JP2007273205A - Luminaire - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To radiate heat of an LED lamp by bringing the LED lamp into contact with the component of a luminaire to cause heat conduction from the contact part to the luminaire, and to facilitate mounting of the LED lamp. <P>SOLUTION: This luminaire 400 is equipped with a luminaire body 300, an LED lamp mounting fixture 100, and LED lamps 200. The LED lamp 200 is formed by disposing an LED 203 and a locking piece 208 on a substrate 202 in the shape of a circular flat plate. The LED lamp mounting fixture 100 takes shape of a hat, and has a locking plate 700 on its plane part 102 to lock the lock piece 208 of the LED lamp 200. When the base 205 of the LED lamp 200 is mounted to a connector 330 and the locking piece 208 of the LED lamp 200 is locked to the locking plate 700, the substrate 202 of the LED lamp 200 is brought into contact with the plane part 102 of the mounting fixture 100. Thereby, heat of the LED lamp 200 is radiated by being conducted to the lamp mounting fixture 100 and the luminare body 300. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a lighting fixture that radiates heat generated in a light emitting diode (hereinafter referred to as LED), for example.

Conventional lighting fixtures using an LED lamp as a light source have a shape similar to that of an incandescent light bulb for general lighting, and thus the LED lamp itself has a heat dissipation means and does not take heat dissipation measures on the side of the lighting fixture.
The LED lamp shown in Patent Document 1 is arranged between an LED arrangement surface on which a plurality of LEDs are arranged, a lens that covers at least the plurality of LEDs, a base that receives power supply, a light emitting diode arrangement surface, and the base. A heat radiating portion and a circuit housing portion. Moreover, the LED board is provided with the plurality of LEDs mounted on one surface of the LED arrangement surface and disposed so that the other surface is in contact with the heat radiating portion. The circuit housing portion includes an exterior body that connects the heat radiating portion and the base. The LED lamp is disclosed as further including a lighting circuit board.
As shown in this example, conventionally, a heat radiating portion is formed in the LED lamp itself, and heat is dissipated from the heat radiating portion.
However, this heat dissipation measure has a limit in the amount of heat dissipation since the LED lamp has a heat dissipation means.
JP 2005-286267 A JP 2005-38798 A

In order to efficiently release the heat generated in the LED lamp to the outside of the LED lamp, there is a limit to the amount of heat dissipation in the device of the LED lamp itself. That is, the heat radiation path from the LED lamp is “radiant heat conduction” and “convection heat conduction” from the light-transmitting bulb part of the LED lamp and the heat radiation part formed on the LED lamp, and the socket from the base that is a component of the LED lamp. There are three possible routes for “thermal conduction”. That is, the current heat dissipating destination to the lighting fixture by the “heat conduction” that is the third heat dissipating path is only the socket, and no other device is devised.
Therefore, heat conduction to a part other than the base of the lamp is necessary. However, when the shape of the LED lamp is similar to a conventional incandescent light bulb for general illumination, it is difficult to consider a heat dissipation measure by heat conduction to a part other than the base.
In addition, as a heat dissipation measure for an LED lamp without a base, Patent Document 2 discloses a heat dissipation measure by heat conduction performed by pressing a flat LED lamp against a socket.
However, this heat dissipation measure has a problem in terms of cost, such as the need for a separate part that serves as a pressing means.

  An object of the present invention is, for example, to bring an LED lamp into contact with a component of a lighting fixture and to dissipate heat of the LED lamp by heat conduction from the contact portion to the lighting fixture, and to facilitate the mounting of the LED lamp. With the goal.

  The lighting fixture of the present invention is a cylindrical body having a side surface, an end surface having a locking hole, and a locking plate formed to project from the end surface to a cylindrical inner side formed by the side surface and the end surface. Engaging the locking piece of the lamp having a light source, a flat plate on which the light source is arranged, and a locking piece protruding from the flat plate from the outside of the cylindrical body to the locking hole and the locking plate of the end surface. It is characterized by including a cylindrical body that stops.

  According to the present invention, for example, by bringing the LED lamp into contact with the end face of the cylindrical body, the heat generated by the LED lamp can be conducted to the cylindrical body and radiated from the end face and the side face. Moreover, an LED lamp can be attached to a cylindrical body by latching the latching piece of an LED lamp to the latching plate of a cylindrical body.

