JP6719097B2 - Mounting auxiliary member and lighting device including the mounting auxiliary member - Google Patents

Description

The present disclosure relates to a mounting auxiliary member and a lighting device including the mounting auxiliary member.

2. Description of the Related Art Conventionally, as a lighting device, there is known a lighting device in which a lamp is embedded and fixed in a through hole of a wall portion by using a mounting auxiliary member (see, for example, Patent Document 1).

In Patent Document 1, the mounting auxiliary member includes a main body portion that covers the through hole of the wall portion, and a plate mounting portion that is fixed to the main body portion and that mounts the plate to the wall portion.

A mounting hole having an opening area smaller than that of the through hole of the wall is formed in the main body, and the lamp is fixed to the mounting auxiliary member by inserting the lamp into the mounting hole.

On the other hand, the plate mounting portion includes two side walls fixed to the main body portion, mounting springs respectively disposed on the side walls, and a top wall connecting the tips of the side walls.

Then, by sandwiching the wall portion between the main body portion and the attachment spring, the attachment auxiliary member is fixed to the wall portion.

As described above, in Patent Document 1, by fixing the mounting auxiliary member in which the mounting hole for embedding and fixing the lamp is formed in the through hole of the wall, the existing lamp is mounted in the through hole of the wall. , It is possible to install a lamp that has a smaller outer shape than existing lamps.

JP, 2014-007082, A

By the way, when the above-mentioned conventional lighting device is installed in a building where heat insulation is applied, the heat insulating material is pushed in a direction away from the wall by the plate mounting portion, and a space is formed between the lamp and the heat insulating material. Will be done. Then, the heat generated in the lamp is radiated to the space formed between the lamp and the heat insulating material.

However, among the lamps (lamps having substantially the same outer diameter) that can be fixed to the mounting auxiliary member, there are lamps with various heat generation amounts. There are also lamps that have different heights in the insertion direction when they are inserted into the mounting holes and fixed to the mounting auxiliary member. That is, there are various types of lamps that can be fixed to the mounting auxiliary member, and among them, there are lamps that generate a relatively large amount of heat, and those that can be inserted into the mounting hole and used as the mounting auxiliary member. There are lamps and the like that have a relatively large height in the insertion direction in a fixed state.

Therefore, depending on the type of the lamp fixed to the attachment assisting member, the heat accumulated in the space formed between the lamp and the heat insulator may be affected.

As described above, in the above-described conventional technique, it may be impossible to secure the heat radiation space for releasing the heat of the lamp.

Therefore, an object of the present disclosure is to provide a mounting auxiliary member that can ensure a heat dissipation space more reliably and an illumination device including the mounting auxiliary member.

The attachment assisting member according to the present disclosure is embedded in and fixed to the through hole of the wall portion, and the lamp is attached thereto.

The attachment assisting member includes a main body portion that covers the peripheral portion of the through hole in the wall portion, and a side wall portion that is provided in the main body portion and that is inserted into the through hole.

Further, the main body portion is formed with a mounting hole having an opening area smaller than that of the through hole and into which the lamp is inserted.

The side wall portion has a variable structure capable of changing the height from the root portion of the main body portion side to the tip end, and the tip end side is projected more than the lamp fitting inserted in the mounting hole. It is configured to be able to.

Further, an illumination device according to the present disclosure includes the mounting auxiliary member and a lamp attached to the mounting auxiliary member.

According to the present disclosure, it is possible to obtain a mounting auxiliary member and a lighting device including the mounting auxiliary member that can ensure the heat dissipation space more reliably.

It is a figure which shows the state which embedded and fixed the illuminating device concerning one Embodiment in the through-hole of a wall part, (a) is the perspective view seen from one side of a wall part, (b) is the other side of a wall part. It is the top view seen. It is an exploded perspective view showing a lighting installation concerning one embodiment. It is a figure which shows the relationship between a lighting fixture and an attachment auxiliary member, and a through-hole concerning one Embodiment, (a) is a figure which shows the relationship between a lighting fixture and a through-hole, (b) is a mounting assistance member and a through-hole. It is a figure which shows a relationship. It is a 1st perspective view which shows the state which decomposed|disassembled the lamp body concerning one embodiment into a lamp body and a power supply device. It is a 2nd perspective view which shows the state which decomposed|disassembled the lamp body concerning one embodiment into a lamp body and a power supply device. It is a 1st perspective view which shows the state which decomposed|disassembled the lamp main body concerning one Embodiment. It is a 2nd perspective view showing the state where the lamp body concerning one embodiment was disassembled. It is a perspective view showing the state where the attachment auxiliary member concerning one embodiment was disassembled. It is a perspective view showing the state where the attachment auxiliary member concerning one embodiment was disassembled into the body part with a side wall, and the side wall extension member. It is a perspective view showing an attachment auxiliary member concerning one embodiment. It is sectional drawing which shows the state which embeds and fixes the illuminating device concerning one Embodiment in the through-hole of a wall part. It is the top view which looked at the state where the lighting installation concerning a modification of one embodiment was embedded and fixed in the penetration hole of the wall, from the other side of the wall. It is sectional drawing which shows the state which embedded and fixed the illuminating device concerning the modification of one Embodiment in the through-hole of a wall part.

Hereinafter, a mounting auxiliary member according to the present embodiment and a lighting device including the mounting auxiliary member will be described in detail with reference to the drawings. In addition, below, the ceiling-embedded downlight embedded in a ceiling (wall part) is illustrated as a lamp. In addition, as a mounting auxiliary member, the size (outside) of the existing downlight (existing lamp) is set in the ceiling hole (through hole) of the ceiling (wall) where the existing downlight (existing lamp) is embedded and fixed. An example of a renewal plate used when attaching a downlight (lamp) having a small diameter is illustrated.

Further, the downlight (lamp) and the renewal plate (attachment auxiliary member) will be described with the indoor side in the state of being attached to the ceiling (wall portion) being the lower side and the ceiling back side being the upper side.

As shown in FIG. 1, the lighting device 10 according to the present embodiment assists in mounting the downlight 20 on a downlight (lamp) 20 and a ceiling (wall part) 60 that defines an indoor space R of a building. And a renewal plate (attachment auxiliary member) 50.

The downlight 20 is embedded and fixed in a ceiling hole (through hole) 61 formed so as to penetrate in the thickness direction of the ceiling 60, and the light from the light source 330 provided in the downlight 20 is introduced into the indoor space R. It is intended to irradiate.

