JP2021007112A - Luminaire - Google Patents

Abstract

To provide a luminaire that can restrain a power source part arranged between a radiator and a fitting part of an arm from being thermally affected by the radiator.SOLUTION: A luminaire 10 comprises a light emitting module 11, a radiator 12, an arm 14, and a power source part 15. The radiator 12 comprises a light source fitting part 26 in which the light emitting module 11 is arranged on a lower surface. The arm 14 comprises a fitting part 31 arranged with a space above the radiator 12, and arm parts 32 provided at both ends of the fitting part 31 and supporting the radiator 12. The power source part 15 comprises a power source circuit 39 and a power source box 38 housing the power source circuit 39, and is arranged between the arm parts in such a manner that an upper surface side of the radiator 12 and a lower surface side of the power source box 38 are opposed to each other between the radiator 12 and the fitting part 31 of the arm 14.SELECTED DRAWING: Figure 1

Description

An embodiment of the present invention relates to a luminaire using a light emitting module.

Conventionally, for example, there are lighting fixtures for high ceilings used for illuminating spaces with high ceilings such as facilities. In this luminaire, a light emitting module having a light emitting element is used, and this light emitting module is attached to the lower surface of the radiator. A plurality of heat radiating fins for radiating heat generated by the light emitting element are provided on the upper surface of the radiator. The radiator is supported by a main body chassis arranged above the radiator, and a power supply unit is arranged on the main body chassis. An arm for installing on the ceiling or the like is connected to the main body chassis. The arm has a mounting portion to be installed on the ceiling or the like, and an arm portion bent from both ends of the mounting portion, and the arm portion is connected to the main body chassis. When the lighting equipment is lit, the heat generated by the light emitting element is dissipated by the radiator to suppress the temperature rise of the light emitting element.

Further, for example, in order to reduce the size, there is a lighting fixture in which a power supply unit is arranged between a radiator and an arm mounting portion arranged with a space above the radiator.

In the case of this luminaire, a relatively large space is provided between the power supply unit and the arm mounting portion in order to facilitate the work of mounting the arm mounting portion on the ceiling or the like.

Therefore, the radiator and the power supply unit may be arranged relatively close to each other, and the heat released from the radiator raises the temperature of the power supply unit, resulting in an increase in power consumption and thermal stress on the power supply parts and the like. It is easy for thermal effects to occur.

Japanese Unexamined Patent Publication No. 2013-201080

An object to be solved by the present invention is to provide a luminaire capable of suppressing the heat influence from the radiator on the power supply portion arranged between the radiator and the mounting portion of the arm.

The luminaire of the embodiment includes a light emitting module, a radiator, an arm, and a power supply unit. The radiator has a light source mounting portion that disposes the light emitting module on the lower surface. The arm has a mounting portion arranged above the radiator with a space, and an arm portion provided at both ends of the mounting portion to rotatably support the radiator. The power supply unit has a power supply circuit and a power supply box for accommodating the power supply circuit, and the arm portion is such that the upper surface side of the radiator and the lower surface side of the power supply box face each other between the radiator and the mounting portion of the arm. It is arranged between them.

According to the present invention, it can be expected that the power supply unit arranged between the radiator and the mounting portion of the arm is suppressed from being affected by heat from the radiator.

It is a perspective view seen from the lower surface side of the luminaire which shows the 1st Embodiment. It is a perspective view seen from the upper surface side of the above-mentioned lighting equipment. It is a perspective sectional view of the luminaire which shows the 2nd Embodiment.

Hereinafter, the first embodiment will be described with reference to FIGS. 1 and 2.

The luminaire 10 is a high-ceiling luminaire used for illuminating a space with a high ceiling such as a facility.

The luminaire 10 includes a light emitting module 11, a radiator 12 for arranging the light emitting module 11, a translucent cover 13 for covering the light emitting module 11, an arm 14 for supporting the radiator 12, and a power supply arranged on the arm 14. It has a part 15 etc.