Embodiment 1 FIG.
FIG. 1 is a cross-sectional view of a lighting fixture 400 after the LED lamp 200 according to Embodiment 1 is attached.
FIG. 2 is a configuration diagram showing the inside of the LED lamp fixture 100 according to the first embodiment.
FIG. 3 is a perspective view of the locking plate 700 in the first embodiment.
FIG. 4 is a perspective view of LED lamp 200 in the first embodiment.
FIG. 5 is a cross-sectional view of the lighting fixture 400 before the LED lamp 200 according to Embodiment 1 is attached.
FIG. 6 is a cross-sectional view of lighting fixture 400 when LED lamp 200 in Embodiment 1 is attached.
FIG. 7 is a cross-sectional view of a locking portion when the LED lamp 200 according to Embodiment 1 is attached.
The lighting fixture 400 in Embodiment 1 is demonstrated below based on FIGS.

In FIG. 1, a lighting fixture 400 includes an LED lamp fixture 100 (tubular body), an LED lamp 200, and a fixture body 300, and is attached to a fixture mounting plate 310.
The lighting fixture 400 in Embodiment 1 is characterized by the LED lamp fixture 100 and the LED lamp 200.

In FIG. 2, the LED lamp fixture 100 (tubular body) has a side surface portion 101 (side surface) and a flat surface portion 102 (end surface), and forms a hollow cylindrical shape with one end open. Further, the LED lamp fixture 100 has a flange 104 (head) on the open end side to form a hat shape.
The side portion 101 is open at both ends to form a cylindrical shape or a pipe shape.
The flat surface portion 102 forms a disk shape and is positioned so as to close the open end of the side surface portion 101 on one open end side of the side surface portion 101. Further, the flat surface portion 102 has a through hole 106 at the center, and has a plurality of boring holes 108 (locking holes) around the through hole 106. Each daruma hole 108 (locking hole) has a large-diameter hole (large-diameter portion) and a small-diameter hole (small-diameter portion) to form a dharma-shaped hole. Further, the plurality of daruma holes 108 form a circle around the through-hole 106, and each daruma hole 108 has a large-diameter portion and a small-diameter portion positioned in the same circumferential direction. That is, the large-diameter portion of the other daruma hole 108 is positioned on the small-diameter portion side of the adjacent daruma hole 108. Further, the flat portion 102 is attached to the small diameter portion side of each daruma hole 108 with a Z-shaped locking plate 700 protruding inward. Each locking plate 700 has a slit 706 that is open at one end, the closed end side of the slit 706 is positioned on the small diameter side of the scoop hole 108, and the open end side of the slit 706 is on the large diameter side of the scoop hole 108. Position.
The flange 104 is positioned to extend (protrude) outward from the side surface portion 101 on the other end side of the side surface portion 101 opened on the side where the flat surface portion 102 is not positioned. The flange 104 forms a ring shape or a donut shape.

In FIG. 3, the locking plate 700 includes a locking surface 701 that locks the LED lamp 200, a vertical surface 704 that gives the locking surface 701 a height, and a coupling surface 705 that is coupled to the flat portion 102 of the LED lamp fixture 100. Thus, a Z shape and a step shape are formed.
In addition, the locking plate 700 has a slit 706 whose one end is open on the locking surface 701, a flat surface portion 707, and an inclined portion 702 extending obliquely downward on the open end side (first end side) of the slit 706. And a recess 703 having a step 708 with respect to the flat surface portion 707 on the closed end side (second end portion side) of the slit 706.

In FIG. 4, the LED lamp 200 includes a pin-type base 205, a substrate 202 (flat plate), an LED 203 (light source), and a locking piece 208 that is locked to the locking plate 700 of the LED lamp fixture 100.
The pin-type base 205 is formed so as to protrude from the substrate 202 and is coupled to the connector 330 (see FIG. 1) to electrically connect the LED 203.
The substrate 202 is formed in a circular flat plate shape, and a pin-type base 205, an LED 203 (see FIG. 1), and a locking piece 208 are disposed.
A plurality of LEDs 203 are light sources of the lighting fixture 400 arranged on the substrate 202.
The number of the locking pieces 208 is the same as the number of the dart holes 108 (see FIG. 2) of the LED lamp fixture 100 at the periphery of the substrate 202.

