JP2007213881A - Lighting system unit, lighting system and lighting system mechanism - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lighting system unit easily manufacturable, facilitating replacement of an incorporated component without applying stress to the incorporated component, nor causing a separation problem of the incorporated component, nor changing LED wavelength, and capable of contributing to reduction of thickness of a product composed by applying this invention such as an advertising sign; to provide a lighting system; and to provide a lighting system mechanism. <P>SOLUTION: This lighting system unit is provided with: a board having a light emitting part having light emitting diodes mounted thereon and electrically connected to an external power source; and a housing part for housing the board. The lighting system unit is characterized by being further provided with a cover contacting the housing part and capable of transmitting light emitted from the light emitting part. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

The present invention relates to a lighting device unit, a lighting device, and a lighting device mechanism, and more particularly, to a lighting device unit, a lighting device, and a lighting device mechanism using a light emitting diode (LED).

2. Description of the Related Art Conventionally, there is an illuminating device using a light emitting diode, which is used for illuminating something with light such as decoration indoors and outdoors, a display, and signboard illumination.
As an example to which such a lighting device is applied, there is a signboard 400 incorporating a light emitting diode device unit 401 as shown in FIG. 16 (Patent Document 1).

The sign 400 shown in FIG. 16 has various components (wire 402, case 404, printed circuit board 405, transformer 406, light emitting diodes 407 to 410, caps 411 and 412) shown in FIG. 17 as shown in FIG. The light emitting diode device unit 401 is formed into a unit, and a plurality of the light emitting diode device units 401 are connected and applied to the signboard 400.

The light emitting diode device unit 401 is configured to fill the case 404 with a synthetic resin (not shown) and seal the printed circuit board 405, the caps 411 and 412 and the light emitting diodes 407 to 410.
By adopting such a resin-filled configuration, the light-emitting diodes 407 to 410 can be waterproofed and can withstand external impacts.

  Further, the light emitting diode device unit 401 is configured to be operated by an external AC power source or a DC power source.

JP 2004-310090 A

However, the light emitting diode device unit 401 employing the resin filling method has the following problems.

First, since it takes a long time to cure the filled resin, there is a problem that it takes a long time to manufacture the light emitting diode device unit 401.
Secondly, the volatile substance contained in the solvent mixed with the resin at the time of resin curing becomes a gas, and the resin cures before it sufficiently volatilizes and may remain as bubbles inside the resin. Therefore, there is a problem that it is necessary to remove bubble components in the solvent by vacuum defoaming before curing.

Third, when the device unit 401 is used, there is a problem that the heat generated from the components such as the LEDs is burned by the intimate resin, and the life of the heat generating electronic components such as the LEDs is shortened.
Fourth, since the printed circuit board 405 and the resin are in close contact with each other, these members are made of different materials and have different coefficients of thermal expansion. In this case, there is a problem that the component on the substrate is peeled off.

Fifth, since the wavelength of the LED light may be changed depending on the type of resin, in such a case, there is a problem that it becomes necessary to avoid resin application on the LED illumination part. That is, there is a problem in that it is necessary to pay close attention in order to avoid resin application on the LED illumination part, and it takes a lot of time to manufacture the light emitting diode device unit 401.
Sixth, there is a problem that it is impossible to change or replace components such as LEDs after resin filling.

Seventh, when the light emitting diode device unit 401 is used for the sign 400, the light emitting diodes 407 to 410 are not subjected to luminance unevenness, that is, unevenness due to a bright part that is well illuminated and a dark part that is not well illuminated. It is necessary to provide a diffusion plate for diffusing the light emitted from the LED at the front part of the resin (or not shown resin or light emitting diode device unit 401). This is intended by the resin filled with the illumination angle of the light emitting diodes 407 to 410. Therefore, the distance between the light emitting diode device unit 401 and the diffusion plate must be kept to some extent, and as a result, the thickness of the signboard 400 increases.

Further, although the light emitting diode device unit 401 is configured to be operated by an external AC power source or a DC power source, how the plurality of light emitting diode device units 401 are connected as shown in FIG. It is not clarified whether to construct a simple light emitting device.
Therefore, for example, when only one external DC power supply is provided and all of the LEDs used for the sign 400 are connected in series, all other LEDs are turned on when one of the LEDs is damaged. There is a problem that it does not emit light by losing.

The present invention has been made in view of the above, is easy to manufacture, does not apply stress to the built-in electronic component, does not cause a problem of peeling of the built-in component, does not change the LED wavelength, and replaces the built-in component An object of the present invention is to provide an illuminating device unit, an illuminating device, and an illuminating device mechanism that can easily contribute to a reduction in thickness of a signboard or other application object of the present invention.
It is another object of the present invention to provide an illuminating device unit, an illuminating device, and an illuminating device mechanism that can meet various needs of users by clarifying various circuit configurations.

In order to solve the above problem, the lighting device unit according to claim 1 is mounted with a light emitting unit having a light emitting diode and a power supply circuit that can be connected to an external power source and supplies power to the light emitting unit. A substrate,
A storage section for covering and storing the periphery of the substrate;
A lighting device unit comprising:
Further comprising a light condensing diffusion cover that is in contact with the storage portion, can transmit light emitted from the light emitting portion, and can be fixed to the storage portion;
The condensing diffusion cover has a configuration in which a surface thereof is formed in a lens shape at a portion corresponding to the light emitting diode, and the light from the light emitting portion is condensed and diffused outward. .

