JP6960599B2 - Lighting equipment and lighting equipment - Google Patents

Description

The present invention relates to a luminaire and a luminaire.

The lighting fixture of Patent Document 1 includes a plurality of LED elements, and further has a power supply device (power supply unit) for supplying electric power to the plurality of LED elements.

Further, the luminaire of Patent Document 1 is a luminaire to be mounted on the ceiling, and includes a mounting portion that is mechanically and electrically connected to a hook ceiling installed on the ceiling.

Japanese Unexamined Patent Publication No. 2017-120487

The power supply unit of a lighting fixture generally generates heat during operation, and heat dissipation from this power supply unit is important. However, the lighting fixture of Patent Document 1 does not disclose the heat dissipation of the power supply device.

Further, in the lighting fixture of Patent Document 1, it is preferable that a power supply unit for supplying input power from the outside to the power supply device is inserted in the fixture, and the temperature rise due to heat generation of the power supply device is suppressed as much as possible. However, in the lighting fixture of Patent Document 1, it is not easy to provide a configuration for heat dissipation of the power supply device in the fixture due to the space limitation in the fixture.

The present invention has been made in view of the above reasons, and an object of the present invention is a lighting device and a lighting device capable of suppressing a temperature rise due to heat generation of a power supply device even if a power feeding unit is inserted. Is to provide.

The lighting device of the present invention includes a power supply device that supplies load power to the light source to turn on the light source, and a case in which the power supply device is housed. Inside the case, there is an insertion space into which a power feeding unit that supplies input power from the outside to the power supply device is inserted. The power supply device has a first power supply board and a second power supply board housed in the case with the insertion space interposed therebetween. The first power supply board includes an input connection unit that receives an input voltage from the power supply unit, and a booster circuit that outputs a boosted voltage obtained by boosting the input voltage to the second power supply board. The second power supply board includes a step-down circuit that outputs a load voltage obtained by stepping down the step-up voltage to the light source, and a control circuit that controls the step-up circuit and the step-down circuit. Of the first space and the second space located across the insertion space in the case, the first power supply board is housed in the first space, and the second power supply board is housed in the second space. Has been done. The first power supply board is arranged closer to the insertion space in the first space, and the second power supply board is arranged so that the step-down circuit is closer to the insertion space than the control circuit.

The luminaire of the present invention includes the above-mentioned luminaire and the luminaire main body to which the luminaire is attached.

As described above, the present invention has an effect that the temperature rise due to the heat generation of the power supply device can be suppressed even in the configuration in which the power feeding unit is inserted.

FIG. 1 is an exploded perspective view showing a lighting fixture according to an embodiment of the present invention. FIG. 2 is another exploded perspective view showing the above-mentioned luminaire. FIG. 3 is an exploded perspective view showing the above-mentioned lighting device. FIG. 4 is another exploded perspective view showing the above-mentioned lighting device. FIG. 5 is a front view showing a power supply unit included in the above-mentioned lighting device. FIG. 6 is an exploded perspective view showing a power supply unit included in the above-mentioned lighting device. FIG. 7 is a block diagram showing a power supply device included in the above-mentioned lighting device. FIG. 8 is a front view showing an LED module included in the above-mentioned lighting device. FIG. 9 is a front view showing a state in which the lens block is attached to the above-mentioned LED module. FIG. 10 is a side view showing a lens block attached to the above-mentioned LED module. FIG. 11A is a perspective view showing the above-mentioned luminaire as viewed from below. FIG. 11B is a perspective view showing the above-mentioned luminaire as viewed from above.

Hereinafter, embodiments of the luminaire according to the present invention and embodiments of the luminaire according to the present invention will be described in detail with reference to the drawings. The embodiments described below are merely examples of the embodiments of the present invention. The present invention is not limited to the following embodiments, and various modifications can be made depending on the design and the like as long as the effects of the present invention can be achieved.