  In FIG. 5, the instrument main body 300 has a side surface portion 301 and a flat surface portion 302, and forms a cylindrical shape like the LED lamp mounting tool 100. Furthermore, the instrument main body 300 has a through hole 304 at the center of the flat portion 302 in the same manner as the LED lamp fixture 100, and the connector 330 connected to the electric cord 305 is taken out from the through hole 304. The connector 330 is mechanically and electrically connected to the pin type cap 205 of the LED lamp 200 and supplies power to the LED lamp 200. In addition, the instrument main body 300 has an attachment portion 303 that extends inward on the side where the flat portion 302 is not located.

As shown in FIG. 5, the instrument body 300 is attached to an instrument mounting plate 310 such as a ceiling material at a mounting portion 303 with screws 311 such as wood screws and metal screws, or other mounting means such as rivets, adhesive tapes, and adhesives. Fixed.
The LED lamp fixture 100 is fixed to the flat surface portion 302 of the instrument main body 300 by means of attachment means such as screws, rivets, adhesive tape, and adhesive at the flange 104.
Then, the LED 330 can be easily electrically connected by setting the connector 330 to the outside through the through hole 106 from the LED lamp fixture 100 and fitting the pin-type base 205 into the connector 330.

  Further, after inserting the connector 330 fitted with the pin-type base 205 into the through-hole 106 and inserting the locking piece 208 into the saddle hole 108, the LED lamp 200 is rotated as shown in FIG. The locking piece 208 of the LED lamp 200 is locked to the dart hole 108 and the locking plate 700 of the LED lamp fixture 100. Thereby, mechanical connection of the LED lamp 200 can be performed easily.

When the LED lamp 200 is rotated, the locking piece 208 of the LED lamp 200 is locked to a locking plate 700 attached to the LED lamp mounting tool 100 as shown in FIG.
First, the locking piece 208 moves in the direction of the locking plate 700 (a in FIG. 7A).
Next, the locking piece 208 is guided to the locking surface 701 along the inclination of the inclined portion 702 of the locking plate 700 (b in FIG. 7).
Then, the locking piece 208 passes through the flat portion 707 of the locking plate 700 and is locked to the recess 703 (the lower diagram in FIG. 7).
The locking plate 700 can hold the locking piece 208 by a step 708 formed by the flat portion 707 and the recess 703. That is, the locking plate 700 can prevent the locking piece 208 from rotating backward and coming off the locking plate 700.

  The locking plate 700 is formed of an elastic member, and the locking piece 208 of the LED lamp 200 is lifted upward by an elastic action. That is, the locking plate 700 attracts the substrate 202 of the LED lamp 200 to the flat portion 102 of the LED lamp fixture 100, and improves the adhesion between the LED lamp 200 and the LED lamp fixture 100.

  Then, by locking the locking piece 208 to the locking plate 700 and mounting the LED lamp 200 to the LED lamp mounting tool 100, as shown in FIG. The flat surface portion 102 is contacted from the outside of the LED lamp fixture 100. A contact portion between the substrate 202 and the flat portion 102 is referred to as a contact portion 103.

  At this time, the heat generated from the LED 203 is thermally conducted from the substrate 202 to the flat part 102 of the LED lamp fixture 100 in the contact part 103, and the heat transferred to the flat part 102 is conducted to the side part 101 and the flange 104, and the flange The heat transferred to 104 conducts heat to the instrument body 300.

The heat generated by the LED 203 and conducted to the LED lamp fixture 100 and the fixture body 300 is radiated from the side surface portion 301 and the plane portion 302 of the fixture body 300, the side surface portion 101 and the plane portion 102 of the LED lamp fixture 100, and The convection is dissipated into the air inside and outside the fixture body 300 and the LED lamp fixture 100.
Further, the heat generated by the LED 203 is also radiated to the substrate 202 and dissipated into the air.

