KR20130098128A - A light emitting device module with waterproof function and a plane light source apparatus using the same - Google Patents

Abstract

PURPOSE: An optical device module with a waterproof function and a surface light source device using the same are provided to prevent an electric leakage due to moisture or water included in air by including a waterproof member in an inner space between a housing and a substrate. CONSTITUTION: A substrate (100) is formed with a planar member and forms the lower area of an optical device module (10). An optical device (200) is combined with the upper section of the substrate. A housing (300) is separated into a first inner space which is close to the optical device and a second inner space which is distant from the optical device. A light control unit (400) is formed with a planar shape to control the light emission of the optical device. Waterproof members (500) are formed in the first inner space and the second inner space.

Description

Optical device module with waterproof function and surface light source device using the same {A Light Emitting Device Module With Waterproof Function and A Plane Light Source Apparatus Using the Same}

The present invention relates to an optical device module having a waterproof function and a surface light source device using the same, and more particularly, to a light emitting device having excellent waterproofness and a wide range of direct angles and excellent durability and economical efficiency.

Recently, light emitting diodes (LEDs) are driven with low power consumption and have low heat generation, and thus are used as light sources in various technical fields. Many efforts have been made to realize illumination with uniform brightness with a small difference in contrast using LEDs, which are point sources. In addition, efforts are being made to make durable LEDs that can be used stably for a long time regardless of indoor or outdoor.

Accordingly, Korean Patent Publication No. 10-2010-0127895 minimizes the components and easily implements the coupling between the components. However, the waterproof silicon is formed on the top to block the exposure of the electrical connection to the outside to increase durability. It was.

However, this disclosure has not been provided with a lens for light diffusion on the top of the LED chip to emit light in a narrow range of light efficiency is inferior. In addition, even in a light emitting device having a conventional light diffusing lens, the light directing angle with respect to the light emitting member is only about 120 °, and light is concentrated around the optical axis A, so that smooth light dispersion is achieved even within the range of the directing angle. There was a problem not to lose.

In addition, when waterproof silicone was applied and formed on the LED chip as it was, it was not possible to effectively cool the heat generated by the use of the LED. This causes a problem that rather hinders the durability of the LED module.

In addition, in the case of forming the waterproof silicon on the LED chip, it had to be formed of a transparent material so that the light generated from the LED chip can pass. This results in a light uniformity depending on the coating thickness, the coating uniformity of the waterproof silicone, or the degree of inclusion of impurities in the silicone. This has a problem in that the light quality of the LED module cannot be kept constant.

Accordingly, the present invention has been made to solve the above problems, it is provided with a waterproof member in the inner space between the housing and the substrate having a waterproof function that can prevent a short circuit due to moisture or water contained in the air. An optical device module and a surface light source device using the same are provided.

In addition, the optical control unit is coupled to the upper surface of the housing to implement a wide range of light directing angle (150 °) of the optical device, and provides an optical device module having a waterproof function to achieve a light uniformity through the depression and the surface light source device using the same. There is.

In addition, the present invention provides a surface light source device capable of more stably supplying power and controlling current by driving a plurality of optical device modules with a dedicated constant current driver.

In addition, by providing a heat sink between the optical device module and the frame to provide an optical device module having a waterproof function that can effectively remove the heat generated by the use of the optical device module and a surface light source device using the same.

The problems to be solved by the present invention are not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

Means for achieving the object of the present invention, the plate-shaped substrate; An optical device coupled to the top surface of the substrate; A housing coupled to the top surface of the substrate to receive the optical device and forming an inner space together with the substrate; It is coupled to the upper surface of the housing, it is made of a plate to control the emission of light generated from the optical device, the upper surface is formed with a flat output surface for emitting light generated from the optical device to the outside, the lower surface from the optical device A light control unit having a recessed portion formed concave upward with respect to an optical axis from which the generated light is straight; And an inner space divided into a first inner space close to the optical element and a second inner space far from the optical element, and include a waterproof member provided in the second inner space.

In addition, the depression is characterized in that the angle between the direction of emitting light of maximum intensity from the optical element and the direction of emitting light that is half of the maximum intensity is characterized in that it is formed to be 75 °.

