JP5774861B2 - Light emitting device - Google Patents

Description

  The present invention relates to a light emitting device using a large number of light emitting diodes (LEDs).

  In a light-emitting device such as a lighting fixture that uses a large number of LEDs, the LEDs are mounted on a substrate. In order to make the electric current which flows through LED the same, several LED is normally electrically connected in series.

JP 2007-96287 A

When one of the plurality of LEDs mounted on one substrate fails and the LED is replaced, the entire substrate is replaced. An LED that has not failed will also be replaced.
In particular, when an LED has an insulation failure (open failure), all LEDs that are electrically connected in series, including those that have not failed, will not light up.
The present invention has been made, for example, in order to solve the above-described problems, and an object thereof is to reduce the number of LEDs discarded when the LEDs are replaced.

  The light emitting diode module according to the present invention is a printed wiring board having a substantially rectangular plate shape, and has an engagement convex portion on one of the long sides, and the engagement on the opposite side of the long side with the engagement convex portion A printed wiring board having an engaging recess having a shape engageable with a convex part, a light emitting diode mounted on the printed wiring board, and an anode connection terminal electrically connected to an anode of the light emitting diode, the printed wiring An anode connection terminal located on one short side of the plate, and a cathode connection terminal electrically connected to a cathode of the light emitting diode, the cathode connection terminal located on the opposite side of the short side where the anode connection terminal is located It is characterized by having.

  According to the present invention, a plurality of light emitting diode modules are arranged side by side in both vertical and horizontal directions, and the adjacent light emitting diode modules can be easily electrically connected. Therefore, when an LED fails, the light emitting diode module including the failed LED It is only necessary to exchange them, and the waste of resources can be reduced.

FIG. 3 is a front view showing the structure of the LED module 100 of the first embodiment. FIG. 3 is a front view showing the structure of the connection module 101 according to the first embodiment. FIG. 3 is a front view showing the structure of the base 210 according to the first embodiment. The figure which shows a mode that the LED module 100 and the connection module 101 were arrange | positioned on the base 210 of Embodiment 1. FIG. FIG. 5 is a front view showing the structure of the connection module 102 according to the second embodiment. FIG. 6 is a front view showing the structure of the connection module 103 according to the second embodiment. The figure which shows a mode that the LED module 100 and the connection modules 101-103 were arrange | positioned on the base 210 of Embodiment 2. FIG. The figure which shows a mode that the LED module 100 and the connection modules 104 and 105 are arrange | positioned on the base 210 of Embodiment 3. FIG. The figure which shows a mode that the LED module 100 and the connection modules 104 and 105 are arrange | positioned on the base 210 of Embodiment 4. FIG. FIG. 6 is a front view showing a structure of an LED module 100 according to a fifth embodiment. FIG. 10 is a front view showing a structure of an LED module 100 according to a sixth embodiment. FIG. 10 is a front view showing the structure of an LED module 100 according to a seventh embodiment. The figure which shows a mode that the connector 130 of Embodiment 7 and the connector 140 are fitting. FIG. 10 is a front view showing the structure of an LED module 100 according to an eighth embodiment. The figure which shows a mode that LED module 100 of Embodiment 8 connects. FIG. 10 is a front view showing the structure of the connection module 106 according to the eighth embodiment. The figure which shows a mode that the LED module 100 and the connection module 106 were arrange | positioned on the base 210 of Embodiment 8. FIG. FIG. 10 is a front view showing the structure of an LED module 100 according to a ninth embodiment. FIG. 10 is a front view showing the structure of the connection module 107 according to the ninth embodiment. The figure which shows a mode that the LED module 100 and the connection module 107 were arrange | positioned on the base 210 of Embodiment 9. FIG.

Embodiment 1 FIG.
The first embodiment will be described with reference to FIGS.
In addition, when there are a plurality of the same constituent elements, they may be distinguished by adding lower case letters after the reference numerals.

FIG. 1 is a front view showing the structure of the LED module 100 of this embodiment.
The LED module 100 (light emitting diode module) has one or more LEDs 120. A plurality of LED modules 100 are used for one lighting fixture (light emitting device). Thereby, the lighting fixture provided with many LED120 as a light source is formed.

The LED module 100 includes, for example, a substrate 110, three LEDs 120, and two connectors 130 and 140.
The substrate 110 is a substantially rectangular printed wiring board. The substrate 110 has printed wirings 113 to 117 formed of copper foil or the like. The substrate 110 has two engaging convex portions 111 on the upper long side in the drawing, and two engaging concave portions 112 on the lower long side in the drawing. The distance 532 between the two engagement convex portions 111 is substantially equal to the distance between the two engagement concave portions 112. The distance 531 from the short side on the left side of the substrate 110 to the engagement convex portion 111a on the left side in the drawing is substantially equal to the distance from the short side on the left side of the substrate 110 to the engagement concave portion 112a on the left side in the drawing. A distance 533 from the short side on the right side of the substrate 110 to the engagement convex portion 111b on the right side in the drawing is substantially equal to the distance from the short side on the right side of the substrate 110 to the engagement concave portion 112b on the right side in the drawing. The engagement convex part 111 and the engagement concave part 112 are shapes engaged with each other. Further, the sum of the distance 531 and the distance 533 is substantially equal to the distance 532. That is, the length of the long side of the substrate 110 is about twice the distance 532. On the substrate 110, three LEDs 120 and two connectors 130 and 140 are mounted.
The three LEDs 120 are arranged substantially linearly in parallel with the long side direction of the substrate 110. The distances 512 and 513 between two adjacent LEDs 120 are all approximately equal. Further, the total of the distance 511 from the short side on the left side of the substrate 110 to the leftmost LED 120a in the drawing and the distance 514 from the short side on the right side of the substrate 110 to the rightmost LED 120c in the drawing is 2 adjacent. It is approximately equal to the distance 512, 513 between the two LEDs 120. That is, the length of the long side of the substrate 110 is about three times the distances 512 and 513. The distances 521 from the upper long side of the substrate 110 to the respective LEDs 120 are almost equal. All of the distances 522 from the lower long side of the substrate 110 to the respective LEDs 120 are substantially equal. The sum of the distance 521 and the distance 522 (that is, the length of the short side of the substrate 110) is substantially equal to the distances 512 and 513 between the two adjacent LEDs 120. That is, the length of the long side of the substrate 110 is about three times the length of the short side of the substrate 110. Each LED 120 has an anode electrode 121 (anode) and a cathode electrode 122 (cathode).
The connector 130 is, for example, a female connector, and includes a fitting protrusion 131 and two female contacts 132 and 133. The connector 140 is a male connector, for example, and includes a fitting recess 141 and two male contacts 142 and 143. The fitting convex portion 131 and the fitting concave portion 141 are shaped to fit each other. When the fitting convex portion 131 and the fitting concave portion 141 are fitted, the female contact 132 and the male contact 142 come into contact with each other. Then, the female contact 133 and the male contact 143 come into contact with each other for electrical connection. The connector 130 is disposed outward on one short side of the substrate 110. The connector 140 is disposed outward on the other short side of the substrate 110. The distance from the long side on the upper side of the board 110 to the connector 130 is substantially equal to the distance from the long side on the upper side of the board 110 to the connector 140.