The light emitting module 11 includes a substrate 20 and a plurality of light emitting elements 21 mounted on one surface of the substrate 20 (note that a part of the light emitting element 21 is shown in the figure, and the others are omitted). doing.). The substrate 20 is formed in a quadrangle (for example, a square), and a pattern for mounting the light emitting element 21 is provided on one surface thereof. The substrate 20 is attached to the lower surface of the radiator 12 by, for example, a plurality of screws so that the other surface of the substrate 20 is in close contact with the lower surface of the radiator 12 via the heat radiating sheet 22 having an insulating property. A wiring hole 23 is formed in the center of the substrate 20. A wiring hole (not shown) is also formed in the center of the heat radiating sheet 22. Further, as the light emitting element 21, for example, a surface mount type LED is used, and the light emitting element 21 is mounted in a predetermined arrangement on a pattern on one surface of the substrate 20. The light emitting element 21 is not limited to the LED, and other light emitting elements such as an organic EL may be used.

Further, the radiator 12 includes a light source mounting portion 26, a plurality of heat radiating fins 27 protruding from the upper surface of the light source mounting portion 26, and a pair of arm connecting portions 28 provided on both sides of the light source mounting portion.

The radiator 12 is made of a metal material such as aluminum. The light source mounting portion 26 and each heat radiation fin 27 may be separated from each other, and each heat radiation fin 27 may be inserted and fixed in a plurality of slits provided on the upper surface of the light source mounting portion 26, or the light source mounting portion 26 and the heat radiation fins may be fixed. 27 may be integrally formed by, for example, extrusion molding.

The light source mounting portion 26 is provided in a square shape (for example, a square shape) and in a flat plate shape, and a wiring hole (not shown) is formed in the center. Then, the substrate 20 of the light emitting module 11 is attached to the lower surface of the light source mounting portion 26 via the heat radiating sheet 22.

The heat radiation fins 27 are provided on the upper surface of the light source mounting portion 26 so as to be parallel to each other between one of the opposite side surfaces of the light source mounting portion 26. The distance between the heat radiation fins 27 adjacent to each other near the center of the light source mounting portion 26 is larger than the distance between the heat radiation fins 27 adjacent to each other near the ends on both sides centered near the center portion of the light source mounting portion 26. Widely formed. That is, the heat radiation fins 27 are not provided near the central portion of the light source mounting portion 26, and the wiring holes of the light source mounting portion 26 are opened.

The pair of arm connecting portions 28 are provided so as to project from the center of both side surfaces of the light source mounting portion 26 intersecting the fin parallel arrangement direction to both end sides of the plurality of heat radiation fins 27. The arm connecting portion 28 may be integrally formed with the light source mounting portion 26 and bent from the light source mounting portion 26, or may be formed separately from the light source mounting portion 26 and mounted on the light source mounting portion 26. It may have been.

Further, the translucent cover 13 covers the light emitting module 11 and is attached to the radiator 12. The light-transmitting cover 13 may be a clear cover having good light transmission, or a diffusion cover that diffuses light. The translucent cover 13 closes the lower surface side of the radiator 12 to which the light emitting module 11 is attached to prevent insects, dust, and the like from entering.

Further, the arm 14 is arranged so as to face each other with a space above the radiator 12, and is bent downward from both ends of the attachment 31 and directly connected to both sides of the radiator 12. It is provided with a pair of arm portions 32 to be formed. The arm 14 is integrally formed of, for example, a metal plate.

The mounting portion 31 is provided with a plurality of mounting holes 33 for mounting the mounting portion 31 on the ceiling or the like as a mounted portion.

Each arm portion 32 is connected to both sides in a direction intersecting the fin parallel arrangement direction of the radiator 12, that is, is connected to arm connecting portions 28 on both sides of the radiator 12.

The tip end side of each arm portion 32 is arranged outside the arm connecting portion 28, and a connecting tool (for example, a bolt) (for example, a bolt) for inserting the connecting hole 34 provided in the arm portion 32 and the hole provided in the arm connecting portion 28 is inserted. And nuts) are rotatably connected. An arc-shaped angle adjusting groove 35 centered on the connecting hole 34 is formed in the arm portion 32, and tightening (not shown) through which the angle adjusting groove 35 of the arm portion 32 and the hole provided in the arm connecting portion 28 are inserted. It is tightened and fixed by tools (eg bolts and nuts). The angle of the arm 14 installed on the ceiling or the like can be adjusted so that the light irradiation direction of the lighting fixture 10 is a predetermined direction such as a direction directly below.