In addition, a plate-shaped substrate, an optical element coupled to the upper end surface of the substrate, a housing coupled to the upper side to accommodate the optical element and to form an inner space with the substrate, coupled to the housing upper surface to control the emission of light generated from the optical element The upper surface is flat, and the upper surface has a flat output surface for emitting the light emitted from the optical element to the outside, and the lower surface has the recessed portion concave upward on the optical axis from which the light emitted from the optical element goes straight. The optical control unit and the internal space formed are divided into a first internal space close to the optical device and a second internal space far from the optical device and a plurality of optical device module including a waterproof member provided in the second internal space; A frame accommodating a plurality of optical device modules; And wires for supplying power by connecting the optical device modules to each other.

In addition, the depression is characterized in that the angle between the direction of emitting light of maximum intensity from the optical element and the direction of emitting light that is half of the maximum intensity is characterized in that it is formed to be 75 °.

In addition, a heat sink is further provided between the optical device module and the frame.

In addition, the plurality of optical device module is characterized in that the operation by receiving power through a power supply of the constant current drive method or constant voltage drive method.

According to the present invention, the waterproof member is provided in the inner space between the housing and the substrate to prevent a short circuit caused by moisture or water contained in the air, thereby providing stable use indoors and outdoors.

In addition, the optical control unit is coupled to the upper surface of the housing to implement a wide and uniform light directivity angle (150 °) of the optical device, even if a small number of optical device modules can be realized the same brightness as the conventional light emitting device, through the depression There is an effect that can achieve a smooth light dispersion in which no dark portion is formed within the range of light directivity angle.

In addition, by driving the plurality of optical device modules with a dedicated constant current driver, the power supply and current control to the optical device module is made more stable, thereby increasing the stability and durability of the surface light source device.

In addition, by providing a heat sink between the optical device module and the frame can effectively remove the heat generated by the use of the optical device module has the effect of increasing the stability and durability.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a perspective view of an optical device module according to the present invention.
2 is an exploded perspective view of an optical device module according to the present invention.
3 is a front sectional view, a plan view and a rear view of an optical device module according to the present invention.
Figure 4 is a front sectional view showing a directing angle to the light control unit of the optical device module according to the present invention.
5 is a front view of the surface light source device according to the present invention.
6 is a partially exploded perspective view of the surface light source device according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the configuration of the optical device module 10 having a waterproof function and the surface light source device 1 using the same according to a preferred embodiment of the present invention.

(Optical device module)

1 is a perspective view of an optical device module according to the present invention, Figure 2 is an exploded perspective view of the optical device module according to the invention, Figure 3 is a front sectional view, a plan view and a bottom view of the optical device module according to the invention, 4 is a front sectional view showing a directing angle to the light control unit of the optical device module according to the present invention.

The optical device module 10 having a waterproof function according to the present invention can implement a wide and uniform light directivity, achieve a smooth light dispersion, and implements an optical device module 10 having excellent waterproof function. .

1 to 4, the optical device module 10 having a waterproof function according to the present invention is approximately the substrate 100, the optical device 200, the housing 300, the light control unit 400 and It may be made to include a waterproof member 500.

First, the substrate 100 is formed of a plate-shaped member to form a lower region of the optical device module 10. An upper surface of the substrate 100 is provided with an area in which the optical device 200 is installed, and wiring is formed to supply driving power to the optical device 200. At this time, the wiring (not shown) may be made of a thin wire, but it is preferable to provide a driving power by forming a printed circuit (PCB).

The electrical connection between the wiring formed on the substrate 100 and the external power supply device is connected through the wire 110, and the series connection between the plurality of optical device modules 10 is also performed through the wire 110. In this case, the electrical connection between the wire 110 and the substrate 100 may be formed by soldering or the like.

In addition, one side of the wire 110 may be provided with a fuse 120 to block the overcurrent. By providing the fuse 120 as described above, excessive current of more than a predetermined value can be prevented from continuously flowing, and thus, the stable optical device module 10 can be operated.

The outer shell of the wire 110 in the embodiment according to the present invention may be formed of a silicon material. The outer sheath of the silicon material may help to increase the waterproof effect of the optical device module 10 because the mutual adhesiveness strongly acts with the waterproof member 500 to be described later.

On the other hand, the substrate 100 may be equipped with a device for smoothing or stepping down the input power source, a device for rectifying the power source, a resistor or a capacitor for the stable operation of the optical device 200.

