JP5677138B2 - Lamp and lighting device - Google Patents

Description

  The present invention relates to a lamp and a lighting device. The present invention particularly relates to a straight tube lamp using an LED as a light source and an illumination device using the lamp.

  The spread of illuminating devices using LEDs with longer life and less power consumption than conventional fluorescent lamps as light sources is accelerating. However, if the LED is simply housed in a straight tube, measures against the heat generated from the LED are not taken, and the LED itself heats up so that the deterioration of the LED is accelerated and the life is shortened. was there.

  To solve this problem, by attaching a board on which LEDs are mounted to the heat radiating part in which the through holes are formed, heat generated from the LEDs is efficiently radiated to the outside through the through holes, in addition to the cold caused by alternating current with the outside air. An LED lighting device is known (see, for example, Patent Document 1).

  In addition, when an LED package (hereinafter referred to as “LED”) is simply mounted on a long substrate (hereinafter referred to as “LED module”) and only in a straight tube, the LED has strong directivity. When an illumination device using a straight tube LED lamp as a light source is installed on the ceiling, light is irradiated only on the floor surface side where the LED faces in the LED module, and the ceiling surface side where the LED does not face becomes dark. There was a problem.

  With respect to such a problem, an LED illumination device is known that combines a plurality of LED modules to increase the irradiation direction of light emitted from the LED, and uniformly irradiates light in all directions of the straight pipe (for example, (See Patent Document 1 and Patent Document 2).

JP 2009-170186 A JP 2010-129185 A

  However, in the techniques of Patent Document 1 and Patent Document 2, since a plurality of LED modules are combined, there is a problem that the number of assembling steps is increased, and it takes time for assembly.

  Moreover, since it was necessary to electrically connect LEDs mounted on a plurality of substrates, there was a problem that the electrical connection between the substrates was complicated.

  An object of the present invention is to provide an easily assembled lamp including a plurality of substrates on which light emitting elements are mounted, for example. Another object is to provide a lamp capable of simultaneously performing physical connection and electrical connection between substrates on which light-emitting elements are mounted in one operation.

A lamp according to one aspect of the present invention includes:
A plurality of longitudinal substrates on which light-emitting elements that emit light are mounted, each of which includes a plurality of substrates provided with cutouts extending in the longitudinal direction,
The notches are fitted to each other, and the plurality of substrates are combined so as to intersect when viewed from the longitudinal direction.

  According to one aspect of the present invention, the plurality of substrates on which the light emitting elements are mounted are provided with cutouts that are fitted to each other, so that the lamp can be easily assembled.

1 is a perspective view of a straight tube LED lamp according to Embodiment 1. FIG. 1 is an exploded perspective view of a straight tube LED lamp according to Embodiment 1. FIG. FIG. 2 is a cross-sectional view of the straight tube LED lamp according to Embodiment 1 taken along line AA. FIG. 3 is a perspective view of the lighting apparatus according to Embodiment 1. (A) Top view of LED module according to Embodiment 1, (b) Side view of LED module, (c) Top view of LED module, (d) Side view of LED module, (e) Side view of LED module unit Figure. (A) Top view of LED module, (b) Side view of LED module, (c) Top view of LED module, (d) Side view of LED module, (e) Side view of LED module unit according to Embodiment 2 Figure. (A) Top view of LED module concerning Embodiment 3, (b) Side view of LED module, (c) Top view of LED module, (d) Side view of LED module. (A) Top view of LED module concerning Embodiment 3, (b) Side view of LED module, (c) Side view of LED module unit. The perspective view of the straight tube | pipe type LED lamp which concerns on Embodiment 4. FIG. FIG. 6 is an exploded perspective view of a straight tube LED lamp according to a fourth embodiment. (A) Top view of LED module, (b) Side view of LED module, (c) Top view of LED module, (d) Side view of LED module, (e) Side view of LED module unit according to Embodiment 4 Figure. (A) Top view of LED module according to Embodiment 5, (b) Side view of LED module, (c) Top view of LED module, (d) Side view of LED module. FIG. 6 is a side view of an LED module unit according to Embodiment 5. (A) Top view of LED module according to Embodiment 6, (b) Side view of LED module, (c) Top view of LED module, (d) Side view of LED module. (A) Top view of LED module concerning Embodiment 6, (b) Side view of LED module, (c) Side view of LED module unit. FIG. 10 shows an assembly procedure of the LED module unit according to the sixth embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the description of each embodiment, directions such as “front”, “back”, “up”, “down”, “left”, and “right” are simply written as such for convenience of explanation. The arrangement and orientation of the devices, instruments, parts, etc. are not limited.

  In the description of each embodiment, an LED module refers to an LED package (in which an LED is mounted on a substrate as a chip component, hereinafter simply referred to as “LED”) mounted on a single substrate. Say. An LED module unit refers to a unit in which two or more LED modules are combined and connected.

Embodiment 1 FIG.
FIG. 1 is a perspective view of a straight tube LED lamp 100 according to the present embodiment. FIG. 2 is an exploded perspective view of the straight tube LED lamp 100 shown in FIG. FIG. 3 is a cross-sectional view of the straight tube LED lamp 100 shown in FIG.

  The straight tube LED lamp 100 includes a tube-shaped cylindrical cover part 200, a base 300 attached to both ends of the cylindrical cover part 200, and an LED module unit 400 housed inside the cylindrical cover part 200. Prepare.

  The cylindrical cover unit 200 includes a cover upper part 210 and a cover lower part 240 made of translucent resin or glass and sandwiches a metal heat sink 220 and a heat sink 230 that radiate heat from the LED module unit 400. It has a configuration. The cover upper part 210 and the cover lower part 240, the heat sink 220, and the heat sink 230 are the same parts. The heat sink 220 and the heat sink 230 are configured by heat radiating fins or heat insulating materials. A through hole may be formed in the center of the heat sink 220 and the heat sink 230 in order to improve heat dissipation by air convection. The heat sink 220 and the heat sink 230 have a structure in which the cover upper part 210, the LED module unit 400, and the cover lower part 240 are sandwiched and fixed. In the present embodiment, the cover upper part 210 and the cover lower part 240 are examples of a light-transmitting cover, and the material, shape, etc. thereof can be appropriately selected (changed) according to the application of the straight tube LED lamp 100 and the like. It is. It is not essential that the cover upper part 210 and the cover lower part 240 are the same part. Further, in the present embodiment, the heat sink 220 and the heat sink 230 are examples of heat radiating members, and the material, shape, and the like thereof can be appropriately selected (changed) according to the application of the straight tube LED lamp 100 and the like. It is not essential that the heat sink 220 and the heat sink 230 are the same component.

  The base 300 includes a base attaching part 310 attached to the cylindrical cover part 200 and a pair of base pins 320 protruding outward from the base attaching part 310. In the present embodiment, the number and shape of the base pins 320 can be appropriately selected (changed) according to the type of the socket to which the base 300 is attached. For example, in the straight tube LED lamp 100, a base 300 from which a pair of base pins 320 (electrode terminals) for power feeding protrudes is disposed at one end in the longitudinal direction, and the grounding is disposed at the other end in the longitudinal direction. The base 300 from which the single base pin 320 (ground terminal) protrudes may be disposed.

  The LED module unit 400 has a configuration in which a long LED module 410 in which the LEDs 412 are mounted on both sides and a long LED module 420 in which the LEDs 422 are mounted on both surfaces are combined so as to intersect when viewed from the longitudinal direction. It has become. The LEDs 412 and 422 emit white light, for example. Note that in this embodiment, the LEDs 412 and 422 are examples of light emitting elements, and may be replaced with EL or other light emitting elements.