Further, the power supply unit 15 is attached to the arm 14. That is, the power supply unit 15 is erected between the arm units 32 on both sides of the arm 14. The power supply unit 15 is arranged between the radiator 12 and the mounting portion 31 of the arm 14 with a space between the radiator 12 and the mounting portion 31 of the arm 14, respectively. Let x be the distance between the upper part of the radiator 12 (the upper end of the heat dissipation fin 27) and the lower surface of the power supply unit 15, and y be the distance between the mounting portion 31 of the arm 14 and the upper surface of the power supply unit 15. The distance x between the 12 and the power supply unit 15 is wider than the distance y between the mounting portion 31 of the arm 14 and the power supply unit 15, and the distance x is arranged in a positional relationship of x> y. The height h of the power supply unit 15 is smaller than the distance x between the radiator 12 and the power supply unit 15 and the distance y between the mounting portion 31 of the arm 14 and the power supply unit 15.

The power supply unit 15 includes a power supply box 38 and a power supply circuit 39 housed in the power supply box 38.

The power supply box 38 is a square body having a pair of rectangular main surfaces 40 having the widest surface, a pair of side surfaces 41 in contact with the long sides of these main surfaces 40, and a pair of end faces 42 in contact with the short sides of the main surface 40. It is formed in a shape. Both end faces 42 of the power supply box 38 are attached to the inside of the arm portion 32.

The power supply box 38 (power supply unit 15) is attached to the arm 14 so that the main surface 40 faces sideways along the direction in which the main surface 40 intersects the longitudinal direction of the arm unit 32. In this case, the main surface 40 of the power supply box 38 (power supply unit 15) faces the radiator 12 and covers the upper part of the radiator 12.

The power supply circuit 39 includes a power supply board and electronic components mounted on the power supply board. Then, the power supply circuit 39 inputs an AC power source, converts the AC power source into a predetermined DC power source, supplies the AC power source to the light emitting module 11, and lights the light emitting element 21. Further, the power supply circuit 39 inputs a dimming signal from an external control device, and dimming controls the light emitting element 21 according to the dimming signal.

The power supply unit 15 and the light emitting module 11 are electrically connected by a power supply cable. The power supply cable is wired through the wiring hole 23 of the board 20, the wiring hole of the heat dissipation sheet 22, the wiring hole of the light source mounting portion 26 of the radiator 12, and the heat radiation fin 27 in the center, and one end is connected to the power supply portion 15. The other end is connected to the substrate 20 of the light source module 11.

Then, the lighting fixture 10 configured in this way is installed by mounting the mounting portion 31 of the arm 14 on the ceiling or the like. When the ceiling or the like is tilted, the arm 14 is also tilted, but by adjusting the angle of the radiator 12 with respect to this arm 14, the light irradiation direction from the luminaire 10 can be changed to, for example, directly below. Can be set.

The AC power source is converted into a predetermined DC power source by the power supply unit 15 and supplied to the light emitting module 11, so that the light emitting element 21 of the light emitting module 11 is turned on. The light from the light emitting element 21 that lights up passes through the translucent cover 13 and irradiates the illumination space.

The heat generated by the light emitting element 21 at the time of lighting is mainly transmitted from the substrate 20 to the radiator 12, and is dissipated into the air from the plurality of heat radiating fins 27 of the radiator 12.

By the way, since the power supply unit 15 attached to the arm 14 is arranged between the radiator 12 and the attachment portion 31 of the arm 14, it is easy to approach the radiator 12. The heat radiated from the radiator 12 is diffused into the air, but if the power supply unit 15 is arranged near the top of the radiator 12, the power supply unit 15 will be affected by the heat from the radiator 12. It is easily affected, and the temperature of the power supply unit 15 rises, which tends to affect the increase in power consumption and the life of electronic components.