However, in the present embodiment, the downlight 20 having a smaller outer shape than the existing downlight (existing lamp) (not shown) embedded and fixed in the ceiling hole 61 formed in the ceiling 60 is used. Specifically, the downlight 20 is used in which the outer diameter of the flange portion 328 of the downlight 20 described later is smaller than the inner diameter of the ceiling hole 61 (see FIG. 3A). Therefore, when the downlight 20 is directly attached to the ceiling 60, a gap D is formed between the flange portion 328 of the downlight 20 and the ceiling hole 61. As described above, the downlight 20 used in the present embodiment has a configuration in which the ceiling hole 61 cannot be directly covered with the flange portion 328.

Therefore, in the present embodiment, by using the renewal plate 50 embedded and fixed in the ceiling hole 61 formed in the ceiling 60, the downlight 20 having a size that does not match the existing ceiling hole 61 is attached to the ceiling hole 61. I am allowed to do so.

As will be described later, the renewal plate 50 is provided with a flange portion 511 having an outer diameter larger than the inner diameter of the ceiling hole 61. Therefore, when the renewal plate 50 is embedded and fixed in the ceiling hole 61, the peripheral edge portion 60c of the ceiling hole 61 on the lower surface (front surface) 60b of the ceiling 60 is covered by the flange portion 511 (see FIG. 3B). ).

Further, a mounting hole (lamp mounting hole: a through hole penetrating in the thickness direction of the flange portion 511) 514 to be mounted in a state where the downlight 20 is inserted is formed in a central portion of the flange portion 511. The inner diameter of the mounting hole 514 is smaller than the outer diameter of the flange portion 328 of the downlight 20. Therefore, when the downlight 20 is attached to the renewal plate 50, the attachment hole 514 is covered by the downlight 20.

In this embodiment, by using such a renewal plate 50, the downlight 20 can be attached to the ceiling 60 in a state where the ceiling hole 61 is covered with the renewal plate 50 and the downlight 20.

The downlight 20 and the renewal plate 50 can be attached to the ceiling 60 by the following method, for example.

First, the downlight 20 is attached to the renewal plate 50. Next, the renewal plate 50 to which the downlight 20 is attached is embedded and fixed in the ceiling hole 61. By doing so, the downlight 20 and the renewal plate 50 can be attached to the ceiling 60 with the ceiling hole 61 being covered. Note that, after the renewal plate 50 is embedded and fixed in the ceiling hole 61, the downlight 20 may be attached to the renewal plate 50 which is embedded and fixed in the ceiling hole 61.

Hereinafter, each configuration of the lighting device 10 will be specifically described.

First, a specific configuration of the downlight 20 will be described with reference to FIGS.

As shown in FIGS. 4 and 5, the downlight 20 includes a lamp body 30 and a power supply device 40.

The lamp body 30 has a light source 330, as shown in FIG. The power source device 40 is electrically connected to the light source 330. As the light source 330, for example, one including a plurality of LEDs (light emitting elements) and an LED substrate (light emitting element base) on which the plurality of LEDs (light emitting elements) are arranged can be used. It is also possible to use a semiconductor light source or the like as the light source 330.

In addition, the lamp body 30 includes a heat radiating portion 310 that radiates heat generated by the light source 330 to the outside of the downlight 20, as shown in FIGS. 6 and 7. The heat radiating portion 310 can be formed by using, for example, aluminum die casting having a high thermal conductivity, and the heat generated by the light source 330 can be radiated more efficiently.

The heat dissipation part 310 includes a heat dissipation part body 311 to which the light source 330 is thermally connected, and a plurality of heat dissipation fins 312 connected to the heat dissipation part body 311.

In the present embodiment, the heat dissipation unit main body 311 includes a substantially disc-shaped top wall 313 and a peripheral wall 314 extending downward (inside the indoor space R) from the peripheral edge of the top wall 313. That is, the heat dissipation unit main body 311 has a housing space defined by the top wall 313 and the peripheral wall 314 and opening downward. Then, a first reflecting portion 321 described later is housed in this housing space. The plurality of heat radiation fins 312 are formed so as to project upward from the upper surface 313a of the top wall 313.

Further, in this embodiment, the light source 330 is fixed to the central portion of the lower surface 313b of the ceiling wall 313. In this way, by fixing the light source 330 to the central portion of the lower surface 313b of the ceiling wall 313, the light source 330 and the ceiling wall 313 (heat dissipation portion 310) are thermally connected. By doing so, the heat generated by the light source 330 is transmitted from the lower surface 313b of the ceiling wall 313 to the heat dissipation section 310 and is emitted from the heat dissipation section 310 to the outside of the downlight 20. When the LED substrate on which a plurality of LEDs are arranged is used as the light source 330, the LED substrate is fixed to the central portion of the lower surface 313b of the ceiling wall 313 with the plurality of LEDs facing downward. ..

Further, as shown in FIGS. 6 and 7, the lamp body 30 is attached to the heat dissipation portion 310 to which the light source 330 is fixed, and assists in the irradiation of the light emitted from the light source 330 to the outside (indoor space R or the like). The light irradiation auxiliary section 320 is provided. By using the light irradiation auxiliary section 320, the light of the downlight 20 can be oriented in a predetermined direction, or the light irradiated from the downlight 20 can be irradiated in a predetermined range. You can

In the present embodiment, the light irradiation auxiliary section 320 has an opening 320a that opens downward (on the side of the indoor space R), and by using such a light irradiation auxiliary section 320, the light emitted from the light source 330 is emitted. Is irradiated to a predetermined range on the lower side (the floor side of the indoor space R) through the opening 320a.

The light irradiation assisting unit 320 has a first reflecting unit 321 that reflects the light emitted from the light source 330 so as to face downward, a diffusion plate 322 that diffuses the light when transmitting the light, and a diffusion plate 322 that diffuses the light. And a second reflecting portion 323 that reflects light so as to face downward (see FIGS. 6 and 7).

In the present embodiment, the first reflecting portion 321 includes a bottom wall 324 and an outer peripheral wall 325 that extends upward from the outer peripheral edge portion of the bottom wall 324. In the present embodiment, the bottom wall 324 has a shape in which a substantially circular opening (lower opening 326c) is formed in the center of a disk-shaped member, and has a substantially annular shape in plan view.