  As described above, a plurality of LED modules 100 are used in one lighting fixture. The plurality of LED modules 100 are arranged side by side in a substantially planar shape. When the LED modules 100 are arranged in the long side direction of the substrate 110, the connector 140 of one LED module 100 is fitted into the connector 130 of the adjacent LED module 100 to be electrically connected. Further, when the LED modules 100 are arranged in the short side direction of the substrate 110, the engagement protrusions 111 of one LED module 100 are engaged with the engagement recesses 112 of the adjacent LED modules 100 for alignment.

LED 120a has anode electrode 121 printed on printed wiring 114, cathode electrode 122 printed on printed wiring 115, LED 120b anode electrode 121 printed on printed wiring 115, cathode electrode 122 printed on printed wiring 116, and LED 120c printed on anode electrode 121. The cathode electrode 122 is electrically connected to the wiring 116 and the printed wiring 117, respectively. Thereby, the three LEDs 120 are electrically connected to each other in series. The female contact 133 (anode connection terminal) is electrically connected to the printed wiring 114. Thereby, the female contact 133 is electrically connected to the anode electrode 121 of the LED 120a. The male contact 143 (cathode connection terminal) is electrically connected to the printed wiring 117. Thereby, the male contact 143 is electrically connected to the cathode electrode 122 of the LED 120c.
The female contact 132 (return connection terminal) and the male contact 142 (return connection terminal) are electrically connected to each other by being electrically connected to the printed wiring 113.

FIG. 2 is a front view showing the structure of the connection module 101 of this embodiment.
The connection module 101 (joint) is used together with the LED module 100. For example, the connection module 101 includes a substrate 110 and a connector 130.
The substrate 110 is a substantially rectangular printed wiring board. The substrate 110 has a shape in which the substrate 110 of the LED module 100 is cut in half in the long side direction. The substrate 110 has a printed wiring 113. The substrate 110 has an engaging convex portion 111 on the upper long side in the drawing, and an engaging concave portion 112 on the lower long side in the drawing.
The connector 130 is the same connector as the connector 130 of the LED module 100. The connector 130 is disposed outward on the short side of the left side of the substrate 110 in the drawing. The position of the connector 130 is substantially the same as the connector 130 of the LED module 100. The connector 130 is electrically connected to the connector 140 of the adjacent LED module 100 by fitting.

  The two female contacts 132 and 133 are electrically connected to each other by being electrically connected to the printed wiring 113.

FIG. 3 is a front view showing the structure of the base 210 of this embodiment.
The base 210 is a base for arranging the LED module 100 and the connection module 101 side by side. The base 210 also serves as a heat radiating part for radiating heat generated by the LED 120. The base 210 has a flat surface portion 211 and a plurality of convex portions 212 and 213.
The flat part 211 is substantially flat plate-shaped.
The plurality of convex portions 212 are arranged in a substantially straight line. The distance between the adjacent two convex portions 212 is substantially equal to the distance between the two engaging convex portions 111 of the LED module 100. The convex portion 212 has a shape that engages with the engaging convex portion 111 of the LED module 100.
The plurality of convex portions 213 are arranged in a substantially straight line. The distance between the two adjacent protrusions 213 is approximately equal to the distance between the two adjacent protrusions 212 and approximately equal to the distance between the two engagement recesses 112 of the LED module 100. The convex portion 213 has a shape that engages with the engaging concave portion 112 of the LED module 100. Each convex portion 213 is paired with the convex portion 212. The distance between the convex part 212 and the convex part 213 that are paired is substantially equal to the length of the short side of the substrate 110 of the LED module 100.

FIG. 4 is a diagram showing a state in which the LED module 100 and the connection module 101 are arranged on the base 210 of this embodiment.
Due to the positional relationship between the convex portions 212 and the convex portions 213 described above, the LED module 100 is positioned by being fitted between the two convex portions 212 and the two convex portions 213. In addition, the connection module 101 is positioned by being just fitted between one convex portion 212 and one convex portion 213. For example, the two LED modules 100 and the connection module 101 are disposed between the five convex portions 212 and the five convex portions 213. At this time, the connector 140 of the LED module 100a arranged on the left side in the drawing and the connector 130 of the LED module 100b arranged on the right side in the drawing are fitted and electrically connected. Further, the connector 140 of the LED module 100b and the connector 130 of the connection module 101 are fitted and electrically connected.
For example, a harness 220 is connected to the connector 130 of the LED module 100a. The harness 220 is connected to a lighting circuit (not shown). The lighting circuit converts, for example, power supplied from a power source such as a commercial power source into power for lighting the LED 120 and supplies the power to the LED module 100 via the harness 220.

  Thus, by connecting the two LED modules 100 and the connection module 101, a circuit in which six LEDs 120 are electrically connected in series is formed.

In this way, the number of LEDs 120 mounted on one LED module 100 is reduced, and a plurality of LED modules 100 are used to constitute one lighting fixture. If any LED 120 stops lighting due to a failure, only the LED module 100 on which the LED 120 is mounted can be replaced.
Further, since the shape of the LED module 100 is not rotationally symmetric, the LED module 100 cannot be arranged in the wrong direction. For this reason, it is possible to prevent the LED module 100 from being placed in the wrong direction when manufacturing or repairing the lighting fixture.
Also, the distances between the LEDs 120 mounted on the LED module 100 are all substantially equal, and the length of the LED module 100 in the long side direction of the substrate 110 is expressed as [Distance between adjacent LEDs 120] and [Number of LEDs 120]. When the LED modules 100 are connected in the long side direction, the distance between adjacent LEDs 120 in the same LED module 100 and the distance between adjacent LEDs 120 between different LED modules 100 are approximately equal to each other. Will be equal. Thereby, it is possible to prevent a sense of incongruity caused by configuring a lighting fixture using a plurality of LED modules 100.

Embodiment 2. FIG.
The second embodiment will be described with reference to FIGS.
In addition, about the part which is common in Embodiment 1, the same code | symbol is attached | subjected and description is abbreviate | omitted.
The LED module 100 and the connection module 101 in this embodiment are the same as those in the first embodiment.