  As shown in FIG. 3, when the LED module 410 and the LED module 420 intersect, four V-shaped grooves are formed between the LED module 410 and the LED module 420 as viewed from the longitudinal direction. The LEDs 412 and 422 are mounted on the LED modules 410 and 420 so as to be positioned only in two V-shaped grooves facing each other (upper and lower V-shaped grooves in FIG. 3) among these four V-shaped grooves. The That is, if the LED 412 is mounted on the lower surface side of the left half and the upper surface side of the right half when viewed from the longitudinal direction of the LED module 410, the LED 422 is mounted on the upper surface side and the right side of the left half when viewed from the same longitudinal direction of the LED module 420. It will be mounted on the lower side of the half. By adopting such a configuration, according to the present embodiment, light is emitted not only in one direction (for example, the floor direction) but also in the other direction (for example, the ceiling direction) from the straight tube LED lamp 100. be able to.

  Of the four V-shaped grooves, two V-shaped grooves (upper and lower V-shaped grooves in FIG. 3) having the LEDs 412 and 422 are covered with an upper cover portion 210 and a lower cover portion 240. For this reason, the light emitted from the LEDs 412 and 422 can be diffused, and the uniformity of the irradiation light from the straight tube LED lamp 100 is improved. Of the four V-shaped grooves, the other two V-shaped grooves facing each other, that is, two V-shaped grooves without LEDs 412 and 422 (left and right V-shaped grooves in FIG. 3) are provided. A heat sink 220 and a heat sink 230 are provided. For this reason, the heat generated from the LED modules 410 and 420 can be efficiently radiated to the outside of the straight tube LED lamp 100.

  FIG. 4 is a perspective view of a lighting fixture 900 according to the present embodiment.

  The lighting fixture 900 includes a fixture body 910 installed on the ceiling and two pairs of sockets 920 attached to the fixture body 910. The appliance main body 910 includes a terminal block connected to a commercial power source, a lighting device connected to the terminal block, and the like. The socket 920 is connected to a lighting device built in the appliance body 910.

  By attaching the two straight tube LED lamps 100 to the lighting fixture 900, one lighting device is configured. At this time, the cap pin 320 on the cap 300 of the straight tube LED lamp 100 is inserted into a hole provided in the socket 920 of the lighting fixture 900, and the lighting device built in the fixture main body 910 of the lighting fixture 900 is electrically connected. Connected. Thereby, power is supplied from the commercial power source to the LED module unit 400 of the straight tube LED lamp 100 through the terminal block of the lighting fixture 900, the lighting device, the socket 920, and the cap pin 320 of the straight tube LED lamp 100. The LEDs 412 and 422 mounted on the LED modules 410 and 420 of the LED module unit 400 are turned on. In the present embodiment, the number of straight tube LED lamps 100 attached to the lighting fixture 900 is not limited to two, and the lighting fixture 900 is configured so that only one straight tube LED lamp 100 is attached. Alternatively, three or more straight tube LED lamps 100 may be attached.

  FIG. 5A is a top view of the LED module 410. FIG. 5B is a side view of the LED module 410 as viewed from the direction of the arrow in FIG. FIG. 5C is a top view of the LED module 420. FIG.5 (d) is a side view of the LED module 420 seen from the arrow direction of FIG.5 (c). FIG. 5E is a side view of the LED module unit 400.

  As shown in FIGS. 5A and 5B, the LED module 410 has a mounting substrate 411 (first plate) in which a notch 415 is provided in the approximate center on the short side of the substrate from the end of the substrate to the approximate center in the longitudinal direction of the substrate. 1 board), LEDs 412 mounted on the mounting board 411, male connectors 413a and 413b, and connectors 414a and 414b to which harnesses for supplying power from the base pins 320 to the LED module unit 400 are connected.

  The LEDs 412 are mounted on the upper and lower surfaces of the mounting substrate 411 in a symmetrical arrangement with the axis along the notch 415 as the center. Twelve LEDs 412 are mounted on the top surface of the mounting substrate 411 and twelve LEDs 412 are mounted on the bottom surface of the mounting substrate 411. The LEDs 412 are arranged substantially linearly in a line along the longitudinal direction of the substrate. The connectors 413a and 413b are respectively arranged on the upper surface and the lower surface of the mounting substrate 411 so as to be adjacent to the tip of the notch 415 at the substantially central portion in the substrate longitudinal direction. The connectors 414a and 414b are disposed on the substrate end (or in the vicinity thereof) on the upper surface and the lower surface of the mounting substrate 411, respectively. On the upper surface of the mounting substrate 411, each component is electrically connected by a wiring pattern from the connector 414a through the LED 412 to the connector 413a. On the lower surface of the mounting substrate 411, each component is electrically connected by a wiring pattern from the connector 414b through the LED 412 to the connector 413b. In the present embodiment, the number and arrangement of the LEDs 412 can be appropriately selected (changed) according to the application of the straight tube LED lamp 100 and the like. Further, in the present embodiment, the connectors 414a and 414b are not essential, and instead, for example, a harness from the base pin 320 may be soldered directly to a land provided on the mounting board 411.

  As shown in FIGS. 5C and 5D, the LED module 420 has a mounting substrate 421 (first substrate) in which a notch 425 is provided in the approximate center on the short side of the substrate from the end of the substrate to the approximate center in the longitudinal direction of the substrate. 2 substrates), LEDs 422 mounted on the mounting substrate 421, and female connectors 423a and 423b.

  The LEDs 422 are mounted on the upper and lower surfaces of the mounting substrate 421 in a symmetrical arrangement with the axis along the notch 425 as the center. Twelve LEDs 422 are mounted on the upper surface of the mounting substrate 411 and twelve LEDs 422 are mounted on the lower surface of the mounting substrate 411, and are arranged in a straight line and in a row along the longitudinal direction of the substrate. The connectors 423a and 423b are respectively arranged on the upper surface and the lower surface of the mounting substrate 421 so as to be adjacent to the front end of the notch 425 at the substantially central portion in the substrate longitudinal direction. On the upper and lower surfaces of the mounting substrate 421, each component is electrically connected by a wiring pattern from the connector 423a through the LED 412 to the connector 423b. In the present embodiment, the number and arrangement of the LEDs 422 can be appropriately selected (changed) in accordance with the application of the straight tube LED lamp 100 or the like.

  The LED module 410 and the LED module 420 use the same substrate only in the components to be mounted (male / female connector, presence / absence of wiring to the cap pin 320). That is, the mounting substrate 411 and the mounting substrate 421 have the same shape. For this reason, the cost concerning components can be reduced. In this embodiment, it is arbitrarily determined which LED module connector is a male type, which LED module connector is a female type, and which LED module is connected to the base pin 320. It's okay. For example, the connectors 413a and 413b of the LED module 410 may be female, and the connectors 423a and 423b of the LED module 420 may be male. For example, instead of the connectors 414 a and 414 b of the LED module 410, a similar connector may be provided in the LED module 420.

  As shown in FIG. 5 (e), the LED module unit 400 has an LED module 410 and an LED module 420 that are substantially cross-shaped so that the notches 415 and 425 of the respective mounting boards 411 and 421 are fitted to each other. It is assembled by crossing and pushing. That is, in the LED module unit 400, the notch 415 extending in the longitudinal direction of the mounting substrate 411 and the notch 425 extending in the longitudinal direction of the mounting substrate 421 are fitted, and the mounting substrate 411 and the mounting substrate 421 are viewed from the longitudinal direction. It is combined in an X shape. By taking such a configuration, according to the present embodiment, assembly of straight tube LED lamp 100 is facilitated.