The illumination device unit according to claim 2 further includes a diffuser for uniformizing light intensity between the light emitting unit and the cover.
The lighting device unit according to claim 3 further includes an O-ring between the substrate and the diffuser.
The illumination device unit according to claim 4 further includes a light guide for guiding light emitted from the light emitting section, and the light emitting diode is a bullet-type light emitting diode.
The lighting device unit according to claim 5, wherein the external power source is an external DC power source,
The light emitting unit includes a first light emitting unit having a first resistor and a first at least one light emitting diode, and a second light emitting unit having a second resistor and a second at least one light emitting diode,
The first light emitting unit and the second light emitting unit are connected in parallel to the external DC power supply.
The lighting device unit according to claim 6, wherein the first at least one light emitting diode is a first plurality of light emitting diodes, and the second at least one light emitting diode is a second plurality of light emitting diodes. There,
The first and second light emitting diodes are mounted on the substrate so that at least a part thereof intersects.
The lighting device unit according to claim 7 is characterized in that the first plurality of light emitting diodes are three light emitting diodes, and the second plurality of light emitting diodes are three light emitting diodes.
A lighting device according to an eighth aspect is characterized in that a plurality of the lighting device units according to any one of the first to seventh aspects are connected in parallel.

The lighting device unit according to claim 9, wherein the external power source is an external AC power source,
The substrate is connected in series between the external AC power supply and the rectifying means in a predetermined AC oscillation cycle by receiving a supply of the external AC power and supplying a rectified power to the light emitting unit. And a current stabilizing circuit that stably supplies a current to the rectifying means synchronously.
According to a tenth aspect of the present invention, a plurality of lighting device units according to the ninth aspect are provided independently of each other.
The lighting device according to claim 11 has a plurality of lighting device units according to claim 9 provided with connection points on the input side of the current stabilization circuit, and connects the connection points to each other. Features.
A lighting device mechanism according to a twelfth aspect of the present invention includes a lighting device in which a plurality of lighting device units according to the ninth aspect are provided independently of each other;
A lighting device comprising a plurality of lighting device units according to claim 9, wherein a connection point is provided on an input side of the current stabilization circuit, and connecting the mutual connection points;
It is provided with.

The lighting device according to claim 13, wherein the external power source is an external AC power source,
At least one lighting device unit according to any one of claims 1 to 4;
Rectifying means for receiving a supply of the external AC power and supplying a rectified power to the at least one lighting device unit between the external AC power source and the at least one lighting device unit, the external AC power source and the rectification A current stabilization circuit connected in series with the means and stably supplying a current to the rectifying means in synchronization with a predetermined AC oscillation cycle;
It is provided with.

According to the lighting device unit of claim 1, a board on which a light-emitting unit having a light-emitting diode, a power supply circuit that can be connected to an external power source and supplies power to the light-emitting unit, and a board of the board are mounted. And a storage unit that covers and surrounds the surroundings, is in contact with the storage unit, is capable of transmitting light emitted from the light emitting unit, and with respect to the storage unit A condensing diffusion cover that can be fixed is further provided, and the condensing diffusion cover has a surface formed in a lens shape at a portion corresponding to the light emitting diode, and condenses the light from the light emitting portion and faces outward. Therefore, it can be manufactured without sealing with resin.
Therefore, it is easy to manufacture, does not apply stress to the built-in electronic component, does not cause a problem of peeling of the built-in component, does not change the LED wavelength, and can easily replace the built-in component. It can contribute to thinning.

According to the illumination device unit of the second aspect, since the diffuser for further uniforming the intensity of light is further provided, it is not necessary to provide a diffuser at a location away from the illumination device unit.
Therefore, when the lighting device unit is applied to various products, the product can be thinned.
According to the lighting device unit of the third aspect, since the O-ring is further provided, the waterproof or drip-proof effect can be enhanced.
According to the illuminating device unit of the fourth aspect, since the bullet-type light emitting diode is used and the light guide is provided, the illumination brightness can be remarkably increased.
According to the lighting device unit of the fifth aspect, since the DC power source is used as the external power source and the first light emitting unit and the second light emitting unit are provided, the electrical continuity of one light emitting unit is lost. Even if broken, since the electrical continuity of the other light emitting portion can be maintained, a highly reliable lighting device unit can be provided.
According to the lighting device unit of claim 6, since the first light emitting unit and the second light emitting unit each having a plurality of light emitting diodes are provided, and the plurality of light emitting diodes are arranged so as to intersect with each other, Luminance unevenness that occurs when the electrical continuity of one light-emitting portion is lost can be minimized.
According to the lighting device unit of claim 7, since the number of light emitting diodes provided in the first light emitting unit and the second light emitting unit is three, the lighting device unit is small and relatively easy to wire. can do.
According to the lighting device of the eighth aspect, since the plurality of lighting device units are configured to be connected in parallel, some unnecessary lighting device units are disconnected from the lighting device, or conversely, are unnecessary. A simple lighting device unit can be reconnected to the lighting device.

According to the lighting device unit of claim 9, since the AC power source is used as the external power source and the rectifying means and the current stabilizing circuit are provided, the DC power source is provided in addition to the already prepared AC power source. Therefore, a stable current can be provided.
According to the illumination device of the tenth aspect, since the plurality of illumination device units are provided independently of each other, some unnecessary illumination device units are cut from the illumination device or are cut in reverse. An unnecessary lighting device unit can be reconnected to the lighting device and used.
According to the illuminating device of the eleventh aspect, since the connection point is provided on the input side of the current stabilization circuit of each illuminating device unit and the connection points are connected to each other, some unnecessary components are required from the illuminating device. The length of the wire to be connected to each lighting device unit can be used in addition to being able to cut off the unnecessary lighting device units, or reconnecting unnecessary lighting device units that have been cut off to the lighting device. Can be made uniform.
According to the illumination device mechanism according to claim 12, the connection points of the illumination device in which a plurality of illumination device units are provided independently of each other and the illumination device unit in which a connection point is provided on the input side of the current stabilization circuit. It is the structure provided with the illuminating device which connected.
Therefore, it is possible to disconnect some unnecessary illumination device units from the illumination device mechanism or the illumination device, or to use the disconnected unnecessary illumination device units reconnected to the illumination device mechanism or the illumination device. In addition, the length of the wire to be connected to each lighting device unit can be made uniform.