As shown in FIGS. 1 and 2, the lighting fixture 1 of the present embodiment includes a lighting device 2 and a fixture main body 9. The instrument body 9 includes a cover 91, a frame 92, and a glove 93. It is preferable that the instrument main body 9 further includes a pair of light guide members 94. The luminaire 1 is attached to a construction material (ceiling finishing material). The lighting fixture 1 is a so-called ceiling light that is detachably attached to a hook ceiling body 101 installed on the ceiling of a house. In FIGS. 1 and 2, the direction from the cover 91 to the glove 93 is downward, and the direction from the glove 93 to the cover 91 is upward.

As shown in FIGS. 3 and 4, the lighting device 2 includes a case 3, a power supply unit 4, an LED module 5, and two lens blocks 6.

The case 3 has a first case 31 and a second case 32. The first case 31 is formed of a metal plate such as a steel plate in a rectangular box shape having an opening on the lower surface. The second case 32 is formed in a rectangular plate shape by a metal plate such as a steel plate. An oval recess 311 is formed in the center of the upper surface of the first case 31, and a circular hole 312 penetrates in the center of the recess 311 in the vertical direction. Further, a circular hole 321 penetrates in the vertical direction in the center of the second case 32. Further, a rectangular through hole 324 penetrates in the vertical direction on one end side of the second case 32 in the longitudinal direction.

Further, a collar portion 313 is formed along the longitudinal direction at the edge of the lower surface opening of the first case 31. Further, the longitudinal edge of the second case 32 is bent downward, and the second case 32 has a side wall 322 along the longitudinal direction. Further, a flange portion 323 is formed at the lower end of the side wall 322 along the longitudinal direction. Then, the collar portion 323 is screwed to the collar portion 313, so that the second case 32 is attached to the first case 31 so as to cover the lower surface of the first case 31. That is, the first case 31 and the second case 32 are coupled to each other to form a long rectangular box-shaped case 3. The power supply unit 4 is housed inside the case 3.

In the longitudinal direction of the case 3, the space on one side of the circular hole 312 is the first space 3a, and the space on the other side of the oval recess 311 is the second space 3b. ..

As shown in FIGS. 5 and 6, the power supply unit 4 has a mounting base 40, a holder 41, and a power supply device 42.

The power supply device 42 is configured to convert AC power (input power) supplied from a commercial power source into DC load power and supply the DC load power to the LED module 5. The power supply device 42 includes a first circuit block 43 and a second circuit block 44.

The first circuit block 43 is a power factor improving circuit 43a which is a booster circuit in which an AC input voltage is input from a commercial power source, the input voltage is rectified, the rectified voltage is boosted, and the boosted DC voltage (boost voltage) is output. Consists of. The first circuit block 43 is realized by a printed circuit in which circuit components 432 such as a semiconductor switching element, an inductor, a diode, a capacitor, and a drive circuit of the semiconductor switching element are mounted on a first power supply board 431 which is a printed wiring board. ing.

The second circuit block 44 has a step-down circuit 44a and a control circuit 44b. The step-down circuit 44a is a step-down chopper circuit that steps down the step-up voltage output by the first circuit block 43 and supplies a DC load current to the LED module 5, and constitutes a step-down type DCDC converter.

The control circuit 44b has a computer, and the computer executes a program to control each operation of the power factor improving circuit 43a and the step-down circuit 44a. A computer is mainly composed of a device having a processor for executing a program, a device for an interface for sending and receiving signals to and from other devices, and a device for storing programs and data. Prepare as. A device equipped with a processor is either a CPU (Central Processing Unit) or MPU (Micro Processing Unit) that is separate from the storage device, or a microcomputer that is integrally equipped with a storage device. May be good. As a storage device, a storage device having a short access time such as a semiconductor memory is mainly used. Examples of the form of providing the program include a form in which the program is stored in advance in a recording medium such as a semiconductor memory and an optical disk that can be read by a computer, and a form in which the program is supplied to the recording medium via a wide area communication network including the Internet and the like.

The second circuit block 44 mounts a circuit component 442 such as a semiconductor switching element, an inductor, a diode, a capacitor, a drive circuit of the semiconductor switching element, and an integrated circuit for arithmetic processing on a second power supply board 441 which is a printed wiring board. It is realized by the printed circuit.

