24) is sewn and fixed to the surface of the front-side elastic holding layer (16) and the back-side elastic holding layer (17), and the front-side elastic holding layer is interposed via the metal wire (24). (16) and the back side elastic retaining layer (17) are energized,
In the light emitting diode (1), one lead (2) is an insulating lead (2A) that insulates the penetrating part of the surface side elastic holding layer (16), and the light emitting diode (1) is an insulating lead (2A). Is inserted through the back side elastic holding layer (17) without being electrically connected to the front side elastic holding layer (16) through the front side elastic holding layer (16), and the other lead (2) is held elastically by the front side. The light-emitting diode (1) is energized by the front-side elastic holding layer (16) and the back-side elastic holding layer (17) through the layer (16) to emit light. Lighting device.   The conductive material is a conductive paint, and the conductive paint is applied to a synthetic resin foam or rubber-like elastic body to form a front-side elastic holding layer (16) and a back-side elastic holding layer (17). The lighting device described in any one of 7 above.   The distance (D) between the metal wire (24) disposed on the front surface side elastic retaining layer (16) and the metal wire (24) disposed on the back surface side elastic retaining layer (17) is determined by the distance of the light emitting diode (1). The lighting device according to any one of claims 5 to 7, wherein the lighting device is larger than a distance (d) between the pair of leads (2). A plurality of light emitting diodes (1) projecting a pair of leads (2), and a power supply device (3) for connecting the leads (2) of the plurality of light emitting diodes (1) in an electrically connected state, A plurality of light emitting diodes (1) connected to a power supply device (3) is a lighting device that emits light by energizing the light emitting diode (1) from the power supply device (3),
The power supply device (3) is a surface-side elastic holding layer (5) that connects the lead (2) of the light emitting diode (1) and holds the connecting portion (5) through the lead (2) of the light emitting diode (1). 16) and the back side elastic holding layer (17), the front side elastic holding layer (16) and the back side elastic holding layer (17) that can be inserted and held through the lead (2) of the light emitting diode (1) (2) is an insulating layer (18) that can be inserted and laminated, and the front-side elastic holding layer (16) and the back-side elastic holding layer (17) are light-emitting diodes (1 ) Has electrical conductivity that can be electrically connected to the lead (2),
In the light emitting diode (1), one lead (2) is an insulating lead (2A) that insulates the penetrating portion of the surface side elastic holding layer (16),
This light emitting diode (1) is provided with an insulating lead (2A) by fixing an insulating tube to the lead (2) by inserting and heating an insulating tube which is thermally contracted to one lead (2).
The light-emitting diode (1) passes through the insulating lead (2A) through the front-side elastic holding layer (16) and is not electrically connected to the front-side elastic holding layer (16), and is inserted into the back-side elastic holding layer (17). The other lead (2) is inserted into the front side elastic holding layer (16), and the light emitting diode (1) is energized by the front side elastic holding layer (16) and the back side elastic holding layer (17) to emit light. The lighting device according to claim 1, which is configured as described above.   A surface layer (21) made of silicon rubber is provided on one or both surfaces of the front-side elastic holding layer (16) and the back-side elastic holding layer (17), and the surface-side elastic holding layer is formed by the surface layer (21). The lighting device according to any one of claims 4 to 10, wherein the surface of (16) is insulated from the surface of the back-side elastic holding layer (17).   The power supply device (3) includes an auxiliary electrode (27) for supplying power to the connection portion (5). The auxiliary electrode (27) is connected to the connection portion (5) and connected from the auxiliary electrode (27). The lighting device according to claim 1, wherein power is supplied to the portion (5). A power supply device for light emitting diodes connected in a state where the light emitting diode (1) is electrically connected,
It has a connection part (5) that connects the lead (2) of the light-emitting diode (1), and this connection part (5) is elastic and can hold the lead (2) of the light-emitting diode (1). The lead (2) is electrically conductive, and the lead (2) of the light emitting diode (1) is inserted into the connection part (5), and the connection part (5) is energized to light up. Power supply device for light emitting diodes. A power supply device for light emitting diodes connected in a state where the light emitting diode (1) is electrically connected,
A connecting part (5) for connecting the pair of leads (2) of the light emitting diode (1) is arranged on both sides of the insulating part (4), and the connecting part (5) is a lead (2) of the light emitting diode (1). ), And the elastic holding part (6) includes a conductive part (7) electrically connected to the lead (2) to be inserted,
Insert the pair of leads (2) of the light emitting diode (1) into the elastic holding part (6) of the connecting part (5) arranged on both sides of the insulating part (4) in a posture straddling the insulating part (4). The light-emitting diode power supply device according to claim 13, wherein the light-emitting diode (1) is held by the elastic holding portion (6) and is turned on when energized.   The power supply device for a light emitting diode according to claim 14, wherein the elastic holding portion (6) is a synthetic resin foam or a rubber-like elastic body containing a conductive substance. A power supply device for light emitting diodes connected in a state where the light emitting diode (1) is electrically connected,
The front-side elastic holding layer (16) and the back-side elastic holding layer that can hold the connecting portion (5) connecting the lead (2) of the light-emitting diode (1) by inserting the lead (2) of the light-emitting diode (1). As (17), the front side elastic holding layer (16) and the back side elastic holding layer (17) that can be inserted and held through the lead (2) of the light emitting diode (1), the insulating layer ( 18), the front-side elastic holding layer (16) and the back-side elastic holding layer (17) are a synthetic resin foam or rubber-like elastic body containing a conductive material, and are inserted through here. It has conductivity that can be electrically connected to the lead (2) of the light emitting diode (1)
