JP2014089934A - Lamp device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lamp device capable of reducing the load to a socket and a lamp when a base type lamp is attached to a lamp holder.SOLUTION: A lamp device 100 includes: an LED lamp 1 having an LED substrate 11 on which LEDs 15 are mounted, a light source holding part 20 for holding the LED substrate 11 by placing it on a surface thereof, and a cylindrical part 30 extended from a rear surface of the light source holding part 20 and having a base 3 on a terminal end 30B; and a lamp holder 110 having a cylindrical holder part 111 into which the cylindrical part 30 of the LED lamp 1 is inserted from an end opening 115. A self-weight center of gravity position X of the LED lamp 1 is provided at a position nearer the base 3 than a position on which an end 114 of the holder part 111 is positioned when the LED lamp 1 is attached to the lamp holder 110.

Description

  The present invention relates to a lamp device including a cap lamp using a light emitting element such as an LED (Light Emitting Diode) or an organic EL (Electro Luminescence) as a light source, and a lamp holder to which the lamp is mounted.

  In recent years, with the increase in output and cost of LEDs, which are a kind of semiconductor light-emitting elements, cap-type LED lamps that can be used as an alternative to light bulbs have become widespread. In general, this type of LED lamp has a plurality of LEDs mounted on the surface of a flat LED substrate, and leads that supply electricity to the plurality of LEDs are passed through the inside of a cylindrical portion that extends from the back side of the LED substrate. It connects with the nozzle | cap | die provided in the terminal end of the cylindrical part (for example, refer patent document 1, patent document 2, and patent document 3).

JP 2010-010134 A JP 2009-206104 A JP 2011-60754 A

By the way, the LED lamp becomes heavier due to the heat dissipation structure that dissipates the heat generated by the LED as the output increases. In a lamp device in which an LED lamp is mounted on a socket arranged inside the lamp holder, the load on the base of the LED lamp and the socket of the lamp holder is increased. In particular, when the lamp device is used to illuminate an illumination target such as a signboard, for example, vibration of a car traveling on a road is applied, and the effect accumulates in the socket or base, resulting in damage to the socket or base. There is.
The present invention has been made in view of the above-described circumstances, and an object thereof is to provide a lamp device that can reduce a load on a socket and a base when a base-type lamp is mounted on a lamp holder. To do.

  In order to achieve the above object, the present invention provides a substrate on which a light emitting element is mounted, a light source holding unit for placing and holding the substrate on the surface, and a base extending from the back surface of the light source holding unit. In a lamp device comprising: a lamp having a cylindrical portion formed therein; and a lamp holder having a cylindrical holder portion into which the cylindrical portion of the lamp is inserted from a front end opening. When the lamp is mounted on the lamp holder, the lamp is provided on the base side from the position where the tip of the holder portion is located.

  According to the present invention, in the lamp device described above, a back surface of the light source holding portion is in contact with and closed by a tip opening of the lamp holder.

  In the lamp device according to the present invention, a plurality of heat radiation fins extending along an outer peripheral surface of the holder portion of the lamp holder are provided on the back surface of the light source holding portion.

  According to the present invention, in the lamp device, a seal member that is pressed by a back surface of a light source holding portion of the lamp is provided at a front end opening of the lamp holder.

  According to the present invention, in the lamp device described above, a power supply unit that generates direct-current power for lighting a light emitting element of the lamp is provided separately from the lamp.

  According to the present invention, since the center of gravity of the lamp is provided on the base side from the position where the tip of the holder portion is located when the lamp is mounted on the lamp holder, the load of the lamp and the socket of the lamp holder, It can be received not only at the lamp base but also at the tip position of the holder portion of the lamp holder, and the load on the socket and the base can be reduced.

