JP2019102359A - Light source unit and lighting device - Google Patents

Abstract

To provide a light source unit that can widen a light distribution property of light.SOLUTION: Provided is a three-dimensional light source unit 10 constituted of multiple light source modules 1 connected to one another in a three-dimensional manner. The light source module 1 includes: at least one set of electric conductive wiring board having a high-potential side wiring board 11 and a low-potential side wiring board 12 while being separated apart from each other; and at least one light source element 13 implemented so as to straddle between the high-potential side wiring board 11 and the low-potential side wiring board 12.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a three-dimensional light source unit and a lighting device formed by connecting a plurality of light source modules in a three-dimensional manner.

  As a pendant light used by inserting a light bulb in a spherical globe and suspending it from a wall, a lighting device is disclosed which inserts a fluorescent light bulb in a spherical globe and emits light in a spherical manner (eg, patent document) 1).

JP, 2011-222423, A

However, in the pendant light of Patent Document 1, since a fluorescent light bulb is used, a base, a socket and a base holding member are present in the ceiling direction. Therefore, even if the amount of light in the downward direction and the lateral direction is sufficient, the amount of light emitted toward the ceiling is not sufficient, and it is difficult to widen the light distribution characteristic of light.
An object of the present invention is to provide a light source unit and a lighting device which can widen the light distribution characteristic of light.

A light source unit according to the present invention is a three-dimensional light source unit formed by connecting a plurality of light source modules in a three-dimensional manner, and the light source module separates a high potential side wiring board and a low potential side wiring board And at least one light source element mounted so as to straddle the high potential side wiring board and the low potential side wiring board.
A lighting device according to the present invention is a lighting device including a light source unit having a light source element and a lighting circuit for supplying power to the light source element, wherein the light source unit is the light source unit described above.

  According to the above configuration, by disposing the plurality of light source modules in a three-dimensional manner, light can be emitted in a desired direction, so that light distribution characteristics can be broadened.

It is a perspective view of a pendant light of an embodiment. It is a front view showing a light source module. It is explanatory drawing which shows the manufacturing method of a light source unit. It is a front view which shows the light source unit which concerns on another embodiment. (A) is a front view which shows the balloon illuminating device of embodiment, (b) is a front view which shows the balloon illuminating device of another embodiment. It is a perspective view of the pendant light of another embodiment.

<Overview>
The light source unit according to one aspect of the embodiment is a three-dimensional light source unit formed by connecting a plurality of light source modules in a three-dimensional manner, and the light source module comprises a high potential side wiring board and a low potential side wiring board And at least one light source element mounted so as to straddle the high potential side wiring board and the low potential side wiring board.
In the light source unit according to another aspect of the embodiment, the light source element is mounted on the surface of the conductive wiring board. Thereby, the utilization efficiency of light can be improved.
In the light source unit according to another aspect of the embodiment, the light source module has a reinforcing body that reinforces the connection between the high potential side wiring board and the low potential side wiring board. Thereby, the light source module can be further reinforced.
In the light source unit according to another aspect of the embodiment, the conductive wiring board is configured of a conductive metal plate. As a result, the conductive wiring board performs the function of a heat sink, so that a separate heat sink is not necessary, and the weight of the light source unit can be reduced.
In the light source unit according to another aspect of the embodiment, the light source module is a regular n-gon (n is an integer of 3 or more). Thereby, highly symmetrical emission characteristics can be obtained.
In the light source unit according to another aspect of the embodiment, the light source module has a through groove separating the high potential side wiring board and the low potential side wiring board. Thereby, the insulation between the high potential side wiring board and the low potential side wiring board becomes more reliable.

Embodiment
In the embodiment, a pendant light will be described as an example of a lighting device.
First Embodiment

1. Overview Overview will be described mainly using FIGS. 1 to 3.
The lighting apparatus 100 which is a pendant light includes a light source unit 10 including a plurality of light source modules 1 and a lighting circuit (not shown in FIGS. 1 to 3) for supplying power to the light source unit 10. The lighting device 100 is suspended from a ceiling or the like by a cable or string 30.
Each part will be described below.