According to the illuminating device of the thirteenth aspect, since the power supply unit and the illuminating device unit are provided, it is possible to eliminate the necessity of preparing a separate DC power source and to connect a large number of light emitting diodes. Heat loss can be minimized.

DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, the best mode for carrying out an illumination device unit and an illumination device according to the invention will be described with reference to the accompanying drawings. In the drawings, the same reference numerals indicate the same members or the same parts.

A. First Embodiment The first embodiment is an embodiment using a chip-type LED as a light emitting element.
FIG. 1 is an overhead view of a lighting device unit 1 according to the present invention according to such an embodiment, and FIGS. 2 and 3 are a structural sectional view and a mounting sectional view of the lighting device unit 1, respectively.

1 to 3, a lighting device unit 1 of several centimeters square includes a bottom case 2 for storing various components, and a substrate 3 on which chip LEDs 4 to 9 and the like are mounted and accommodated in the bottom case 2. ing.
An O-ring 10 is provided on the substrate 3 for waterproofing and drip-proof purposes. In this respect, for the purpose of waterproofing and drip-proofing, a configuration in which a sealing agent such as a silicone resin is filled in a portion where the O-ring is provided instead of the O-ring may be used.

Note that a diffuser (not shown) for making the intensity of light emitted from the chip LEDs 4 to 9 uniform may be provided on the substrate 3 via the O-ring 10.
That is, since the chip LEDs 4 to 9 diffuse a certain amount of light (that is, emit light over a wide range), even if there is no such diffuser, it is not possible to notice luminance unevenness at first glance. Although it is not necessary to provide a diffuser, a diffuser (not shown) may be provided through the O-ring 10 from the viewpoint of surely preventing uneven brightness.

As described above, by providing the diffuser, it is not necessary to provide a diffuser plate at a position away from the illuminating device unit 1. Therefore, when the illuminating device unit 1 is applied to various products, the thickness of these products can be reduced. Can be planned.
Furthermore, the O-ring 10 can enhance the waterproofing and drip-proof effect of the product.

The substrate 3 includes conductive wires 13 and 14 for connection for electrical connection with both or one of an external power source and another lighting device unit L (representing a lighting device unit similar to the lighting device unit 1). These wires 13 and 14 are fixed so as not to move by fixing members 15, 17 and 16, 18, respectively.
The wires 13 and 14 are fixed to the bottom case 2 so as to lie in a plane direction (lateral direction) parallel to the substrate 3 (see FIGS. 1 and 2). By adopting such a structure that is easy to sag in the parallel plane direction (lateral direction), the shadow of the wire can be prevented from being reflected on the front illumination panel.
This point is described in more detail as follows.
When a lighting device is formed by connecting a plurality of lighting device units, the wire may be distorted depending on the arrangement of the lighting device units (specifically, the distance between the lighting device units is compared with the length of the wire). If the wire is structured to fold in the plane direction (vertical direction) perpendicular to the substrate, in other words, the wire 13, 14 is rotated 90 degrees and fixed to the bottom case 2. Then, the shadow of the wire is reflected in the front illumination panel.
Therefore, in the present invention, in order to prevent such reflection of the shadow of the wire, the wires 13 and 14 are laid on the bottom case 2 so as to lie in the plane direction (lateral direction) parallel to the substrate 3 as described above. (See FIGS. 1 and 2).
On the other hand, the fixing members 15 to 18 are desirably rubber-based resins from the viewpoint of waterproofing and the like. In addition, in the integral molding of the wire 13 and the like and the fixing member 15 and the like, since a commercially available wire can be used, a waterproof product having excellent versatility can be obtained (see FIG. 4). For waterproofing and drip-proof purposes, a sealing agent such as a silicone resin can be used instead of the fixing members 15-18.

After the substrate 3 and the O-ring 10 are housed in the bottom case 2 and the fixing members 15 and 16 are fixed to the bottom case 2, the bottom case 2 and a light collecting and diffusing cover 12 for collecting and diffusing light are provided. Screwed at the four corners using screws 19-22.
The condensing diffusion cover 12 is provided with a lens-shaped portion corresponding to the positions of the LEDs 4 to 9 provided on the substrate 3 (see FIGS. 1 to 3).
By having such a lens shape, the condensing diffusion cover 12 can efficiently condense light from the chip LEDs 4 to 9 and diffuse and irradiate the light forward (irradiation direction).
It should be noted that it is desirable to use a transparent resin with good light transmittance as the material of the light condensing diffusion cover 12, and the bottom case 2 and the light condensing diffusion cover 12 are not used as a screw structure as described above. It is good also as a meshing structure which provides an appropriate meshing part and meshes both.

According to the present embodiment, the condensing / diffusion cover 12 is used as described above instead of resin sealing.
Therefore, since it is not resin-sealed, it becomes easy to manufacture the lighting device unit 1, no stress is applied to the chip LEDs 4 to 9 and the substrate 3, and the problem of peeling the chip LEDs 4 to 9 does not occur. Without changing the LED wavelength, the chip LEDs 4 to 9 can be easily replaced when they are damaged, and when the present invention is applied to a signboard or the like, the signboard or the like can be thinned.