The mounting base 40 is an insulating member formed in a rectangular flat plate shape by a material having electrical insulating properties such as synthetic resin. An oval through hole 401 penetrates the mounting base 40 in the vertical direction. A long cylindrical partition wall 402 projecting downward is provided around the through hole 401 on the lower surface of the mounting base 40.

The first circuit block 43 and the second circuit block 44 are arranged side by side along the longitudinal direction of the mounting base 40 with the partition wall 402 interposed therebetween, and the first power supply board 431 and the second power supply board 441 are mounted on the mounting base. It is attached to the lower surface of the 40 by being screwed. That is, the power supply device 42 is attached to the lower surface of the mounting base 40. Then, the power supply device 42 is attached to the first case 31 by screwing the mounting base 40 to the first case 31, and is housed in the case 3.

Then, when the power supply device 42 is housed in the case 3, the first circuit block 43 is housed in the first space 3a, which is a space on one side of the hole 312 in the longitudinal direction of the case 3. Further, the second circuit block 44 is housed in the second space 3b, which is on the other side of the hole 312 in the longitudinal direction of the case 3.

The first power supply board 431 is formed in a rectangular plate shape, and insertion holes 436 are formed at three corners. Further, on the lower surface of the mounting base 40, three positioning protrusions 405a project from the location where the first power supply board 431 is arranged. Then, the first power supply board 431 is positioned on the lower surface of the mounting base 40 by inserting the three protrusions 405a into the three insertion holes 436, respectively. Further, a locking claw 407a is formed on the outer peripheral side of the partition wall 402. The locking claw 407a is a substrate holding portion that holds the first power supply board 431 by pressing the surface 433 (lower surface) of the first power supply board 431, and the first power supply board 431 is positioned in the vertical direction. ing.

The second power supply board 441 is formed in a rectangular plate shape, and insertion holes 448 are formed at four corners. Further, on the lower surface of the mounting base 40, three positioning protrusions 405b project from the location where the second power supply board 441 is arranged. Then, the second power supply board 441 is positioned on the lower surface of the mounting base 40 by inserting the three insertion holes 448 out of the four insertion holes 448 into the three protrusions 405b, respectively. Further, a locking claw 407b is formed on the outer peripheral side of the partition wall 402, and a locking claw 407c is formed at the end of the mounting base 40. The locking claws 407b and 407c are board holding portions that hold the second power supply board 441 by pressing the surface 443 (lower surface) of the second power supply board 441, and the second power supply board 441 is positioned in the vertical direction. Has been made.

Further, on the lower surface of the mounting base 40, a convex wall 409 having a substantially rectangular frame shape is formed at a position facing the back surface 434 (upper surface) of the first power supply board 431, and a silicone resin or the like is formed inside the convex wall 409. The thermal sheet generated in is placed. The thermal sheet efficiently dissipates heat from the first power supply board 431 by transmitting the heat generated by the first power supply board 431 to the mounting base 40.

Conductors (copper foil) electrically connected to the circuit component 432 are formed on the front surface 433 (lower surface) and the back surface 434 (upper surface) of the first power supply board 431. The conductor of the front surface 433 and the conductor of the back surface 434 are electrically connected to each other by a through hole provided in the first power supply board 431 if necessary. Further, a receptacle connector 430a is mounted on the surface 433 of the first power supply board 431 as an input connection portion. The hook sealing adapter 102 (feeding part) (see FIGS. 1 and 2) is inserted into the tubular body 410 of the holder 41, and the receptacle connector 430a is connected to a plug connector electrically connected to the electrode of the hook sealing adapter 102. It is electrically and mechanically connected so that it can be inserted and removed. Then, the receptacle connector 430a receives AC power from the hook sealing adapter 102. Further, the receptacle connector 430a is electrically connected to the conductor of the first power supply board 431. An electric wire holding portion 404a is provided on the outer surface of the partition wall 402. The electric wire holding portion 404a holds the electric wire connected to the receptacle connector 430a in order to suppress the tension applied to the electric wire. The voltage of AC power is the input voltage.