On the other hand, the outer peripheral wall 325 has a substantially cylindrical shape, and the outer peripheral wall 325 is formed so that the outer diameter thereof is slightly smaller than the inner diameter of the peripheral wall 314 of the heat dissipation part main body 311. That is, the bottom wall 324 and the peripheral wall 314 are formed to have a size capable of being accommodated in the accommodation space defined by the top wall 313 and the peripheral wall 314.

Further, a reflection plate 326 extends from the peripheral edge of the opening (lower opening 326c) formed in the center of the bottom wall 324. The reflection plate 326 can be formed of, for example, PBT (polybutylene terephthalate) resin or the like, and has a substantially bowl shape that expands in diameter downward. An upper opening 326b that opens upward and a lower opening 326c that opens downward are formed at the upper and lower ends of the reflecting plate 326, respectively. The curved surface below the reflection plate 326 is the reflection surface 326a.

Then, when the first reflecting section 321 is housed in the housing space of the heat dissipation section body 311, the upper opening 326b is covered by the ceiling wall 313. At this time, it is preferable that at least the light emitting portion of the light source 330 (for example, the plurality of LEDs arranged on the LED substrate) is arranged in the upper opening 326b when viewed from below. By doing so, of the light emitted from the light source 330, most of the light emitted so as to spread to the peripheral portion of the light source 330 (light having a large inclination with respect to the main optical axis direction) is reflected by the reflecting surface 326a and directed downward. Will be able to.

A diffusion plate 322 is arranged below the first reflecting section 321. The diffusion plate 322 has a substantially disc shape, and can be formed using, for example, a translucent acrylic resin or the like.

Further, in the present embodiment, the second reflecting portion 323 is arranged below the diffusion plate 322. As described above, the second reflecting section 323 reflects (distributes) the light diffused by the diffusing plate 322 so as to face downward, and is formed using, for example, a steel plate or resin. can do.

Then, the second reflecting portion 323 is provided radially outward from the main body portion 327 in which the upper opening 327b and the lower opening 327c are formed, and the lower end of the main body portion 327 (the peripheral portion of the lower opening 327c). And a flange portion 328. In the present embodiment, the lower opening 327c is the opening 320a of the light irradiation auxiliary section 320.

The main body portion 327 includes a substantially bowl-shaped auxiliary reflection plate 327d that expands in diameter downward, and a cylindrical portion 327e that is connected to the upper end of the auxiliary reflection plate 327d and into which the diffusion plate 322 is inserted. ing.

The curved surface on the lower side of the auxiliary reflection plate 327d is the auxiliary reflection surface 327a. The cylindrical portion 327e is provided with an annular mounting portion 327f so as to project inward. By mounting the outer peripheral portion of the diffusion plate 322 on this mounting portion 327f, diffusion is performed. The plate 322 is supported by the main body 327.

Further, in the present embodiment, the second reflecting portion 323 is formed with the leaf spring attachment portion 323a to which the leaf spring 340 is attached. The down spring 20 is attached to the down spring 20 by sandwiching the attached member (for example, the wall portion of the ceiling 60 or the renewal plate 50) between the leaf spring 340 attached to the leaf spring attaching portion 323a and the flange portion 328. It can be attached to. In the present embodiment, the downlight 20 is attached to the renewal plate 50 by sandwiching the flange portion 511 and the inner vertical wall portion 513 between the leaf spring 340 and the flange portion 328.

The power supply device 40 is a device that is electrically connected to the light source 330 of the lamp body 30 and converts commercial power to supply power to the light source 330.

In the present embodiment, as shown in FIG. 2, the power supply device 40 and the lamp body 30 are integrally formed. Specifically, the heat dissipation fins 312 are formed in a substantially half area of the top wall 313 of the heat dissipation unit main body 311, and the power supply device 40 is placed in the remaining approximately half area of the top wall 313, whereby the power supply device is placed. 40 and the lamp body 30 are integrally formed.

The power supply device 40 includes a substantially rectangular parallelepiped casing 41. The housing 41 can be formed of, for example, a resin having an insulating property, and an electronic component 42 for supplying power to the light source 330 is housed inside the housing (see FIG. 4). The electronic component 42 can be electrically connected to the light source 330 via, for example, a cable.

As shown in FIG. 5, a power supply terminal block 43 is formed on one end side in the longitudinal direction of the housing 41, and a VVF cable 44 is connected to the power supply terminal block 43. The VVF cable 44 has one end electrically connected to a terminal portion (not shown) formed on the power supply terminal block 43 and the other end electrically connected to a commercial power supply (not shown). Power is supplied from a commercial power supply to the electronic component 42 inside the housing 41 via the.

Next, a specific configuration of the renewal plate 50 will be described based on FIGS. 8 to 10.

The renewal plate 50 can be formed using, for example, a steel plate, resin, or the like, and includes a main body portion 510 that covers the peripheral edge portion 60 c of the ceiling hole 61 in the ceiling 60, as shown in FIGS. 8 to 10. Further, the renewal plate 50 includes a side wall portion 520 provided on the main body portion 510 and inserted into the ceiling hole 61.

The main body portion 510 includes a flange portion 511, an outer vertical wall portion 512 that is continuously provided at an outer peripheral end of the flange portion 511, an inner vertical wall portion 513 that is continuously provided at an inner peripheral end of the flange portion 511, and a ceiling hole 61. And a mounting hole 514 into which the downlight 20 is inserted.

The outer vertical wall portion 512 is extended so as to project upward from the outer peripheral end of the flange portion 511. Then, when the renewal plate 50 is embedded and fixed in the ceiling hole 61, the renewal plate 50 is positioned by bringing the upper end of the outer vertical wall portion 512 into contact with the lower surface (front surface) 60b of the ceiling 60. ..

The inner vertical wall portion 513 is extended so as to project upward from the outer peripheral end of the flange portion 511, and the projection amount of the inner vertical wall portion 513 is larger than the projection amount of the outer vertical wall portion 512. There is. That is, when the renewal plate 50 is positioned by the contact of the upper end of the outer vertical wall portion 512 with the lower surface (front surface) 60b of the ceiling 60, the upper end of the inner vertical wall portion 513 causes the lower surface (front surface) of the ceiling 60. It is adapted to project above 60b.

