KR20230088899A - light fixture - Google Patents

Abstract

[Problem] To provide a flexible substrate in which the degree of decrease in brightness across the ends is small when the product is elongated and the brightness of a luminous body does not become uneven even when cut, and a lighting fixture using the flexible substrate.
[Solution Means] Each unit is configured to conduct a first outgoing wiring and a second return wiring through a first light emitting element, and a first conducting wiring to conduct the first outgoing wiring and the second return wiring through a second light emitting element. A second energization wire is provided, and electric power supplied from the front end to the first outgoing path wire is supplied to the first light emitting element by the first energization wire in each unit, and the second return wire is provided. , and the electric power supplied from the front end to the second outgoing route wiring is once reversed to the first return route wiring through the first conducting portion at the end, and then, in each of the units, the first Electricity is supplied to the second light emitting element by the 2 conducting wiring and circulated to the second return wiring.

Description

light fixture

The present invention relates to a lighting fixture in which light emitting elements are arranged.

Conventionally, it is called a line light, and the product which arranged LED light emitting bodies on a flexible board|substrate is known. This product is used, for example, for outdoor façades, indirect lighting, and under-shelf lighting, and generally has an arbitrary length between 50 mm in short dimension and 5 m in long dimension according to the dimensions of the installation location. It is designed so that it can be cut and used (for example, see Patent Document 1).

As shown in FIG. 3 , on the normal flexible substrate 102, one wiring 104 on the positive electrode side and one wiring 106 on the negative electrode side are disposed. (In some inventions, there is a lighting fixture having a structure in which the energized capacitance is increased by using a plurality of flexible substrates 102 and separately providing a bypass wiring (for example, see Patent Document 2).) . In these cases, power supplied from one end 108 in the longitudinal direction of the lighting fixture first travels from the end 108 on the flexible substrate 102 toward the end 110 through the wiring 104 on the positive electrode side. Thus, power is supplied to all of the light emitting elements 112 (at this time, the resistor is included in the expression of the light emitting element 112) arranged in each unit 111 in order from the power supply side to light them.

Electric power for lighting the light emitting element 112 of each unit 111 is circulated from the end 110 toward the tip 108 to the tip through the wiring 106 on the negative electrode side as a return path. With this structure, the voltage is gradually lost due to the electric power entering the nearby unit 111 from the supply side and the resistance of the wiring 104 on the positive electrode side, which is the outgoing path, and the unit 111 near the end of the long lighting fixture Only low voltage power can be supplied.

Japanese Unexamined Patent Publication No. 2013-118169 Japanese Unexamined Patent Publication No. 2011-090849

By the way, since such lighting fixtures are usually supplied with power from one end 108 in the longitudinal direction of the fixture, for example, if the product has a length of 5 m or more, a flexible substrate for supplying electricity to the light emitting element 112 ( 102) Due to the voltage drop of the phase wiring, the distal end becomes darker than the distal end.

In this respect, by increasing the thickness of the wiring on the flexible substrate 102, by providing a bypass wiring separately as shown in Patent Document 2, increasing the electrical capacity that can conduct electricity, and by increasing the metal purity of the wiring, the resistance value can be reduced. Although it is possible to reduce it, in products with a length of 5 m or longer, the effect on the lowering of the brightness of the end portion is limited.

In addition, a resistor is connected to the light emitting element 112, but it is technically possible to equalize the brightness by connecting a resistor with strong resistance to the front end and a resistor with weak resistance to the end. However, in this case, the resistance of the tip portion must be constant, and for example, when a 5m lighting fixture is cut into 5 pieces every 1m, the brightness of each lighting fixture becomes non-uniform.

For these reasons, the brightness of the tip 110 hardly decreases even if it is longer than 5 m, and when cut to an arbitrary length, lighting in which light emitting elements 112 are arranged on each cut flexible substrate 102 It has been difficult to develop a lighting product in which each appliance has the same brightness.