  Further, in the LED module unit 400, the connectors 413a and 413b of the mounting board 411 and the connectors 423a and 423b of the mounting board 421 are connected to each other so that the LED module 410 and the LED module 420 are not detached. . That is, in the LED module unit 400, the connectors 413a and 413b of the mounting board 411 and the connectors 423a and 423b of the mounting board 421 are fitted to each other with the notches 415 and 425 of the mounting boards 411 and 421 fitted to each other. Thus, the mounting boards 411 and 421 are electrically and physically connected. By adopting such a configuration, according to the present embodiment, physical connection and electrical connection between the mounting boards 411 and 421 can be simultaneously performed in one operation. Further, it is not necessary to fix the mounting boards 411 and 421 with an adhesive or a screw.

  The power supply from the base pin 320 of the base 300 to each component of the LED module unit 400 is performed by, for example, the connector 414a, the LED 412, the connector 413a on the upper surface of the LED module 410, the connector 423a, the LED 422, the connector 423b, and the LED module 410 on the LED module 420. This is performed through the path of the lower connector 413b, the LED 412, and the connector 414b. Thus, in this embodiment, since only one LED module 410 needs to be electrically connected to the base 300, assembly of the straight tube LED lamp 100 is further facilitated.

  When the connectors 413a and 413b and the connectors 423a and 423b are connected to each other, the angle at which the LED modules 410 and 420 intersect each other is adjusted within a range of about 30 to 90 degrees as indicated by an arrow in FIG. Even so, it is desirable that the part has a structure that does not receive stress. In this case, there is an advantage that the range of the light emitted from the LEDs 412 and 422 can be changed for each product of the straight tube LED lamp 100.

  In the present embodiment, the mounting substrates 411 and 421 have notches 415 and 425 having slits extending from a substantially central portion in the longitudinal direction of the substrate to one end portion in the longitudinal direction of the substrate at a substantially central portion in the lateral direction of the substrate. Although provided, the arrangement and shape of the slits can be appropriately selected (changed) in accordance with the use of the straight tube LED lamp 100 or the like. For example, a slit is provided from one end in the lateral direction of the substrate, and among the four V-shaped grooves described above, the lower V-shaped groove is made larger than the upper V-shaped groove, and the lower V-shaped groove is formed. If the number of mounted LEDs 412 and 422 in the groove is larger than that of the upper V-shaped groove, it is possible to provide a straight tube LED lamp 100 that illuminates the lower direction more brightly than the upper direction.

  As described above, in the present embodiment, the straight tube LED lamp 100 having the bases 300 provided at both ends of the straight tube includes two long mounting boards 411 and 421 having the notches 415 and 425. The LED module unit 400 (LED light source unit) formed in combination and a plurality of LEDs 412 and 422 arranged in the LED module unit 400 are provided. In the LED module unit 400, when the mounting boards 411 and 421 are combined using the notches 415 and 425, the mounting boards 411 and 421 are physically and electrically connected to each other. Specifically, the LED module unit 400 completes the operation of pushing together the notches 415 and 425, and at the same time, the connectors 413a and 413b and the connectors 423a and 423b provided on the two mounting boards 411 and 421, respectively. (Connecting portions) are connected, and the mounting boards 411 and 421 are physically and electrically connected to each other.

  With this configuration, the LED module 410 and the LED module 420 are connected by the notches 415 and 425 of the mounting boards 411 and 421 and the connectors 413a, 413b, 423a, and 423b, so that the assembly is facilitated. effective. That is, the straight tube LED lamp 100 can be assembled with a small number of man-hours.

  In addition, according to the present embodiment, there is an effect that heat generation of the LED module unit 400 can be suppressed by radiating heat with the heat sink 220 and the heat sink 230. That is, in the straight tube LED lamp 100, the heat dissipation is improved. In addition, when the straight tube LED lamp 100 is installed on the ceiling, it is possible to illuminate not only the floor surface direction but also the ceiling direction. That is, in the straight tube LED lamp 100, sufficient illuminance on the floor surface and ceiling surface can be secured. Note that the light to the ceiling does not need to be as strong as the light to the floor surface, and therefore the straight tube to the lighting fixture 900 that can specify the direction in which the straight tube LED lamp 100 is installed on the ceiling surface side and the floor surface side. If the LED lamp 100 is attached, the number of LEDs 412 and 422 arranged on the ceiling surface side may be thinned out (by making the number of LEDs on one side thinned to make a lamp with different illuminance on the upper and lower surfaces of the lamp) Can increase product variations).

  Further, according to the present embodiment, the cover upper portion 210 of the cylindrical cover portion 200, the LED module unit 400 configured by intersecting the LED module 410 and the LED module 420, and the cover lower portion 240 are combined with the heat sink 220. In addition, since the protrusions of the heat sink 230 are sandwiched and fixed, attachment parts such as screws can be reduced, and the assemblability is improved. The cylindrical cover part 200 is completely fixed by attaching a base 300 to both ends and sealing it. However, even when the base 300 is not attached, the straight tube part (the LED module unit 400 and the cylindrical cover part). 200) is temporarily fixed (positioned), so that workability is improved.

  Note that the LED module unit 400 having the same configuration as that of the present embodiment may be used for a lamp other than the straight tube LED lamp 100 (for example, a bulb-type LED lamp).

Embodiment 2. FIG.
In the present embodiment, differences from the first embodiment will be mainly described.

  FIG. 6A is a top view of the LED module 410. FIG. 6B is a side view of the LED module 410 as seen from the direction of the arrow in FIG. FIG. 6C is a top view of the LED module 420. FIG.6 (d) is a side view of the LED module 420 seen from the arrow direction of FIG.6 (c). FIG. 6E is a side view of the LED module unit 400.

  As shown in FIGS. 6A and 6B, the LED module 410 is electrically connected to the mounting substrate 411, the LED 412, and the connectors 413a, 413b, 414a, and 414b shown in FIGS. 5A and 5B. Have dummy connectors 413c to 413f that are not physically connected but are only physically connected.

  The connectors 413c and 413d are arranged at the same position in the short direction as the connectors 413b and 413a on the upper surface and the lower surface of the mounting substrate 411, respectively, on the substrate end (or the vicinity thereof) where the notch 415 is present. The connectors 413e and 413f are respectively disposed at the same position in the short direction as the connectors 413b and 413a on the upper and lower surfaces of the mounting substrate 411 on the substrate end (or the vicinity thereof) where the notch 415 is not provided.

  As shown in FIGS. 6C and 6D, the LED module 420 is electrically connected in addition to the mounting substrate 421, the LED 422, and the connectors 423a and 423b shown in FIGS. 5C and 5D. In addition, dummy connectors 423c to 423f that are only physically connected are provided.

  The connectors 423f and 423e are disposed at the same position in the short direction as the connectors 423b and 423a on the upper and lower surfaces of the mounting substrate 421, respectively, on the substrate end (or the vicinity thereof) where the notch 425 is present. The connectors 423d and 423c are arranged at the same position in the short direction as the connectors 423b and 423a on the upper and lower surfaces of the mounting substrate 421 on the substrate end (or the vicinity thereof) where the notch 425 is not provided.

  Although not shown, in the present embodiment, the heat sink 220 and the heat sink 230 are shaped so as not to contact the connectors 413c to 413f and the connectors 423c to 423f. Further, as described above, in this embodiment, the connectors 413c to 413f and the connectors 423c to 423f are arranged at positions that do not interfere with each other when the mounting boards 411 and 421 are combined in a substantially cross shape. In the present embodiment, the number and arrangement of dummy connectors 413c to 413f, 423c to 423f can be appropriately selected (changed) in accordance with the application of the straight tube LED lamp 100.