FIG. 5 is a front view showing the structure of the connection module 102 of this embodiment.
The connection module 102 is used when the LED modules 100 are arranged in the short side direction. The connection module 102 includes, for example, a substrate 110, a connector 130, and two connectors 140.
The substrate 110 is a substantially rectangular printed wiring board. The substrate 110 has a shape in which the substrate 110 of the LED module 100 is cut in half in the long side direction, like the substrate 110 of the connection module 101. The substrate 110 has printed wirings 113 to 115. The substrate 110 has an engaging convex portion 111 on the upper long side in the drawing, and an engaging concave portion 112 on the lower long side in the drawing.
The connector 130 is the same connector as the connector 130 of the LED module 100. The connector 130 is disposed outward on the long side of the lower side of the substrate 110 in the drawing. The two connectors 140 are the same connectors as the connector 140 of the LED module 100. The connector 140a is arranged outward on the short side of the right side of the substrate 110 in the drawing. The position of the connector 140a is substantially the same as the position of the connector 140 of the LED module 100. The connector 140a is fitted and electrically connected to the connector 130 of the adjacent LED module 100. The connector 140b is disposed outward on the upper long side of the substrate 110 in the drawing. The distance from the short side on the right side of the substrate 110 to the connector 130 is substantially equal to the distance from the short side on the right side of the substrate 110 to the connector 140b.

  The connector 130 has a first female contact on the printed wiring 113, a second female contact on the printed wiring 115, and the connector 140a has a first male contact on the printed wiring 114 and a second male contact. Are connected to the printed wiring 115, and the connector 140b is electrically connected to the printed wiring 113 at the first male contact and to the printed wiring 114 at the second male contact. As a result, the first female contact and the first male contact of the connector 140b are electrically connected to each other, and the second female contact and the second male contact of the connector 140a are electrically connected to each other. The first male contact at 140a and the second male contact at connector 140b are electrically connected to each other.

FIG. 6 is a front view showing the structure of the connection module 103 of this embodiment.
The connection module 103 is obtained by removing the connector 140b for connection in the upward direction in the figure from the connection module 102. The connection module 103 includes, for example, a substrate 110, a connector 130, and a connector 140.
The board 110 has the same shape as the connection modules 101 and 102, and the board 110 of the LED module 100 is cut in half in the long side direction. The substrate 110 has printed wirings 113 and 115. The substrate 110 has an engaging convex portion 111 on the upper long side in the drawing, and an engaging concave portion 112 on the lower long side in the drawing.
The connector 130 is the same connector as the connector 130 of the LED module 100. The connector 130 is disposed at substantially the same position as the connector 130 of the connection module 102. The connector 140 is the same connector as the connector 140 of the LED module 100. The connector 140 is disposed at substantially the same position as the connector 140a of the connection module 102.

  The connector 130 has a first female contact on the printed wiring 113, the second female contact on the printed wiring 115, and the connector 140 has a first male contact on the printed wiring 113 and a second male contact. Are electrically connected to the printed wiring 115 respectively. Thereby, the first female contact and the first male contact are electrically connected to each other, and the second female contact and the second male contact are electrically connected to each other.

FIG. 7 is a diagram illustrating a state in which the LED module 100 and the connection modules 101 to 103 are arranged on the base 210 according to this embodiment.
The base 210 is larger than the base 210 described in the first embodiment, and the distance between the convex portion 212 and the convex portion 213 is about six times. For this reason, six LED modules 100 can be arranged on the base 210 in the short side direction. Moreover, the base 210 has six convex portions 212 and six convex portions 213, respectively.
In the leftmost column in the figure, the connection module 103 is arranged at the upper end in the figure, and five connection modules 102 are arranged below it. Six connection modules 101 are arranged in the rightmost column in the figure. A total of 12 LED modules 100 are arranged in the other columns.
The LED modules 100 and the connection modules 101 and 103 arranged in the uppermost row in the figure are positioned by engaging the engaging protrusions 111 with the protrusions 212 provided on the base 210. Further, the LED module 100 and the connection modules 101 and 102 arranged in the lower end row in the drawing are positioned by engaging the engaging recess 112 with the protruding portion 213 provided on the base 210. In the LED modules 100 and the connection modules 101 and 102 arranged in the other rows, the engagement convex portions 111 are engaged with the engagement concave portions 112 of the LED modules 100 and the connection modules 101 to 103 adjacent on the upper side in the drawing. The engagement recess 112 is engaged and positioned with the LED module 100 and the connection modules 101 and 102 adjacent to the lower side in the drawing.
The connector 130 and the connector 140 are fitted and connected between the LED modules 100 adjacent in the long side direction or between the LED module 100 and the connection modules 101 to 103. Further, the connector 130 and the connector 140 are also connected and connected between the connection modules 102 adjacent in the short side direction or between the connection module 102 and the connection module 103. Further, for example, a harness 220 is connected to the connector 130 of the connection module 102 in the lower left in the drawing, and is connected to the lighting circuit via the harness 220.
The distance 523 between the LEDs 120 adjacent in the short side direction is equal to the sum of the distance 521 and the distance 522 described in FIG. 1, that is, the length of the short side of the substrate 110, and between the LEDs 120 adjacent in the long side direction. It is approximately equal to the distance 513. For this reason, the LEDs 120 are arranged at the same intervals in both the vertical and horizontal directions and are arranged in a square lattice pattern.

  In this way, a circuit in which 36 LEDs 120 are electrically connected in series is formed by connecting 12 LED modules 100, 6 connection modules 101, 5 connection modules 102, and 1 connection module 103. .

As described above, the LED modules 100 can be arranged not only in the long side direction of the substrate 110 but also in the short side direction of the substrate 110. Thereby, the lighting fixture with which LED120 was located in a grid | lattice form can be manufactured.
In addition, by using the same LED module 100 as in the first embodiment and changing the shape of the base 210, it is possible to easily manufacture lighting fixtures having different numbers and arrangements of LEDs 120. For this reason, even when manufacturing many types of lighting fixtures in which the number and arrangement of the LEDs 120 are changed, only one type of LED module 100 is required. Moreover, even when manufacturing a new type of lighting fixture in which the number and arrangement of the LEDs 120 are changed, the same LED module 100 can be used, and there is no need to design and manufacture the new LED module 100. In this way, since the same LED module 100 can be used to manufacture a wide variety of lighting fixtures, the design cost of the LED module 100 can be reduced, and even when the lighting fixtures are produced in a variety of low-volume production, the same LED module 100 can be manufactured. Since mass production is possible, the manufacturing cost of the LED module 100 can be suppressed.
In addition, by making the length of the substrate 110 of the LED module 100 in the short side direction substantially equal to the distance between the LEDs 120, the distance between the LEDs 120 in the long side direction and the distance between the LEDs 120 in the short side direction Are almost equal. Thereby, it is possible to prevent a sense of incongruity caused by configuring a lighting fixture using a plurality of LED modules 100.