Then, in the present embodiment, the side wall portion 520 is fixed to the inner vertical wall portion 513 with the screw 526b. As described above, in order to screw the side wall portion 520 to the inner vertical wall portion 513, the inner vertical wall portion 513 needs to be projected to some extent. However, if the protrusion amount of the inner vertical wall portion 513 is too large, the upper end of the inner vertical wall portion 513 may interfere with a pressing spring 540 described later. Therefore, it is preferable that the inner vertical wall portion 513 is made to project so as not to interfere with the pressing spring 540. In the present embodiment, with the side wall portion 520 fixed to the inner vertical wall portion 513, is the upper end of the inner vertical wall portion 513 equal to the lower end of the groove 524 formed in the side wall portion 520 and to which the pressing spring 540 is attached? The inner vertical wall portion 513 is projected so as to be less than that. In other words, in the side view with the side wall portion 520 fixed to the inner vertical wall portion 513, the groove 524 to which the pressing spring 540 is attached does not overlap with the inner vertical wall portion 513.

Further, in the present embodiment, the flange portion 511 has a step portion 511a formed on the inner peripheral side, and the step portion 511a is formed so that the inner side is positioned higher than the outer side. The inner vertical wall portion 513 is continuously provided at the inner peripheral end of the step portion 511a.

Thus, by forming the step portion 511a on the inner peripheral side of the flange portion 511, the flange portion 328 abuts on the step surface of the step portion 511a when the downlight 20 is attached to the renewal plate 50. There is. That is, the downlight 20 is attached to the renewal plate 50 with the flange portion 328 abutting on the step surface of the step portion 511a. In this way, when the downlight 20 is attached to the ceiling 60 via the renewal plate 50, the downlight 20 is prevented from protruding below the renewal plate 50, and the appearance is deteriorated. You will be able to suppress. When forming the step portion 511a, it is preferable that the step portion 511a has multiple steps. By doing so, even when the outer diameter of the flange portion 328 of the downlight 20 is slightly different, the flange portion 328 can be brought into contact with one of the step surfaces of the step portion 511a.

On the other hand, the side wall portion 520 has a vertically elongated, substantially plate-like shape, and when the downlight 20 is attached to the renewal plate 50, the main body portion 510 is arranged so that the tip 520 b projects above the downlight 20. It is provided in.

In this embodiment, as described above, the side wall 520 is provided in the main body 510 by fixing the plate member separate from the main body 510 to the inner vertical wall 513 with the screw 526b.

Specifically, two (plural) plate members are attached to the inner vertical wall portion 513 in a state where they are spaced apart from each other in the circumferential direction of the attachment hole 514, so that two (a plurality of) plate members are spaced apart in the circumferential direction of the attachment hole 514 ( A plurality of side wall portions 520 are provided on the main body portion 510. Furthermore, in the present embodiment, two plate members are provided at both ends of the diameter of the mounting hole 514 so as to face each other, so that the two (plurality) side wall portions 520 are attached to the mounting hole 514 in the inner vertical wall portion 513. It is provided at a position symmetrical with respect to the center of. Although two plate members having the same shape are used in the present embodiment, the side wall portion 520 can be formed using plate members having different shapes.

Further, a pressing spring 540 used when the renewal plate 50 is embedded and fixed in the ceiling hole 61 is attached to each side wall portion 520.

In the present embodiment, the pressing spring 540 is attached to the side wall portion 520 so as to be vertically slidable. Specifically, the side wall portion 520 is formed with a groove 524 elongated in the vertical direction, and the pressing spring 540 is attached to the side wall portion 520 so as to be movable along the groove 524.

In the present embodiment, the pressing spring 540 is installed in the side wall portion 520 and is disposed outside the side wall portion 520, and the outer main body portion 541 is continuously provided in the outer body portion 541 and is attached to the side wall portion 520. And an inner main body portion 542 arranged inside the side wall portion 520.

Further, the groove 524 is formed such that the upper end side (on the side of the tip 520b of the side wall portion 520 in the groove 524) is wider than the other portion, and has a substantially T shape in a side view.

The wide portion of the groove 524 is sized so that the outer main body portion 541 can be inserted therein, and the other portion of the groove 524 is narrower than the outer main body portion 541 and the inner main body portion 542. ..

With such a configuration, for example, the pressing spring 540 can be attached to the side wall portion 520 by the following method.

First, the outer main body portion 541 is inserted from the inside of the side wall portion 520 into the wide portion of the groove 524 to dispose the outer main body portion 541 outside the side wall portion 520, and the inner main body portion 542 is placed inside the side wall portion 520. Place it.

Next, the pressing spring 540 is moved downward along the narrow portion of the groove 524 in a state where the outer main body portion 541 is arranged outside the side wall portion 520 and the inner main body portion 542 is arranged inside the side wall portion 520. At this time, the pressing spring 540 is moved downward with the connecting portion between the outer main body portion 541 and the inner main body portion 542 being inserted into the narrow portion of the groove 524.

By doing so, the pressing spring 540 is attached to the side wall portion 520 so as to be slidable in the vertical direction in a state in which the outer body portion 541 and the inner body portion 542 are prevented from coming off from the groove 524.

As described above, in this embodiment, the wide portion of the groove 524 serves as the insertion portion 524a into which the outer main body portion 541 is inserted, and the narrow portion of the groove 524 slides the pressing spring 540 in the vertical direction. It is a slide portion 524b.

Further, in the present embodiment, the outer body 541 is provided with the urging spring 541 a, and when the pressing spring 540 is attached to the side wall 520, the urging spring 541 a moves the outer side surface of the side wall 520. I try to press it. By doing so, the side wall portion 520 is sandwiched between the biasing spring 541a and the inner main body portion 542, and the vertical displacement of the pressing spring 540 is suppressed, so that the pressing spring 540 is moved to a desired height of the side wall portion 520. It will be possible to install in the position.

Further, with the pressing spring 540 attached to the side wall portion 520, the urging spring 541a presses the outer side surface of the side wall portion 520 so that the outer main body portion 541 exerts an urging force for moving the outer end downward. I have to. That is, when the side wall portion 520 of the renewal plate 50 is inserted into the ceiling hole 61 from the lower surface (front surface) 60b side, the outer main body portion 541 presses the upper surface (rear surface) 60a of the ceiling 60.

Therefore, when the renewal plate 50 is embedded and fixed in the ceiling hole 61, the outer main body portion 541 presses the upper surface (back surface) 60a of the ceiling 60, and the ceiling spring 60 is sandwiched by the pressing spring 540 and the flange portion 511. Becomes As described above, in the present embodiment, the renewal plate 50 is fixed (embedded and fixed) to the ceiling 60 by sandwiching the ceiling 60 with the pressing spring 540 and the flange portion 511.