  As shown in FIG. 6E, in the LED module unit 400, not only the connectors 413a and 413b of the mounting board 411 and the connectors 423a and 423b of the mounting board 421 are connected, but also the connectors 413c to 413f of the mounting board 411. And the connectors 423c to 423f of the mounting board 421 are connected to each other (in the drawing, the connectors 413c and 413d and the connectors 423c and 423d are behind the connectors 413e and 413f and the connectors 423e and 423f, and therefore are not shown in the figure). LED module 410 and LED module 420 are more firmly fixed than in the first embodiment. That is, in the LED module unit 400, the connectors 413c to 413f of the mounting board 411 and the connectors 423c to 423f of the mounting board 421 are fitted to each other with the notches 415 and 425 of the mounting boards 411 and 421 fitted to each other. By doing so, the mounting boards 411 and 421 are physically connected. By adopting such a configuration, according to the present embodiment, the force for fixing the mounting boards 411 and 421 to each other can be increased, and the connectors 413a and 413b and the connectors 423a and 423b can be prevented from being loosened and damaged.

Embodiment 3 FIG.
In the present embodiment, differences from the first embodiment will be mainly described.

  FIG. 7A is a top view of the LED module 430. FIG.7 (b) is a side view of the LED module 430 seen from the arrow direction of Fig.7 (a). FIG. 7C is a top view of the LED module 440. FIG.7 (d) is a side view of the LED module 440 seen from the arrow direction of FIG.7 (c). FIG. 8A is a top view of the LED module 450. FIG. 8B is a side view of the LED module 450 as viewed from the direction of the arrow in FIG. FIG. 8C is a side view of the LED module unit 400.

  In the present embodiment, the LED module unit 400 includes a longitudinal LED module 430 in which the LED 432 is mounted on one side, a longitudinal LED module 440 in which the LED 442 is mounted on both sides, and a longitudinal direction in which the LED 452 is mounted on one side. The LED module 450 is combined so as to intersect with each other when viewed from the longitudinal direction. The LEDs 432, 442, and 452 are the same as the LEDs 412 and 422 of the first embodiment.

  As shown in FIGS. 7A and 7B, the LED module 430 is a mounting board in which notches 435 are provided at three locations on one end portion in the short-side direction of the substrate to form two protrusions 436 on the one end portion. 431 (first substrate), LEDs 432 mounted on the mounting substrate 431, and male connectors 433a and 433b.

  Twelve LEDs 432 are mounted on the upper surface of the mounting substrate 431, and are arranged in a straight line and in a line along the longitudinal direction of the substrate. The connectors 433a and 433b correspond to the protrusions 436 on a one-to-one basis, and are disposed on the corresponding protrusions 436 on the upper surface of the mounting substrate 431, respectively. On the upper surface of the mounting substrate 431, each component is electrically connected by a wiring pattern from the connector 433a via the LED 432 to the connector 433b. In the present embodiment, the number and arrangement of the LEDs 432 can be appropriately selected (changed) in accordance with the application of the straight tube LED lamp 100 or the like.

  As shown in FIGS. 7C and 7D, the LED module 440 has four cutouts 445 at substantially equal intervals from one substrate end to the other substrate end in the approximate center on the short side of the substrate. From a mounting board 441 (third board), LEDs 442 mounted on the mounting board 441, female connectors 443a to 443d, and connectors 444a and 444b to which harnesses for supplying power from the base pins 320 to the LED module unit 400 are connected. It is configured.

  The LEDs 442 are mounted on the upper and lower surfaces of the mounting substrate 441 in a symmetrical arrangement with the axis along the notch 445 as the center. Twelve LEDs 442 are mounted on the upper surface of the mounting substrate 441 and twelve on the lower surface of the mounting substrate 441, and are arranged substantially in a straight line and in a row along the longitudinal direction of the substrate. The connectors 443a to 443d correspond to the notches 445 on a one-to-one basis, the connectors 443a and 443b correspond to the lower surface of the mounting substrate 441, and the connectors 443c and 443d correspond to the upper surface of the mounting substrate 441, respectively. It arrange | positions so that a substantially intermediate part may be adjoined. The connectors 444a and 444b are disposed on the substrate end (or in the vicinity thereof) on the upper surface and the lower surface of the mounting substrate 441, respectively. On the upper and lower surfaces of the mounting substrate 441, each component is electrically connected by a wiring pattern from the connector 444a to the connector 443c via the LED 442. Further, the connector 443b and the connector 443d are electrically connected by a wiring pattern. Each component is electrically connected by a wiring pattern from the connector 443a to the connector 444b via the LED 442. In the present embodiment, the number and arrangement of the LEDs 442 can be appropriately selected (changed) according to the application of the straight tube LED lamp 100 and the like. Further, in the present embodiment, the connectors 444a and 444b are not essential, and instead, for example, a harness from the base pin 320 may be soldered directly to a land provided on the mounting board 441.

  As shown in FIGS. 8A and 8B, the LED module 450 has a notch 455 provided at three locations on one end in the short side direction of the substrate, and two projections 456 are formed at the one end. 451 (second substrate), LEDs 452 mounted on the mounting substrate 451, and male connectors 453c and 453d.

  Twelve LEDs 452 are mounted on the upper surface of the mounting substrate 451, and are arranged in a straight line and in a row along the longitudinal direction of the substrate. The connectors 453 c and 453 d correspond to the protrusions 456 on a one-to-one basis, and are disposed on the corresponding protrusions 456 on the upper surface of the mounting substrate 451. On the upper surface of the mounting substrate 451, each component is electrically connected by a wiring pattern from the connector 453c to the connector 453d via the LED 452. In the present embodiment, the number and arrangement of the LEDs 452 can be appropriately selected (changed) according to the application of the straight tube LED lamp 100 and the like.

  The LED module 430 and the LED module 450 use the same substrate only in the arrangement of components (LED, connector) to be mounted. That is, the mounting substrate 431 and the mounting substrate 451 have the same shape. For this reason, the cost concerning components can be reduced. In this embodiment, it is arbitrarily determined which LED module connector is a male type, which LED module connector is a female type, and which LED module is connected to the base pin 320. It's okay. For example, the connectors 433a and 433b of the LED module 430 and the connectors 453c and 453d of the LED module 450 may be female, and the connectors 443a to 443d of the LED module 440 may be male. For example, instead of the connectors 444a and 444b of the LED module 440, similar connectors may be provided in the LED module 430 or the LED module 450.

  As shown in FIG. 8C, in the LED module unit 400, the LED module 430, the LED module 440, and the LED module 450 are fitted with the notches 435, 445, and 455 of the respective mounting boards 431, 441, and 451. As you can see, they are assembled by pushing them in a cross shape. That is, in the LED module unit 400, the two protrusions 436 of the mounting board 431 are fitted into two of the notches 445 of the mounting board 441, and the two protrusions 456 of the mounting board 451 are the two protrusions of the mounting board 431. The mounting board 431, the mounting board 441, and the mounting board 451 are combined in an X shape when viewed from the longitudinal direction by fitting into the remaining two of the cutouts 445 of the mounting board 441 from the opposite side of 436. By taking such a configuration, according to the present embodiment, assembly of straight tube LED lamp 100 is facilitated.

  In the LED module unit 400, the connectors 433a and 433b of the mounting board 431 and the connectors 443a and 443b of the mounting board 441 are connected to each other so that the LED module 430 and the LED module 440 are not detached. . That is, in the LED module unit 400, the connectors 433a and 433b of the mounting board 431 and the connectors 443a and 443b of the mounting board 441 are fitted to each other with the notches 435 and 445 of the mounting boards 431 and 441 fitted to each other. Thus, the mounting boards 431 and 441 are electrically and physically connected. By adopting such a configuration, according to the present embodiment, physical connection and electrical connection between the mounting boards 431 and 441 can be simultaneously performed by one operation. Further, it is not necessary to fix the mounting boards 431 and 441 to each other with an adhesive or a screw.