Embodiment 3 FIG.
A third embodiment will be described with reference to FIG.
In addition, about the part which is common in Embodiment 1 and Embodiment 2, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 8 is a diagram illustrating a state in which the LED module 100 and the connection modules 104 and 105 are arranged on the base 210 according to this embodiment.
The LED module 100 in this embodiment is the same as that in the first and second embodiments. The base 210 is the same as that in the second embodiment.
The connection module 104 is substantially U-shaped. The connection module 104 is electrically equivalent to a combination of six connection modules 101 in one. That is, the connection module 104 has six connectors 130, and each connector 130 has two female contacts 132 and 133 that are electrically connected to each other.
The connection module 105 is substantially U-shaped. The connection module 105 is electrically equivalent to a combination of five connection modules 102 and one connection module 103. In addition, since the connection module 105 is comprised with the one board | substrate 110, the connectors 130 and 140 for connecting between the connection modules 102 and between the connection module 102 and the connection module 103 are unnecessary. That is, the connection module 105 has one connector 130 and six connectors 140, and detailed description thereof is omitted, but between the female contacts 132 and 133 of the connector 130 and the male contacts 142 and 143 of the connector 140. Are properly connected.
A total of ten LED modules 100 are arranged between the two connection modules 104 and 105. Unlike the second embodiment, only one LED module 100 is arranged in the upper row in the figure and the lower row in the figure. The LED modules 100 arranged in the upper row in the figure and the lower row in the figure are arranged at positions shifted by half in the long side direction of the substrate 110 with respect to the LED modules 100 adjacent in the short side direction of the substrate 110. The
As in the second embodiment, the LED modules 100 and the connection modules 104 and 105 are engaged with the convex portions 212 provided on the base 210 and the LED modules 100 and the connection modules 104 and 105 adjacent on the upper side in the drawing. Engagement convex part 111 engages with concave part 112, and convex part 213 provided on base 210, or engagement convex part 111 of LED module 100 and connection modules 104 and 105 adjacent to the lower side in the figure, Positioning is achieved by engaging the engaging recess 112.
Further, the connector 130 and the connector 140 are fitted and electrically connected between the LED modules 100 adjacent in the long side direction or between the LED module 100 and the connection modules 104 and 105.

  As described with reference to FIG. 1, the length of the long side of the substrate 110 of the LED module 100 is approximately twice the distance 532 between the engagement convex portions 111 of one LED module 100. For this reason, as shown to this figure, the LED module 100 can be arrange | positioned in the position shifted half in the long side direction. Thereby, the variation of the lighting fixture which can be manufactured using the same LED module 100 increases. In particular, in this example, since the number of LEDs 120 mounted on one LED module 100 is an odd number, if the LED module 100 is arranged at a position shifted by half in the long side direction, the positional relationship between the LEDs 120 adjacent in the short side direction is It is not a square lattice but a triangular lattice. Thereby, the variation of arrangement | positioning of LED120 of the lighting fixture which can be manufactured using the same LED module 100 increases further.

Thus, the length of the LED module 100 in the long side direction of the substrate 110 is made substantially equal to the product of [distance between adjacent engaging convex portions 111] and [number of engaging convex portions 111]. When there are three or more engaging convex portions 111 (and engaging concave portions 112) in one LED module 100, all the distances between the adjacent engaging convex portions 111 (and engaging concave portions 112) are substantially equal. . Thereby, the position of the LED module 100 adjacent in the short side direction can be shifted in the long side direction, and the variation of arrangement | positioning of LED120 increases. If the number of the LEDs 120 is equal to the number of the engaging protrusions 111 or an integer multiple of the number of the engaging protrusions 111, the positional relationship between the LEDs 120 adjacent in the short side direction is not changed, and the short The position of the LED module 100 adjacent in the side direction can be shifted in the long side direction.
In the second embodiment, it has been described that the number and arrangement of the LEDs 120 can be changed by changing the shape of the base 210. However, the shape of the base 210 is not changed as in this embodiment. The number and arrangement of the LEDs 120 can be changed.
Furthermore, by using the connection modules 104 and 105 having a shape according to the number and arrangement of the LEDs 120, the number of connection modules is reduced compared to the case of using the connection modules 101 to 103 as in the second embodiment. Increases work efficiency when manufacturing and repairing lighting fixtures. Further, since the total number of connectors 130 and 140 is reduced, the manufacturing cost of the lighting fixture can be suppressed.

Embodiment 4 FIG.
The fourth embodiment will be described with reference to FIG.
In addition, about the part which is common in Embodiment 1- Embodiment 3, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 9 is a diagram illustrating a state in which the LED module 100 and the connection modules 104 and 105 are arranged on the base 210 according to this embodiment.
The LED module 100 in this embodiment is the same as the LED module 100 described in the first to third embodiments, but the length in the short side direction of the substrate 110 is slightly shorter. The LED module 100 has a length in the short side direction of the substrate 110 of about 0.866 times that of the LED module 100 described in the first to third embodiments. This is because the LED modules 100 adjacent in the short side direction are basically arranged at positions shifted by half in the long side direction so that the triangular lattice formed at that time becomes a regular triangle. That is, when the distance 513 between the LEDs 120 adjacent in the long side direction is x, the distance 523 between the LEDs 120 in the short side direction is 0.866x, and thus the distance 524 between the LEDs 120 adjacent in the diagonal direction is , √ [(x / 2) ^ 2 + (0.866x) ^ 2] ≈√ (0.25 + 0.75) x = x, and therefore the distance 524 is substantially equal to the distance 513.
Although the base 210 and the connection modules 104 and 105 are different in shape from those described in the third embodiment, they are basically the same and will not be described.

  As described above, the length in the short side direction of the substrate 110 of the LED module 100 is set to about 0.866 times the [distance between adjacent LEDs 120]. It is assumed that the number of engaging convex portions 111 (and engaging concave portions 112) in one LED module 100 is an even number, and the number of LEDs 120 is an odd number. As a result, the LED modules 100 adjacent in the short side direction can be arranged at positions shifted by half in the long side direction, and the LEDs 120 are arranged in a substantially equilateral triangular triangular lattice pattern.