In the case where the substrate 100 is formed of a printed circuit board (PCB), the plate-shaped member serving as the base material of the substrate 100 is made of aluminum having a high thermal conductivity, and thus heat generated due to the use of the optical device 200 is obtained. It is desirable to be able to release well to the outside.

If the heat dissipation is well done, it is possible to prevent the current flowing through the optical device 200 (in the case of a semiconductor light emitting diode (LED)) to increase. This is because the resistance of the semiconductor decreases as the temperature rises and the current increases. (See Ohm's law.) Therefore, the heat radiation helps to increase the durability of the optical device module 10.

The optical device 200 is a light emitter for generating light, and the optical device 200 according to the present invention may use an LED which is a semiconductor device that emits light by passing a current through a compound such as gallium arsenide. The optical device 200 is coupled to the top surface of the substrate 100 on which the wiring is formed to receive driving power from an external power supply device to generate light. Since the optical device 200 such as an LED corresponds to known technologies, a detailed description thereof will be omitted.

However, as described above, the LED made of a semiconductor has a characteristic that the resistance value decreases as the temperature rises.

The housing 300 is a component constituting the appearance of the optical device module 10 according to the present invention, and is positioned above the substrate 100. The housing 300 may be formed in a tubular shape of which the lower side is open. The lower opening of the housing 300 may be larger than the size of the substrate 100 to accommodate the optical device 200, the substrate 100, and the like in the internal space 310 of the housing 300.

The housing 300 accommodates the substrate 100, but is coupled to the top surface of the substrate 100 while being spaced apart from each other. As a result, a constant internal space 310 is formed between the inner surface of the housing 300 and the substrate 100. At this time, the coupling method between the housing 300 and the upper surface of the substrate 100 may be a method of fastening at least two symmetrical points using the screw 340.

On the other hand, at least one of the housing 300 and the substrate 100 may be formed with a wire fixing groove 330 in a position where the wire 110 is connected to support and fix the wire 110.

The housing 300 may be made of any material as long as it can be molded into a shape that can accommodate the optical device 200 and the substrate 100. However, in the embodiment of the present invention, the housing 300 is manufactured of a synthetic resin made of a transparent material that can transmit light.

Light control unit 400 is a component that diffuses the light by controlling the emission of the light generated from the optical device 200, the light generated from the optical device 200 passes through the light control unit 400 in a wide range of a predetermined range And have a uniform light directivity angle. The light control unit 400 is to determine the characteristics of the light emitted is a part that can be variously modified according to the purpose and use of the optical device 200.

Light control unit 400 according to the present invention is formed in a plate shape is coupled to the top surface of the housing 300, may be formed integrally with the housing 300, of course, can be manufactured separately. The light control unit 400 formed as described above is positioned above the optical device 200.

Looking in detail with respect to the light control unit 400, the light control unit 400 may include a substantially planar exit surface 410, the depression 420 and the like.

The plane exit surface 410 is a surface from which light passing through the light control unit 400 exits toward an illuminated member (not shown: located at the upper end of FIG. 3 (a)), and is the front surface as shown in FIG. 3 (a). On the figure it forms a flat top surface of the light control unit 400. And it can be implemented in a circular shape on the top view as shown in Figure 3 (b).

The plane emission surface 410 serves to widen the directing angle of light emitted radially from the optical device 200. That is, since the light exiting the plane exit surface 410 is refracted from the dense medium to the little medium, the angle of refraction becomes larger than the angle of incidence. (Snell's Law)

The depression 420 is a surface in which the light emitted from the optical device 200 first comes into contact with the light control unit 400, which is a dense medium, through the internal space 310, which is a slight medium, in front view as shown in FIG. 3 (a). A lower surface of the light control unit 400 is formed. And it can be implemented in a circular shape on the top view as shown in Figure 3 (b).

The depression 420 may be formed by concave upward from the optical axis A from which the light generated from the optical device 200 is straight out. In this case, as shown in FIG. 4, the optical axis A may be referred to as a traveling direction of light, which may be located at the center among a myriad of light emitted radially from the optical device 200, and may be generated from the optical device 200. It can be said that the direction in which the emitted light goes straight out (that is, the direction in which light of maximum intensity is emitted).

As the size of the concave recess 420 and the radius of curvature formed by the surface are varied, the light directivity angle and the light uniformity emitted through the plane exit surface 410 may be variously changed.