Further, a receptacle connector 435a is mounted on the surface 433 of the first power supply board 431, and the receptacle connector 435a is electrically connected to the conductor of the first power supply board 431. The receptacle connector 435a is electrically and mechanically and detachably connected to the plug connector 435b, which has a one-to-one correspondence with the receptacle connector 435a. One connector 435 is composed of one receptacle connector 435a and one plug connector 435b.

The plug connector 435b is electrically and mechanically connected to one end of a plurality of electric wires 45. Plug connectors 445b are electrically and mechanically connected to the other ends of the plurality of electric wires 45, respectively. The plug connector 445b is electrically and mechanically connected to the receptacle connector 445a mounted on the front surface 443 (lower surface) of the second power supply board 441 so as to be removable. A conductor (copper foil) electrically connected to the circuit component 442 is formed on the front surface 443 and the back surface 444 (upper surface) of the second power supply board 441. The conductor on the front surface 443 and the conductor on the back surface 444 are electrically connected to each other by a through hole provided in the second power supply board 441, if necessary. The receptacle connector 445a is electrically connected to the conductor of the second power supply board 441. One connector 445 is composed of one receptacle connector 445a and one plug connector 445b. An electric wire holding portion 404b is provided on the outer surface of the partition wall 402. The electric wire holding portion 404b holds a plurality of electric wires 45 in order to suppress the tension applied to the electric wires.

As described above, the first circuit block 43 and the second circuit block 44 are electrically connected to each other via a plurality of electric wires 45. In this embodiment, four electric wires 45 are provided, and each of the four electric wires 45 constitutes a DC voltage line, an input detection line, a control line, and a ground line. A DC boost voltage output by the power factor improving circuit 43a is applied to the DC voltage line to supply DC power from the first circuit block 43 to the second circuit block 44. A rectified voltage of the AC input voltage input to the power factor improving circuit 43a is applied to the input detection line to notify the second circuit block 44 that the supply of AC power has started. The control voltage generated by the second circuit block 44 is applied to the control line to supply a control power supply from the second circuit block 44 to the first circuit block 43. The ground line becomes the electrical ground level of the first voltage line, the second voltage line, and the control line.

Here, as shown in FIG. 7, the step-down circuit 44a has four step-down chopper circuits PS1-PS4, and the four step-down chopper circuits PS1-PS4 have a step-up voltage V1 (boost voltage V1 output by the power factor improving circuit 43a). (DC voltage) is input, and the boost voltage V1 is stepped down to the respective load voltages V21-V24 and output. The step-down chopper circuit PS1 supplies DC load power to the daylight-colored LED element 52a of the LED module 5 described later. The step-down chopper circuit PS2 supplies DC load power to the light bulb-colored LED element 52b of the LED module 5 described later. The step-down chopper circuit PS3 supplies DC load power to the light bulb-colored LED element 53a of the LED module 5 described later. The step-down chopper circuit PS4 supplies DC load power to the light bulb-colored LED element 53b of the LED module 5 described later.

Then, as shown in FIGS. 5 and 6, in the second circuit block 44, two receptacle connectors 446a and 447a are further mounted on the surface 443 of the second power supply board 441. The receptacle connector 446a is electrically connected to each positive potential of the load voltage V21-V24 output by the step-down chopper circuit PS1-PS4. The receptacle connector 447a is electrically connected to each negative potential of the load voltage V21-V24 output by the step-down chopper circuit PS1-PS4.

Then, the receptacle connector 446a is electrically and mechanically and electrically connected to the plug connector 446b, which has a one-to-one correspondence with the receptacle connector 446a. The plug connector 446b is electrically and mechanically connected to one end of a plurality of electric wires 461. Further, the receptacle connector 447a is electrically and mechanically and electrically connected to the plug connector 447b, which has a one-to-one correspondence with the receptacle connector 447a. The plug connector 447b is electrically and mechanically connected to one end of a plurality of electric wires 462. One connector 446 is composed of one receptacle connector 446a and one plug connector 446b. Further, one receptacle connector 447a and one plug connector 447b constitute one connector 447.

The output of the step-down circuit 44a (each output of the step-down chopper circuits PS1-PS4) is electrically connected to the LED module 5 via a plurality of electric wires 461 and 462.