For this reason, for example, in the case where line lighting is to be installed in the vertical direction on the outer wall of a building with a height of 30 m (equivalent to an 8-story building), first, six lighting fixtures are installed every 5 m, and power is supplied to each lighting fixture. A hole had to be drilled into the outer wall of the building, approximately for each floor. For this reason, not only the problems of safety and workability, but also the economic burden were great.

An object of the present invention is to provide a flexible substrate in which the degree of decrease in brightness across the ends is small when the product is elongated and the brightness of the luminous body does not become uneven even when cut, and a lighting fixture using the flexible substrate.

The lighting fixture of the present invention,

A lighting fixture in which first outgoing wiring, second outgoing wiring, first outgoing wiring, and second outgoing wiring are wired from the front end in the longitudinal direction toward the end, and a plurality of light emitting elements are arranged,

a first conducting portion for conducting electricity between the second outgoing wiring and the first returning wiring is formed at the end;

A plurality of units having a predetermined number of first light emitting elements and second light emitting elements as a set are connected,

Each of the units comprises: a first conducting wiring that conducts electricity between the first outgoing wiring and the second returning wiring through the first light emitting element, and the first returning wiring and the second returning wiring through the second light emitting element. A second conducting wire for conducting the wiring is provided;

Electric power supplied from the front end to the first outgoing wiring is, in each of the units, supplied to the first light emitting element by the first conducting wiring and circulated to the second return wiring;

The electric power supplied from the front end to the second outgoing wiring is once reversed to the first return wiring through the first conducting portion at the end, and then, in each of the units, to the second conducting wiring. It is characterized in that power is supplied to the second light emitting element and circulated to the second return line.

As described above, the first outgoing wiring, first conducting wiring, and second return wiring, which are the first wiring system, and the second outgoing wiring, the first conducting part, the first return wiring, and the second returning wiring, which are the second wiring system. By providing on the same circuit, power in the forward direction flowing from the tip to the end and power in the reverse direction flowing from the end to the end can be supplied. For this reason, when the product is elongated, the degree of decrease in brightness is small across the end, and even if the dimension is changed to an arbitrary length by cutting between units, the brightness of the light emitting body of each cut unit is not uneven. Provided can do.

In addition, the lighting fixture of the present invention,

It is characterized in that a connecting point is formed between the units.

In this way, by providing the connecting point, it is possible to provide a first conducting portion that short-circuits the second outbound wiring and the first return route wiring at the new end that has been cut. Thereby, even if it cuts between any unit, the effect of this invention is maintainable.

In addition, the lighting fixture of the present invention,

At the tip, a first lead wire for supplying electric power to the first outgoing wiring is connected to the first outgoing wiring;

It is characterized in that a second conducting portion for conducting electricity between the first outgoing wiring and the second outgoing wiring is formed on the distal end side.

This makes it possible to simultaneously supply power to both the first wiring system and the second wiring system from the same lead wire.

ADVANTAGE OF THE INVENTION According to this invention, when a product is elongated, the degree of decrease in brightness across an end is small, and the lighting fixture in which the brightness of a luminous body does not become uneven even if it is cut can be provided. That is, in a long flexible lighting fixture far exceeding 5 m, while solving the problem that the brightness of the end decreases due to a voltage drop, it is possible to prevent non-uniform brightness of the light emitting body even if it is cut between any unit.

In addition, by commercializing the lighting fixture of the present invention by sealing it with an insulated softening resin or the like, for example, as a lighting fixture of 30 m (equivalent to an 8-story building) without dividing the exterior wall lighting of a high-rise building every 5 m. It becomes possible to install For this reason, it becomes possible to remarkably improve safety, workability, and economical efficiency including maintenance.

In addition, since there is no problem in using it as a product even if it is cut at any part, it is also economically effective.

1 is a perspective view showing a tape light according to an embodiment.
Fig. 2 is a conceptual diagram showing the structure of a circuit of a printed wiring incorporated in a tape light according to an embodiment.
3 is a conceptual diagram showing a conventional circuit structure.