The lighting fixture 400 according to Embodiment 1 conducts heat generated in the LED 203 from other than the base 205 due to the contact between the member (substrate 202) other than the base 205 of the LED lamp 200 and the LED lamp fixture 100. be able to. Thereby, the lighting fixture 400 can dissipate more heat generated by the LED 203.
Moreover, since the LED lamp fixture 100 has the side surface portion 101 to increase the area in contact with the outside air, more heat generated by the LED 203 can be dissipated.
Moreover, since the LED lamp fixture 100 is hollow, the heat generated by the LED 203 can be radiated not only to the outside of the LED lamp fixture 100 but also to the inside.
Moreover, since the LED lamp fixture 100 can conduct the heat generated by the LED 203 to the instrument body 300 by contacting the instrument body 300, the heat generated by the LED 203 can also be dissipated from the instrument body 300.
Moreover, since the board | substrate 202 which arrange | positions LED203 forms the flat form in the LED lamp 200, the area which contacts external air is widened, Therefore The heat | fever generate | occur | produced by LED203 can be thermally radiated from LED lamp 200 itself efficiently.
Further, since the LED lamp fixture 100 has an elastic member locking plate 700 to improve the adhesion between the LED lamp 200 and the LED lamp fixture 100, heat from the LED lamp 200 to the LED lamp fixture 100 is increased. Conductivity can be increased. And the LED lamp fixture 100 can improve the heat dissipation effect with respect to the heat | fever which generate | occur | produced in LED203 by improving thermal conductivity with LED lamp 200. FIG.

That is, since the lighting fixture 400 in Embodiment 1 has many heat dissipating means and enhances the heat dissipating effect, the heat generated by the LED 203 can be efficiently dissipated, and the temperature of the LED lamp 200 can be sufficiently increased. Can be lowered.
The lighting fixture 400 can solve the following problems by sufficiently lowering the temperature of the LED lamp 200.

The LED lamp 200 using the LED 203 as a light source has advantages such as less power consumption and longer life compared to conventional lamps such as incandescent bulbs, but also has the disadvantage of being vulnerable to heat for the following reasons. Have.
Each LED 203 is made by arranging about 10 to 100 elements on a 100 mm (millimeter) square substrate, for example. Since each of these elements is as small as 0.1 mm to 0.3 mm square, even if the calorific value is small, the calorific value per unit area is very large. For this reason, the cap of a 60 W (watt) incandescent lamp can withstand temperatures up to about 170 degrees, whereas the LED lamp 200 can only withstand temperatures up to about 60 degrees.

  Since the lighting fixture 400 in Embodiment 1 can sufficiently reduce the temperature of the LED lamp 200, it is possible to prevent the failure of the LED lamp 200 due to the temperature rise.

  Since the lighting fixture 400 in Embodiment 1 conducts and dissipates heat generated by the LEDs 203 to the LED lamp fixture 100 and the fixture main body 300, the substrate 202 of the LED lamp 200, the flat portion 102 of the LED lamp fixture 100, It is desirable to use a member having high thermal conductivity for the side surface portion 101, the flange 104, the flat surface portion 302, the side surface portion 301, etc. of the instrument body 300. For example, the substrate 202 of the LED lamp 200, the flat surface portion 102, the side surface portion 101, and the flange 104 of the LED lamp fixture 100, and the flat surface portion 302 and the side surface portion 301 of the instrument main body 300 may be made of metal.

Moreover, in order to improve thermal conductivity, it is good to improve the adhesiveness of the LED lamp 200 and the LED lamp fixture 100. FIG.
Therefore, it is preferable that at least one of the LED lamp 200 and the LED lamp fixture 100 has an elastic member having high thermal conductivity in the contact portion 103. The elastic member has the same shape as that of the substrate 202 and has a hole having the same shape as that of the through hole 106 at the center. For example, if the substrate 202 and the through hole 106 are circular, the elastic member has a ring shape or a donut shape.
The elastic member having high thermal conductivity is, for example, a silicon pad.

Further, as shown in FIG. 8, the flat portion 102 of the LED lamp fixture 100 protrudes downward (outside of the LED lamp fixture 100) into a convex shape and a mountain shape so that the LED lamp 200 and the LED lamp fixture 100 You may improve adhesiveness. At this time, the flat surface portion 102 is given elasticity so as to change its shape flatly when a pressing force is applied from the raised portion of the flat surface portion 102. Then, the LED lamp 200 is rotated and attached to the socket 320 as shown in FIG. At this time, since the force in the direction of the LED lamp 200 to be restored to the mountain shape acts on the flat portion 102 of the LED lamp fixture 100 that has been flattened by receiving a pressing force from the LED lamp 200, the LED lamp 200 And the LED lamp fixture 100 can be further improved in contact with each other.
FIG. 8 is a cross-sectional view of LED lamp fixture 100 having flat portion 102 raised in a mountain shape in the first embodiment.