It is a schematic diagram which shows the illuminating device provided with the LED lamp which concerns on embodiment of this invention. It is a figure which shows the gravity center of an LED lamp. It is sectional drawing of an LED lamp and a lamp holder. It is a top perspective view of an LED lamp. It is a bottom perspective view of an LED lamp. It is a disassembled perspective view of an LED lamp. (A) is sectional drawing of an LED lamp, (B) is the B section enlarged view in a figure. It is a top view of an LED lamp. It is a figure which shows the arrangement | positioning relationship between a globe attachment part and LED. It is a disassembled perspective view of a light source holding part and a cylindrical part. It is a figure which shows the structure of a holder part, (A) is a perspective view which shows the structure of a holder part, (B) is a front perspective view which shows the state which supported the electric circuit board in the holder part, (C) is a holder part It is a back perspective view which shows the state which supported the electric circuit board. It is a circuit diagram of an electric circuit board.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
In the following embodiments, an LED lamp having an LED as a light source is exemplified as a lamp having a light emitting element as a light source. However, the present invention is not limited to this, and other light emission such as an organic EL, for example. The present invention can also be applied to a lamp having an element as a light source.
FIG. 1 is a diagram showing a lamp device 100 including an LED lamp 1 according to the present embodiment.
A lamp device 100 shown in the figure is an outdoor installation type lighting fixture used for outdoor signboard illumination and the like, and includes an LED lamp 1, a lamp holder 110 to which the LED lamp 1 is mounted, and a power supply line to the lamp holder 110. And a power supply unit 101 connected at 102.

The lamp holder 110 is a holder to which an existing light bulb can be mounted. The LED lamp 1 is configured to have substantially the same shape and optical characteristics as the existing light bulb, and is mounted on the lamp holder 110 instead of the existing light bulb. Can be used. A glove (cover) 12 is attached to the tip of the LED lamp 1. The globe 12 is formed using, for example, glass or resin whose surface is polished (frosted), and has light diffusibility. Light emitted from the LED lamp 1 is diffused and emitted by the globe 12. The LED lamp 1 is provided with a plurality of radiating fins 25 extending along the outer peripheral surface of the lamp holder 110.
The lamp holder 110 includes a cylindrical holder housing (holder portion) 111, and an end portion 112 of the holder housing 111 is provided with an arm attachment portion 113 to which a support arm (not shown) is rotatably attached. ing.

  The power supply unit 101 accommodates a power supply (power converter) that generates a direct current for lighting the LED 15 of the LED lamp 1 and a power supply board (not shown) on which a drive circuit is mounted. As described above, the LED lamp 1 of the present embodiment includes the power supply unit 101 that houses the power supply board as a separate body. When using an existing light bulb such as a mercury lamp in the lamp holder 110, it is necessary to provide a ballast separate from the light bulb. When the LED lamp 1 is mounted on the lamp holder 110 instead of the existing light bulb, the power supply unit 101 can be replaced with a ballast. According to this configuration, since the power supply unit 101 including the power supply board for lighting the LED 15 is provided separately from the LED lamp 1, the LED lamp 1 can be reduced in weight.

As shown in FIG. 2, the LED lamp 1 is configured such that its own weight center position X is located in the heat radiation fin 25 in the lamp optical axis direction. A tip opening 115 into which the LED lamp 1 is inserted is provided at the tip 114 of the holder housing 111. The tip opening 115 of the holder housing 111 is abutted against the LED lamp 1 when the LED lamp 1 is mounted, and is closed. Further, a waterproof packing (seal member) 116 is provided at the tip opening 115, and the waterproof packing 116 is sandwiched between the LED lamp 1 and water can be reliably prevented from entering from the edge of the opening. . Thereby, the lamp device 100 can be suitably used by being installed in a place that is affected by rainwater outdoors or the like.
The self-weight center position X of the LED lamp 1 is higher than the position where the tip opening 115 of the holder housing 111 abuts the LED lamp 1 when the LED lamp 1 is mounted on the lamp holder 110 as described above. It is configured to be located inside the body 111.

As shown in FIG. 3, a socket (not shown) into which the base 3 of the LED lamp 1 is screwed is disposed inside the holder housing 111. Although not shown, the socket is connected to a power supply line 102 that is drawn from outside and supplies power via the power supply unit 101, and power is supplied from the base 3 to the LED lamp 1.
According to these configurations, the lamp holder 110 can support the LED lamp 1 at two locations: a socket into which the base 3 is screwed and a tip opening 115 of the holder housing 111 that contacts the LED lamp 1. Therefore, the strength for holding the LED lamp 1 can be improved. In addition, since the center X of the weight of the LED lamp 1 is located inside the holder housing 111, the LED lamp 1 can be supported also at the position of the front end opening 115 of the holder housing 111, and the LED holder 110 The strength against vibration when the lamp 1 is mounted can be improved.
Further, the LED lamp 1 is formed so that the length of the portion accommodated inside the holder housing 111 is longer than the length of the exposed portion outside the holder housing 111 in the optical axis direction. Since the LED lamp 1 is supported at the position of the tip 114 of the holder housing 111 and is formed with a short length exposed to the outside of the holder housing 111, the strength against vibration is improved.