The holder 41 has a tubular body 410 that supports the hook sealing adapter 102, and a fixing plate 411 that is integrally formed with the tubular body 410. The fixing plate 411 is formed of a synthetic resin into a circular flat plate shape. A circular hole penetrates the center of the fixing plate 411. The tubular body 410 is formed in a cylindrical shape by a synthetic resin. The tubular body 410 is integrally formed with the fixing plate 411 so as to project downward from the peripheral edge of the hole on the lower surface of the fixing plate 411. The fixing plate 411 of the holder 41 is screwed to the mounting base 40. The tubular body 410 of the holder 41 is arranged inside the partition wall 402 with the fixing plate 411 screwed to the mounting base 40. The long cylindrical internal space of the partition wall 402 is the long cylindrical insertion space 403, and the tubular body 410 of the holder 41 is arranged in the insertion space 403.

The power supply unit 4 is attached to the first case 31 by screwing the mounting base 40 to the first case 31, and is housed in the case 3. The lower end of the partition wall 402 of the mounting base 40 is inserted into the hole 321 of the second case 32. Then, the hook sealing adapter 102 is inserted into the tubular body 410 of the holder 41. In other words, the hook sealing adapter 102 corresponding to the feeding portion is inserted into the insertion space 403 in the partition wall 402.

Then, the hook ceiling adapter 102 is detachably attached to the hook ceiling body 101 installed on the ceiling. The case 3 in which the power supply unit 4 is housed is detachably attached to the hook sealing adapter 102. That is, the case 3 is detachably attached to the hook sealing body 101 via the hook sealing adapter 102, and is supported by the hook sealing body 101 via the hook sealing adapter 102. However, since the hook sealing body 101 and the hook sealing adapter 102 are well known in the past, detailed configuration illustration and description will be omitted.

The schematic operation of the power supply device 42 will be described with reference to FIG.

The power factor improving circuit 43a includes an input circuit 43b and a boost chopper circuit 43c. The input circuit 43b full-wave rectifies the AC input voltage Vac input to the power factor improving circuit 43a, and outputs the rectified voltage Vr to the boost chopper circuit 43c. The step-up chopper circuit 43c boosts the rectifying voltage Vr and outputs the boosted DC voltage V1 to the step-down circuit 44a.

The step-down circuit 44a has four step-down chopper circuits PS1-PS4. The four step-down chopper circuits PS1-PS4 receive the boost voltage V1 output by the power factor improving circuit 43a, step-down the step-up voltage V1 and output the step-down DC voltage V21-V24, respectively.

The control circuit 44b includes a control power supply CP1 and a control block CB1. The control power supply CP1 generates a control voltage Vc for driving the power supply device 42. The control block CB1 includes a computer such as a CPU, MPU, or a microcomputer, and peripheral circuits such as a buzzer, an LED element for a nightlight, and an infrared light receiving element.

Then, when the input voltage Vac is input to the power factor improving circuit 43a of the first circuit block 43, the rectified voltage Vr is transmitted from the power factor improving circuit 43a to the second circuit block 44 as a notification signal for notifying the start of supply of AC power. Is output. In the second circuit block 44, the control power supply CP1 generates a control voltage Vc from the rectified voltage Vr, and outputs this control voltage Vc as an INT signal S1 to the control block CB1. The computer of the control block CB1 that has received the INT signal S1 is supplied with the control voltage Vc and starts operating. Then, the computer of the control block CB1 supplies the control voltage Vc from the control power supply CP1 to the first circuit block 43. In the first circuit block 43 to which the control voltage Vc is supplied, the power factor improving circuit 43a is activated to start the boosting operation, and the power factor improving circuit 43a outputs the boosting voltage V1 to the second circuit block 44. Then, the computer of the control block CB1 controls each operation of the step-down chopper circuits PS1-PS4.

The computer of the control block CB1 outputs a dimming signal S11 to the step-down chopper circuit PS1 to control the load voltage V21, thereby controlling the lighting, extinguishing, dimming, and the like of the daylight-colored LED element 52a. Further, the computer of the control block CB1 outputs the control signal S12 to the step-down chopper circuit PS2-PS4 to control the load voltage V22-V24, respectively, so that the light bulb-colored LED elements 52b, 53a, and 53b are turned on. Controls extinguishing and so on.