As described above, in the present embodiment, since the pressing spring 540 is attached to the side wall portion 520 so as to be slidable in the vertical direction, the renewal plate 50 includes the wall portions (ceilings having various thicknesses within a predetermined range). 60).

When the downlight 20 is attached to the ceiling 60 using the renewal plate 50 having such a configuration, the side wall portion 520 of the renewal plate 50 and the heat dissipation portion 310 of the downlight 20 are inserted into the ceiling hole 61 from the indoor space R side. It will be accommodated in the ceiling space S.

Here, when the downlight 20 is attached to the ceiling 60 of the building that has been subjected to heat insulation using the renewal plate 50 having the above-described configuration, the heat insulating material 70 arranged behind the ceiling is pushed upward by the side wall portion 520. (See FIG. 11). The heat insulating material 70 can be formed using, for example, glass wool or a blowing material.

In this way, when the heat insulating material 70 is arranged on the back of the ceiling, the heat radiating portion 310 is surrounded by the heat insulating material 70 unless the side wall portion 520 is provided, so that the heat generated by the light source 330 is radiated. It stays in the vicinity of 310. On the other hand, when the side wall portion 520 is provided on the renewal plate 50 as in the present embodiment, the side wall portion 520 functions as a push-up member and pushes the heat insulating material 70 upward, so that the space S1 is provided around the heat dissipation portion 310. Can be secured. As a result, it is possible to suppress the heat discharge from being hindered by the heat insulating material 70.

However, among the downlights 20 (downlights 20 having substantially the same outer diameter) that can be fixed to the renewal plate 50, there are downlights 20 with various heat generation amounts. There are downlights 20 and the like using a high-output light source such as.

Further, there are downlights 20 having different heights in the insertion direction when they are inserted into the mounting holes 514 and fixed to the renewal plate 50. For example, by increasing the height of the heat radiation fins 312, the heat radiation efficiency is improved. There are downlights 20 and the like that are enhanced.

As described above, there are various types of downlights 20 (downlights 20 having substantially the same outer diameter) that can be fixed to the renewal plate 50.

Therefore, depending on the type of the downlight 20 that can be fixed to the renewal plate 50, the downlight 20 may be affected by the heat accumulated in the space S1 formed between the downlight 20 and the heat insulating material 70.

For example, when the downlight 20 having a relatively large heat generation amount is fixed to the renewal plate 50, the volume of the space S1 formed by the wall portion 520 pushing up the heat insulating material 70 allows the heat of the downlight 20 to be radiated. It may be smaller than the required volume. Further, when the downlight 20 whose heat dissipation efficiency is improved by increasing the height of the heat dissipation fins 312 is fixed to the renewal plate 50, the distance between the downlight 20 (heat dissipation part 310) and the heat insulating material 70 becomes short. As a result, heat may be trapped in the vicinity of the heat dissipation portion 310. Further, since the volume of the space S1 is reduced by the increase in the volume of the downlight 20, the volume necessary for radiating the heat of the downlight 20 may not be secured.

As described above, simply providing the side wall portion 520 on the renewal plate 50 may not be able to secure the heat radiation space (space S1) for releasing the heat of the downlight 20 fixed to the renewal plate 50.

Therefore, in the present embodiment, the heat radiation space (space S1) can be secured more reliably. Specifically, the side wall portion 520 has a variable structure 560 capable of changing the height from the root portion 520a on the main body portion 510 side to the tip end 520b. By doing so, the volume of the heat radiation space (space S1) required for each downlight 20 can be secured more reliably.

The side wall portion 520 has a tip 520b side that can be projected above the downlight 20 inserted into the mounting hole 514. In the present embodiment, the tip 520b side protrudes above the downlight 20 even when the height of the side wall portion 520 is the lowest. That is, the tip 520b is located above the upper end of the downlight 20 in a state where the height is the lowest.

Note that the tip 520b is located below the upper end of the downlight 20 in the lowest height state, but the tip 520b is in the upper end of the downlight 20 in the highest height state. It may be located above.

Further, in the present embodiment, the side wall portion 520 is provided with the side wall portion main body 521 provided in the main body portion 510 and the extended wall 522 attached to the side wall portion main body 521.

Then, the extended wall 522 is attached to the side wall body 521 in a state in which the amount of protrusion from the tip 521b of the side wall body 521 is changed.

In the present embodiment, the side wall main body 521 has a shape obtained by bending a single plate-shaped member, and includes a slide wall main body 523a, a connecting wall 523b, and a flange 523c.

Specifically, the connecting walls 523b are continuously provided at both ends in the width direction (circumferential direction of the mounting hole 514) of the slide wall body 523a, and each connecting wall 523b extends radially inward of the mounting hole 514. Are arranged in series. A flange portion 523c is continuously provided at the inner end of each connecting wall 523b, and each flange portion 523c extends outward in the width direction (circumferential direction of the mounting hole 514) of the slide wall portion main body 523a. It is lined up.

In this way, when the side wall body 521 is formed by the slide wall body 523a, the connecting wall 523b, and the flange portion 523c, the side wall body 521 projects outward in the radial direction of the mounting hole 514 and extends in the vertical direction. The sliding protrusion 523 is formed.

Further, in the present embodiment, the slide wall portion main body 523a is formed with the above-mentioned groove 524 extending from the substantially central portion in the vertical direction to the lower portion. Further, an elongated hole 525 that extends from the substantially central portion in the vertical direction to the lower portion (elongate vertically) is formed above the groove 524 of the slide wall portion main body 523a.

A mounting piece 526 extending in the circumferential direction of the mounting hole 514 is provided at the lower end of the flange portion 523c (on the side of the root portion 521a of the side wall body 521). A screw hole 526a is formed in the mounting piece 526, and the side wall body 521 is fixed to the inner vertical wall portion 513 by inserting a screw 526b into the screw hole 526a. In the present embodiment, the root portion 521a of the side wall body 521 is the root portion 520a of the side wall portion 520.

On the other hand, the extended wall 522 also has a shape obtained by bending a single plate member in the present embodiment, and includes a slide wall portion main body 527a and a connecting wall 527b.