Embodiment 5 FIG.
Embodiment 5 will be described with reference to FIG.
In addition, about the part which is common in Embodiment 1- Embodiment 4, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 10 is a front view showing the structure of the LED module 100 of this embodiment.
The LED module 100 includes a detour element 150 in addition to the LED module 100 described in the first embodiment. The number of bypass elements 150 is the same as the number of LEDs 120.
In the bypass element 150 (disconnection bypass circuit), a current flows when the voltage between both ends exceeds a predetermined voltage. The bypass element 150 is, for example, a constant voltage diode such as a Zener diode or an avalanche diode, an antifuse element, or the like.

The bypass element 150a has one electrode on the printed wiring 114, the other electrode on the printed wiring 115, and the bypass element 150b has one electrode on the printed wiring 115 and the other electrode on the printed wiring 116. In 150c, one electrode is electrically connected to the printed wiring 116 and the other electrode is electrically connected to the printed wiring 117. Thereby, the bypass element 150a is electrically connected to the LED 120a, the bypass element 150b is electrically connected to the LED 120b, and the bypass element 150c is electrically connected to the LED 120c in parallel.
Note that the threshold voltage at which current starts to flow through the bypass element 150 is sufficiently larger than the forward voltage drop when the maximum rated current of the LED 120 flows through the LED 120. For example, the forward voltage drop of the LED 120 is 3V, and the threshold voltage of the detour element 150 is 5V.

  In the first embodiment, it has been described that when the LED 120 stops lighting due to a failure, only the LED module 100 including the LED 120 needs to be replaced. In the case of the configuration in which the LEDs 120 of the plurality of LED modules 100 are electrically connected in series, if the failure mode of the LED 120 is a short-circuit failure, only the failed LED 120 becomes inconsequential. Recognize. However, if the failure mode of the LED 120 is an insulation failure, not only the failed LED 120 but also all the LEDs 120 electrically connected in series are inconsequential, so which LED module 100 should be selected unless inspected using a tester. I don't know if I should replace it.

  On the other hand, in the LED module 100 in this embodiment, the bypass element 150 is electrically connected in parallel with the LED 120. When an insulation failure occurs in any of the LEDs 120 during lighting, the voltage across the detour element 150 electrically connected in parallel with the failed LED 120 increases, and the detour element 150 becomes conductive. As a result, the LEDs 120 other than the failed LED 120 continue to be lit, and only the failed LED 120 becomes unsatisfactory. Therefore, it can be readily seen which LED module 100 should be replaced.

  As described above, by providing the bypass element 150 electrically connected in parallel with each LED 120, even if the LED 120 has an insulation failure, the LEDs 120 other than the failed LED 120 continue to be lit, so which LED module 100 should be replaced. You can see how quickly it is, and you can reduce the labor and cost of repairing lighting fixtures.

Embodiment 6 FIG.
A sixth embodiment will be described with reference to FIG.
In addition, about the part which is common in Embodiment 1- Embodiment 5, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 11 is a front view showing the structure of the LED module 100 of this embodiment.
The LED module 100 further includes a detour element 150 in addition to the LED module 100 described in the first embodiment. The detour elements 150 are the same as those described in the fifth embodiment, but the number of detour elements 150 is one.

In the bypass element 150, one electrode is electrically connected to the printed wiring 114 and the other electrode is electrically connected to the printed wiring 117. Thereby, the detour element 150 is electrically connected in parallel with the series circuit of the three LEDs 120.
Note that the threshold voltage at which current starts to flow through the bypass element 150 is sufficiently larger than the voltage generated at both ends of the series circuit of the three LEDs 120 when the maximum rated current of the LED 120 flows through the LED 120. For example, the forward voltage drop of one LED 120 is 3V, and the threshold voltage of the bypass element 150 is 15V.

  In the fifth embodiment, it has been described that by providing one bypass element 150 for one LED 120, it is possible to immediately know which LED 120 has an insulation failure. However, since the replacement of the LED 120 is performed in units of LED modules 100, it is not necessary to know which LED 120 has failed in one LED module 100, and it is possible to determine which LED 120 in the LED module 100 has failed. That's fine.

  In the LED module 100 according to this embodiment, when one of the LEDs 120 has an insulation failure during lighting, the voltage across the detour element 150 becomes high and the detour element 150 becomes conductive. Thereby, LED120 of the other LED module 100 electrically connected in series continues lighting, and only LED120 of the LED module 100 including the failed LED120 becomes a point. Therefore, it can be readily seen which LED module 100 should be replaced.

  In this way, by providing the bypass element 150 electrically connected in parallel with the series circuit of the LED 120, even if the LED 120 has an insulation failure, the LEDs 120 other than the LED module 100 including the failed LED 120 continue to be lit. It is immediately known whether or not 100 should be replaced, and the labor and cost for repairing the lighting fixture can be reduced.

Embodiment 7 FIG.
A seventh embodiment will be described with reference to FIGS.
In addition, about the part which is common in Embodiment 1- Embodiment 6, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 12 is a front view showing the structure of the LED module 100 of this embodiment.
The LED module 100 differs in the shape of the connectors 130 and 140 compared with the LED module 100 described in the embodiment.
The connector 130 has a fitting protrusion 131 and two female contacts 132 and 133. In the connector 130, the female contacts 132 and 133 are oriented in a direction substantially perpendicular to the substrate 110.
The connector 140 includes a fitting recess 141, two male contacts 142 and 143, a fixed portion 144, a shaft 145, and a movable portion 146. The fixing part 144 is fixed to the substrate 110. The shaft 145 has a substantially cylindrical shape substantially parallel to the short side direction of the substrate 110 and is formed integrally with the fixed portion 144 or fixed to the fixed portion 144 so as to be rotatable or non-rotatable. The movable portion 146 engages with the shaft 145 and can rotate about 90 degrees about the shaft 145. When the shaft 145 is fixed so as to be rotatable with respect to the fixed portion 144, the movable portion 146 may be formed integrally with the shaft 145. The fitting recess 141 and the two male contacts 142 and 143 are provided near the tip of the movable portion 146.
Note that the connectors 130 and 140 of the connection modules 101 to 105 have the same shape as the connectors 130 and 140 of the LED module 100.

FIG. 13 is a diagram showing a state in which the connector 130 and the connector 140 of this embodiment are fitted.
By arranging the two LED modules 100 in the long side direction and rotating the movable portion 146 of the connector 140, the connector 140 is fitted and connected to the connector 130 of the adjacent LED module 100.