EMBODIMENT OF THE INVENTION Hereinafter, with reference to drawings, the lighting apparatus which concerns on embodiment of this invention is demonstrated taking a tape light as an example. FIG. 1 is a plan view showing a tape light 2 which is a lighting device according to an embodiment, and FIG. 2 is a plan view showing a circuit 8 of a printed wiring incorporated in the tape light 2 .

As shown in FIG. 1, the tape light 2 is a long-shaped product extending in one direction, and is provided with a substrate 4, a sheet 6, an LED chip 10, and a resistor 11, A lead wire 14 is provided on the front end 12 side, and the end 16 side is open.

Here, the substrate 4 is a strip-shaped plate material having flexibility formed of FPC (Flexible Print Circuits). Such a substrate 4 is formed by stacking a plurality of wiring layers on which printed wiring is applied.

The sheet 6 is, for example, a thin film made of synthetic resin and has insulating properties, and covers the surface of the substrate 4 excluding portions where the LED chips 10 and resistors 11 are mounted.

The LED chips 10 are light emitting elements arranged in a row in the longitudinal direction at predetermined intervals on the surface of the substrate 4 . In this embodiment, six LED chips 10 constitute one set, and the substrate 4 is formed by connecting each unit 17 on which one set of LED chips 10 are mounted. In addition, in FIG. 2, what the three units 17 are shown schematically is illustrated.

The resistor 11 has a function of limiting the input current in order to drive the LED chip 10 normally, and like the LED chip 10, the resistor 11 is arranged in a row on the surface of the substrate 4 at predetermined intervals in the longitudinal direction. are arranged as Furthermore, in this embodiment, each unit 17 is mounted with four resistors 11 constituting a set.

Further, a plurality of connecting points 19 are provided on the boundary of each unit 17 in a direction orthogonal to the longitudinal direction. The connecting points 19 connect wiring (first outgoing wiring 22, second outgoing wiring 24, first return wiring 26, and second return wiring 28 described later) to the substrate 4. This is the point exposed on the surface.

By providing such a connecting point 19, when the tape light 2 is cut between the units 17, the lead wire 14 is connected to the board 4 at the new tip 12 by soldering or the like, Further, at the new terminal 16, the outgoing wiring and the returning wiring can be short-circuited.

In addition, a plurality of through holes (not shown) are formed in the substrate 4 . These through holes conduct between the plurality of wiring layers stacked on the substrate 4 .

In this embodiment, the board 4 in which three units 17 are connected is exemplified, but the length from the front end 12 to the end 16 of the board 4 is a single unit at the shortest. It is possible to set it as the length of the dimension of (17), and it is possible to set it as arbitrary length of 5 m or more as the longest.

2, in the circuit 8 of the substrate 4, first outgoing wiring 22 and second outgoing wiring are provided in a straight line from the front end 12 to the end 16 in the longitudinal direction. (24), the first return wiring 26, and the second return wiring 28 are wired.

Further, a first conducting wire 32 and a second conducting wire 34 are wired to each unit 17 . Here, the first conduction wiring 32 conducts the first outgoing wiring 22 and the second return wiring 28 through the odd-numbered LED chips 10 (first light emitting element) from the front end 12 side, there is. Similarly, the second conduction wiring 34 conducts the first return wiring 26 and the second return wiring 28 through the even-numbered LED chips 10 (second light emitting elements) from the front end 12 side, there is.

Further, at the tip 12, a second conducting portion 36 that conducts current between the first outgoing wiring 22 and the second outgoing wiring 24 is shorted by soldering or the like by connecting the connecting points 19a1 and 19b1, At the end 16, a first conducting portion 38 that conducts current between the second outgoing wiring 24 and the first returning wiring 26 is short-circuited by soldering or the like by connecting the connecting points 19b2 and 19c2.