Further, in order to efficiently conduct heat from the LED lamp 200 to the LED lamp fixture 100 and the instrument body 300, the area of the contact portion 103 between the substrate 202 of the LED lamp 200 and the flat portion 102 of the LED lamp fixture 100, the LED lamp The area of the flange 104 where the fixture 100 is in contact with the instrument body 300 should be large.
In addition, in order to efficiently radiate and convect heat from the LED lamp fixture 100 and the fixture body 300, the LED lamp fixture 100 and the fixture body 300 should have a large surface area.

In addition, as shown in FIG. 9, the LED lamp 200 may have a side surface portion 204 to increase the area in contact with the outside air, thereby enhancing the heat dissipation effect from the LED lamp 200 itself.
FIG. 9 is a cross-sectional view of lighting fixture 400 in the first embodiment.
The side surface portion 204 is positioned along the end portion of the substrate 202 and is formed along the end portion of the substrate 202, and the substrate 202 and the side surface portion 204 form a cylindrical shape with one end opened. That is, the cross section of the side surface portion 204 has the same shape as the substrate 202. For example, if the substrate 202 is circular, the side surface portion 204 is cylindrical.

The following lighting fixtures have been described in the first embodiment.
The lighting fixture 400 in Embodiment 1 has a flat plate shape, the LED 203 is mounted on one side, a connector (pin type base 205) for supplying electricity to the central portion, and a plurality of locking pieces 208 on the peripheral portion. The LED lamp 200 is provided with a cylindrical shape with one end open, and a through hole 106 is provided in the center of the other end plane, and a plurality of darling holes 108 are formed around the through hole 106 and the inner plane of the darling hole 108 is formed. And an LED lamp fixture 100 to which an elastic locking portion (locking plate 700) having a Z-shaped slit 706 having one end opened is fixed to the portion.

  Moreover, the lighting fixture 400 in which the locking piece 208 is locked by the mounting operation of rotating the LED lamp has been described.

  Moreover, the lighting fixture 400 in which the Z-shaped locking portion forms a step (recess 703) to prevent the LED lamp from falling off has been described.

  Moreover, the lighting fixture 400 in which a ring-shaped and thermally conductive elastic member is disposed on the opposite side of the socket 320 located in the through hole 106 portion has been described.

  Moreover, the lighting fixture 400 in which the flat portion 102 of the LED lamp fixture 100 in which the through hole 106 is formed is convex outward has been described.

The lighting fixture 400 in Embodiment 1 can obtain a heat dissipation effect even for a light source other than the LED 203.
In the above description, the LED lamp fixture 100 and the instrument body 300 are cylindrical, and the LED lamp 200 is circular. However, other shapes may be used. For example, it may be a rectangular tube, a rectangle, or other polygons.

Further, as shown in FIG. 10, the locking plate 700 may not have the slit 706. For example, if the locking piece 208 of the LED lamp 200 is L-shaped as shown in FIG. 11, the locking piece 208 can be locked to the locking plate 700 without the slit 706.
FIG. 10 is a perspective view of the locking plate 700 that does not have the slit 706 in the first embodiment.
FIG. 11 is a perspective view of LED lamp 200 having L-shaped locking piece 208 in the first embodiment.

FIG. 12 is a cross-sectional view of the locking portion when the locking plate 700 according to Embodiment 1 is attached with the rivet 110.
In addition, when the locking plate 700 is attached to the flat portion 102 of the LED lamp fixture 100 with the rivet 110, as shown in FIG. 12, the concave portion 109 is provided in the flat portion 102 so that the head of the rivet 110 does not protrude. It is good to do so.

Embodiment 2. FIG.
In the first embodiment, the LED lamp 200 is rotated and locked to the LED lamp fixture 100. However, in the second embodiment, the LED lamp 200 is moved linearly and the LED lamp fixture 100 is engaged. The form which stops is demonstrated.
Hereinafter, items different from the first embodiment will be described, and items not described will be the same as those of the first embodiment.