Next, the configuration of the LED lamp 1 will be described. 4 is a top perspective view of the LED lamp 1, FIG. 5 is a bottom perspective view of the LED lamp 1, FIG. 6 is an exploded perspective view of the LED lamp 1, and FIG. 7 is a cross-sectional view of the LED lamp 1. .
As shown in FIGS. 4 to 7, the LED lamp 1 includes a light emitting portion 10, a cylindrical portion 30 that extends downward and perpendicular to the light emitting portion 10, and has a base 3 provided at a terminal end 30B. And a plurality of heat dissipating fins 25 provided on the back surface of the portion 10.

The light emitting unit 10 emits light upward from substantially the entire upper surface 10A, and includes a globe 12 formed in a circular shape in a top view as shown in FIG. As shown in FIG. 8, the light emitting unit 10 includes a plurality of LEDs 15 that are light sources, an LED substrate (substrate) 11 on which these LEDs 15 are mounted, a globe 12, and a light source holding unit that holds the LED substrate 11 on which the LEDs 15 are mounted. 20.
The surface of the globe 12 on which a light beam in the radiation range of the LED 15 as a light source enters is formed with a constant curvature. As shown in FIG. 4, the globe 12 is provided with a screwing portion 13 for screwing a screw 41 for fixing the globe 12 to the light source holding portion 20. The screwing portion 13 is formed by denting a plurality of locations of the edge portion 12 </ b> A of the globe 12 toward the center of the globe 12. In the present embodiment, four screwing portions 13 are formed at equal intervals in the circumferential direction of the globe 12.

As shown in FIG. 9, the screwing portion 13 is provided at a location outside the radiation range α of the LED 15. More specifically, the screwing portion 13 is provided at a location outside the radiation range α where the light emitted from the LED 15 is half the maximum luminous intensity from the optical axis C of the LED 15 where the light emitted from the LED 15 has the maximum luminous intensity. It is done. In the present embodiment, the light intensity of the light emitted from the LED 15 is a half beam angle that is twice the angle between the light intensity direction at which the light intensity is half the maximum light intensity and the optical axis C. β is 120 degrees. And the screwing part 13 is provided in the location remove | deviated from 1/2 beam angle (beta) of LED15. That is, the surface of the globe 12 on which a light beam in the range of at least a half beam angle β of the LED 15 is incident is formed with a constant curvature.
In the position where the screwing portion 13 is provided, the surface of the globe 12 on which the light beam enters cannot be made to have a constant curvature, which may affect the light distribution of the LED 15, but according to this configuration, Since the screwing portion 13 is provided at a position deviating from the half beam angle β, the influence of color unevenness, illuminance unevenness and the like due to the screwing portion 13 can be reduced.

  As shown in FIG. 6, the light source holding unit 20 is a substantially circular member having a diameter larger than that of the cylindrical unit 30 when viewed from above. The light source holding part 20 is formed of a metal having heat dissipation properties. In the present embodiment, the light source holding unit 20 is formed by aluminum die casting. The light source holding part 20 includes a placement part 21 on which the LED substrate 11 is placed on the surface, and the radiation fins 25 are provided on the back surface of the placement part 21. The heat radiation fin 25 is formed integrally with the light source holding unit 20. Thus, by integrally forming the radiation fin 25 on the light source holding unit 20, the thermal resistance between the mounting portion 21 on which the LED substrate 11 is placed and the radiation fin 25 is suppressed, High heat dissipation performance can be obtained by increasing the amount of heat transfer.

  Each of the heat radiation fins 25 is a thin plate having substantially the same shape, and a large number of radiating fins 25 are arranged substantially radially about the axis of the cylindrical portion 30 when viewed from the back surface 20B of the light source holding portion 20 and are erected on the back surface 20B of the light source holding portion 20. Has been. Further, the radiation fins 25 are formed so as to protrude in the radial direction of the light source holding unit 20 outside the outer periphery of the placement unit 21. Further, the heat radiating fins 25 extend toward the base 3 along the axis of the cylindrical portion 30. The light emitting unit 10 can efficiently dissipate heat generated by the LED substrate 11 mounted on the mounting unit 21 of the light source holding unit 20 by using the heat radiation fins 25. Moreover, since the radiation fin 25 is erected on the back surface 20B of the light source holding part 20 and extends in the direction of the base 3 along the axis of the cylindrical part 30, as described above, the weight center position X of the LED lamp 1 is When the LED lamp 1 is mounted on the lamp holder 110, the LED lamp 1 can be configured to be positioned inside the holder housing 111. The heat radiation fin 25 is configured such that a gap S is formed between the LED lamp 1 and the outer peripheral surface of the holder housing 111 when the LED lamp 1 is mounted on the lamp holder 110 as shown in FIG. According to this configuration, the cooling performance of the radiating fins 25 can be improved without the flow of air flowing between the adjacent radiating fins 25 being hindered by the holder housing 111.