That is, the depression 420 ultimately reduces the amount of emitted light in the direction of the optical axis A (the direction of emitting light of maximum intensity) and increases the amount of emitted light at a position away from the optical axis A. It is formed to be concave upward from the center. The shape of the recessed portion 420 reduces the difference between the amount of light in the direction of the optical axis A and the amount of light at a position far from the optical axis A to emit light of uniform brightness to the illuminated member.

In the embodiment of the present invention, the curvature formed by the size and the surface of the depression 420 is the direction of emitting light having maximum intensity from the optical device 200 (optical axis: A) and the direction of emitting light having half the maximum intensity. The angle θ of (B) is formed to be approximately 75 ° (when the light control part is formed of a transparent resin material having a refractive index of n = 1.49). As a result, the optical device 200 emits light to the member to be illuminated. The light directivity angle is 150 degrees as a whole, which is clearly distinguished from the light directivity angle (about 120 degrees) of the conventional light emitting device.

The light control unit 400 having a 150 ° optical directivity as a whole has a uniform light dispersion through the depression 420 even though the directing angle is enlarged, thereby avoiding a smooth light dispersion in which dark parts are not formed. The lighting member is illuminated.

On the other hand, the lower surface of the light control unit 400 may be formed to be in close contact with the substrate 100, it is preferable to be separated from the substrate 100 so that the heat radiation through the internal space is made. At this time, the waterproof member 500 is not filled in the space between the lower surface of the light control unit 400 and the substrate 100.

The light control unit 400 is formed of a material that can transmit light well. Specifically, it may be formed of a transparent resin material such as PMMA (methyl methacrylate), PC (polycarbonate), EP (epoxy resin) or transparent glass.

The waterproof member 500 is a component for preventing the optical device module 10 from shorting due to moisture or water contained in the air. The waterproof member 500 is provided in the internal space 310 formed by the housing 300 and the substrate 100. It is provided.

In detail, the internal space 310 may be divided into a first internal space 312 and a second internal space 314. Here, the first inner space 312 refers to an inner space formed in an area close to the optical device 200, that is, a space formed by the light control unit 400 and the substrate 100 adjacent to each other.

In addition, the second inner space 314 may be formed by adjoining the housing 300 and the substrate 100 in an inner space formed in a region far from the optical device 200, that is, in an area other than the first inner space 312. Say space.

At this time, if the waterproof member 500 is in a range that does not interfere with the light output of the optical device 200, although not shown in the drawing may be provided with the waterproof member 500 in both the first and second internal spaces (312,314). have. However, in the exemplary embodiment of the present invention, the waterproof member 500 is provided only in the second inner space 314 in order to smoothly dissipate heat generated by the light output of the optical device 200.

The waterproof member 500 may be formed by first bonding the housing 300 and the substrate 100 and then filling and solidifying the waterproof member 500 such as epoxy or silicon in a liquid state through the internal space 310. In this case, a transparent material may be used, but the reflective particles may be included to increase light efficiency.

Alternatively, the shape corresponding to the internal space 310 may be manufactured by using a waterproof member 500 such as a soft synthetic resin in advance and positioned between the housing 300 and the substrate 100 and then coupled to each other. However, in order to effectively waterproof, it is preferable to fill a liquid waterproof member 500 in the internal space 310.

Meanwhile, the partition wall 320 partitioning a boundary between the first inner space 312 and the second inner space 314 to prevent the liquid waterproof member 500 from flowing into the first inner space 312. It can be provided. The partition 320 is positioned between the substrate 100 and the light control unit 400.

Thus, the waterproof member 500 is provided in the internal space 310 between the housing 300 and the substrate 100 to prevent the short circuit due to moisture or water included in the air, thereby providing the optical device module 10 according to the present invention. ) Can be used stably indoors and outdoors.

(Surface Light Source Device)

5 is a front view of the surface light source device according to the present invention, Figure 6 is a partial exploded perspective view of the surface light source device according to the present invention.

5 and 6, the surface light source device 1 according to the present invention may include a plurality of optical device modules 10, a frame 20, a wire 110, and the like. Heat sink 30 and power supply 40 may be further included.

Since the optical device module 10 and the wire 110 used in the surface light source device 1 are the same as those described in the above "optical device module", a structure other than the configuration and the plurality of optical device modules 10 will be described below. The description of the connection between the two will be described.