Next, the flow of electricity in the circuit 8 is explained. First, when power is supplied from the first lead wire 14a to the first outgoing wire 22, power is shunted to the first conducting wire 32 at point A. The split electric power is supplied to the odd-numbered LED chips 10 (first light emitting element) from the tip 12 side to light them, and then supplied to the second return wiring 28 and passed to the second lead wire 14b. is returned

The unclassified power flows through the first outgoing wire 22 as it is, but is shunted to the first conducting wire 32 at point B of the second unit 17 from the tip 12 side, and the odd-numbered LEDs. It is circulated to the second lead wire 14b through the chip 10 (first light emitting element) and the second return wire 28. The same is repeated for the third unit 17 from the front end 12 side.

On the other hand, when power is supplied from the first lead wire 14a to the second outgoing wiring 24 through the second conductive part 36, the electric power once flows through the second outgoing wiring 24 to the end 16 as it is. . Next, it returns from the end 16 through the first conducting portion 38, and is circulated from the end 16 toward the tip 12 in the first return wiring 26.

Next, electric power is shunted to the second conducting wiring 34 at point D of the unit 17 on the most distal 16 side. The split electric power is supplied from the tip 12 side to even-numbered LED chips 10 (second light emitting elements) to light them, and then supplied to the second return wiring 28 and passed to the second lead wire 14b. is returned

Electric power that has not been divided flows as it is through the first return wiring 26 from the end 16 toward the tip 12, but at point E of the second unit 17 from the end 16 side, the second conducting wiring (34), and is circulated to the second lead wire 14b through the even-numbered LED chip 10 (second light emitting element) and the second return wire 28. The same is repeated for the third unit 17 from the end 16 side.

According to the invention related to this embodiment, the first outgoing wiring 22 as the first wiring system, the first conducting wiring 32, and the second return wiring 28 as the first wiring system, and the second outgoing wiring as the second wiring system ( 24), the first conducting portion 38, the first return wiring 26, and the second return wiring 28 are provided on the same circuit 8, so that the forward direction flowing from the tip 12 to the end 16 At the same time as the power of the reverse direction flowing from the end (16) to the tip (12) can be supplied simultaneously. For this reason, when the product is elongated, the degree of decrease in brightness across the end 16 is small, and even if the size is changed to an arbitrary length by cutting between the units 17, the LED chip of each cut unit 17 ( 10) It is possible to provide a lighting fixture in which the brightness does not become non-uniform.

In addition, since the brightness of the light emitting body does not become uneven even if the tape light 2 is cut between any of the units 17, it is possible to change the dimensions of the product to an arbitrary length, and each divided by cutting is independently illuminated. made as an instrument. In addition, since there is no problem in using it as a product even if it is cut at any part, it is also economically effective.

In addition, by sealing the tape light 2 with an insulated softening resin or the like and commercializing it, for example, as a lighting fixture of 30 m (equivalent to an 8-story building) as one light without dividing the exterior wall lighting of a high-rise building by 5 m. It becomes possible to install For this reason, it becomes possible to remarkably improve safety, workability, and economical efficiency including maintenance.

In addition, by providing the connecting point 19, when the tape light 2 is cut between the units 17, the lead wire 14 is connected to the substrate 4 at the new tip 12, or a new unit (17) is prepared, and the tape light 2 can be extended by connecting the connecting point 19 at the end 16 and the new unit 17 at the tip 12 of the new unit 17 with solder or the like. there is.

This method is a normal usage for the conventional connecting point 19, but in the present invention, the first conducting portion 38 connecting the connecting points 19b2 and 19c2 at the new end 16 is provided, whereby the second outgoing wiring 24 and the first return wiring 26 can be short-circuited. Thus, even if cutting is performed between any of the units 17 constituting the tape light 2, the above-described effect can be maintained.

Further, in the distal end 12, by connecting the connecting points 19a1 and 19b1 and soldering the second conducting part 36, both the first wiring system and the second wiring system are simultaneously connected from the same lead wire 14. can supply power.