The LED 15 is formed, for example, by packaging an LED element. In this embodiment, a white LED is used as the LED 15. Needless to say, an LED having a light emitting color other than white may be used for the LED 15.
The LED substrate 11 is formed in a substantially cross shape (see FIG. 8), a plurality of LEDs 15 are mounted on the front surface, and the back surface is brought into contact with the mounting portion 21 of the light source holding unit 20, so It is fixed by screws 42 with screws. The LED board 11 is provided with a wiring hole 11 </ b> A through which a lead wire (not shown) for supplying power is passed substantially at the center. A lead wire drawn out from the wiring hole 11A to the surface side of the LED substrate 11 is electrically connected to an LED light emitting circuit 70 (see FIG. 12) including four LEDs 15.

  A plurality of fixing portions 29 for fixing the globe 12 covering the LED substrate 11 with screws 41 are provided on the surface 20A of the light source holding portion 20 in the vicinity of the outer peripheral edge of the mounting portion 21 at equal intervals in the circumferential direction. . The fixing portion 29 is provided at a position corresponding to the screwing portion 13 provided on the globe 12. Further, the surface 20 </ b> A of the light source holding part 20 is provided with a groove 26 provided along the outer peripheral edge of the mounting part 21 provided inside the fixing part 29 so as to avoid the fixing part 29. A waterproof member 27 that waterproofs the light emitting unit 10 is fitted into the groove 26. The waterproof member 27 is formed in advance in a shape that matches the shape of the groove 26 by an elastic member such as silicon, and is fitted into the groove 26. The globe 12 is provided with a flange 14 that abuts against a waterproof member 27 fitted in the groove 26. The flange 14 is formed integrally with the globe 12 along the outer periphery of the globe 12. Since the screwing portion 13 described above is formed inside the outer periphery of the globe 12, the outer dimensions of the globe 12 can be reduced as compared with the case where the flange 14 is screwed to the light source holding portion 20.

  The waterproof member 27 is mounted on the flange 14 of the globe 12 as the screw 41 inserted through the screwing portion 13 is screwed into a boss 29A provided on the fixing portion 29 of the surface 20A of the light source holding portion 20. It is crushed and pinched with the mounting part 21. As described above, the mounting structure of the globe 12 to the mounting portion 21 is a screw structure, and the waterproofing member 27 is sandwiched between the flange 14 of the globe 12 and the mounting portion 21, thereby making the light emitting portion 10 waterproof. Has been enhanced. In particular, by sandwiching the waterproof member 27 between the flange 14 and the placement portion 21, the flange 14 of the flat planar globe 12 is brought into contact with the vicinity of the periphery of the flat planar placement portion 21. Even if the globe 12 is fixed to the light source holding part 20, the water such as rain water does not enter the light emitting part 10 from between the contact surfaces between the flange 14 and the light source holding part 20, and the LED lamp 1 is It can be a waterproof structure.

  The screw hole provided in the screwing portion 13 of the globe 12 is formed to have a size that allows insertion of the boss 29A provided in the fixing portion 29 provided on the surface 20A of the light source holding portion 20. According to this configuration, when the globe 12 is fixed to the light source holding unit 20, the boss 29 </ b> A of the light source holding unit 20 is inserted into the screw hole of the globe 12, and the globe 12 is fixed to the light source holding unit 20 in a predetermined manner. Since it can be positioned, the workability of attaching the globe 12 to the light source holding part 20 is improved.