2. Configuration of Each Part (1) Light Source Unit Description will be made mainly with reference to FIG.
The light source unit 10 has a polyhedral shape in which a plurality of (in this case, eighteen) light source modules 1 are connected three-dimensionally.
In the present specification, the polyhedral shape means a solid having a plurality of planes or a solid surrounded by a plurality of (four or more) planes. The polyhedron here is an orthorhombic octahedron consisting of squares (18 pieces) and regular triangles (8 pieces), but the light source unit 10 is composed of only squares (18 pieces).
(2) Light Source Module This will be described mainly with reference to FIG.
The light source module 1 includes a pair of conductive wiring boards having a high potential side wiring board 11 and a low potential side wiring board 12 separated from one another, and a plurality (here, six pieces) disposed on one side of the conductive wiring board. And an LED element (hereinafter simply referred to as “LED”) 13 as a light source of Here, the light source module 1 includes a reinforcing body 14 that reinforces the conductive wiring board.
The light source module 1 here is square in plan view.

(2-1) Conductive Wiring Board This will be described mainly with reference to FIG.
The conductive wiring board has an annular through groove 15 between the high potential side wiring board 11 and the low potential side wiring board 12. Thereby, the high potential side wiring board 11 and the low potential side wiring board 12 are separated. Here, the outer peripheral side of the annular through groove 15 is the high potential side wiring board 11, and the inner peripheral side of the annular through groove 15 is the low potential side wiring board 12.
As the conductive wiring board, a thin plate-like conductive metal plate (for example, a tin-plated steel plate or the like) is used. As a result, the conductive wiring board performs the function of a heat sink, so that a separate heat sink is not required, and the weight reduction of the light source unit 10 can be achieved.
The high potential side wiring board 11 has a square outer peripheral shape, and the low potential side wiring board 12 has a circular shape. The intersection (center) of the diagonal of the high potential side wiring board 11 coincides with the center of the low potential side wiring board 12.
The high potential side wiring board 11 and the low potential side wiring board 12 divide one plate member into two parts, one of which is the high potential side wiring board 11 and the other is the low potential side wiring board 12. Here, it is divided into two by the annular through groove 15.

(2-2) LED
This will be described mainly with reference to FIG.
The LED 13 is mounted so as to straddle the high potential side wiring board 11 and the low potential side wiring board 12 which are separated. The LEDs 13 are electrically connected in a desired connection form (parallel connection in this case). That is, the anode of the LED 13 is electrically connected to the high potential side wiring board 11, and the cathode of the LED 13 is electrically connected to the low potential side wiring board 12.
The LED 13 has a rectangular shape in a plan view, and the longitudinal direction thereof is arranged to coincide with the radial direction of the low potential side wiring board 12.
In the light source module 1, six LEDs 13 are mounted. The LEDs 13 are provided at positions symmetrical with respect to the intersection (center) of the diagonal of the square light source module 1. Particularly in FIG. 2, the six LEDs 13 are arranged to form a regular hexagon. Thereby, highly symmetrical emission characteristics can be obtained. Further, since the plurality of light source modules 1 are connected to form a polyhedron, it is possible to emit light having a wide and uniform light amount in the vertical and horizontal directions (all directions).
For example, a so-called Middle Power chip having a power consumption of 0.1 W or more and less than 1 W per chip is used as the LED 13. As a result, cost is low and high efficiency can be realized.
Here, in the polyhedron-shaped light source unit 10, the surface on which the LED 13 is mounted is taken as the surface. That is, the LED 13 is mounted on the surface of the polyhedron-shaped light source unit 10.
In the polyhedron-shaped light source unit 10, the conductive wiring board (high potential side wiring board 11 and low potential side wiring board 12) has a reflection film on the surface (surface) on which the LED 13 is mounted except for the mounting portion ing. The reflection film here is made of a white high reflection resin. Thereby, the light emitted from the LED 13 can be reflected to improve the utilization efficiency of the light.