  Similarly, in the LED module unit 400, the connectors 443c and 443d of the mounting board 441 and the connectors 453c and 453d of the mounting board 451 are connected to each other so that the LED module 440 and the LED module 450 are fixed so as not to be disconnected. Yes. That is, in the LED module unit 400, the connectors 443c and 443d of the mounting board 441 and the connectors 453c and 453d of the mounting board 451 are fitted to each other with the notches 445 and 455 of the mounting boards 441 and 451 fitted together. Thus, the mounting boards 441 and 451 are electrically and physically connected. With this configuration, according to the present embodiment, it is possible to simultaneously perform physical connection and electrical connection between the mounting boards 441 and 451 in one operation. Further, it is not necessary to fix the mounting boards 441 and 451 to each other with an adhesive or a screw.

  The power supply from the base pin 320 of the base 300 to each component of the LED module unit 400 includes, for example, a connector 444a on the lower surface of the LED module 440, an LED 442, a connector 443c on the upper surface of the LED module 440, a connector 453c on the LED module 450, an LED 452, and a connector. 443d, LED module 440 upper surface connector 443d, LED module 440 lower surface connector 443b, LED module 430 connector 433b, LED 432, connector 433a, LED module 440 lower surface connector 443a, LED module 440 upper surface LED 442, connector This is performed along the route 444b. Thus, in this embodiment, since only one LED module 440 needs to be electrically connected to the base 300, assembly of the straight tube LED lamp 100 is further facilitated.

  In the present embodiment, the mounting substrate 441 is provided with four grooves at substantially equal intervals in the short side direction of the substrate as the notches 445. However, the number, arrangement, and shape of the grooves are not limited. Can be appropriately selected (changed) in accordance with the application of the straight tube LED lamp 100 or the like. The number, arrangement, shape, and the like of the protrusions 436, 456 of the mounting substrates 431, 451 can be appropriately selected (changed) in accordance with the number, arrangement, shape, etc. of the grooves of the mounting substrate 441. For example, the mounting board 441 is provided with seven grooves (notches 445), the mounting board 431 has four protrusions 436 (five notches 435), and the mounting board 451 has three protrusions 456 (notches). 4) 435) may be provided.

  According to the present embodiment, the number of connectors to be physically connected can be increased as compared with the first embodiment, so that the substrates can be more firmly fixed. In the present embodiment, the number and arrangement of the connectors 443a to 443d of the mounting board 441 can be appropriately selected (changed) in accordance with the use of the straight tube LED lamp 100. For example, the number of connectors corresponding to each of the cutouts 445 of the mounting substrate 441 may be increased or decreased.

Embodiment 4 FIG.
In the present embodiment, differences from the first embodiment will be mainly described.

  FIG. 9 is a perspective view of a straight tube LED lamp 100 according to the present embodiment. FIG. 10 is an exploded perspective view of the straight tube LED lamp 100 shown in FIG.

  As in the first embodiment, straight tube LED lamp 100 is housed inside tube-shaped cylindrical cover portion 200, base 300 attached to both ends of cylindrical cover portion 200, and cylindrical cover portion 200. LED module unit 500 to be provided.

  The cylindrical cover part 200 is a cylindrical cover made of translucent resin or glass. In the present embodiment, the cylindrical cover portion 200 is an example of a translucent cover, and the material, shape, and the like thereof can be appropriately selected (changed) according to the application of the straight tube LED lamp 100 and the like. .

  The base 300 includes a base attaching part 310 attached to the cylindrical cover part 200 and a pair of base pins 320 protruding outward from the base attaching part 310. The base pin 320 is the same as the base pin 320 of the first embodiment.

  In the LED module unit 500, one longitudinal LED module 510 on which the LEDs 512 are mounted and three longitudinal LED modules 520 on which the LEDs 522 are mounted are combined so as to intersect when viewed from the longitudinal direction. It has a configuration. The LEDs 512 and 522 are the same as the LEDs 412 and 422 of the first embodiment.

  The LEDs 512 and 522 are mounted on the surface exposed to the outside of the LED modules 510 and 520. The LED module unit 500 is covered with a cylindrical cover part 200. For this reason, the light emitted from the LEDs 512 and 522 can be diffused, and the uniformity of the irradiation light from the straight tube LED lamp 100 is improved.

  A rectangular space (cavity) surrounded by the LED modules 510 and 520 is formed between the LED modules 510 and 520. A rectangular heat radiating member 250 is disposed in this space. The heat dissipation member 250 dissipates heat generated from the LEDs 512, 522 and the like mounted on the LED modules 510, 520. A through hole 251 is provided at the center of the heat radiating member 250 to enhance heat dissipation by air convection. In the present embodiment, the material, shape, and the like of the heat radiating member 250 can be appropriately selected (changed) in accordance with the application of the straight tube LED lamp 100 and the like.

  FIG. 11A is a top view of the LED module 510. FIG.11 (b) is a side view of the LED module 510 seen from the arrow direction of Fig.11 (a). FIG. 11C is a top view of the LED module 520. FIG.11 (d) is a side view of the LED module 520 seen from the arrow direction of FIG.11 (c). FIG. 11E is a side view of the LED module unit 500.

  The LED module unit 500 has a structure in which four LED modules 510 and 520 each formed of a bowl-shaped substrate are combined to form a substantially rectangular cross section as a whole. As shown in FIG. 11E, at each of the four corners of the rectangular parallelepiped, each board protrudes from the surface forming the quadrangle, and the connectors provided on the respective boards on the board protruding from the cross section of the quadrangle. Is connected.

  As shown in FIGS. 11A and 11B, the LED module 510 includes a mounting board 511, an LED 512 mounted on the mounting board 511, a male connector 513 a, a female connector 513 b, and a base pin 320. It consists of connectors 514a and 514b to which harnesses for supplying power to the module unit 500 are connected.

  At both ends of the mounting substrate 511 in the short-side direction of the substrate (upper right and lower left in FIG. 11A), the mounting substrate has a width equal to or greater than the lateral width of the connectors 513a and 513b from the substrate end to the substantially central portion in the substrate longitudinal direction. A cutout 515 having a width equal to or greater than 511 is included. Twelve LEDs 512 are mounted on the upper surface of the mounting substrate 511, and are arranged substantially in a straight line and in a line along the longitudinal direction of the substrate. The connectors 513a and 513b are arranged on the upper surface of the mounting substrate 511 so as to be adjacent to the tip of the notch 515 at the substantially central portion in the substrate longitudinal direction. The connectors 514a and 514b are disposed on the substrate end (or in the vicinity thereof) on the upper surface of the mounting substrate 511. On the upper surface of the mounting substrate 511, each component is electrically connected by a wiring pattern from the connector 514a through the LED 512 to the connector 513a. Further, the connector 513b and the connector 514b are electrically connected by a wiring pattern. In the present embodiment, the number and arrangement of the LEDs 512 can be appropriately selected (changed) in accordance with the application of the straight tube LED lamp 100 or the like. In the present embodiment, the connectors 514a and 514b may be combined into one connector having two electrodes, + and −. The connectors 514a and 514b are not essential, and instead, for example, a harness from the cap pin 320 may be soldered directly to a land provided on the mounting board 511.

  When the power supplied from the base pin 320 is once input to a substrate having a diode bridge, a current detection resistor, etc. and then supplied to the LED module unit 500 via the substrate, a harness extending from the substrate is connected to the LED. Connect to the connectors 514a and 514b of the module unit 500.

  As shown in FIGS. 11C and 11D, the LED module 520 includes a mounting board 521, an LED 522 mounted on the mounting board 521, a female connector 523a, and a male connector 523b.