  The LED substrate 11 has an outer peripheral edge formed in a shape along the shape of the groove 26 provided in the mounting portion 21. That is, the LED substrate 11 is formed in a substantially cross shape in which a portion corresponding to a part of the outer periphery of the flat disk, in particular, the fixing portion 29 provided on the surface 20A of the light source holding portion 20 is cut out (see FIG. 8). The LED substrate 11 is mounted on the mounting portion 21 and is fixed to the mounting portion 21 with screws 42 inside the groove 26. Further, since the LED substrate 11 is made of a metal material such as an aluminum material having a high thermal conductivity, the heat generated by the LED 15 is efficiently transferred to the mounting portion 21 of the light source holding portion 20 and radiated from the radiation fins 25. Can be made. A plurality of LEDs 15 are mounted concentrically on the mounting surface, which is the surface of the LED substrate 11, and in particular, mounted near the outer periphery of the LED substrate 11. In particular, the LED substrate 11 is disposed at a position that is farthest from the center of the LED substrate 11 in the radial direction, in a position that avoids the position where the globe 12 is screwed to the light source holding unit 20 by the screw 41. Thereby, the irradiation range of the LED lamp 1 can be widened.

The cylindrical portion 30 is provided with a base 3 attached to the end 30B. The cylindrical portion 30 is formed by using an insulating resin material such as polycarbonate. Thereby, insulation with the cylindrical part 30 and the nozzle | cap | die 3 is achieved. According to this structure, weight reduction of the cylindrical part 30 can be achieved by shape | molding the cylindrical part 30 using a resin material.
In addition, the structure which forms the member formed from the metal which has heat conductivity, and the member formed from the material which has insulation may be sufficient as the cylindrical part 30.

The cylindrical portion 30 includes a flange portion 31 at the tip 30 </ b> A fixed to the light source holding portion 20. The flange portion 31 is formed integrally with the cylindrical portion 30 by resin molding. According to this structure, since the cylindrical part 30 was integrally molded using the resin material, the cylindrical part 30 can be reduced in weight.
Inside the cylindrical portion 30, the electric circuit board 50 is held and stored in a board holder 55. The electric circuit board 50 is electrically connected to the base 3 through a lead wire (not shown) at the end on the base 3 side.

  The base 3 is provided with a cylindrical shell 6 that is threaded into a socket (for example, E26 type socket) of an existing lamp holder 110 and an insulating portion 4 at the top of the end of the shell 6. The shell 6 and the eyelet 5 are configured to have a shape and dimension that can be attached to an existing socket. Thereby, the said LED lamp 1 can be mounted | worn with the socket of the said lamp holder 110 which mounts and uses the existing socket and the existing light bulb, and can use it as an alternative of the existing light bulb.

By the way, although the light source holding part 20 can obtain a high heat dissipation performance by using a metal material such as aluminum, the weight increases, so that the strength of the connection part with the resin cylindrical part 30 is insufficient. There is also. Therefore, in the LED lamp 1 of the present embodiment, the fixing structure between the light source holding part 20 and the cylindrical part 30 is a fixing structure for firmly fixing the light source holding part 20 and the cylindrical part 30.
The fixing structure between the light source holding part 20 and the cylindrical part 30 will be described in detail. As shown in FIGS. 6 and 10, the light source holding part 20 is a recess formed by recessing a substantially central part of the surface 20A. 22 is provided. In addition, a through hole 23 penetrating the front and back is provided in the bottom portion 22 </ b> A of the concave portion 22 at substantially the center of the light source holding portion 20. The through hole 23 is formed to have a diameter that allows the cylindrical portion 30 to pass therethrough. The recess 22 is formed in a truncated cone shape whose diameter decreases toward the bottom 22A. A plurality of thin plate-like fins 28 are erected on the side surface 22 </ b> B of the recess 22. The fin 28 is configured such that the upper end 28 </ b> A comes into contact with the back surface of the LED substrate 11 when the LED substrate 11 is placed on the placement portion 21 of the light source holding portion 20. In particular, the fin 28 is desirably provided in the vicinity of a position where the LED 15 mounted on the LED substrate 11 mounted on the mounting unit 21 of the light source holding unit 20 is disposed. According to this configuration, the light source holding part 20 reduces the area of the mounting part 21 that contacts the LED substrate 11 to form the concave part 22, thereby reducing the weight of the light source holding part 20, and from the fins 28. The heat generated by the LED 15 can be transferred to the light source holding unit 20 via the LED substrate 11 and efficiently radiated by the radiation fins 25.