(2-3) Reinforcement Body This will be described mainly with reference to FIG.
The reinforcing body 14 is disposed across the high potential side wiring board 11 and the low potential side wiring board 12 which are disposed to be separated by the annular through groove 15. Here, six reinforcing members 14 are disposed only on the surface (surface) on which the LEDs 13 are mounted. Six locations are provided between the six LEDs 13 and approximately in the middle.
The reinforcing body 14 is made of an insulating material. Thereby, the insulation between the high potential side wiring board 11 and the low potential side wiring board 12 can be secured, and the connection between the high potential side wiring board 11 and the low potential side wiring board 12 can be reinforced.
Here, as the insulating material, an insulating resin such as flame retardant V-0 glass-containing nylon and glass particles are used. By using the glass particles, the flame retardancy can be further improved.
The reinforcing body 14 may not necessarily be an insulating material. It may be a resistive element having a high resistance value (for example, MΩ), a capacitor, or the like. The reinforcing body 14 may be any type as long as the high potential side wiring board 11 and the low potential side wiring board 12 are not conducted.
(2-4) Connection The light source module 1 is in a state in which all the high potential side wiring boards 11 are connected according to a method to be described later, and electrical connection of the high potential side wiring boards 11 is unnecessary. The electrical connection between the low potential side wiring boards 12 may use jumpers or other connectors.

(2-5) Manufacturing Method of Light Source Unit This will be described mainly with reference to FIG.
First, one conductive metal plate 21 is prepared, and the eighteen light source modules 1 are pressed and punched into a shape 21a connected in a pendant shape (at the time of assembly). This is three-dimensionally bent as shown in FIG. 1 to produce a polyhedron-shaped light source unit 10.
In FIG. 3, since it pierce | punches from the conductive metal plate 21 of 1 sheet, the area | region 21b will remain. Therefore, 18 square light source modules 1 may be individually manufactured, and these may be joined using welding, a tape, a jig or the like to manufacture a polyhedral light source unit similar to that of FIG. According to this, the area 21b is full, which is more economical.
(3) Lighting Circuit The lighting circuit here is disposed in the internal space of the polyhedron-shaped light source unit 10.
The lighting circuit has a function of supplying power to the LED 13. The light source module 1 includes an output terminal unit for connecting an input terminal connected to the high potential side wiring board 11 with the lighting circuit and for connecting each low potential side wiring board 12 to the lighting circuit. The input terminal portion is for input (+) to the high potential side wiring board 11, and the output terminal portion is for output (-) from the low potential side wiring board 12 to the lighting circuit.

Second Embodiment
Next, a second embodiment of the light source unit will be described using FIG.
In FIG. 2 and FIG. 3 in the first embodiment, the annular through groove 15 in each light source module 1 is independent, and is not connected to the through groove 15 of the adjacent light source module 1. In FIG. 4 which is the second embodiment, the annular through groove 115 in each light source module 101 extends in at least one of upper, lower, left, and right directions, and is connected to the through groove 115 of the adjacent light source module 101. Thus, the high potential side wiring boards 111 in the light source module 101 can be connected to each other, and the low potential side wiring boards 112 in the light source module 101 can be connected to each other. be able to. The light source module 101 includes at least one of the high potential side wiring boards 111 with an input terminal connected to the lighting circuit, and each low potential wiring board 112 with an output terminal connected to the lighting circuits.
In this embodiment, reinforcements are not used but may be present.