FIG. 13 is a configuration diagram showing the inside of the LED lamp fixture 100 according to the second embodiment.
FIG. 14 is a cross-sectional view of lighting fixture 400 when LED lamp 200 according to Embodiment 2 is attached.
FIG. 13 is a diagram corresponding to FIG. 2 of the first embodiment, and FIG. 14 is a diagram corresponding to FIG. 6 of the first embodiment.

As shown in FIG. 13, the LED lamp fixture 100 according to the second embodiment arranges two daruma holes 108 and a locking plate 700 in a linear direction with a through hole 106 interposed therebetween. Further, each daruma hole 108 has a large-diameter portion and a small-diameter portion positioned in the same linear direction. In other words, each daruma hole 108 has a large diameter portion located on the left side in FIG. 13 and a small diameter portion located on the right side in FIG.
Further, in the second embodiment, as shown in FIG. 14, the LED lamp 200 is moved linearly in the A direction so that the locking piece 208 of the LED lamp 200 is locked with the dart hole 108 of the LED lamp fixture 100. Lock to the plate 700. That is, the mechanical connection of the LED lamp 200 can be easily performed.
Further, the two daruma holes 108 and the locking plate 700 may be arranged in parallel with the through hole 106 therebetween, and the daruma hole 108 and the locking plate 700 may be one instead of a plurality.

  In the second embodiment, the lighting fixture 400 in which the locking piece 208 is locked by the linear mounting operation of the LED lamp 200 has been described.

Embodiment 3 FIG.
In the third embodiment, a mode for further enhancing the heat radiation effect of each embodiment will be described.
Hereinafter, with respect to the lighting fixture 400 in the third embodiment, matters different from those in the first embodiment will be described, and the other matters shall be the same as those in the first embodiment.

FIG. 15 is a cross-sectional view of lighting fixture 400 before attaching auxiliary body 600 in the second embodiment.
FIG. 16 is a cross-sectional view of lighting fixture 400 after attaching auxiliary body 600 in the second embodiment.
The lighting fixture 400 in Embodiment 2 is demonstrated below based on FIG.
In order to increase the thermal conductivity from the LED lamp 200 to the LED lamp fixture 100, the adhesion between the LED lamp 200 and the LED lamp fixture 100 may be increased.

  Therefore, the lighting fixture 400 may improve the adhesion between the LED lamp 200 and the LED lamp fixture 100 by having an auxiliary body 600 that presses the LED lamp 200 against the flat portion 102 of the LED lamp fixture 100 from the outside.

In FIG. 15, the auxiliary body 600 has a side surface portion 601 and a flat surface portion 602, and forms a hollow cylindrical shape whose one end is open, like the LED lamp fixture 100.
The side portion 601 is open at both ends to form a cylindrical shape or a pipe shape. Further, the side surface portion 601 has a threaded portion 607 that forms a spiral groove.
The flat surface portion 602 forms a disk shape and is positioned so as to close the open end of the side surface portion 601 on one open end side of the side surface portion 601. Moreover, the plane part 602 has a through hole 606 in the center, and forms a ring shape or a donut shape.
Further, the auxiliary body 600 is slightly larger than the LED lamp fixture 100 and can be put on the LED lamp fixture 100. When the LED lamp fixture 100 is put on the auxiliary body 600, the side surface portion 101 of the LED lamp fixture 100 is inscribed in the side surface portion 601.

  The LED lamp fixture 100 also has a threaded portion 107 that forms a spiral groove in the side surface portion 101. The threaded portion 107 of the LED lamp fixture 100 is paired with the threaded portion 607 of the auxiliary body 600.

The auxiliary body 600 is mechanically coupled to the LED lamp fixture 100 so as to cover the peripheral edge (circumferential end) of the LED lamp 200 as shown in FIG. 16 by rotating over the LED lamp fixture 100. At this time, as shown in FIG. 16, the auxiliary body 600 is in contact with the periphery of the substrate 202 of the LED lamp 200 at the end of the flat portion 602 on the through hole 606 side, and attaches the substrate 202 of the LED lamp 200 to the LED lamp fixture 100. The flat portion 102 is pressed.
Thereby, the auxiliary body 600 can enhance the adhesion between the LED lamp 200 and the LED lamp fixture 100, and can enhance the heat dissipation effect on the LED lamp 200.
In addition, since the flat portion 602 of the auxiliary body 600 conducts heat and emits heat from the contact portion of the LED lamp 200 with the substrate 202, the heat dissipation effect on the LED lamp 200 can be enhanced.