With one lead (2) as an insulating lead (2A) and the light emitting diode (1) that insulates the penetration part of the surface side elastic holding layer (16) attached, the insulating lead (2A) is held elastically on the surface side Insert the other lead (2) into the front-side elastic holding layer (16) without passing through the layer (16) and electrically connecting to the front-side elastic holding layer (16). The power supply for a light-emitting diode according to claim 13, wherein the light-emitting diode is inserted into the light-emitting diode (1) and caused to emit light by the front-side elastic holding layer (16) and the back-side elastic holding layer (17). Feeding device.   The metal wire (24) is disposed in contact with the front-side elastic holding layer (16) and the back-side elastic holding layer (17), and the front-side elastic holding layer (16 And a back-side elastic holding layer (17). A power supply device for light emitting diodes connected in a state where the light emitting diode (1) is electrically connected,
The front-side elastic holding layer (16) and the back-side elastic holding layer that can hold the connecting portion (5) connecting the lead (2) of the light-emitting diode (1) by inserting the lead (2) of the light-emitting diode (1). As (17), the front side elastic holding layer (16) and the back side elastic holding layer (17) that can be inserted and held through the lead (2) of the light emitting diode (1), the insulating layer ( 18), the front-side elastic holding layer (16) and the back-side elastic holding layer (17) are electrically conductive to be electrically connected to the lead (2) of the light-emitting diode (1) inserted therethrough. Have
Further, a metal wire (24) is sewn and fixed to the surface of the front-side elastic holding layer (16) and the back-side elastic holding layer (17), and the front-side elastic holding layer is interposed via the metal wire (24). (16) and the back side elastic retaining layer (17) are energized,
With one lead (2) as an insulating lead (2A) and the light emitting diode (1) that insulates the penetration part of the surface side elastic holding layer (16) attached, the insulating lead (2A) is held elastically on the surface side Insert the other lead (2) into the front-side elastic holding layer (16) without passing through the layer (16) and electrically connecting to the front-side elastic holding layer (16). The power supply for a light-emitting diode according to claim 13, wherein the light-emitting diode is inserted into the light-emitting diode (1) and caused to emit light by the front-side elastic holding layer (16) and the back-side elastic holding layer (17). Feeding device. A power supply device for light emitting diodes connected in a state where the light emitting diode (1) is electrically connected,
The front-side elastic holding layer (16) and the back-side elastic holding layer that can hold the connecting portion (5) connecting the lead (2) of the light-emitting diode (1) by inserting the lead (2) of the light-emitting diode (1). As (17), the front side elastic holding layer (16) and the back side elastic holding layer (17) that can be inserted and held through the lead (2) of the light emitting diode (1), the insulating layer ( 18), the front-side elastic holding layer (16) and the back-side elastic holding layer (17) are a synthetic resin foam or rubber-like elastic body containing a conductive material, and are inserted through here. It has conductivity that can be electrically connected to the lead (2) of the light emitting diode (1)
Further, a metal wire (24) is sewn and fixed to the surface of the front-side elastic holding layer (16) and the back-side elastic holding layer (17), and the front-side elastic holding layer is interposed via the metal wire (24). (16) and the back side elastic retaining layer (17) are energized,
With one lead (2) as an insulating lead (2A) and the light emitting diode (1) that insulates the penetration part of the surface side elastic holding layer (16) attached, the insulating lead (2A) is held elastically on the surface side Insert the other lead (2) into the front-side elastic holding layer (16) without passing through the layer (16) and electrically connecting to the front-side elastic holding layer (16). The power supply for a light-emitting diode according to claim 13, wherein the light-emitting diode is inserted into the light-emitting diode (1) and caused to emit light by the front-side elastic holding layer (16) and the back-side elastic holding layer (17). Feeding device.   The conductive material is a conductive paint, and the conductive paint is applied to a synthetic resin foam or rubber-like elastic body to form a front-side elastic holding layer (16) and a back-side elastic holding layer (17). , 19 is a power supply device for a light-emitting diode.   The distance (D) between the metal wire (24) disposed on the front surface side elastic retaining layer (16) and the metal wire (24) disposed on the back surface side elastic retaining layer (17) is determined by the distance of the light emitting diode (1). 20. The power supply device for a light emitting diode according to claim 17, wherein the power supply device is larger than a distance (d) between the pair of leads (2).   A surface layer (21) made of silicon rubber is provided on one or both surfaces of the front-side elastic holding layer (16) and the back-side elastic holding layer (17), and the surface-side elastic holding layer is formed by the surface layer (21). The power supply device for a light-emitting diode according to any one of claims 16 to 21, wherein (16) and the surface of the back-side elastic holding layer (17) are insulated.   An auxiliary electrode (27) for supplying power to the connecting portion (5) is provided, and the auxiliary electrode (27) is connected to the connecting portion (5) so as to energize the connecting portion (5) from the auxiliary electrode (27). The power supply device for a light emitting diode according to claim 13. A conductive board that can form a conductive layer of a power supply device for a light emitting diode, and is made of a synthetic resin foam or rubber-like elastic body that contains a conductive material almost uniformly on the entire surface. A conductive board characterized in that a current capable of lighting 1) can be applied at an arbitrary position of the conductive board.

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