Third Embodiment
The balloon illuminating device shown in FIG. 5 is demonstrated as an example of the illuminating device which is another embodiment.
The balloon illumination device 200 shown in FIG. 5A mainly includes a light source unit 201 as an illumination balloon, a cylindrical support 202 for supporting the light source unit 201, and a movable carriage 203. The arrow indicates the light emission direction.
As the light source unit 201, a plurality of light source modules 211 mounted with LEDs 213 can be used. The light source unit 201 here is a semi-polyhedron shape in which the upper half of the polyhedron shape is omitted. As a result, light can be emitted uniformly only in the lower direction and obliquely lower direction of the light source unit 210, and light can not be emitted in the upper direction. Therefore, it is suitable for use in a place (for example, a construction site etc.) which does not require upward light.
As the LED 213, for example, a so-called High Power chip (made of ceramic) having a power consumption per chip of 1 W or more is used. As a result, a light flux of 100,000 lm class required for the balloon illumination device can be secured, and the reliability is improved.
FIG. 5B shows another example of the balloon illumination device 300, which mainly includes a light source unit 301 as an illumination balloon, a cylindrical support base 302 for supporting the light source unit 301, and a movable carriage 303. Be done.
As the light source unit 301, a combination of a plurality of light source modules 311 on which the LEDs 313 are mounted can be used. The light source unit 301 here has a larger number of connected light source modules 311 than the light source unit 201 shown in FIG. 5A, and is configured to emit light uniformly in the lateral direction.

As mentioned above, although embodiment was described, it is not restricted to this embodiment, For example, the following modifications may be sufficient. In addition, the embodiment, the modification, and the modifications may be combined.
In addition, even if there is an example not described in the embodiment or the modification, or a design change in a range not departing from the gist, the present invention is included in the present invention.

<Modification>
1. Light Source Unit The polyhedron-shaped light source unit 10 according to the embodiment is formed of only squares (18 pieces), but may include equilateral triangles (8 pieces) that fill the gaps generated between the square light source modules. The shape of the light source unit is not particularly limited as long as the light source unit has a three-dimensional structure by electrically connecting a plurality of light source modules, but a wide and uniform amount of light is emitted in all directions. A polyhedron shape is preferable in that the emitted light can be obtained.
In the embodiment, a plurality of light source modules are connected so as to form a space inside, but for example, a flat plate may be connected in a two-dimensional manner such as being bent in a zigzag shape in the thickness direction.
Also, a plurality of light source modules may be arranged in a row, and in that case, LEDs with different emission colors in each row may be used. For example, one row of bulb colors, the other row may be daylight.
2. Light Source Module In the embodiment, the light source module 1 is a square, but may be a polygon such as a triangle, and is preferably a regular n-gon (n is an integer of 3 or more). Also, it may include a curved line other than the connecting part, for example, a curve such as a missing circle shape.
Moreover, although all the light source modules 1 in the light source unit 10 have the same shape (square), they may be a combination of different shapes (for example, a square and a triangle).
In the embodiment, all of the high potential side wiring board and the low potential side wiring board of the light source module have the same shape, but for example, the shapes of the high potential side wiring board are all the same, and the shape of the low potential side wiring board May be different. As a specific example, the low potential side wiring board may be circular, triangular or square. Also, the shape of the high potential side wiring board may be different from the shape of the low potential side wiring board.