As described above, when the power supply device 42 is housed in the case 3, the first circuit block 43 is housed in the first space 3a. Further, the second circuit block 44 is housed in the second space 3b. That is, the first power supply board 431 is housed in the first space 3a on one end side in the longitudinal direction of the case 3, and the second power supply board 441 is housed in the second space 3b on the other end side in the longitudinal direction of the case 3. It is stored in.

When the power supply device 42 is housed in the case 3, the first space 3a and the second space 3b are located in the case 3 with the insertion space 403 in between. In other words, the first power supply board 431 and the second power supply board 441 are located in the case 3 with the insertion space 403 sandwiched between them. The first power supply board 431 includes a power factor improving circuit 43a which is a booster circuit, and the power factor improving circuit 43a tends to generate a large amount of heat during operation. Further, the second power supply board 441 includes a step-down circuit 44a, and the step-down circuit 44a tends to generate a large amount of heat during operation. Each heat generated by the power factor improving circuit 43a and the step-down circuit 44a causes a temperature rise in the lighting device 2.

Therefore, in the present embodiment, the first circuit block 43 and the second circuit block 44 are combined with the two power supply boards (first power supply) without forming the first circuit block 43 and the second circuit block 44 on one power supply board. It is composed of a board 431 and a second power supply board 441), respectively. That is, the power supply device 42 is composed of two power supply boards (first power supply board 431 and second power supply board 441). Then, by arranging the first power supply board 431 in the first space 3a and the second power supply board 441 in the second space 3b, an insertion space is provided between the first power supply board 431 and the second power supply board 441. 403 is present. Therefore, the insertion space 403 weakens the thermal coupling between the first power supply board 431 and the second power supply board 441 as compared with the case where the power supply device 42 is composed of one power supply board. As a result, the power supply device 42 can suppress the temperature rise (particularly the local temperature rise) due to the heat generated by the power factor improving circuit 43a and the step-down circuit 44a, and can suppress the temperature rise of the lighting device 2.

Further, since the power supply device 42 is composed of two power supply boards (first power supply board 431 and second power supply board 441), the warp of the power supply board is increased as compared with the case where the power supply device 42 is composed of one power supply board. Occurrence can be suppressed.

Further, the first space 3a is a space having a substantially rectangular shape, which is larger than the first power supply board 431 in a plan view. In the present embodiment, in the first space 3a, the first power supply board 431 is arranged closer to the insertion space 403. The second space 3b is a space having a substantially rectangular shape, and is substantially the same size as the second power supply board 441 in a plan view. In the present embodiment, in the second power supply board 441, the step-down circuit 44a and the control circuit 44b are formed side by side along the longitudinal direction of the second power supply board 441. When the second power supply board 441 is arranged in the second space 3b, the step-down circuit 44a is closer to the insertion space 403 than the control circuit 44b, and the control circuit 44b is farther from the insertion space 403 than the step-down circuit 44a. Therefore, the wire lengths of the plurality of electric wires 45 that electrically connect the first power supply board 431 and the second power supply board 441 can be shortened. As a result, it is possible to suppress the influence of noise generated during the operation of the power supply device 42 on the voltage and electrical signals transmitted by the plurality of electric wires 45. Further, since the control circuit 44b can be separated from the power factor improving circuit 43a as much as possible, the influence of the noise of the power factor improving circuit 43a on the control circuit 44b can be suppressed. Further, since the control circuit 44b can be separated from the insertion space 403 as much as possible, it is possible to suppress the influence of the noise generated from the hook sealing adapter 102, which is the feeding portion, on the control circuit 44b.

Further, the receptacle connector 435a is mounted at a position close to the insertion space 403 on the first power supply board 431. The receptacle connector 445a is mounted at a position close to the insertion space 403 on the second power supply board 441. As a result, the wire lengths of the plurality of electric wires 45 that electrically connect the first power supply board 431 and the second power supply board 441 can be shortened.