  At both ends of the mounting substrate 521 in the short side direction (upper right and lower left in FIG. 11C), the width of the connectors 523a and 523b is equal to or greater than the width of the connectors 523a and 523b from the end of the substrate to the substantially central portion in the substrate longitudinal direction A notch 525 having a width of 521 or more is included. Twelve LEDs 522 are mounted on the upper surface of the mounting substrate 521, and are arranged in a straight line and in a line along the longitudinal direction of the substrate. The connectors 523a and 523b are arranged on the upper surface of the mounting substrate 521 so as to be adjacent to the front end of the notch 525 at the substantially central portion in the substrate longitudinal direction. On the upper surface of the mounting substrate 521, each component is electrically connected by a wiring pattern from the connector 523a to the connector 523b via the LED 522. In the present embodiment, the number and arrangement of the LEDs 522 can be appropriately selected (changed) according to the application of the straight tube LED lamp 100 and the like.

  The LED module 510 and the LED module 520 use the same board only with different components to be mounted (whether or not there is wiring to the cap pin 320). That is, the mounting substrate 511 and the mounting substrate 521 have the same shape. In the present embodiment, three LED modules 520, that is, three identical modules are used in one LED module unit 500. For this reason, the cost concerning components can be reduced.

  As shown in FIG. 11E, in the LED module unit 500, notches 515 and 525 are provided at both ends in the short direction of the four mounting boards 511 and 512, and the mounting boards 511 and 512 of these mounting boards 511 and 512 are provided. Notches 515 and 525 of adjacent mounting boards 511 and 512 are fitted to each other, and four mounting boards 511 and 512 are combined in a lattice pattern. By taking such a configuration, according to the present embodiment, assembly of straight tube LED lamp 100 is facilitated.

  In the LED module unit 500, the connector 513a (or the connector 513b) of the mounting board 511 and the connector 523a (or the mounting board 521) (or the mounting board 521) with the notches 515 and 525 of the mounting boards 511 and 521 adjacent to each other fitted. The mounting boards 511 and 521 are electrically and physically connected to each other by being fitted to the connector 523b). Further, in a state where the notches 525 of the mounting boards 521 adjacent to each other are fitted, the connector 523a (or the connector 523b) of one mounting board 521 and the connector 523b (or the connector 523a) of the other mounting board 521 are mutually connected. The two mounting substrates 521 are electrically and physically connected by fitting. By adopting such a configuration, according to the present embodiment, physical connection and electrical connection between the mounting boards 511 and 521 can be simultaneously performed in one operation. Further, it is not necessary to fix the mounting substrates 511 and 521 with an adhesive, screws, or the like.

  The power supply from the base pin 320 of the base 300 to each component of the LED module unit 500 is performed by, for example, the connector 514a, the LED 512, the connector 513a of the LED module 510, the connector 523a of the LED module 520, the LED 522, the connector 523b, or the other LED module 520. This is performed in the route of the connector 523a, the LED 522, the connector 523b, the connector 523a of another LED module 520, the LED 522, the connector 523b, the connector 513b of the LED module 510, and the connector 514b. Thus, in this embodiment, since only one LED module 510 needs to be electrically connected to the base 300, assembly of the straight tube LED lamp 100 is further facilitated.

  In the present embodiment, in the mounting substrates 511 and 521, the notches 515 and 525 are provided one by one at positions symmetrical to the center of the substrate. However, the number, arrangement, and shape of the notches 515 and 525 are not limited. Etc. can be appropriately selected (changed) in accordance with the use of the straight tube LED lamp 100. For example, in the mounting substrates 511 and 521, the notches 515 and 525 may be provided one by one at positions symmetrical to the substrate center line along the substrate longitudinal direction. Alternatively, in the mounting substrates 511 and 521, two notches 515 and 525 are provided at one end in the short side direction of the substrate and one at the other end, and the one end is convex and the other end is concave. It may be made to become.

  According to the present embodiment, when straight tube LED lamp 100 is installed on the ceiling, it is possible to illuminate not only the floor surface direction but also all directions including the ceiling direction.

  In addition, according to the present embodiment, the cylindrical cover portion 200 is configured by one circular pipe, and therefore, assembly is easier than in the first embodiment. The cylindrical cover part 200 is completely fixed by housing the LED module unit 500 therein, attaching the caps 300 to both ends, and sealing.

  Further, according to the present embodiment, unlike the first embodiment, all components such as LEDs and connectors can be arranged on one side of the mounting boards 511 and 521. The working process can be greatly reduced. Moreover, since the same module can be used for three LED modules 520 among the four LED modules 510 and 520 constituting the LED module unit 500, the LED module unit 500 can be configured by two types of modules. In other words, there is an effect that the parts can be shared.

  In addition, according to the present embodiment, the heat radiation member 250 is disposed in the central cavity surrounded by the four mounting boards 511 and 521, so that the heat generated from the four LEDs 512 and 522 can be efficiently radiated. Can do. Since the heat radiating member 250 does not enter between the mounting boards 511 and 521 and the cylindrical cover part 200, the light emitted from the LEDs 512 and 522 is not blocked, and the light from the LEDs 512 and 522 can be irradiated uniformly 360 degrees. There is an effect that can be done.

  The space at the center may be used not only for installing the heat dissipating member 250 but also for installing the power supply module of the straight tube LED lamp 100 and the like. For example, the central portion of the heat radiating member 250 may be hollow, and a dedicated power supply module for the straight tube LED lamp 100 may be installed in this cavity (the heat radiating member 250 prevents the power module from being heated by the heat of the LEDs 512 and 522). Therefore, it is a heat insulating member). In this case, a power supply module is installed in the fixture main body 910 of the lighting fixture 900, the power supply module from the commercial power supply, the socket 920 of the lighting fixture 900 from the power supply module, the base pin 320 of the straight tube LED lamp 100, the base pin from the socket 920. Instead of connecting the wiring from 320 to the LED module unit 500, the socket 920 of the lighting fixture 900 is connected from the commercial power source, the socket pin 920 is connected to the cap pin 320 of the straight tube LED lamp 100, and the tube pin 320 is connected to the straight tube LED lamp 100. Wiring can be connected through the internal power supply module and the route from the power supply module to the LED module unit 500. When the power supply module is installed in the fixture main body 910 of the lighting fixture 900, the wiring from the commercial power source to the power supply module and from the power supply module to the socket 920 of the lighting fixture 900 becomes long, but the power supply module is installed in the center of the heat dissipation member 250. In this case, since only the wiring from the commercial power source to the socket 920 of the lighting fixture 900 needs to be long, wiring members can be reduced. In the former case, a substrate on which a diode bridge or current detection resistor is mounted may be inserted between the base pin 320 and the LED module unit 500. In the latter case, a diode bridge or current detection resistor is mounted in the power supply module. Since it is possible, it is not necessary to install another board.

  At present, LEDs have a long life of about 40,000 hours, and the life of the LEDs is increasing so as to be almost the same as that of the power supply module. Therefore, the LED module 510 (or the LED module 520) and the power supply module may be integrated. In this case, there is an effect that the power supply module can be replaced at the same time when the straight tube LED lamp 100 is replaced. In this case, when installing the lighting fixture 900, care must be taken because commercial power must be supplied from the socket 920.

Embodiment 5 FIG.
In the present embodiment, differences from the fourth embodiment will be mainly described.

  FIG. 12A is a top view of the LED module 510. FIG. 12B is a side view of the LED module 510 viewed from the direction of the arrow in FIG. FIG. 12C is a top view of the LED module 520. FIG.12 (d) is a side view of the LED module 520 seen from the arrow direction of FIG.12 (c). FIG. 13 is a side view of the LED module unit 500.