B. Second Embodiment The second embodiment is an embodiment using a bullet-type LED as a light emitting element.
The second embodiment differs from the first embodiment mainly in that a bullet type LED is used instead of a chip type LED. Thus, by using the bullet-type LED, the illumination brightness can be increased. Details will be described below.

  FIG. 5 is a bird's-eye view of the illumination device unit 31 according to the second embodiment, that is, an embodiment using a bullet-type LED, and FIGS. 6 and 7 are a cross-sectional view and a mounting cross-section of the illumination device unit 31, respectively. FIG.

  5 to 7, the lighting device unit 31 includes a bottom case 32 that stores various components, and a substrate 33 that is mounted and supported by the bottom case 32 with bullet-type LEDs 34 to 39 and the like mounted thereon.

  As shown in FIGS. 5 to 7, bullet-type LEDs 34 to 39 are mounted on the substrate 33 instead of the chip-type LEDs, and the emitted light is reflected on these bullet-type LEDs 34 to 39. In addition, light guide reflectors 40 to 45 for guiding in a certain direction are covered.

FIG. 8 is a drawing explaining in detail this point.
As shown in FIG. 8, the light emitted from the bullet-type LED 34 is reflected inside the light guide reflector 40 and guided in the direction of the arrow in the figure.
In order to increase the efficiency of the reflection, a light reflecting material is provided inside the light guide reflector 40 by plating, vapor deposition, coating, or other known techniques.
Although the light guide reflector 40 has a so-called funnel shape in FIG. 8, it can take a shape other than the funnel shape as appropriate depending on the shape of the bullet-type LED used. For example, it can be a parabolic shape.

  As described above, the illumination brightness can be increased by employing the bullet-type LEDs 34 to 39 instead of the chip LEDs, and the brightness can be remarkably increased by using the light guide reflector 40 that has been appropriately processed. it can.

Returning to FIG. 5 to FIG. 7, the other configuration of the lighting device unit 31 will be described. The lighting device unit 31 has an O-ring 46, a condensing diffusion cover 48, and a connection in substantially the same manner as in the first embodiment. Conductive wires 49, 50 and fixing members 51, 52, 53, 54 are provided.
The effects of providing these members are not different from those described in the context of the first embodiment.

Moreover, in the illuminating device unit 31 which concerns on 2nd Embodiment, the diffuser 47 is comprised as an essential structure.
This is because, in the second embodiment, bullet-type LEDs 34 to 39 having strong light directivity are used instead of chip LEDs, and in addition, the light guide reflector 40 that increases the luminance and directivity by the light reflecting action. This is because luminance unevenness occurs when the diffuser 47 is not used.
As described above, by arranging the diffuser 47 as an essential member inside the lighting device unit 31, only the irradiation axis direction becomes bright despite the use of the bullet-type LEDs 34 to 39 having a narrow illumination angle. The occurrence of uneven brightness can be suppressed.
In terms of suppressing this luminance unevenness, it is also effective to add a diffused light reflecting material to the diffuser 47 and / or the condensing diffusion cover 48 by a known method such as coating, vapor deposition, or molding.

  Note that the above description that states that the diffuser 47 cannot be omitted is merely a statement that the diffuser 47 cannot be omitted as the best embodiment, and these are intended to limit the scope of the claims. The member is not supposed to be an essential configuration.

According to the present embodiment, the condensing diffusion cover 48 is used as described above instead of resin sealing.
Therefore, since it is not resin-sealed, the illuminating device unit 31 can be easily manufactured, and the bullet-type LEDs 34 to 39 and the substrate 33 are not stressed, and the bullet-type LEDs 34 to 39 are peeled off. Without changing the LED wavelength, the bullet-type LEDs 34 to 39 can be easily replaced when they are damaged. When the present invention is applied to a signboard or the like, the signboard or the like can be thinned. it can.

C. Circuit Configuration FIGS. 9 to 11 are circuit configuration diagrams selectively employed in the first and second embodiments.
Therefore, there are six best embodiments according to the present invention depending on which circuit configuration is employed (2 × 3).
The circuit configurations shown in FIGS. 9, 10, and 11 will be referred to as a DC power supply type, an AC power supply independent type, and an AC power supply series type, respectively.

C. 1 DC power supply system The DC power supply system in FIG. 9 includes a plurality of blocks 101 and 102 each corresponding to a lighting device unit of the present invention. In the figure, only two blocks are shown, but three or four are connected in succession, and a plurality of lighting device units are connected to constitute a lighting device as a whole.

Next, each of these blocks includes a sub-block. That is, in the case of the block 101, the sub-blocks 103 and 104 are provided in the block 101. Other blocks 102 and the like similarly include sub-blocks 105 and 106.

Each of these sub-blocks includes three LEDs and one resistor. That is, in the case of the subblock 103, the LEDs 107 to 109 and the resistor 110 are provided in the subblock 103. Each LED corresponds to the chip LEDs 4 to 9 and the bullet type LEDs 34 to 39 described above.
The other sub-blocks 104, 105, 106 and the like similarly include three LEDs (LEDs 111 to 113, LEDs 115 to 117, and LEDs 119 to 121) and one resistor (resistor 114, resistor 118, resistor 122).
Note that, for example, the sub-block 103 is configured to include three LEDs, but may be four or five. Conversely, the number may be two or one. The reason why the sub-block 103 includes three LEDs is that a general power supply can be used, so that it is easy to obtain and can be provided with a lighting device unit that is relatively easy to wire due to its small size. .