On the surface of the bottom 22A of the recess 22, four bosses 24 for screwing the cylindrical portion 30 to the light source holding portion 20 are provided at equal intervals.
The cylindrical part 30 is inserted into the through hole 23 of the light source holding part 20 from the surface side of the light source holding part 20. A disc-shaped flange portion 31 is provided in a collar shape at the tip 30 </ b> A of the cylindrical portion 30. The flange portion 31 is integrally formed with the tubular portion 30 by resin molding. The outer diameter of the flange portion 31 is formed to be substantially the same as or slightly smaller than the outer diameter of the bottom portion 22 </ b> A of the light source holding portion 20. Moreover, the structure which the several rib 31A is standingly arranged in the surface of the flange part 31, and the intensity | strength of the flange part 31 is improved by the said rib 31A may be sufficient. When the cylindrical portion 30 is inserted into the through hole 23 from the surface side of the light source holding portion 20, the flange portion 31 of the cylindrical portion 30 is hooked on the bottom portion 22 </ b> A along the edge of the through hole 23.

  The flange portion 31 is provided with a boss hole 33 penetrating the front and back. The boss hole 33 is provided at a position corresponding to the boss 24 provided in the bottom 22 </ b> A of the recess 22. When the cylindrical part 30 is inserted into the through hole 23 of the light source holding part 20, the boss 24 is inserted into the boss hole 33. That is, the cylindrical portion 30 is inserted into the through hole 23 of the light source holding portion 20, the flange portion 31 is hooked on the bottom portion 22 </ b> A of the light source holding portion 20, and further, the bottom portion 22 </ b> A is engaged with the boss hole 33 of the flange portion 31. The boss 24 is inserted and locked to the light source holding part 20. Then, as shown in FIG. 10, the cylindrical portion 30 is inserted into the boss hole 33 and fixed to the light source holding portion 20 by a screw 43 that is screwed into the boss 24. Note that a washer 44 may be sandwiched between the screw 43 and the boss 24.

In the present embodiment, the light source holding unit 20 is made of metal, and thus is heavy. The cylindrical part 30 fixed to the light source holding part 20 with a screw 43 is formed of a resin whose strength tends to be lower than that of metal. Therefore, the cylindrical portion 30 is likely to be subjected to a load due to the weight of the light source holding portion 20 in the boss hole 33 into which the screw 43 is inserted. Moreover, the cylindrical part 30 shape | molded with the resin material may deteriorate by external factors, such as an ultraviolet-ray and a vibration, and intensity | strength may fall. Due to these factors, the flange portion 31 may be cracked from the boss hole 33. According to the configuration of the present application, the cylindrical portion 30 of the through hole 23 of the light source holding portion 20 is inserted, and the flange portion 31 of the cylindrical portion 30 is hooked on the bottom portion 22 </ b> A of the edge portion of the through hole 23. Since 30 is fixed to the light source holding part 20, even if the flange part 31 is cracked due to deterioration, the light source holding part 20 is not detached from the cylindrical part 30, and the connection function is not lost. .
Further, since the flange portion 31 of the cylindrical portion 30 is fixed to the bottom portion 22A of the concave portion 22 provided on the surface 20A of the light source holding portion 20, the flange portion 31 is placed on the placement portion 21 of the light source holding portion 20. The touched LED substrate 11 is not directly touched. Thereby, it can prevent that the flange part 31 shape | molded by the resin material becomes the thermal resistance of the LED board 11. FIG. Moreover, since the cylindrical part 30 can be arrange | positioned away from the LED board 11, the cylindrical part 30 formed from the resin material touches directly the LED board 11 which becomes high temperature with the heat | fever which LED15 emits, a deformation | transformation, etc. It is possible to prevent problems such as deterioration.

  As shown in FIG. 5, the back surface 20 </ b> B of the light source holding unit 20 is formed in a shape along the concave portion 22 formed on the front surface 20 </ b> A of the light source holding unit 20. The back surface 20 </ b> B is provided with an extending portion 37 that is formed along the edge portion of the through hole 23 and extends from the bottom portion 22 </ b> A along the cylindrical portion 30 in a shaft shape. Further, a bottomed end portion 38 of the boss 24 formed on the surface of the bottom portion 22A protrudes from the back surface of the bottom portion 22A. When the LED lamp 1 is mounted on the lamp holder 110 between the heat radiating fins 25 and the recesses 22 on the back surface 20B of the light source holding unit 20, a front end opening 115 of the holder housing 111 has a waterproof packing (not shown). A contact portion 36 is formed to be in contact with the seal member 116 therebetween. The abutting portion 36 is a surface substantially parallel to the mounting portion 21 of the light source holding portion 20, and the tip opening 115 to which the waterproof packing 116 is attached in advance abuts against the abutting portion 36, so that the inside of the lamp holder 110 is securely It is configured to be sealed.