  In the third embodiment, the auxiliary body 600 is provided to improve the adhesion between the LED lamp 200 and the LED lamp fixture 100, thereby increasing the thermal conductivity from the LED lamp 200 to the LED lamp fixture 100, and the LED lamp. The lighting fixture 400 which improves the heat dissipation effect with respect to the LED lamp 200 by increasing the thermal conductivity from the 200 to the LED lamp fixture 100 has been described.

Embodiment 4 FIG.
In the fourth embodiment, a mode for preventing the LED lamp 200 from falling will be described.
Hereinafter, regarding the lighting fixture 400 according to the fourth embodiment, matters different from those of the first embodiment will be described, and other matters shall be the same as those of the first embodiment.

FIG. 17 is a perspective view of the LED lamp fixture 100 according to the fourth embodiment.
FIG. 18 is a perspective view of LED lamp 200 in the fourth embodiment.
FIG. 19 is a cross-sectional view of lighting fixture 400 after LED lamp 200 according to the fourth embodiment is attached.
The lighting fixture 400 of Embodiment 4 is demonstrated below based on FIGS.

As shown in FIG. 17, the LED lamp fixture 100 has a pair of auxiliary metal fittings 500 (support pieces) that protrude outward from the periphery of the through hole 106 in the flat portion 102. The auxiliary metal fitting 500 has a Z-shaped cross section and an arc shape in the entire longitudinal direction. The arc-shaped auxiliary metal fitting 500 is disposed along the through hole 106. At this time, the auxiliary metal fitting 500 is located outside the substrate 202 when the LED lamp 200 is attached to the socket 320. The auxiliary metal fitting 500 has one piece fixed to the flat portion 102 and the other piece extended in the direction of the through hole 106 to the extent that it overlaps the periphery of the substrate 202 when the LED lamp 200 is attached to the socket 320. Prevents falling off.
As shown in FIG. 18, the LED lamp 200 has a cutout portion 207 having a shape that matches the auxiliary metal fitting 500 of the LED lamp fixture 100 at least at one location on the substrate 202.

  The LED lamp 200 is connected to the socket 320 by using the notch 207 to fit the substrate 202 into the auxiliary metal fitting 500 of the LED lamp fixture 100 and the latch piece 208 to the LED lamp fixture 100. This is done by locking to the plate 700. FIG. 19 shows a cross-sectional view of the lighting fixture 400 after the LED lamp 200 is attached.

  The lighting fixture 400 can prevent the LED lamp 200 from falling by having the auxiliary fitting 500 in the LED lamp fixture 100.

In the fourth embodiment, the following lighting fixture has been described.
Located outside the through-hole 106 formed in the central portion of the flat portion 102, the cross-section is Z-shaped and attached outside the board outline of the LED lamp, and the other end is arranged inside the board outline. An LED lamp fixture 100 having a pair of holding metal fittings (auxiliary metal fittings 500), and an LED lamp in which a part of the periphery of the LED lamp substrate 202 is cut out in substantially the same shape as the holding metal fittings (auxiliary metal fittings 500). Lighting fixture 400.