Thus, by dividing the LED in each block into two sub-blocks, even if one circuit block (for example, sub-block 103) loses electrical continuity due to breakage of the LED, the other circuit block (for example, sub-block) Since the block 104) can maintain electrical continuity, luminance unevenness that occurs when a plurality of blocks are viewed as a whole can be suppressed, and a highly reliable lighting device unit can be provided.

The blocks 101, 102, etc. configured as described above are connected in parallel to the external DC power supply 100 as shown in FIG.
When a lighting device is formed by connecting a large number of lighting device units, the user can divide or cut several units from the lighting device so as to obtain a desired length, and appropriately process the wiring. Can be used.
On the contrary, it is also possible to connect a lighting device unit that is divided and not used to a lighting device that is used and connect the lighting device unit to a required length. At this time, the connection may be performed by using a connector (not shown).

The voltage applied from the external DC power supply 100 is limited in current by the resistor 110 or the like, and the LEDs 107 to 109 and the like are lit.

C. 2 AC power supply independent type The AC power supply independent type shown in Fig. 10 also includes a plurality of blocks 131 and 132, each of which corresponds to the lighting device unit of the present invention. Although only two blocks are shown in the figure, a plurality of lighting device units are connected in series with three or four to constitute a lighting device as a whole.

Each of these blocks includes an inrush current limiting resistor, a constant current generating capacitor, a discharge resistor, a rectifying bridge diode, and six LEDs.
For example, in the block 131, an inrush current for protecting a subsequent circuit by suppressing a pulse voltage that can be transiently applied when the power is turned on or a pulse current when an instantaneous induced pulse voltage is applied like lightning. A limiting resistor 133 is connected between the external AC power supply 130 and one input side of the rectifying bridge diode 136, and between the external AC power supply 130 and the other input side of the rectifying bridge diode 136, the external AC power supply 130 is connected. A constant current generating capacitor 134 is connected to supply a stable current to the subsequent circuit repeatedly by repeating charging and discharging in synchronization with the oscillation cycle. Further, a discharge resistor 135 for discharging the charge accumulated in the constant current generating capacitor 134 is connected in parallel to the constant current generating capacitor 134.
The rectifying bridge diode 136 corresponds to the rectifying means of the present invention, and the inrush current limiting resistor 133, the constant current generating capacitor 134, and the discharge resistor 135 correspond to the current stabilizing circuit of the present invention.

As shown in FIG. 10, LEDs 137 to 142 are continuously connected to the output side of the rectifying bridge diode 136 having the input side configured in this manner. These LEDs 137 to 142 correspond to the above-described LEDs 4 to 9 and bullet-type LEDs 34 to 39.
A capacitor for stabilizing the rectified voltage may be provided between the rectifying bridge diode 136 and the LEDs 137 to 142 and the like.

  As described above, the AC power supply 130 is used as the external power supply, and the configuration including the rectifying means and the current stabilization circuit eliminates the need to prepare a DC power supply in addition to the already prepared AC power supply 130. A stable current can be provided.

The blocks 131, 132, etc. configured as described above are connected to the external AC power supply 130 independently of each other so that they can receive the same voltage supply, thereby configuring an illumination device ( System 1 not shown in Fig. 10. A connection point provided on the left side of the inrush current limiting resistor 133, the constant current generating capacitor 134, and the discharge resistor 135 and extending to the block 132 is a unit. 131 is a method of connecting to each other by providing outside of 131.)
In this regard, when a lighting device is formed by a plurality of lighting device units, avoid the situation where the wire of a specific lighting device unit is short and the wire of another specific lighting device unit becomes long. In order to equalize the length, a connection point for receiving a voltage supply from the external AC power supply 230 is provided on the input side of the current stabilization circuit in each unit, and the units are connected through this connection point. It is desirable to connect them independently so as to receive a voltage supply (method 2 shown in FIG. 10).
Furthermore, combining the above two different illumination devices (method 1 + method 2), that is, an illumination device in which a plurality of illumination device units are provided independently from each other, and connected to the input side of the current stabilization circuit You may combine with the illuminating device which connected the connection points of the illuminating device unit provided with the point (system 3). What was combined in this way is called an illuminating device mechanism.

Regardless of whether the above connection points are provided inside or outside the unit, when a large number of lighting device units are connected to form a lighting device, the user can adjust the lighting so that the required length is obtained. Several units can be divided or cut from the apparatus, and the wiring can be appropriately processed for use.
On the contrary, it is also possible to connect a lighting device unit that is divided and not used to a lighting device that is used and connect the lighting device unit to a required length. At this time, the connection may be performed by using a connector (not shown).
In the case of the method 2, as described above, the wire length can be made uniform.

The AC voltage applied by the external AC power supply 130 can suppress a transient current when the voltage is applied by the inrush current limiting resistor 133, and after the voltage is stabilized, a constant current is generated by the constant current generating capacitor 134 according to the frequency. The LED is rectified from AC to DC by the rectifier bridge diode 136, and the LEDs 137 to 142 and the like emit light.

C. 3 AC power supply serial type In the AC power supply serial type shown in FIG. 11, each of the blocks 161, 162, 163 and the like corresponding to the lighting device unit is electrically provided with LEDs 164 to 169 and the like, and is necessary for causing the LEDs to emit light. The device is realized by a power supply unit 182 provided separately.
As shown in FIG. 11, the power supply unit 182 includes an inrush current limiting resistor 183, a constant current generating capacitor 184, a discharge resistor 185, and a rectifier bridge diode 186. The functional operation of these members is described in C.I. 2 is the same as the inrush current limiting resistor 132 of FIG.
When only the lighting device unit 161 is connected to the output side of the rectifier bridge diode 186 of the power supply unit 182, C.I. In FIG. 2, the circuit is the same as the case where only the illuminating device unit 161 is connected to the external AC power supply 130, and in that sense, the AC power supply series type has no characteristics.