When the LED module 100 is to be replaced, the connector 140 of the LED module 100 to be replaced is rotated and fitted to the connector 130 of the adjacent LED module 100 (or the connection module 101 or the like) fitted to the connector 140. -Disconnect the connection. Further, the connector 140 of the adjacent LED module 100 (or the connection module 102 or the like) fitted to the connector 130 of the LED module 100 to be replaced is rotated to release the fitting / connection with the connector 130.
As described above, since the fitting / connecting between the connector 130 and the connector 140 can be easily released, it is possible to reduce labor and cost for replacing the LED module 100.

Embodiment 8 FIG.
An eighth embodiment will be described with reference to FIGS.
In addition, about the part which is common in Embodiment 1- Embodiment 7, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 14 is a front view showing the structure of the LED module 100 of this embodiment.
The LED module 100 includes six leaf springs 160 instead of the connectors 130 and 140 of the LED module 100 described in the first embodiment. In addition, the substrate 110 has a printed wiring 118.
The leaf spring 160 is formed of a metal having conductivity and elasticity. The leaf spring 160 has, for example, a shape obtained by rounding one end of an elongated rectangular plate. The leaf spring 160 is arranged such that the flat end is fixed to the substrate 110 and the rounded portion slightly protrudes from the substrate 110. The three plate springs 160a to 160c are provided on the short side on the left side of the substrate 110 in the drawing, and the remaining three plate springs 160d to 160f are provided on the short side on the right side of the substrate 110 in the drawing. The respective leaf springs 160b and 160e at the center are located at substantially the center of the short side of the substrate 110. The other four leaf springs 160 a, 160 c, 160 d, and 160 f are disposed at substantially symmetrical positions, and the distance from the long side of the substrate 110 is substantially the same.

  The leaf spring 160a is printed on the printed wire 113, the leaf spring 160b is printed on the printed wire 114, the leaf spring 160c is printed on the printed wire 118, the leaf spring 160d is printed on the printed wire 113, the leaf spring 160e is printed on the printed wire 117, and the leaf spring 160f is printed. Each wiring 118 is electrically connected. Thereby, the leaf spring 160a and the leaf spring 160d are electrically connected to each other. The leaf spring 160c and the leaf spring 160f are electrically connected to each other. The leaf spring 160b is electrically connected to the anode electrode 121 of the LED 120a. The leaf spring 160e is electrically connected to the cathode electrode 122 of the LED 120c.

FIG. 15 is a diagram illustrating a state in which the LED modules 100 according to this embodiment are connected to each other.
When the two LED modules 100 are arranged adjacent to each other in the long side direction, the leaf spring 160d of one LED module 100 and the leaf spring 160a of the other LED module 100 are in contact with each other. Due to the elasticity, the two leaf springs 160a and 160d are pressed against each other, so that the two leaf springs 160a and 160d are securely in contact with each other and are electrically connected.
Similarly, the leaf spring 160e of one LED module 100 and the leaf spring 160b of the other LED module 100 are in contact with each other and electrically connected, and the leaf spring 160f of the one LED module 100 and the leaf spring 160c of the other LED module 100 are connected. And make electrical connection.

FIG. 16 is a front view showing the structure of the connection module 106 of this embodiment.
The connection module 106 includes a substrate 110 and five leaf springs 160. The substrate 110 has printed wirings 113 and 114. Unlike the connection module 101 described in Embodiment 1, the shape of the substrate 110 is provided with one engagement recess 112 on each of the long sides. The position of the engagement recess 112a is substantially the same as the position of the engagement recess 112 of the connection module 101 described in the first embodiment. Further, the position of the engagement recess 112b is substantially the same as the position of the engagement protrusion 111 of the connection module 101 described in the first embodiment.
The leaf spring 160 is the same as the leaf spring 160 of the LED module 100. The three leaf springs 160a to 160c are provided on the short side on the left side of the substrate 110 in the drawing. The positions of the three leaf springs 160a to 160c are substantially the same as the positions of the three leaf springs 160a to 160c provided on the left side of the LED module 100 in the drawing. The leaf spring 160d is provided on the upper long side of the substrate 110 in the drawing, and the leaf spring 160e is provided on the lower long side of the substrate 110 in the drawing. The two leaf springs 160d and 160e are for connection in the short side direction, and the distance from the short side on the left side of the substrate 110 in the drawing is substantially equal.

The connection module 106 is disposed adjacent to the right side of the LED module 100 in the drawing, so that the leaf spring 160a is the leaf spring 160d of the LED module 100, the leaf spring 160b is the leaf spring 160e of the LED module 100, and the leaf spring 160c. Are in contact with and electrically connected to 160f of the LED module 100, respectively.
Further, the connection module 106 is rotated 180 degrees and is arranged adjacent to the left side of the LED module 100 in the drawing so that the leaf spring 160a is the leaf spring 160c of the LED module 100 and the leaf spring 160b is the leaf of the LED module 100. The spring 160b and the leaf spring 160c are in contact with and electrically connected to the leaf spring 160a of the LED module 100, respectively.
The two leaf springs 160a and 160d are electrically connected to each other by being electrically connected to the printed wiring 114. The three leaf springs 160b, 160c, and 160e are electrically connected to each other by being electrically connected to the printed wiring 113.

FIG. 17 is a diagram showing a state in which the LED module 100 and the connection module 106 are arranged on the base 210 of this embodiment.
The base 210 includes, for example, a flat portion 211, four convex portions 212, and twelve convex portions 213. The six convex portions 213a to 213f are arranged at equal intervals on the lower side of the flat portion 211 in the drawing. The three convex portions 213g to 213i are arranged at equal intervals from the convex portion 213a, and the three convex portions 213j to 213 are arranged at equal intervals from the convex portion 213f in the upward direction in the drawing, respectively. The four convex portions 212 are arranged at regular intervals between the convex portions 213i and 213l at the upper end in the drawing. In the drawing, the interval between the convex portions 213 adjacent in the vertical direction is substantially equal to the length of the short side of the substrate 110 of the connection module 106. In the drawing, the interval between the convex portions 212 and 213 adjacent in the horizontal direction is substantially equal to the interval between the engagement concave portions 112 of the substrate 110 of the LED module 100 and is approximately half the length of the substrate 110 of the LED module 100 in the long side direction. Yes, the length of the connection module 106 in the long side direction of the substrate 110 is substantially equal.
On the base 210, for example, six LED modules 100 and six connection modules 106 are arranged side by side. In the leftmost column in the figure, the three connection modules 106 are arranged in a direction rotated by 180 degrees with respect to the direction described with reference to FIG. In the rightmost column in the figure, three connection modules 106 are arranged in the direction described with reference to FIG. Three LED modules 100 are arranged in two rows in between. The two LED modules 100 in the uppermost row in the figure are positioned with the engaging convex portion 111 engaging the convex portion 212 of the base 210. The two LED modules 100 in the lower row in the figure are positioned by engaging the engaging recess 112 with the protruding portion 213 of the base 210. In the other LED modules 100, the engaging convex portion 111 engages with the engaging concave portion 112 of the LED module 100 adjacent to the upper side in the drawing, and the engaging concave portion 112 is adjacent to the lower side in the drawing. The engaging projection 111 is engaged and positioned. The connection module 106 is positioned by engaging the two engaging concave portions 112 with the convex portions 213 of the base 210.
Further, between the adjacent LED modules 100 and the connection modules 106, the opposed leaf springs 160 are in contact with each other and are electrically connected.