First, in the surface light source device 1 according to the present invention, a plurality of optical device modules 10 are used. As shown in FIG. 5, the six optical device modules 10 are connected in series to form an upper end, and the surface light source device 1 having the same number of optical device modules 10 is arranged in parallel with the middle and lower ends thereof. Can be formed.

However, if necessary, the optical device module 10 may be zigzag-shaped such that the upper optical device modules 10 are positioned between the intermediate optical device modules 10 for more efficient operation of the optical device module 10. It may be desirable to deploy.

In the embodiment of the present invention, in view of the technical characteristics of the optical device module 10 having a wide and uniform directing angle, the installation interval between the optical device module 10 used in the surface light source device (1) installation interval of the conventional optical device It will be formed to be approximately 24cm longer. As a result, even if a small number of optical device modules 10 are used, the same brightness can be realized, resulting in economical efficiency and smooth light dispersion in which dark parts are not formed.

The frame 20 is a component provided with an inner space capable of accommodating the plurality of optical device modules 10 and protects the plurality of optical device modules 10 from external impact. In addition, the plurality of optical device modules 10 serves to primarily prevent the exposure to water or water vapor.

In this case, the frame 20 may be manufactured in various sizes according to the purpose of use, and the material may be formed of a metal capable of reflecting light, or may be subjected to light reflection by applying a reflecting paint to the inner surface. The light reflection process is performed on the frame 20 to reflect the emitted light, so that even light emitted in a direction other than the light directing angle can be illuminated by the light to be illuminated. Through this, the light efficiency of the optical device module 10 is increased.

In the surface light source device 1 according to the present invention, the wire 110 is a component provided for electrical connection between the optical device modules 10 and the power supply device 40 and the optical device module 10. External power is supplied to the surface light source device 1 through the electrical connection.

A fuse 120 may be provided at one side of the wire 110 to block an overcurrent. Since the surface light source device 1 includes a plurality of optical device modules 10, a fuse may be provided on all or a part of the optical device module 10. 120 may be installed. On the other hand, in the embodiment of the present invention, it is possible to provide a dedicated constant current driver so as to prevent the generation of overcurrent to ensure stability and to smoothly operate and control the surface light source device 1.

The heat sink 30 is a component that prevents the generation of overcurrent due to the temperature rise by dissipating heat generated by the use of the optical device module 10 to the outside, is formed in the internal space of the frame 20, the heat sink The optical device module 10 is seated on the upper surface of the 30.

The heat sink 30 may be formed long along the length or width direction of the frame 20 or individually formed in each region in which the optical device module 10 is located, so that the optical device module 10 may be seated.

The heat dissipation plate 30 may serve as a heat dissipation fin by forming protrusions or grooves formed in the length or width direction of the heat dissipation plate 30 on the upper surface adjacent to the optical device module 10 to increase the heat dissipation efficiency. On the other hand, the heat sink 30 is preferably formed of a material such as aluminum having good thermal conductivity.

The power supply device 40 refers to a device for converting commercial AC power of 100V to 240V supplied from the outside into a predetermined DC power to be used for the optical device module 10.

Specifically, in the embodiment according to the present invention, a switching mode power supply (SMPS) of a constant current driving method and an SMPS of a constant voltage driving method may be used.

The constant current driving method SMPS prevents the optical device module 10 from being burned out by the current gradually increasing due to the heat generated by the use of the optical device module 10, and enables stable driving than the current control method using a simple resistance device. With the power supply device 40, the direct current is controlled to be supplied to the optical device module 10 while maintaining a constant current. At this time, the constant current driving type SMPS is directly connected to the optical device modules 10 connected in series.

On the other hand, if the output voltage of the constant current drive type SMPS is from 27V to 50V, and the output current is 650mA, in the case of the optoelectronic module 10 driven by 2W and 650mA, up to 4 to 15 can be used in series. .

And if the output voltage of the constant current drive type SMPS is 14V to 30V, and the output current is 650mA, in the case of the optoelectronic module 10 driven by 2W and 650mA, 4 to 8 can be connected in series.

The optoelectronic modules 10 can be connected in series in proportion to the output voltage. However, when three or less optical device modules 10 are connected in series, the current flowing through the optical device modules 10 cannot be controlled. This decreases, and when more than 15 optical device modules 10 are connected, they do not operate normally.