As shown in FIG. 6, an O-ring 32 is attached to the tubular part 30 before the tubular part 30 is inserted into the through hole 23 of the light source holding part 20. When the cylindrical part 30 is inserted into the through hole 23 of the light source holding part 20, the O-ring 32 attached to the cylindrical part 30 has an extension part 37 extending from the edge part of the through hole 23, the cylindrical part 30, and It is sandwiched between and compressed. Thereby, it is possible to prevent water such as rainwater from entering the light emitting unit 10 from the gap between the through hole 23 and the cylindrical part 30.
According to these configurations, the LED lamp 1 includes a waterproof member 27 disposed between the light source holding unit 20 and the globe 12, and an O-ring disposed between the tubular unit 30 and the light source holding unit 20. 32 and a waterproof structure sealed with a base 3 attached to the end 30B of the cylindrical portion 30.
The LED substrate 11 and the globe 12 are fixed to the light source holding part 20 after fixing the cylindrical part 30 to the light source holding part 20. The base 3 is attached to the cylindrical portion 30 after fixing the cylindrical portion 30 to the light source holding portion 20.

As shown in FIG. 7, an electric circuit board 50 is accommodated inside the cylindrical portion 30. The electric circuit board 50 is held by the board holder 55 and inserted into the cylindrical portion 30. As shown in FIG. 11A, the substrate holder 55 includes a pair of sandwiching portions 59 that sandwich the electric circuit substrate 50 and a bridge portion 58 that spans between the pair of sandwiching portions 59. In the following description, the front and rear of the substrate holder 55 is based on the direction when the substrate holder 55 is viewed from the direction shown in FIG. The clamping part 59 and the bridge part 58 are integrally formed.
The clamping unit 59 includes a front support part 59A, a rear support part 59B, and a lower end support part 59C. As shown in FIGS. 11B and 11C, the electric circuit board 50 is slid between the front support part 59A and the rear support part 59B, and the lower end is placed on the lower support part 59C. , Held by the holder portion 57.

  As shown in FIG. 7A, the substrate holder 55 is inserted into the tubular portion 30 with the electric circuit board 50 being sandwiched between the sandwiching portions 59, and both end portions 58A of the bridge portion 58 are connected to the tubular portion 30. The flange portion 31 is hooked and locked. As shown in FIG. 7B, the substrate holder 55 is inserted into the screw hole 58B formed in the bridge portion 58 when the cylindrical portion 30 is fixed to the light source holding portion 20 with the screw 43. Then, together with the tubular portion 30, the light source holding portion 20 is fixed to the bottom portion 22 </ b> A by a screw 43.

  By the way, since LED15 has polarity, there exists a problem that it is not lighted when a positive electrode and a negative electrode are reversed and connected. For this reason, when the lamp device 100 is installed, it is necessary to locate the positive / negative electrode of the power supply line 102 that supplies the electric power via the power supply unit 101 to the LED lamp 1 via the base 3, which is inefficient. In this embodiment, the electric circuit board 50 is built in the LED lamp 1 in order to improve the efficiency of the installation work of the lamp device 100.

As shown in FIG. 12, a fuse 51 is connected to the electric circuit board 50 on the input side of the direct current input from the power supply unit 101 separately provided from the LED lamp 1 via the terminals 53 and 54. Note that the fuse 51 is attached to the electric circuit board 50 in order to prevent an accident from occurring when, for example, AC 200V or the like is connected to the lamp holder 110 instead of the power supply unit 101 by mistake.
The electric circuit board 50 includes a rectifier 52 on the downstream side of the fuse 51. The LED light emitting circuit 70 formed on the back surface of the LED substrate 11 is supplied with the power rectified by the rectifier 52. According to this configuration, since the LED lamp 1 includes the electric circuit board 50, the LED 15 can be connected regardless of which of the terminal 53 or the terminal 54 that is the input terminal of the LED lamp 1 is a positive terminal or a negative terminal. Can emit light. As a result, when the lamp device 100 is installed, the power supply line 102 that supplies power via the power supply unit 101 to the LED lamp 1 via the base 3 can be used without worrying about the positive / negative wiring. It is possible to connect to the socket inside, and to improve the efficiency of the installation work.