  The harness 220 contacts and is electrically connected to the leaf spring 160 by hooking an end portion of the harness 220 on the leaf spring 160. The harness 220a is electrically connected to the leaf spring 160e (see FIG. 16) of the connection module 106 at the upper left end in the drawing. The harness 220b is electrically connected to the leaf spring 160e (see FIG. 16) of the connection module 106 at the lower right end in the drawing. The other end of the harness 220 is electrically connected to a lighting circuit (not shown).

  Thus, by connecting the six LED modules 100 and the six connection modules 106, a circuit in which 18 LEDs 120 are electrically connected in series is formed.

As described above, the LED modules 100 and the like are not limited to the configuration of being electrically connected by the connector, but may be of a configuration of being electrically connected by a leaf spring or the like, or may be another configuration.
By configuring the connection portion so that there is no distinction between males and females, such as a leaf spring, a module having no polarity such as the connection module 106 can be arranged by being inverted 180 degrees. Thereby, since there are few kinds of connection modules, the manufacturing cost of a connection module etc. can be held down. Even when the connection portion is configured so that there is no distinction between male and female, the substrate 110 of a module having polarity, such as the LED module 100, has a shape that is not rotationally symmetric, and therefore cannot be reversed 180 degrees. For this reason, the LED module 100 is not mistakenly arranged.

Embodiment 9 FIG.
The ninth embodiment will be described with reference to FIGS.
In addition, about the part which is common in Embodiment 1- Embodiment 8, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 18 is a front view showing the structure of the LED module 100 of this embodiment.
The LED module 100 includes four leaf springs 160 instead of the connectors 130 and 140 of the LED module 100 described in the first embodiment. The leaf spring 160 is the same leaf spring as that described in the eighth embodiment.
Two four leaf springs 160 are arranged on each of the two short sides of the substrate 110. The distance 525 between the two leaf springs 160a and 160b is approximately half the length of the short side of the substrate 110. The two leaf springs 160d and 160e are arranged at positions corresponding to the two leaf springs 160a and 160b.
Moreover, the LED module 100 differs in the shape of the board | substrate 110 compared with Embodiment 1. FIG. In the substrate 110, the position of the engaging convex portion 111b and the position of the engaging concave portion 112b are opposite to those of the substrate 110 described in the first embodiment. Therefore, the outer shape of the substrate 110 is 180 degrees rotationally symmetric.

  The leaf spring 160a and the leaf spring 160d are electrically connected to each other by being electrically connected to the printed wiring 113. The leaf spring 160b is electrically connected to the printed wiring 114, and the leaf spring 160e is electrically connected to the printed wiring 117. Accordingly, the leaf spring 160b is electrically connected to the anode electrode 121 of the LED 120a, and the leaf spring 160e is electrically connected to the cathode electrode 122 of the LED 120c.

FIG. 19 is a front view showing the structure of the connection module 107 of this embodiment.
The connection module 107 includes a substrate 110 and two leaf springs 160. The substrate 110 has a printed wiring 113. The shape of the substrate 110 is the same as that of the connection module 101 described in the first embodiment. The leaf spring 160 is the same as the leaf spring 160 of the LED module 100. The leaf spring 160 is provided on the short side on the left side of the substrate 110 in the drawing. The positions of the two leaf springs 160a and 160b are substantially the same as the positions of the two leaf springs 160a and 160b provided on the left side of the LED module 100 in the drawing.
The connection module 107 is disposed adjacent to the right side of the LED module 100 in the drawing, so that the leaf spring 160a contacts the leaf spring 160d of the LED module 100, and the leaf spring 160b contacts the leaf spring 160e of the LED module 100, respectively. And make electrical connections.
Further, the connection module 106 is rotated 180 degrees and arranged adjacent to the left side of the LED module 100 in the drawing, so that the leaf spring 160a is the leaf spring 160b of the LED module 100, and the leaf spring 160b is the leaf of the LED module 100. The springs 160a are in electrical contact with each other.
The two leaf springs 160 a and 160 b are electrically connected to each other by being electrically connected to the printed wiring 113.

FIG. 20 is a diagram illustrating a state in which the LED module 100 and the connection module 107 are arranged on the base 210 of this embodiment.
The base 210 includes, for example, a flat portion 211, six convex portions 212, and six convex portions 213. The convex portions 212 and 213 are alternately arranged. The six convex portions 212a to 212c and 213a to 213c are arranged alternately at equal intervals on the upper side of the plane portion 211 in the drawing. However, the convex portion 212c at the right end in the drawing is displaced from the other convex portions 212 and 213 by about half the length of the short side of the substrate 110 of the LED module 100 in the lower direction in the drawing. Yes. The six convex portions 212d to 212f and 213d to 213f are alternately arranged at equal intervals on the lower side of the plane portion 211 in the drawing. However, the convex portion 213f at the right end in the drawing is shifted in the direction of the upper side in the drawing of the flat portion 211 by about half the length of the short side of the substrate 110 of the LED module 100 from the other convex portions 212 and 213. Has been placed. The distance between the convex portion 212c and the convex portion 213f facing each other is approximately twice the length of the short side of the substrate 110 of the connection module 107 (LED module 100). Other distances between the convex portions 212 and the convex portions 213 facing each other are approximately three times the length of the short side of the substrate 110 of the LED module 100 (connection module 107).
On the base 210, for example, six LED modules 100 and five connection modules 107 are arranged side by side. In the leftmost column in the figure, three connection modules 107 are arranged in a direction rotated by 180 degrees with respect to the direction described in FIG. In the rightmost column in the figure, two connection modules 107 are arranged in the direction described with reference to FIG. Three LED modules 100 are arranged in two rows in between. The two LED modules 100 in the uppermost row in the figure are positioned with the engaging convex portion 111 engaged with the convex portion 212 of the base 210 and the engaging concave portion 112 engaged with the convex portion 213 of the base 210. The The two LED modules 100 in the lower row in the figure are positioned with the engaging convex portion 111 engaged with the convex portion 212 of the base 210 and the engaging concave portion 112 engaged with the convex portion 213 of the base 210. The In the other LED modules 100, the engaging convex portion 111 engages with the engaging concave portion 112 of the LED module 100 adjacent in the vertical direction in the figure, and the engaging concave portion 112 is adjacent in the vertical direction in the figure. It is positioned by engaging with 100 engaging projections 111.
Since the substrate 110 of the LED module 100 has a 180-degree rotationally symmetric outer shape, some of the six LED modules 100 are arranged in a direction rotated 180 degrees with respect to the direction described in FIG. .
Further, between the LED modules 100 and the connection modules 107 that are adjacent in the horizontal direction in the figure, the opposing leaf springs 160 are in contact with each other and are electrically connected.
The harness 220 is the same as that described in the eighth embodiment. The harness 220a is electrically connected to the leaf spring 160d (see FIG. 18) of the LED module 100 at the upper right end in the drawing, and the harness 220b is electrically connected to the leaf spring 160e (see FIG. 18) of the LED module 100 at the lower right end in the drawing. ing. The other end of the harness 220 is electrically connected to the lighting circuit.