3. Although the number of mounted LEDs 13 in the light source module 1 is six, the number of mounted LEDs can be appropriately changed according to the shape of the light source module and the like. When the light source module is a regular n-gon (n is an integer of 3 or more), the LEDs are preferably arranged to be point-symmetrical with respect to the center of the regular n-gon. As a result, since highly symmetrical emission characteristics can be obtained in the light source module, it is possible to obtain outgoing light with a uniform light quantity.
In the embodiment, the LEDs are connected in parallel, but may be connected in series. For example, as shown in FIG. 6, it may be 6 parallel × 18 series. Specifically, in the light source module 1 in which two adjacent light sources are in one set, the low potential side wiring body 12 of the light source module 1 located on the high potential side and the high potential side of the light source module 1 located on the low potential side It can implement by electrically connecting the wiring body 11 with the lead wire 41 grade | etc.,. The adjacent light source modules 1 are insulated by the insulating frame 40.
In addition, although it is preferable that LED is arrange | positioned on the surface of a light source unit, you may be arrange | positioned on the back surface of a light source unit, and may be arrange | positioned on front and back both surfaces.
In the embodiment, LEDs of the same emission color are used, but plural types of LEDs of different emission colors may be used.
4. In the embodiment, the through groove 15 has an annular shape close to a perfect circle when the light source module 1 is viewed from the front, but it may be an elliptical shape, a polygonal shape such as a triangle, or a linear shape. Moreover, although the penetration groove | channel 15 was arrange | positioned concentrically from the center of the light source module 1, you may shift | deviate from a center.
In the embodiment, the through groove 15 may be closed but not closed in a front view. For example, one side of the outer portion may be recessed inwardly.
5. The high potential side wiring board and the low potential side wiring board In the embodiment, the outer peripheral side of the through groove 15 is the high potential side wiring board, and the inner peripheral side is the low potential side wiring board.
Further, the shapes of the high potential side wiring board and the low potential side wiring board separated by the through groove are not particularly limited, and are appropriately determined according to the shape of the above through groove.
The conductive metal plate used for the conductive wiring board is not limited to metal, and may be a sheet of conductive plate such as copper foil attached to an insulating plate such as paper.

6. Reinforcement Body The reinforcement body 14 is provided only on the mounting surface of the LED 13 (the front surface of the light source module 1), but may be provided only on the back surface or on both front and back surfaces. The through groove may be filled with a resin or the like to bond the high potential side wiring board and the low potential side wiring board.
7. Lighting Circuit The lighting circuit is disposed inside the polyhedron-shaped light source unit 10, but may be disposed outside. Alternatively, the commercial power supply may be directly applied by adjusting the number of LEDs and mounting the anode and the cathode in reverse.
8. In the embodiment, the light source unit constituting the illumination balloon is formed in a semi-polyhedron shape in which the upper half of the polyhedron shape is omitted, but the present invention is not limited thereto. The light may be emitted not only laterally but also upward. Furthermore, the upper half and the lower half may be separate units, and the lower half, the upper half, and the upper and lower may be made to emit light as necessary. The shape of the light source unit constituting the illumination balloon can be appropriately changed in accordance with the use place and purpose of use of the balloon illumination device.
9. Light source cover The light source unit may be covered with a diffusive cover. The cover can use resin and glass. It may have a diffusion on the front or back. The diffusion portion is implemented by blasting, coating of a diffusion film, and in the case of a diffusion film, embossing of a mold or the like.

1 light source module 10 light source unit 11 high potential side wiring board 12 low potential side wiring board 13 LED (light emitting element)
100 lighting system

Claims (7)

A three-dimensional light source unit in which a plurality of light source modules are connected in a three-dimensional manner,
The light source module is
At least one pair of conductive wiring boards having a high potential side wiring board and a low potential side wiring board separated from each other;
A light source unit comprising: at least one light source element mounted so as to straddle the high potential side wiring board and the low potential side wiring board. The light source unit according to claim 1, wherein the light source element is mounted on a surface of the conductive wiring board. The light source unit according to claim 1, wherein the light source module has a reinforcing body that reinforces a connection between the high potential side wiring board and the low potential side wiring board. The light source unit according to any one of claims 1 to 3, wherein the conductive wiring board is configured of a conductive metal plate. The light source unit according to any one of claims 1 to 4, wherein the light source module is a regular n-gon (n is an integer of 3 or more). The light source unit according to any one of claims 1 to 5, wherein the light source module has a through groove separating the high potential side wiring board and the low potential side wiring board. A light source unit having a light source element;
And a lighting circuit for supplying power to the light source element.
The lighting apparatus which is a light source unit in any one of Claims 1-6.

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