  A feature of the AC power supply series type is that lighting devices 162, 163 and the like having the same configuration as the lighting device unit 161 are continuously connected in series on the output side of the rectifier bridge diode 186 of the power supply unit 182 for lighting. It is where the device is configured.

  By connecting in series in this way, the C.I. DC power supply type 1 and the C.I. The disadvantages of the two independent AC power supply systems can be compensated.

That is, the C.I. The DC power supply type 1 has a drawback that it is necessary to prepare the DC power supply 100 separately (in addition to the AC power supply). The C.I. In the AC power supply independent type of 2, the number of LEDs that can be accommodated in a limited size in each illumination device unit such as the illumination device unit 1 or the illumination device unit 31 is physically limited, and the LEDs that are accommodated When the number is small, the difference between the total V _f of the accommodated LEDs and the input voltage becomes large, and this voltage difference is consumed as heat, resulting in a large loss.
On the other hand, in the AC power supply independent type, since the power supply unit 182 for rectification is provided, it is not necessary to prepare a DC power supply separately. In addition, since the LEDs are unitized as the lighting device unit 161, etc., a large number of LEDs (164-169, 170-175, 176-181, etc.) or lighting device units (161, 162, 163, etc.) are connected in series. The LED V _f can be as close as possible to the input voltage to minimize heat loss.

  The power supply unit 182 and, for example, the block 161 may be integrated to form a single unit, and the block 162, 163, etc. may be connected in series to the configured unit to configure the lighting device. .

D. Specific Application of Each Circuit Configuration Hereinafter, a description will be given of the case where each circuit configuration described above is applied to each embodiment.
From the viewpoint of avoiding duplication of explanation and facilitating understanding of the present invention, the case where the DC power supply type is applied to the first embodiment is referred to as “D.1”, and the AC power supply independent of the second embodiment. The case where the equation is applied is referred to as “D.2”, and the case where the AC power supply series equation is applied to the second embodiment is referred to as “D.3”, and only these three cases will be described.

D. 1. When DC power supply type is applied to the first embodiment FIG. 12 is a drawing in which the DC power supply type is applied to the first embodiment.
As shown in FIG. 12, the lighting device unit 1 is constituted by two parallel LED circuit blocks 201 and 202 in terms of a circuit, and each LED circuit block includes three chip LEDs (4, 8, 6). Or 7, 5, 9) and one resistor (203 or 204).
As described above, since the lighting device unit 1 includes the two LED circuit blocks 201 and 202 in parallel, one to at most three of the chip LEDs 4 to 9 included in these LED circuit blocks 201 and 202 are damaged. Even if one of the LED circuit blocks loses electrical continuity, the probability that all the chip LEDs in the lighting device unit 1 will not light up because the other LED circuit block is conductive. Can be suppressed.

As can be seen by comparing and comparing FIGS. 2, 3, and 12, the lighting device unit 1 of the present invention is devised in the arrangement configuration of the chip LEDs 4 to 9 in order to suppress luminance unevenness.
That is, in FIG. 2 and FIG. 3, as can be understood from the fact that the chip LED 5 instead of the chip LED 8 is arranged between the chip LED 4 and the chip LED 6, the LED circuit blocks 201 and 202 are crossed when mounted. Thus, the chip LEDs 4 to 9 are arranged.

This arrangement configuration will be described in more detail with reference to FIG.
It is assumed that one of the two LED circuit blocks 201 and 202 in the lighting device unit 1 is not lit. In this case, if the substrate circuit is designed with the block configuration of a, b, c and d, e, f of FIG. 12, the a, b, c block or the d, e, f block is not lit. Since only the other block that is not lit is lit, there is a bias in the light and dark areas. That is, luminance unevenness occurs.
Such a bias can be solved by setting the block configurations as a, e, c and d, b, f so that both blocks are crossed.
Therefore, in the embodiment according to the present invention, the chip LEDs 4 to 9 are arranged so that the LED circuit blocks 201 and 202 are crossed when mounted.

In addition, when the number of LEDs provided in the LED circuit block is 1, it is not possible to make the cross arrangement, but in the case of two, the case of four, the case of five, and the plurality of other cases can be arranged in a cross.
In the case of providing a plurality, it is desirable to provide as many intersection points as possible. For example, if each block is provided with five LEDs, it is desirable to cross-arrange so that four crossing points are formed in such a manner that W and M are overlapped.
Of course, even when five are provided, luminance unevenness can be suppressed even if only one point, two points, or three points are crossed.
In short, it is desirable to mount with as many intersection points as possible, but a configuration in which at least a part of the intersections are mounted may be used.

  The lighting device unit 1 having the above configuration is connected to an external DC power supply 200. Specifically, as the external DC power supply 200, a switching power supply that converts AC power into DC power or a stable DC power supply such as a battery can be used.

The illumination device unit 1 emits light as described above, and thus functions as an illumination device that illuminates a desired character or picture. However, as shown in FIG. 9, the illumination device unit L having the same configuration as the illumination device unit 1 is illuminated. The lighting device may be configured by connecting a plurality of devices in a chain so as to be parallel to the device unit 1.
When a large number of lighting device units L are connected and commercialized as a lighting device, the user of the product divides several units from the lighting device so that the required length can be obtained. It can be used after appropriate processing.
The divided lighting device units can be connected again and used.