Specifically, connecting walls 527b are continuously provided at both ends in the width direction (circumferential direction of the mounting hole 514) of the slide wall body 527a, and each connecting wall 527b extends radially inward of the mounting hole 514. Are arranged in series.

As described above, when the extending wall 522 is formed by the slide wall portion main body 527a and the connecting wall 527b, the extending wall 522 has a slide groove portion that opens inward in the mounting hole 514 in the radial direction and extends in the vertical direction. 527 will be formed. The slide protrusion 523 is slidably inserted into the slide groove 527.

A screw hole (round hole) 528 is formed on the lower end 522a side of the slide wall body 527a.

Further, in the present embodiment, the tips 522b of the two extended walls 522 are connected by the connecting wall 530.

The connecting wall 530 includes a top wall portion 531 and a connecting wall 532. Specifically, the connecting walls 532 are continuously provided at both ends of the ceiling wall portion 531 in the width direction, and the connecting walls 532 are continuously provided so as to extend downward in the vertical direction.

The top wall portion 531 connects the slide wall portion main bodies 523a to each other. The connecting wall 532 on one side in the width direction of the top wall portion 531 connects the connecting walls 527b on one side in the width direction of the slide wall portion main body 527a to each other, and the connecting wall 532 on the other side is the slide wall. The connecting walls 527b on the other side in the width direction of the part main body 527a are connected to each other.

As described above, in the present embodiment, the two extending walls 522 and the connecting wall 530 are integrally formed, and by integrating the two extending walls 522 and the connecting wall 530, the sidewall extending member is formed. 580 is formed (see FIG. 9).

Therefore, the pair of slide groove portions 527 formed in the side wall extending member 580 are grooves that are open in the inside (sides facing each other) and the lower end 522a side and extend in the vertical direction.

Then, by moving the side wall extending member 580 up and down with the tip 521b side of the slide protrusion 523 inserted in the lower end 522a side of each slide groove 527, the height of the side wall 520 (the main body 510). The height from the root portion 520a on the side to the tip 520b) can be changed.

In the present embodiment, the side wall body 521 is fixed to the inner vertical wall portion 513 to form the side wall-equipped main body portion 570, and the side wall body 521 is fixed to the inner vertical wall portion 513. The extending member 580 is slid.

As described above, in this embodiment, by sliding the side wall extending member 580 up and down with respect to the side wall-equipped main body 570, the height of the side wall 520 (from the base 520a on the side of the main body 510 to the tip 520b). The height can be changed.

Then, the height of the side wall portion 520 is fixed by fixing the side wall-equipped main body portion 570 and the side wall extending member 580 in a state where the extended wall 522 is protruded from the tip end 521b of the side wall portion main body 521 by a predetermined amount. The renewal plate 50 having a height is formed.

In this embodiment, the fixing of the side wall-equipped main body portion 570 and the side wall extending member 580 is performed by inserting the washer 551 into the screw 550 while the screw hole 528 is in communication with the elongated hole 525. It is carried out by inserting it into the screw hole 528 and screwing it.

As described above, in the present embodiment, the variable structure 560 is configured by the elongated hole 525 of the side wall body 521, the screw hole 528 of the extended wall 522, the screw 550, and the washer 551.

In this embodiment, the elongated hole 525 is formed so as to extend vertically in the widthwise center of the slide wall body 523a, and the screw hole 528 is formed in the widthwise center of the slide wall body 527a. ing. By doing so, when the side wall extending member 580 is slid up and down with respect to the side wall-equipped main body 570, the screw hole 528 is located at any position from the upper end to the lower end of the elongated hole 525. 528 and the long hole 525 are communicated with each other.

Therefore, once the side wall extending member 580 is attached to the side wall main body 570, the side wall extending member 580 is slid up and down with respect to the side wall main body 570 simply by loosening the screw hole 528 without removing it. be able to.

Further, in the renewal plate 50 formed by fixing the side wall extending member 580 to the side wall main body 570, the tips 520b of the two side walls 520 (at least two side walls of the plurality of side walls) are connected to each other. They are connected by 530 (see FIG. 10).

As described above, the renewal plate (mounting auxiliary member) 50 of the present embodiment is embedded and fixed in the ceiling hole (through hole) 61 of the ceiling (wall portion) 60, and the downlight (lamp) 20 is mounted. It is a thing. That is, the renewal plate 50 is used for mounting (embedding and fixing) downlights (lamps) 20 that do not fit in the size to the ceiling hole (through hole) 61 in which an existing not-shown downlight (lamp) is embedded and fixed. It is used for.

In the present embodiment, the renewal plate 50 includes a main body portion 510 that covers the peripheral edge portion 60c of the ceiling hole 61 in the ceiling 60, and a side wall portion 520 that is provided in the main body portion 510 and that is inserted into the ceiling hole 61. There is.

Further, the main body portion 510 is formed with a mounting hole 514 having an opening area smaller than that of the ceiling hole 61 and into which the downlight 20 is inserted.

The side wall portion 520 has a variable structure 560 capable of changing the height from the root portion 520a on the main body portion 510 side to the tip end 520b.

This makes it possible to appropriately set the height from the root portion 520a of the side wall portion 520 to the tip 520b.

Further, the side wall portion 520 is configured so that the tip end 520b side can be made to project more than the downlight 20 inserted into the attachment hole 514.

Therefore, if the height of the side wall portion 520 is appropriately set and the amount of protrusion of the side wall portion 520 from the downlight 20 is appropriately set, when the downlight 20 is embedded and fixed in the ceiling 60 of a building on which heat insulation has been performed. The size of the space S1 formed between the downlight 20 and the heat insulating material 70 can be set to a desired size.

For example, if the height of the side wall portion 520 is appropriately set according to the type of the downlight (lamp) 20 attached to the renewal plate (attachment auxiliary member) 50, the space formed between the downlight 20 and the heat insulating material 70. S1 can be set to a size required for heat dissipation of each downlight 20.

Specifically, when the downlight 20 having a relatively large heat generation amount is attached to the renewal plate 50, the height of the side wall portion 520 is increased so that the space S1 formed between the downlight 20 and the heat insulating material 70. Can be increased to a size required for heat dissipation.

On the other hand, when the downlight 20 having a relatively small heat generation amount is attached to the renewal plate 50, it is not necessary to increase the space required for heat dissipation, and therefore the height of the side wall portion 520 can be reduced. When the downlight 20 having a relatively small heat generation amount is attached to the renewal plate 50, it is possible to set the height of the side wall portion 520 to be high. In this way, it is possible to more reliably prevent the downlight 20 from being affected by heat.