In addition, in the present embodiment described above, each unit 17 is not necessarily composed of six LED chips 10, and four, eight, etc. LED chips 10 are a unit. (17) may be provided. Similarly, also about the resistor 11, it is not necessarily a set of 4 pieces, and may be incorporated in the LED chip 10.

Further, in the above-described embodiment, the case where the first conducting portion 38 and the second conducting portion 36 are soldered is exemplified, but they may be short-circuited with a conductive material other than solder. For example, a lead wire or a clip may be used for the first conducting portion 38 or the second conducting portion 36, or it may be connected with a terminal or the like. As an example of using the lead wire as a substitute, for example, the first lead wire 14a whose tip is split into two branches may be connected to the connecting points 19a1 and 19b1 and used as the second conducting portion 36 .

In the above-described embodiment, the substrate 4 may be inserted into a hollow tubular flexible resin or may be covered with the flexible resin. In the above embodiment, the surface of the substrate 4 is covered with the resin sheet 6, but the substrate 4 does not need to be covered with the sheet 6.

In the above-described embodiment, the wiring may be formed on only one surface of the substrate or may be formed on both surfaces of the substrate 4 . In addition, the wiring layer constituting the circuit 8 does not necessarily have to be a multi-layer, and may be a single layer.

Moreover, in the embodiment described above, even if the unit 17 is single, it does not matter even if four or more units are connected.

In addition, in the above-mentioned embodiment, although the connecting point 19 of the shape called a land is illustrated, the shape of the connecting point 19 is not limited to the shape shown in this embodiment. That is, the connecting point 19 is not only used for connecting the lead wires 14 that are generally used, but when changing the size of the tape light 2, etc., short-circuiting between wires, which is essential for the establishment of the present invention, is soldered Since it is provided for the purpose of making it possible to perform such things ex post facto, it does not necessarily have to be in the shape of a land, and an electrode or the like may be provided.

2: Tape Light
4: substrate
6: sheet
8: circuit
10: chip
11: resistor
12: leading edge
14: lead wire
14a: first lead wire
14b: second lead wire
16: terminal
17: unit
19 (19a1, 19b1, 19b2, 19c2): connecting points
22: first outbound wiring
24: second outbound wiring
26: wiring to the first ear
28: wiring to the second ear
32: first conducting wire
34: second conducting wire
36: second conducting part
38: first conducting part
102: flexible substrate
104: wiring
106: wiring
108: front end
110: terminal
111: unit
112: light emitting element

Claims (3)

A lighting fixture in which first outgoing wiring, second outgoing wiring, first outgoing wiring, and second outgoing wiring are wired from the front end in the longitudinal direction toward the end, and a plurality of light emitting elements are arranged,
a first conducting portion for conducting electricity between the second outgoing wiring and the first returning wiring is formed at the end;
A plurality of units having a predetermined number of first light emitting elements and second light emitting elements as a set are connected,
Each of the units comprises: a first conducting wiring that conducts electricity between the first outgoing wiring and the second returning wiring through the first light emitting element, and the first returning wiring and the second returning wiring through the second light emitting element. A second conducting wire for conducting the wiring is provided;
Electric power supplied from the front end to the first outgoing wiring is, in each of the units, supplied to the first light emitting element by the first conducting wiring and circulated to the second return wiring;
The electric power supplied from the front end to the second outgoing wiring is once reversed to the first return wiring through the first conducting portion at the end, and then, in each of the units, to the second conducting wiring. A lighting fixture characterized in that power is supplied to the second light emitting element and circulated to the second return circuit. According to claim 1,
A lighting fixture, characterized in that a connecting point is formed between the units. According to claim 1 or 2,
At the tip, a first lead wire for supplying electric power to the first outgoing wiring is connected to the first outgoing wiring;
A lighting fixture characterized in that a second energized portion for energizing the first outgoing wiring and the second outgoing wiring is formed on the distal end side.

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