As described above, according to the embodiment to which the present invention is applied, the LED board 11 on which the LED 15 is mounted, the light source holding part 20 that places and holds the LED board 11 on the surface, and the light source holding part 20 An LED lamp 1 having a cylindrical portion 30 extending from the back surface and having a base 3 provided at the end 30B, and a lamp having a cylindrical holder portion 111 into which the cylindrical portion 30 of the LED lamp 1 is inserted from the front end opening 115. In the lamp device 100 including the holder 110, the self-weight center position X of the LED lamp 1 is set to be greater than the position where the tip 114 of the holder portion 111 is positioned when the LED lamp 1 is mounted on the lamp holder 110. Provided on the side.
According to this configuration, not only the socket provided inside the lamp holder 110 for the load of the LED lamp 1 and the base 3 of the LED lamp 1 but also the tip 114 of the holder housing 111 of the lamp holder 110 is located. It can be received even at the position, and the load on the socket and the base 3 can be reduced. Thereby, when the lamp device 100 is used for the purpose of illuminating an illumination target such as a signboard, the LED lamp 1 can be stably held by the lamp holder 110 even if vibration of a car traveling on a road is applied. .

  Further, according to the embodiment to which the present invention is applied, the back surface 20B of the light source holding part 20 abuts on the front end opening 115 of the lamp holder 110 and closes, so that water such as rainwater enters the holder housing 111. Can be prevented.

  Further, according to the embodiment to which the present invention is applied, the rear surface 20 </ b> B of the light source holding unit 20 is provided with the plurality of heat radiation fins 25 extending along the outer peripheral surface of the holder housing 111 of the lamp holder 110. Thereby, the heat of the LED substrate 11 on which the LEDs 15 held by the light source holding unit 20 are mounted can be efficiently radiated from the heat radiation fins 25.

  Further, according to the embodiment to which the present invention is applied, the front end opening 115 of the lamp holder 110 is provided with the waterproof packing 116 that is pressed by the back surface 20B of the light source holding part 20 of the LED lamp 1. Water such as rainwater can be reliably prevented from entering the holder housing 111 from the gap between the opening 115 and the back surface 20B of the light source holding part 20 of the LED lamp 1. Therefore, the lamp device 100 can have a waterproof structure, and the lamp device 100 can be suitably used in places that are affected by rainwater such as outdoors.

  Further, according to the embodiment to which the present invention is applied, the power supply unit 101 that generates DC power for lighting the LED 15 of the LED lamp 1 is provided separately from the lamp, so that the LED lamp 1 can be reduced in weight. The load on the socket of the lamp holder 110 and the base 3 of the LED lamp 1 can be reduced.

1 LED lamp (lamp)
3 Base 11 LED board (board)
15 LED (light emitting element)
DESCRIPTION OF SYMBOLS 20 Light source holding part 20B Back surface 25 Radiation fin 30 Cylindrical part 30B Termination 100 Lamp apparatus 101 Power supply unit 110 Lamp holder 111 Holder housing | casing (holder part)
114 tip 115 tip opening 116 waterproof packing (seal member)
X Weight center position

Claims (5)

A substrate having a light emitting element mounted thereon, a light source holding portion for mounting and holding the substrate on the surface, a lamp having a cylindrical portion extending from the back surface of the light source holding portion and provided with a base at the end, and a tip opening A lamp holder having a cylindrical holder part into which the cylindrical part of the lamp is inserted,
The lamp device according to claim 1, wherein the center of gravity of the lamp is provided closer to the base than a position where a tip of the holder portion is located when the lamp is mounted on the lamp holder.   The lamp device according to claim 1, wherein a rear surface of the light source holding part is in contact with and closed by a front end opening of the lamp holder.   The lamp device according to claim 1, wherein a plurality of heat radiating fins extending along an outer peripheral surface of the holder portion of the lamp holder are provided on the back surface of the light source holding portion.   The lamp device according to any one of claims 1 to 3, wherein a seal member that is pressed by a back surface of a light source holding portion of the lamp is provided at a front end opening of the lamp holder.   The lamp device according to any one of claims 1 to 4, wherein a power supply unit that generates direct-current power for lighting a light emitting element of the lamp is provided separately from the lamp.

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