The SMPS of the constant voltage driving method is a power supply device 40 capable of more stable driving when the optical device modules 10 are mixed in series and in parallel. The output voltage is converted into a DC current of a predetermined size and supplied to the optical device module 10.

In the embodiment of the present invention, a separate constant current driver is connected in series between the SMPS of the constant voltage driving method and the optical device module 10 connected first. At this time, when the constant current driver receives the input voltage of 12V and the input current of 3A by the SMPS of the constant voltage driving method, the constant current driver outputs the rated voltage of 13V to 32V and outputs the DC current of 650mA.

In this case, power consumption is 2W and the optoelectronic module 10 driven at 650mA can be connected in series from four to ten, and the optical device modules 10 connected in series can be connected in parallel again.

Thus, the surface light source device 1 equipped with the constant current driver has no abnormality even if the output terminal is shorted during operation, and may be implemented to be in normal operation when the short circuit condition is removed.

As described above, the plurality of optical device modules 10 may be operated by being supplied with power through the constant voltage driving type power supply device 40 as well as the constant current driving type power supply device 40. This enlarged feature becomes.

As described above, in the detailed description of the present invention, specific embodiments have been described. However, various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited by the described embodiments, but should be defined by the appended claims and equivalents thereof.

1: surface light source device 10: optical device module
20: frame 30: heat sink
40: power supply 100: substrate
110: wire 120: fuse
200: optical element 300: housing
310: internal space 312: first internal space
314: second inner space 320: partition wall
330: wire fixing groove 340: screw
400: light control unit 410: plane exit surface
420: recess 500: waterproof member
A: optical axis (direction of emitting light of maximum intensity)
B: Direction of exiting light at half the maximum intensity

Claims (8)

Plate-shaped substrates;
An optical element coupled to the upper surface of the substrate;
A first inner space close to the optical device and a second remote to the optical device are formed by a partition wall formed to protrude downwardly on an inner surface of the housing while receiving the optical device by being coupled to the upper surface of the substrate. A housing partitioned into an inner space;
It is coupled to the housing upper surface, the plate is made of a plate to control the emission of light generated from the optical device, the upper surface is formed with a flat output surface for emitting the light generated from the optical device to the outside, An optical control unit in which a recess is formed to be concave upward with respect to an optical axis from which the light emitted from the optical element is straight out; And
And a waterproof member provided in the first inner space and the second inner space, respectively.
The method of claim 1,
While forming a waterproof member 500, such as epoxy or silicon, transparent to the first and second inner space in a range that does not interfere with the light output of the optical device, it has a waterproof function, characterized in that the reflective member is included in the waterproof member One optical module.
A plate-shaped substrate, an optical element coupled to the upper end surface of the substrate, and coupled to the upper end surface of the substrate to form the inner space with the substrate while receiving the optical element, the optical element by a partition wall protruding downward on the inner surface of the housing A housing partitioned by a first internal space close to the second internal space far from the optical device, the housing being coupled to an upper surface of the housing and configured to have a plate shape to control the emission of light generated from the optical device, wherein an upper surface of the optical device The light emitting part and the first inner part of which the planar emission surface for emitting light generated from the outside is formed flat and the lower surface is recessed upwardly with respect to the optical axis from which the light emitted from the optical element is straight out. A plurality of optical device module including a waterproof member provided in each of the space and the second internal space;
A frame accommodating the plurality of optical device modules; And
And a wire for supplying power by connecting the optical device modules to each other.
The method of claim 3, wherein
The surface light source device, characterized in that to form a waterproof member 500, such as epoxy or silicon, transparent to the first and second inner space in a range that does not interfere with the light output of the optical device, the reflective member is included in the waterproof member.
The method of claim 3, wherein
The depression portion is a surface light source device, characterized in that the angle between the direction of emitting light of maximum intensity from the optical element and the direction of emitting light that is half of the maximum intensity is 75 °.
The method of claim 5, wherein
Surface heat source device characterized in that the heat sink is further provided between the optical element module and the frame.
The method according to claim 6,
Surface light source device characterized in that the one side of the wire is further provided with a fuse for blocking the overcurrent.
The method according to claim 6,
The plurality of optical device module is a surface light source device, characterized in that to operate by receiving power through a power supply of the constant current drive method or constant voltage drive method.

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