D. 2 When the AC power supply independent type is applied to the second embodiment FIG. 13 is a drawing in which the AC power supply independent type is applied to the second embodiment.
The illuminating device unit 211 corresponds to the illuminating device unit 31, and the LEDs 216, 217, and 218 correspond to the bullet-type LEDs 34, 35, and 36, respectively.
As shown in FIG. 13, the lighting device unit 211 of the present invention is connected to, for example, an AC 100 V external AC power supply 210, and an inrush current limiting resistor 212, a constant current generating capacitor 213, A discharge resistor 214 and a rectifying bridge diode 215 are provided. The inrush current limiting resistor 212, the constant current generating capacitor 213, the discharge resistor 214, and the rectifier bridge diode 215 are realized on the substrate 33.

As shown in FIG. 13, an inrush current limiting resistor 212 for suppressing the pulse current and protecting the subsequent circuit is connected between the external AC power supply 210 and one input side of the rectifier bridge diode 215. ing.
Further, between the external AC power supply 210 and the other input side of the rectifier bridge diode 215, charging and discharging are repeated in synchronization with the oscillation cycle of the external AC power supply 210, and a stable current is supplied to the subsequent circuit. A constant current generating capacitor 213 is connected. A discharge resistor 214 is connected in parallel to the constant current generating capacitor 213, whereby the charge accumulated in the constant current generating capacitor 213 is discharged.

  As shown in FIG. 13, bullet-type LEDs 216 to 221 are continuously connected to the output side of the rectifying bridge diode 215 having the input side in this way (the LEDs 219, 230, and 231 are bullet-type). (It corresponds to each of the LEDs 37, 38, and 39, and in FIG. 13, only the LEDs 216 to 218 are shown for easy understanding of the contents shown in the drawing.)

Since the lighting device unit 211 emits light as described above, it functions as a lighting device that illuminates a desired character or picture. According to the lighting device unit 211, since a circuit for converting an AC power source into a rectified power source is provided, it is not necessary to separately prepare a DC power source in addition to a commercial AC power source, and convenience is improved.

As shown in FIG. 13, a plurality of lighting device units M having the same configuration as the lighting device unit 211 are connected in series so as to be parallel to the lighting device unit 211 to form a lighting device. Also good.
When many lighting device units M are connected and commercialized as a lighting device, the user of the product divides several units from the lighting device so as to have a desired length, and performs wiring. It can be used after appropriate processing.
The divided lighting device units can be connected again and used.

D. 3. When the AC power supply series type is applied to the second embodiment FIG. 14 is a drawing in which the AC power supply series type is applied to the second embodiment.
The illuminating device unit 231 corresponds to the illuminating device unit 31, and the LEDs 232 to 237 correspond to the bullet type LEDs 34 to 39, respectively.
When this AC power supply series type is applied, the lighting device unit 231 is electrically provided with LEDs 232 to 237 and is connected to the external AC power supply 230 via a separately provided power supply unit 238.
As shown in FIG. 14, the power supply unit 238 includes an inrush current limiting resistor 239, a constant current generating capacitor 240, a discharge resistor 241, and a rectifying bridge diode 242. The functional operation of these members is described in D.C. 2 is the same as the inrush current limiting resistor 212 of FIG.
When only the lighting device unit 231 is connected to the output side of the rectifier bridge diode 242 of the power supply unit 238, D.I. 2, the circuit is the same as the case where only the illumination device unit 211 is connected to the external AC power supply 210.

  In the present invention according to the case where the AC power supply series type is applied, lighting device units N, N + 1, N + 2,... Having the same configuration as the lighting device unit 231 are provided on the output side of the rectifier bridge diode 242 of the power supply unit 238. It is characterized in that the lighting device is configured by continuously connecting in series.

By connecting in series in this way, D.D. 1 lighting device unit 1 and D.1. The disadvantages of the two lighting device units 211 can be compensated.
That is, since the power supply unit 238 for rectification is provided, it is not necessary to prepare a separate DC power supply. In addition, since the LEDs are unitized as the lighting device unit 231 or the like, a large number of LEDs can be connected in series. The LED V _f can be as close to the input voltage as possible to minimize heat loss.

The above-described embodiments of the present invention are merely examples as the best embodiments, and have been described so that the principle and structure of the present invention can be better understood. It is not intended to limit the scope of the appended claims.
Therefore, it should be understood that all the various variations and modifications that can be made to the above-described embodiments of the present invention are included in the scope of the present invention and protected by the appended claims.
For example, the external AC power supply according to the present invention has been described as AC 100 V, which is a commercial power supply voltage in Japan. However, it is understood that the appropriate design according to the commercial power supply voltage in each country is included in the scope of the present invention. There must be.

FIG. 1 is an overhead view of a lighting device unit according to the first embodiment of the present invention. FIG. 2 is a structural cross-sectional view of the illumination device unit according to the first embodiment of the present invention. FIG. 3 is a mounting cross-sectional view of the lighting device unit according to the first embodiment of the present invention. FIG. 4 is a perspective view of the wire used in the lighting device unit and the lighting device of the present invention. FIG. 5 is an overhead view of the lighting device unit according to the second embodiment of the present invention. FIG. 6 is a structural cross-sectional view of a lighting device unit according to the second embodiment of the present invention. FIG. 7 is a mounting cross-sectional view of the illumination device unit according to the second embodiment of the present invention. FIG. 8 is a cross-sectional view of an LED and a light guide reflector used in the second embodiment of the present invention. FIG. 9 is a circuit diagram of a DC power supply type applied to each embodiment of the present invention. FIG. 10 is a circuit diagram of an AC power supply independent type applied to each embodiment of the present invention. FIG. 11 is a circuit diagram of an AC power supply series type applied to each embodiment of the present invention. FIG. 12 is a circuit diagram when a DC power supply circuit is applied to the first embodiment of the present invention. FIG. 13 is a circuit diagram when an AC power supply independent circuit is applied to the second embodiment of the present invention. FIG. 14 is a circuit diagram when an AC power supply series circuit is applied to the second embodiment of the present invention. FIG. 15 is a diagram for explaining the arrangement of LEDs. FIG. 16 shows a signboard to which a conventional lighting device unit or lighting device is applied. FIG. 17 is an exploded perspective view of the lighting device unit according to FIG. 16. FIG. 18 is a perspective view of the lighting device unit according to FIG. 16.