  As shown in FIGS. 12A and 12B, the LED module 510 includes the mounting substrate 511, the LED 512, the connectors 513a, 513b, 514a, and 514b shown in FIGS. 11A and 11B. Dummy connectors 513c to 513f similar to those in the second embodiment are provided.

  As shown in FIGS. 12C and 12D, the LED module 520 is the same as that of the second embodiment in addition to the mounting substrate 521, the LED 522, and the connectors 523a and 523b shown in FIGS. 11C and 11D. Dummy connectors 523c to 523f.

  Also in the present embodiment, as in the second embodiment, the connectors 513c to 513f and the connectors 523c to 523f are arranged at positions that do not interfere with each other when the mounting boards 511 and 521 are combined. In the present embodiment, the number and arrangement of the dummy connectors 513c to 513f, 523c to 523f can be appropriately selected (changed) in accordance with the application of the straight tube LED lamp 100.

  As shown in FIG. 13, in the LED module unit 500, the connectors 513c and 513f (or connectors 513d and 513e) of the mounting board 511 are fitted with the notches 515 and 525 of the mounting boards 511 and 521 adjacent to each other. And the connectors 523c and 523f (or the connectors 523d and 523e) of the mounting substrate 521 are connected to each other to electrically and physically connect the mounting substrates 511 and 521. Further, in a state where the notches 525 of the mounting boards 521 adjacent to each other are fitted, the connectors 523c and 523f (or the connectors 523d and 523e) of one mounting board 521 and the connectors 523d and 523e of the other mounting board 521 (or The two mounting boards 521 are electrically and physically connected by the connectors 523c and 523f) being fitted to each other. By adopting such a configuration, according to the present embodiment, the force for fixing the mounting boards 511 and 521 can be increased, and the connectors 513a and 513b and the connectors 523a and 523b can be prevented from being loosened and damaged.

Embodiment 6 FIG.
In the present embodiment, differences from the fourth embodiment will be mainly described.

  FIG. 14A is a top view of the LED module 530. FIG. 14B is a side view of the LED module 530 viewed from the direction of the arrow in FIG. FIG. 14C is a top view of the LED module 540. FIG.14 (d) is a side view of the LED module 540 seen from the arrow direction of FIG.14 (c). FIG. 15A is a top view of the LED module 550. FIG. 15B is a side view of the LED module 550 as viewed from the direction of the arrow in FIG. FIG. 15C is a side view of the LED module unit 500. FIG. 16 is a diagram showing an assembly procedure of the LED module unit 500.

  In the present embodiment, the LED module unit 500 includes one longitudinal LED module 530 on which the LEDs 532 are mounted, two longitudinal LED modules 540 on which the LEDs 542 are mounted, and 1 on which the LEDs 552 are mounted. A sheet of long LED modules 550 are combined so as to cross each other when viewed from the longitudinal direction. The LEDs 532, 542, and 552 are the same as the LEDs 412 and 422 of the first embodiment.

  The LED module unit 500 has a substantially quadrangular cross section and a substantially rectangular parallelepiped shape as a whole. As shown in FIG. 15 (c), at the four corners of the rectangular parallelepiped, each board protrudes from the surface forming the quadrangle, and the connectors provided on the respective boards on the board protruding from the cross section of the quadrangle Is connected. In addition, the board | substrates arrange | positioned facing are the same shape.

  As shown in FIGS. 14A and 14B, in the LED module 530, the notches 535 are provided at two positions on both ends in the short-side direction of the substrate, and protrusions 536 having a length A are formed at both ends. (Specifically, it has a shape in which the corners of the four corners of the board are cut into rectangles) mounting board 531 (first board), LED 532 mounted on the mounting board 531, male connectors 533 a and 533 f, and Embodiment 2 And dummy connectors 533b to 533e, and connectors 534a and 534b to which harnesses for supplying power from the cap pin 320 to the LED module unit 500 are connected. The connectors 534a and 534b are the same as the connectors 514a and 514b of the fourth embodiment.

  Twelve LEDs 532 are mounted on the upper surface of the mounting substrate 531 and are arranged in a straight line and in a line along the longitudinal direction of the substrate. The connectors 533a and 533f correspond to the protrusions 536 on a one-to-one basis, and are disposed on the corresponding protrusions 536 on the upper surface of the mounting substrate 531. The connectors 533b and 533c are disposed on the same protrusion 536 as the connector 533a. The connectors 533d and 533e are disposed on the same protrusion 536 as the connector 533f. On the upper surface of the mounting substrate 531, each component is electrically connected by a wiring pattern from the connector 534a through the LED 532 to the connector 533f. Further, the connector 533a and the connector 534b are electrically connected by a wiring pattern. In the present embodiment, the number and arrangement of the LEDs 532 can be appropriately selected (changed) according to the application of the straight tube LED lamp 100 and the like.

  As shown in FIGS. 14C and 14D, the LED module 540 includes a mounting board 541 (second board) including two notches 545 extending in the longitudinal direction of the board at a length A or more, and the mounting board. LED 542 mounted on 541, female connectors 543a and 543f, and dummy connectors 543b to 543e similar to those of the second embodiment.

  Twelve LEDs 542 are mounted on the upper surface of the mounting substrate 541, and are arranged between the two notches 545 in a substantially straight line and in one row along the longitudinal direction of the substrate. The two notches 545 are arranged at positions that are substantially equidistant in the substrate short direction from the line of the LED 542 at the approximate center in the substrate short direction. The connectors 543a and 543f correspond to the notches 545 on a one-to-one basis, and are arranged on the upper surface of the mounting substrate 541 so as to be adjacent to the corresponding notches 545, respectively. The connectors 543b and 543c are disposed adjacent to the same notch 545 as the connector 543a. The connectors 543d and 543e are disposed adjacent to the same notch 545 as the connector 543f. On the upper surface of the mounting substrate 541, each component is electrically connected by a wiring pattern from the connector 543a to the connector 543f via the LED 542. In the present embodiment, the number and arrangement of the LEDs 542 can be appropriately selected (changed) according to the application of the straight tube LED lamp 100 and the like.

  As shown in FIGS. 15A and 15B, in the LED module 550, the notches 555 are provided at two positions on both ends in the short-side direction of the substrate, and the protrusions 556 having a length A are formed on both ends. (Specifically, it has a shape in which the corners of the four corners of the board are cut into rectangles) mounting board 551 (first board), LED 552 mounted on this mounting board 551, male connectors 553a and 553f, Embodiment 2 And the same dummy connectors 553b to 553e.

  The LED module 550 has the same configuration as the LED module 540 except that there is no connector connected to the cap pin 320.

  As shown in FIG. 16, for example, when connecting the LED module 550 to the LED module 550, (1) First, the surface on which the LED 542 of the LED module 540 is mounted faces downward. (2) Then, the protrusion 556 of the LED module 550 is inserted into the notch 545 of the LED module 540 with the surface of the LED module 550 on which the LED 552 is mounted facing outward. At this time, the protrusion 556 of the LED module 550 is inserted until the connector 553c of the LED module 550 and the like completely come out from the notch 545 of the LED module 540 to the surface where the LED 542 is mounted. Note that the width of the notch 545 of the LED module 550 must be a width that allows at least the connector 553c of the LED module 550 to pass through. That is, the width of the connector 553c of the LED module 550 and the thickness of the mounting substrate 551 must be equal to or greater than the combined length. (3) Next, the LED module 550 is moved outward (right in FIG. 16) and pressed against the inner wall of the notch 545 of the LED module 540. (4) Then, the LED module 550 is moved upward to connect the connector 553c with the connector 543c of the LED module 540.