Further, when the downlight 20 having a relatively high height is attached to the renewal plate 50, if the height of the side wall portion 520 is increased, a relatively large gap can be formed between the downlight 20 and the heat insulating material 70. become able to. That is, it is possible to prevent the downlight 20 from coming too close to the heat insulating material 70. Further, since the volume of the space S1 formed between the downlight 20 and the heat insulating material 70 can be changed, the volume of the downlight 20 increases and it becomes impossible to secure the space required for heat dissipation of the downlight 20. It will be possible to suppress the loss.

As described above, according to the present embodiment, even if different types of downlights (lamps) 20 are used, it is possible to more reliably ensure a heat dissipation space of a size suitable for each downlight (lamp). become. That is, it is possible to obtain the luminaire 10 including the renewal plate (attachment auxiliary member) 50 and the renewal plate (attachment auxiliary member) 50 that can ensure the heat dissipation space more reliably.

Further, in the present embodiment, two (plural) side wall portions 520 are provided in the main body portion 510 in a state of being separated from each other in the circumferential direction of the mounting hole 514.

By doing so, the amount of bending of the heat insulating material 70 when the heat insulating material 70 is supported by the side wall portion 520 is relatively small, so that the heat insulating material 70 is more reliably prevented from approaching the downlight (lamp) 20. Will be able to.

It is also possible to provide the side wall portion 520 so as to extend over the entire circumference of the mounting hole 514. If the side wall portion 520 having a cylindrical shape is provided in the main body portion 510 in this manner, one main body portion 510 is provided. The side wall portion 520 will be provided. Even if the side wall portion 520 has a cylindrical shape, the amount of bending of the heat insulating material 70 is relatively small, so that the heat insulating material 70 can be more reliably suppressed from approaching the downlight (lamp) 20. it can.

However, if the side wall portion 520 has a cylindrical shape, the periphery of the downlight (lamp) 20 is completely surrounded by the side wall portion 520, so that heat is accumulated in the vicinity of the downlight 20 and the downlight 20 is affected by the heat. You may receive it.

On the other hand, in the present embodiment, since the two (plurality) side wall portions 520 are separated in the circumferential direction of the mounting hole 514, the entire periphery of the downlight (lamp) 20 is surrounded by the side wall portion 520. It is possible to suppress the loss. Therefore, it is possible to more reliably prevent heat from being accumulated in the vicinity of the downlight 20 and the downlight 20 being affected by the heat.

Further, in this embodiment, the two (plurality) side wall portions 520 are provided so as to be point-symmetric with respect to the center of the mounting hole 514.

By doing so, the distance between the two side wall portions 520 can be made equal to or larger than the opening diameter of the mounting hole 514, and the bent heat insulating material 70 is more reliably prevented from approaching the downlight (lamp) 20. You will be able to suppress.

Further, in the present embodiment, the tips 520b of the two side wall portions 520 (at least two side wall portions of the plurality of side wall portions) are connected by the connecting wall 530.

This makes it possible to more reliably suppress the bending of the heat insulating material 70 between the two side wall portions 520. Moreover, since the heat insulating material 70 can be supported by the surface, the heat insulating material 70 can be supported in a more stable state.

In addition, in the present embodiment, the side wall portion 520 includes a side wall portion main body 521 provided in the main body portion 510 and an extended wall 522 attached to the side wall portion main body 521.

Then, the extended wall 522 is attached to the side wall body 521 in a state in which the amount of protrusion from the tip 521b of the side wall body 521 is changed.

In this way, the structure can be simplified and the side wall portion 520 having the variable structure 560 can be formed more easily.

As shown in FIGS. 12 and 13, the lighting device body 30A of the downlight 20 in which the power supply device 40A and the lighting device body 30A are separately formed may be the lighting device 10 attached to the renewal plate 50. It is possible.

12 and 13 show an example in which the existing power supply device 400 is used as the power supply device 40A.

The power supply device 400 includes a substantially rectangular parallelepiped casing 410 and an attachment portion 450 to which the casing 410 is attached.

The housing 410 can be formed using, for example, a resin having an insulating property, and the housing 410 accommodates electronic parts (not shown) and the like.

A flexible cable 440 is connected to one end of the housing 410 in the longitudinal direction, and electronic components inside the housing 410 are electrically connected to the lamp body 30A via the cable 440. ing.

As shown in FIG. 12, a power supply terminal block 430 is formed on the other end side in the longitudinal direction of the housing 410, and the VVF cable 44 is connected to the power supply terminal block 430. The VVF cable 44 is electrically connected to a commercial power supply (not shown), and electric power is supplied to electronic components inside the housing 410 via the VVF cable 44.

The mounting portion 450 can be formed by bending a single plate-shaped member such as a galvanized steel plate, for example. Specifically, it is formed by bending both ends of one plate-shaped member in the longitudinal direction into an L shape. That is, the mounting portion 450 includes a mounting portion 450a on which the housing 410 is mounted, and leg portions 450b that can be mounted on the upper surface (back surface) 60a of the ceiling (wall portion) 60 and the like. There is.

When the lamp body 30A is attached to the renewal plate 50, such a power supply device 400 is placed on the upper surface (back surface) 60a of the ceiling 60 while being housed in the ceiling space S.

Here, when the power supply device 40A is provided separately from the lamp body 30A, when the lamp body 30A and the renewal plate 50 are attached to the ceiling 60 of the building on which heat insulation has been performed, the upper surface of the ceiling (wall portion) 60 The power supply device 40A is arranged between the (rear surface) 60a and the heat insulating material 70.

However, if the existing power supply device 400 is simply used, it will be covered with the heat insulating material 70 while the upper surface of the housing 410 is in contact with the heat insulating material 70. Therefore, heat may be trapped in the vicinity of the existing power supply device 400, and the power supply device 400 may be affected by the heat.

Therefore, in the power supply device 40A illustrated in FIGS. 12 and 13, it is possible to more reliably suppress the influence of heat while using the existing power supply device 400.

Specifically, the power supply device 40A further includes a pedestal 460 on which the existing power supply device 400 is placed.

The pedestal 460 is preferably made of a hard and durable material, and can be made of, for example, a metal material such as a steel plate or an iron plate.