On the other hand, in the luminaire 10 of the present embodiment, the power supply unit 15 leaves a space between the radiator 12 and the mounting portion 31 of the arm 14 with respect to the radiator 12 and the mounting portion 31 of the arm 14, respectively. It is arranged at a position where the distance x between the power supply unit 15 and the radiator 12 is wider than the distance y between the power supply unit 15 and the mounting portion 31 of the arm 14. Therefore, it is possible to prevent the power supply unit 15 arranged between the radiator 12 and the mounting portion 31 of the arm 14 from being affected by heat from the radiator 12. Therefore, the temperature rise of the power supply unit 15 can be suppressed, the power consumption can be improved, and the life of the electronic component can be extended.

In order to prevent the power supply unit 15 from being affected by heat from the radiator 12, the distance y between the power supply unit 15 and the mounting portion 31 of the arm 14 is made as small as possible, and the power supply unit 15 and the radiator 12 are used. It is preferable to increase the distance x between the two. However, since the distance y between the mounting portion 31 of the arm 14 and the power supply portion 15 is a work space required for mounting the arm 14 on the ceiling or the like, secure a distance that does not interfere with the work. Is preferable.

Next, FIG. 3 shows a second embodiment. Regarding the same configuration as that of the first embodiment, the same reference numerals are used and the description of the configuration and the action and effect will be omitted.

The radiator 12 has a tubular portion 50 projecting from the center of the upper surface of the light source disposing portion 26. The tubular portion 50 is made of metal, for example, and is formed in a cylindrical shape that opens up and down. The lower end is fixed in a state of being thermally connected around the wiring hole of the light source arrangement portion 26, and the inside is the light source arrangement portion. It communicates with 26 wiring holes.

The tubular portion 50 is arranged between the heat radiating fins 27 having a wide space near the center of the light source mounting portion 26, and is projected above the heat radiating fins 27. The distance between the upper end of the tubular portion 50 and the power supply portion 15 is 80 mm or less.

A power supply cable 51 that electrically connects the light emitting module 11 and the power supply unit 15 is wired in the cylinder portion 50.

By the way, by widening the distance x between the radiator 12 and the power supply unit 15, the length of the power supply cable 51 exposed to the outside between the radiator 12 and the power supply unit 15 tends to be long. However, according to the internal wiring regulations, the length that can be exposed is specified as 80 mm.

In the present embodiment, the length of the power supply cable 51 exposed to the outside can be shortened by projecting the tubular portion 50 for wiring the power supply cable 51 to the radiator 12, and the internal wiring regulation can be satisfied. it can.

Further, the heat transferred from the light emitting module 11 to the light source mounting portion 26 is also transmitted to the cylinder portion 50 together with the heat radiating fin 27, and can be radiated into the air from this cylinder portion 50 as well, and the heat dissipation performance of the radiator 12 can be improved.

Moreover, although the temperature tends to be highest in the center of the light source mounting portion 26, by providing the cylinder portion 50 in the center of the light source mounting portion 26, the heat in the center of the light source mounting portion 26 can be effectively dissipated by the cylinder portion 50. , The temperature rise in the center of the light source mounting portion 26 can be suppressed.

In addition, for example, a plurality of heat radiating fins may be provided around the cylinder portion 50 in a radial manner, the heat transferred to the cylinder portion 50 can be radiated more effectively, and the heat radiating performance of the radiator 12 can be further improved.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

10 Lighting equipment
11 Luminous module
12 radiator
14 arm
15 Power supply
26 Light source mounting part
31 Mounting part
32 arm part
38 Power box
39 Power circuit

Claims (1)

With a light emitting module;
With a radiator having a light source mounting portion for arranging the light emitting module on the lower surface;
An arm having a mounting portion arranged with a space above the radiator, and arm portions provided at both ends of the mounting portion to rotatably support the radiator;
The power supply circuit and a power supply box for accommodating the power supply circuit are provided, and the upper surface side of the radiator and the lower surface side of the power supply box face each other between the radiator and the mounting portion of the arm. With the power supply unit arranged between the arm units;
Lighting equipment characterized by being equipped with.

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