Explanation of symbols

1 Lighting device unit 2 Bottom case (housing part)
3 Substrate 4-9 Chip LED (light emitting diode, light emitting part)
10 O-ring 11 Diffuser 12 Condensation diffusion cover 31 Illumination device unit 32 Bottom case (housing part)
33 Substrate 34-39 Cannonball type LED (light emitting diode, light emitting part)
40-45 Light guide reflector (light guide)
46 O-ring 47 Diffuser 48 Condensation diffusion cover (cover)
100 External DC power supply (external power supply)
103 sub-block (first light emitting unit)
104 Sub-block (second light emitting unit)
107-109 LEDs (first at least one light emitting diode, first plurality of light emitting diodes)
110 Resistance (first resistance)
111-113 LEDs (second at least one light emitting diode, second plurality of light emitting diodes)
114 Resistance (second resistance)
130 External AC power supply (external power supply)
133 Inrush current limiting resistor (current stabilization circuit)
134 Capacitor for constant current generation (current stabilization circuit)
135 Discharge resistance (current stabilization circuit)
136 Rectifier bridge diode (rectifier)
160 External AC power supply (external power supply)
182 Power supply unit 183 Inrush current limiting resistor (current stabilization circuit)
184 Capacitor for constant current generation (current stabilization circuit)
185 Discharge resistance (current stabilization circuit)
186 Rectifier bridge diode (rectifier)
200 External DC power supply (external power supply)
201 LED circuit block (first light emitting unit)
202 LED circuit block (second light emitting unit)
203 Resistance (first resistance)
204 Resistance (second resistance)
210 External AC power supply (external power supply)
212 Inrush current limiting resistor (current stabilization circuit)
213 Constant current generating capacitor (current stabilization circuit)
214 Discharge resistance (current stabilization circuit)
215 Rectifying bridge diode (rectifying means)
230 External AC power supply (external power supply)
238 Power supply unit 239 Inrush current limiting resistor (current stabilization circuit)
240 Capacitor for constant current generation (current stabilization circuit)
241 Discharge resistance (current stabilization circuit)
242 Rectifier bridge diode (rectifier means)

Claims (13)

A light-emitting unit having a light-emitting diode, and a power supply circuit that can be connected to an external power source and supplies power to the light-emitting unit;
A storage section for covering and storing the periphery of the substrate;
A lighting device unit comprising:
Further comprising a light condensing diffusion cover that is in contact with the storage portion, can transmit light emitted from the light emitting portion, and can be fixed to the storage portion;
The condensing diffusion cover has a configuration in which a surface thereof is formed in a lens shape at a portion corresponding to the light emitting diode, and the light from the light emitting portion is condensed and diffused outward. Lighting device unit. The illuminating device unit according to claim 1, further comprising a diffuser for uniformizing light intensity between the light emitting unit and the cover. The lighting device unit according to claim 2, further comprising an O-ring between the substrate and the diffuser. The illumination device unit according to any one of claims 1 to 3, further comprising a light guide for guiding light emitted from the light emitting unit, wherein the light emitting diode is a bullet-type light emitting diode. The external power source is an external DC power source,
The light emitting unit includes a first light emitting unit having a first resistor and a first at least one light emitting diode, and a second light emitting unit having a second resistor and a second at least one light emitting diode,
5. The lighting device unit according to claim 1, wherein the first light emitting unit and the second light emitting unit are connected in parallel to the external DC power source. The first at least one light emitting diode is a first plurality of light emitting diodes, and the second at least one light emitting diode is a second plurality of light emitting diodes;
6. The lighting device unit according to claim 5, wherein the first and second light emitting diodes are mounted on the substrate so that at least a part thereof intersects. The lighting device unit according to claim 6, wherein the first plurality of light emitting diodes are three light emitting diodes, and the second plurality of light emitting diodes are three light emitting diodes. A lighting device comprising a plurality of lighting device units according to claim 1 connected in parallel. The external power source is an external AC power source,
The substrate is connected in series between the external AC power supply and the rectifying means in a predetermined AC oscillation cycle by receiving a supply of the external AC power and supplying a rectified power to the light emitting unit. A lighting device unit according to any one of claims 1 to 4, wherein a current stabilization circuit that stably supplies a current to the rectifying means synchronously is mounted. A lighting device comprising a plurality of lighting device units according to claim 9 independently of each other. An illumination device comprising a plurality of illumination device units according to claim 9, wherein connection points are provided on an input side of the current stabilization circuit, and connecting the connection points to each other. A lighting device comprising a plurality of lighting device units according to claim 9 independently of each other;
A lighting device comprising a plurality of lighting device units according to claim 9, wherein a connection point is provided on an input side of the current stabilization circuit, and connecting the mutual connection points;
An illumination device mechanism comprising: The external power source is an external AC power source,
At least one lighting device unit according to any one of claims 1 to 4;
Rectifying means for receiving a supply of the external AC power and supplying a rectified power to the at least one lighting device unit between the external AC power source and the at least one lighting device unit, the external AC power source and the rectification A current stabilization circuit connected in series with the means and stably supplying a current to the rectifying means in synchronization with a predetermined AC oscillation cycle;
An illumination device comprising:

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