  Thus, by connecting the six LED modules 100 and the five connection modules 106, a circuit in which 18 LEDs 120 are electrically connected in series is formed. Even if there is the LED module 100 arranged by rotating 180 degrees among the six LED modules 100, the 18 LEDs 120 are electrically connected in series in the correct orientation.

  As described above, even when the outer shape of the module having the polarity as in the LED module 100 is formed to be 180 degrees rotationally symmetric, the counterpart to which the leaf spring 160 is electrically connected changes when it is rotated 180 degrees. A circuit connected in series in the correct orientation is formed.

As described above, the configuration described in each embodiment is an example. For example, the configuration described in different embodiments may be combined, or the configuration of an unimportant part may be replaced with another configuration.
Moreover, you may use the LED module 100 demonstrated above not only for a lighting fixture but light-emitting parts (light-emitting devices), such as an image display apparatus and a guide light.

  100 LED module, 101 to 107 connection module, 110 substrate, 111 engaging convex part, 112 engaging concave part, 113 to 118 printed wiring, 120 LED, 121 anode electrode, 122 cathode electrode, 130, 140 connector, 131 fitting convex Part, 132, 133 female contact, 141 fitting recess, 142, 143 male contact, 144 fixed part, 145 shaft, 146 movable part, 150 detour element, 160 leaf spring, 210 base, 211 flat part, 212, 213 convex part, 220 harness.

Claims (7)

In a light emitting device comprising a plurality of light emitting diode modules,
The light emitting diode module is
A printed wiring board having a substantially rectangular plate shape, having an engagement convex portion on one of the long sides, and having a shape that can be engaged with the engagement convex portion on the opposite side of the long side with the engagement convex portion. A printed wiring board having an engaging recess;
A plurality of light emitting diodes mounted in line in the long side direction on the printed wiring board and electrically connected in series; and
A first connector that has an anode connection terminal electrically connected to an anode of a light emitting diode at one end of the plurality of light emitting diodes, and is located on a short side of one end of the printed wiring board;
A cathode connecting terminal electrically connected to the cathode of the light emitting diode at the other end of the plurality of light emitting diodes, and a second connector located on the opposite side of the short side where the anode connecting terminal is located,
Each of the plurality of light emitting diode modules has the same shape as each other and is detachably arranged in both the long side direction and the short side direction in the same direction.
Two light emitting diode modules arranged adjacent to each other in the long side direction are fitted with a first connector of one light emitting diode module and a second connector of the other light emitting diode module,
The light emitting device
A base on which a plurality of light emitting diode modules arranged in both the long side direction and the short side direction are placed;
The above base is
1st convex part which has a shape engaged with the said engagement convex part, Comprising: Engage with the said engagement convex part of the light emitting diode module arrange | positioned at the one end part of a short side direction among these light emitting diode modules A first protrusion that
A second convex portion having a shape that engages with the engaging concave portion, and engages with the engaging concave portion of the light emitting diode module disposed at the other end portion in the short side direction among the plurality of light emitting diode modules. The second protrusion and
Have
The first convex portion and the second convex portion are:
A light emitting device characterized by positioning the plurality of light emitting diode modules mounted on the base . The light emitting device
Comprising an upper Symbol printed wiring board, and a said second connector connected to the first connector of the light emitting diode modules disposed at one end of the longer side direction of the plurality of light emitting diode modules, one of the A third connection module used to connect the light emitting diode module arranged at the end to another light emitting diode module adjacent in the short side direction ;
The upper Symbol printed circuit board, a fourth connection Ru and a said first connector connected to said second connector of the light emitting diode modules disposed at the other end of the longer side direction of the plurality of light emitting diode modules Module and
The light emitting device according to claim 1 , wherein the third connection module and the fourth connection module are positioned on the base by the first protrusion and the second protrusion. When the first connector of the one light emitting diode module and the second connector of the other light emitting diode module are fitted, the anode connection terminal of the one light emitting diode module and the other light emitting diode module The cathode connection terminal of the
The two light emitting diode modules arranged adjacent to each other in the short side direction are characterized in that an engagement convex portion of one light emitting diode module is engaged with an engagement concave portion of the other light emitting diode module. Item 3. The light emitting device according to Item 1 or 2 . The light emitting diode module is
A plurality of the light emitting diodes arranged in a substantially straight line;
The plurality of light emitting diodes are arranged such that the distance between two adjacent light emitting diodes is adjacent to the light emitting diode located at the end of the plurality of light emitting diodes and the light emitting diode module in the long side direction. 4. The light emitting device according to claim 1 , wherein the light emitting device is disposed at a position equal to a distance between the light emitting diode located at the end of the other light emitting diode module. The light emitting diode module is
A plurality of the light emitting diodes arranged in a substantially straight line;
A plurality of the light emitting diodes are arranged such that an interval between two adjacent light emitting diodes is between the light emitting diode and a light emitting diode of another light emitting diode module disposed adjacent to the light emitting diode module in the short side direction. The light emitting device according to any one of claims 1 to 4, wherein the light emitting device is disposed at a position equal to an interval between them . The light emitting diode module is
Electrically connected in parallel to the light emitting diodes, light-emitting device according to claim 1, the voltage across and having a disconnection bypass circuit current flows exceeds a predetermined voltage 5. The light emitting diode module is
A plurality of the light emitting diodes electrically connected in series with each other;
The light emitting device according to claim 6 , further comprising: a plurality of disconnection bypass circuits electrically connected in parallel to the plurality of light emitting diodes.

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