The pedestal 460 is provided with a mounting portion 461 having a mounting surface 461a on which the power supply device 400 is mounted, and a partition portion that is continuous with the mounting portion 461 and extends upward (a direction intersecting with the mounting surface 461a). And 462.

Then, the power supply device 400 is placed on the placement surface 461a, and with the power supply device 400 positioned above the placement surface 461a, the tip of the partition 462 is projected above the power supply device 400. ing.

The power supply device 400 is fixed to the mounting portion 461 with screws 80, as shown in FIG. Further, the cable 440 is fixed to the mounting portion 461 by the pressing portion 440a, so that the cable 440 can be prevented from being pulled and detached from the power supply device 400 at the time of mounting work or the like.

Further, as shown in FIG. 13, the partition portion 462 is formed such that the tip end thereof has a semi-arcuate shape with an upward convex shape.

In addition, a pair of partitions 462 is formed, and the pair of partitions 462 mounts the power supply device 400 on the mounting surface 461a and positions the power supply device 400 above the mounting surface 461a. It is arranged so as to be located at diagonal corners of a substantially rectangular parallelepiped casing 410 in a plan view.

Furthermore, when the power supply device 40A is viewed from the width direction (widthwise direction) of the housing 410, the tip of one partition portion 462 of the pair of partition portions and the tip of the other partition portion 462 do not overlap. (See FIG. 13).

In addition, the pedestal 460 includes an extension portion 463 that is continuous with the mounting surface 461a and that extends substantially horizontally outside the mounting surface 461a. A pair of the extension portions 463 is also formed, and the pair of extension portions 463 has a plan view in a state in which the power supply device 400 is mounted on the mounting surface 461a and the power supply device 400 is positioned above the mounting surface 461a. Is located at a diagonal corner of the substantially rectangular parallelepiped casing 410.

Thus, in FIGS. 12 and 13, a pair of partitions 462 and extensions 463 are formed, and one partition 462 and the other extension 463 are arranged side by side in the width direction of the housing 410. The other partition 462 and the one extension 463 are arranged side by side in the width direction of the housing 410.

12 and 13, by bending both longitudinal ends of a single plate-shaped steel plate, leg portions 461b are formed at both longitudinal ends of the mounting portion 461, and the tips of the pair of extension portions 463 are formed. The legs 463a are respectively formed by bending the.

When the power supply device 40A having such a configuration is inserted into the ceiling hole 61 from the indoor space R side and accommodated in the ceiling space S, the thermal insulation 70 is pushed upward by the tip of the partition 462 while the ceiling (wall part) is being pushed upward. )60 is placed on the upper surface (back surface) 60a.

Here, in FIGS. 12 and 13, since the tip of the partition 462 has a semi-circular shape that is convex upward, when the power supply device 40A is moved while pushing the heat insulating material 70 upward, the partition 462 is insulated. It is possible to prevent the power supply device 40A from being caught on the ceiling and to arrange the power supply device 40A more smoothly in the ceiling.

When the power supply device 40A is arranged between the upper surface (back surface) 60a of the ceiling (wall portion) 60 and the heat insulating material 70, the heat insulating material 70 located above the housing 410 is moved upward by the pair of partitions 462. Will be supported in the state of being pushed up. That is, the gap S2 is formed between the upper surface of the housing 410 and the heat insulating material 70 (see FIG. 13).

This makes it possible to further reduce the influence of the heat of the power supply device 40A.

It should be noted that the shape of the pedestal 460 is not limited to the above-mentioned shape, and various shapes can be used.

Although the preferred embodiment of the present disclosure has been illustrated and described above, the present invention is not limited to the above embodiment, and various modifications can be made.

For example, in the above-described embodiment, the downlight embedded in the ceiling is exemplified as the lighting device, but it is also possible to embed and fix the lamp in the wall portion that defines the indoor space of the building and is not the ceiling. Is.

Further, the configurations of the lamp body and the power supply device are not limited to the configurations shown in the above-described embodiments, and conventionally known configurations can be adopted.

Further, the variable structure 560 is not limited to the configuration shown in the above embodiment, but can have various configurations. For example, the side wall 520 may have the variable structure 560 by forming a bellows on the side wall 520. It is also possible to form the side wall 520 in which a cylinder having a slightly smaller diameter is continuously inserted in a cylinder having a larger diameter. That is, it is possible that the side wall portion 520 is formed to be expandable and contractible using a plurality of cylinders having different diameters, and the side wall portion 520 has the variable structure 560.

Further, the specifications (shape, size, layout, etc.) of the extended wall, the side wall body, and other details can be changed as appropriate.

10 Lighting device 20 Downlight (lamp)
50 Renewal plate (attachment auxiliary member)
510 Main Body 514 Mounting Hole 520 Side Wall 520a Root 520b Tip 521 Side Wall Main Body 521b Tip 522 Extension Wall 530 Connecting Wall 560 Variable Structure 60 Ceiling (Wall)
60c peripheral part 61 ceiling hole (through hole)

Claims (6)

A mounting auxiliary member that is embedded and fixed in the through hole of the wall portion and to which the lamp is attached,
A main body portion that covers the peripheral portion of the through hole in the wall portion,
A side wall portion provided in the main body portion and inserted into the through hole,
Equipped with
The main body portion has an opening area smaller than that of the through hole, and a mounting hole into which the lamp is inserted is formed,
The side wall portion has a variable structure capable of changing the height from the root portion of the main body portion side to the tip end, and the tip end side can be projected more than the lamp fitting inserted into the mounting hole. An attachment assisting member, which is configured as follows. The attachment auxiliary member according to claim 1, wherein the main body portion is provided with the plurality of side wall portions so as to be spaced apart from each other in the circumferential direction of the attachment hole. The attachment auxiliary member according to claim 2, wherein the plurality of side wall portions are provided in the main body portion so as to be point-symmetric with respect to the center of the attachment hole. The attachment auxiliary member according to claim 2, wherein at least two side wall portions of the plurality of side wall portions are connected at their tips by a connecting wall. The side wall portion includes a side wall portion main body provided on the main body portion, and an extended wall attached to the side wall portion main body,
The extended wall is configured to be attached to the side wall body in a state in which the amount of protrusion from the tip of the side wall body is changed, and the extended wall is configured to be attached to the side wall body. The mounting auxiliary member according to the item. The mounting auxiliary member according to any one of claims 1 to 5,
A lamp attached to the attachment auxiliary member,
A lighting device comprising:

Images