Sectional drawing of the lighting fixture 400 after attaching the LED lamp 200 in Embodiment 1. FIG. The block diagram which shows the inside of the LED lamp fixture 100 in Embodiment 1. FIG. FIG. 3 is a perspective view of a locking plate 700 according to the first embodiment. FIG. 3 is a perspective view of LED lamp 200 in the first embodiment. Sectional drawing of the lighting fixture 400 before attaching the LED lamp 200 in Embodiment 1. FIG. Sectional drawing of the lighting fixture 400 at the time of attaching the LED lamp 200 in Embodiment 1. FIG. Sectional drawing of the latching | locking part at the time of attaching the LED lamp 200 in Embodiment 1. FIG. Sectional drawing of the LED lamp fixture 100 which has the plane part 102 raised in the mountain shape in Embodiment 1. FIG. Sectional drawing of the lighting fixture 400 in Embodiment 1. FIG. FIG. 3 is a perspective view of a locking plate 700 that does not have a slit 706 in the first embodiment. FIG. 3 is a perspective view of an LED lamp 200 having an L-shaped locking piece 208 in the first embodiment. Sectional drawing of the latching | locking part at the time of attaching the latching board 700 in Embodiment 1 with the rivet 110. FIG. The block diagram which shows the inside of the LED lamp fixture 100 in Embodiment 2. FIG. Sectional drawing of the lighting fixture 400 at the time of attaching the LED lamp 200 in Embodiment 2. FIG. Sectional drawing of the lighting fixture 400 before attaching the auxiliary body 600 in Embodiment 3. FIG. Sectional drawing of the lighting fixture 400 after attaching the auxiliary body 600 in Embodiment 3. FIG. FIG. 6 is a perspective view of an LED lamp fixture 100 according to Embodiment 4. FIG. 6 is a perspective view of an LED lamp 200 in a fourth embodiment. Sectional drawing of the lighting fixture 400 after attaching the LED lamp 200 in Embodiment 4. FIG.

Explanation of symbols

  100 LED lamp fixture, 101 Side surface portion, 102 Flat surface portion, 103 Contact portion, 104 Flange, 106 Through hole, 107 Threaded portion, 108 Daruma hole, 109 Recessed portion, 110 Rivet, 200 LED lamp, 202 Substrate, 203 LED, 204 Side part, 205 Base, 207 Notch part, 208 Locking piece, 300 Instrument body, 301 Side part, 302 Plane part, 303 Attachment part, 304 Through hole, 305 Electrical cord, 310 Instrument attachment plate, 311 Screw, 320 Socket, 330 Connector, 400 Lighting fixture, 500 Auxiliary metal fitting, 600 Auxiliary body, 601 Side surface part, 602 Flat surface part, 606 Through hole, 607 Threaded part, 700 Locking plate, 701 Locking surface, 702 Inclined part, 703 Recessed part , 704 Vertical surface, 705 Bonding surface, 706 Slip G, 707 Plane portion, 708 Step.

Claims (9)

A cylindrical body having a side surface, an end surface having a locking hole, and a locking plate formed to protrude from the end surface to the inner side of the cylindrical shape formed by the side surface and the end surface, and from the outside of the cylindrical body, A cylindrical body for locking the locking piece of the light source body having a light source, a flat plate on which the light source is arranged, and a locking piece protruding from the flat plate in the locking hole and the locking plate on the end surface. A lighting apparatus comprising: The cylindrical body is
The end surface is in contact with the flat plate of the light source body, and heat generated by the light source is thermally conducted from the end surface in contact with the flat plate of the light source body and is radiated from the end surface and the side surface. The lighting apparatus according to claim 1. The cylindrical body is
3. The locking piece of the light source body is guided to the locking plate by having an inclined portion extending obliquely downward on the first end side of the locking plate. The lighting fixture in any one. The cylindrical body is
4. The locking plate according to claim 1, further comprising a recess on the second end portion side of the locking plate to hold the locking piece of the light source body on the locking plate. 5. lighting equipment. The cylindrical body is
The lighting apparatus according to claim 1, wherein the locking plate is formed of an elastic member, and the light source body is lifted by an elastic action to come into contact with the end surface. The cylindrical body is
6. The lighting apparatus according to claim 1, wherein the locking plate has a slit having one end opened. The cylindrical body is
The lighting fixture according to any one of claims 1 to 6, wherein the locking hole of the end face is formed in a dharma shape having a large diameter portion and a small diameter portion. The cylindrical body has the locking hole and the locking plate arranged in the circumferential direction of the end surface, and the light source body rotates in the circumferential direction, whereby the locking piece of the light source body is engaged with the engagement of the end surface. The lighting fixture according to claim 1, wherein the lighting fixture is locked to a stop hole and the locking plate. The cylindrical body has the locking hole and the locking plate arranged in a linear direction of the end surface, and the light source body moves in the linear direction, whereby the locking piece of the light source body is engaged with the engagement of the end surface. The lighting fixture according to claim 1, wherein the lighting fixture is locked to a stop hole and the locking plate.

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