  If the same operation is performed for other combinations of the LED modules 530, 540, and 550, the assembly of the LED module unit 500 is completed. In order to facilitate the work, it is desirable that there is a play in which the substrates can be tilted to some extent even when the substrates are fixed. If the LED modules 530, 540, and 550 are not connected one by one in sequence but the procedure shown in FIG. 16 is performed on all the LED modules 530, 540, and 550 at the same time, as described above. The LED module unit 500 can be easily assembled without any play.

  As shown in FIG. 15C, in the LED module unit 500, the protrusions 536 and 556 formed at one end in the short direction of the mounting boards 531 and 551 are formed on the two notches 545 of one mounting board 541. The projections 536 and 556 formed at the other end in the short direction of the mounting boards 531 and 551 are fitted into the two notches 545 of the other mounting board 541, respectively. 531, 541, 551 are combined in a lattice pattern. By taking such a configuration, according to the present embodiment, assembly of straight tube LED lamp 100 is facilitated.

  In the present embodiment, the mounting substrate 541 is provided with two grooves parallel to the longitudinal direction of the substrate as the notches 545. However, the arrangement and shape of the grooves are the uses of the straight tube LED lamp 100. It can be appropriately selected (changed) according to the above. The arrangement and shape of the protrusions 536 and 556 of the mounting substrates 531 and 551 can be appropriately selected (changed) in accordance with the arrangement and shape of the grooves of the mounting substrate 541.

  According to the present embodiment, since the connectors of all the boards can be mounted on the same surface as the surface on which the LEDs are mounted (front surface), man-hours at the time of manufacture are reduced as compared with the case where the connectors are mounted on the back surface. Can be reduced.

  Further, according to the present embodiment, the number of connectors to be physically connected can be increased as compared with the fourth embodiment, so that the substrates can be more firmly fixed. In the present embodiment, the number and arrangement of the connectors 543b to 543e of the mounting substrate 541 can be appropriately selected (changed) in accordance with the use of the straight tube LED lamp 100.

  As mentioned above, although embodiment of this invention was described, you may implement combining 2 or more embodiment among these. Alternatively, one of these embodiments may be partially implemented. Or you may implement combining two or more embodiment among these partially.

  100 straight tube type LED lamp, 200 cylindrical cover part, 210 cover upper part, 220, 230 heat sink, 240 cover lower part, 250 heat radiating member, 251 through hole, 300 base, 310 base mounting part, 320 base pin, 400, 500 LED Module unit, 410, 420, 430, 440, 450, 510, 520, 530, 540, 550 LED module, 411, 421, 431, 441, 451, 511, 521, 531, 541, 551 Mounting board, 412, 422 , 432, 442, 452, 512, 522, 532, 542, 552 LED, 413a to 413f, 414a, 414b, 423a to 423f, 433a, 433b, 443a to 443d, 444a, 444b, 453c, 453d, 513a to 513f, 514a, 514b, 523a-523f, 533a-533f, 534a, 534b, 543a-543f, 553a-553f Connector, 415, 425, 435, 445, 455, 515, 525, 535, 545, 555 Notch, 436 , 456, 536, 556 protrusion, 900 lighting fixture, 910 fixture body, 920 socket.

Claims (12)

A plurality of longitudinal substrates on which light-emitting elements that emit light are mounted, each of which includes a plurality of substrates provided with cutouts extending in the longitudinal direction, the notches are fitted to each other, and the plurality of substrates are In lamps that are combined so as to intersect when viewed from the longitudinal direction ,
The plurality of substrates, as the notches, consist of a first substrate and a second substrate provided with slits extending from a substantially central portion in the longitudinal direction to one end portion in the longitudinal direction at a substantially central portion in the short direction,
The slit of the first substrate and the slit of the second substrate are fitted, and the first substrate and the second substrate are combined in an X shape when viewed from the longitudinal direction,
The lamp further comprises:
A translucent cover that covers two V-shaped grooves facing each other among the four V-shaped grooves formed between the plurality of substrates;
Of the four V-shaped grooves, a heat radiating member disposed in the other two V-shaped grooves facing each other;
Lamp, characterized in that it comprises a. A plurality of longitudinal substrates on which light-emitting elements that emit light are mounted, each of which includes a plurality of substrates provided with cutouts extending in the longitudinal direction, the notches are fitted to each other, and the plurality of substrates are In lamps that are combined so as to intersect when viewed from the longitudinal direction ,
The plurality of substrates include a first substrate and a second substrate in which the notches are provided at a plurality of locations on one end portion in the short-side direction to form protrusions on the one-end portion, and the short-cut direction as the notch. A third substrate having a groove in the center,
The projection of the first substrate is fitted into the groove of the third substrate, and the projection of the second substrate is fitted into the groove of the third substrate from the opposite side of the projection of the first substrate, so that the first A lamp comprising: a substrate, the second substrate, and the third substrate combined in an X shape when viewed from the longitudinal direction . The lamp further comprises:
A translucent cover that covers two V-shaped grooves facing each other among the four V-shaped grooves formed between the plurality of substrates;
The lamp according to claim 2, further comprising: a heat dissipating member disposed in the other two V-shaped grooves facing each other among the four V-shaped grooves. The lamp according to any one of claims 1 to 3 , wherein the first substrate and the second substrate have the same shape. A plurality of longitudinal substrates on which light-emitting elements that emit light are mounted, each of which includes a plurality of substrates provided with cutouts extending in the longitudinal direction, the notches are fitted to each other, and the plurality of substrates are In lamps that are combined so as to intersect when viewed from the longitudinal direction ,
The plurality of substrates consists of four substrates in which the notches are provided at both ends in the short direction,
The lamp is characterized in that notches of adjacent substrates of the four substrates are fitted to each other and the four substrates are combined in a lattice shape . A plurality of longitudinal substrates on which light-emitting elements that emit light are mounted, each of which includes a plurality of substrates provided with cutouts extending in the longitudinal direction, the notches are fitted to each other, and the plurality of substrates are In lamps that are combined so that they intersect when viewed from the longitudinal direction ,
The plurality of substrates include two first substrates in which the cutouts are provided at a plurality of locations on both ends in the short-side direction to form protrusions on both ends, and two cutouts parallel to the longitudinal direction. Consisting of two second substrates provided with grooves,
A protrusion formed at one end of the two first substrates in the short direction fits into one of the two second substrates and the other end of the two first substrates in the short direction. The projection formed on the portion is fitted into the other two grooves of the two second substrates, and the two first substrates and the two second substrates are combined in a lattice shape. And a lamp. The lamp further comprises:
A heat dissipating member disposed in a rectangular space formed between the plurality of substrates;
Claim 5 or 6 lamps, characterized in that it comprises a cylindrical translucent cover covering the plurality of substrates. It said plurality of substrates are one of claims 1 to 7, characterized in that it has a connector for electrically and physically connecting the plurality of substrates by fitting to each other in a state in which the notch each other fitted Lamp. A plurality of longitudinal substrates on which light-emitting elements that emit light are mounted, each of which includes a plurality of substrates provided with notches extending in a longitudinal direction, and the notches are fitted to each other, and the plurality of substrates are In lamps that are combined so as to intersect when viewed from the longitudinal direction ,
The plurality of substrates include a connector that electrically and physically connects the plurality of substrates by fitting each other in a state in which the notches are fitted to each other . The plurality of boards have other connectors that connect only the plurality of boards physically without being electrically connected to each other in a state where the notches are fitted to each other. The lamp according to claim 8 or 9. The lamp further includes a base disposed at at least one end in the longitudinal direction,
The lamp according to any one of claims 1 to 10, wherein only one of the plurality of substrates is electrically connected to the base. A lamp according to any one of claims 1 to 11,
A lighting apparatus comprising: a lighting fixture to which the lamp is attached.

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