Further, the power factor improving circuit 43a and the step-down circuit 44a have circuit components 432 and 442 having a relatively large height dimension such as a transformer and a smoothing capacitor. In the present embodiment, since the power factor improving circuit 43a and the step-down circuit 44a are arranged around the insertion space 403, circuit components 432 and 442 having a relatively large height dimension are concentrated near the center of the case 3. As a result, the lighting device 2 can suppress the vertical dimension (height dimension) at both ends in the longitudinal direction of the case 3, and the degree of freedom in design is increased.

Further, the first power supply board 431 and the second power supply board 441 are attached to a mounting base 40, which is one insulating member, respectively. Therefore, the configuration of the lighting device 2 can be simplified as compared with the case where the first power supply board 431 and the second power supply board 441 are attached to separate insulating members.

Further, the mounting base 40 includes locking claws 407a, 407b, and 407c. The locking claws 407a, 407b, and 407c hold the first power supply board 431 and the second power supply board 441, and position the first power supply board 431 and the second power supply board 441 in the vertical direction. Therefore, the mounting base 40 can simplify the holding structure of the first power supply board 431 and the second power supply board 441 by providing the locking claws 407a, 407b, and 407c.

Hereinafter, the LED module 5 will be described with reference to FIGS. 3, 4, and 8.

The LED module 5 is a light source that lights up by being supplied with load power from the power supply device 42, and includes two LED boards 51 and a plurality of LED elements 52 mounted on the mounting surface 51a (lower surface) of each LED board 51. I have. The LED substrate 51 is formed in a substantially long rectangular shape. The two LED substrates 51 are formed to have the same shape and dimensions. The two LED substrates 51 are formed of, for example, a glass cloth-based epoxy resin substrate.

The two LED substrates 51 are arranged so that their first ends 51b in the longitudinal direction face each other. A semicircular notch 51c is formed in the center of the first end 51b. Then, the first ends 51b of the two LED substrates 51 face each other, so that the notches 51c of the two LED substrates 51 form one circular through hole 51d. Further, a substantially rectangular notch 51f is formed in the center of the second end 51e (the end opposite to the first end 51b) in the longitudinal direction of the LED substrate 51 along the longitudinal direction of the LED substrate 51. There is.

On the mounting surface 51a of each LED substrate 51, a substantially rectangular elongated region including a semicircular edge of the notch 51c is a mounting region 51g from the first end 51b along the longitudinal direction of the LED substrate 51. That is, a part of the first end 51b becomes a part of the outer edge of the mounting area 51g. In other words, the outer edge of the mounting area 51g includes a semi-circular edge of the notch 51c. The plurality of LED elements 52 are mounted in four rows so as to be arranged along the longitudinal direction of the LED substrate 51 in the mounting region 51g. The plurality of LED elements 52 are mounted so as to have four rows, but may be mounted so as to have three or less rows or five or more rows. In the present embodiment, the plurality of LED elements 52 include a daylight color LED element 52a and a light bulb color LED element 52b.

That is, the LED module 5 includes two mounting regions 51g, and the two mounting regions 51g face each other with a circular through hole 51d in the longitudinal direction of the LED substrate 51.

The mounting area 51g is further divided into a first area 511g and a second area 512g.

The first region 511g is a region on the first end 51b side of the mounting region 51g, and is a region including a semicircular edge of the notch 51c (a part of the outer edge of the mounting region 51g). Then, in the first region 511g, each LED element 52 (first LED element 521) located first and second from the first end 51b is mounted in each row of the plurality of LED elements 52. In this embodiment, eight first LED elements 521 are provided. The first LED element 521 corresponds to the first solid-state light emitting element.

The second region 512g is a region on the second end 51e side other than the first region 511g in the mounting region 51g, and each LED element located in the third and subsequent rows from the first end 51b in each row of the plurality of LED elements 52. 52 (second LED element 522) is mounted. The second LED element 522 corresponds to the second solid-state light emitting element.

Further, on the mounting surface 51a of each LED substrate 51, a plurality of light bulb-colored LED elements 53a are mounted side by side in the longitudinal direction on one side edge. Further, on the mounting surface 51a of each LED substrate 51, a plurality of light bulb-colored LED elements 53b are mounted side by side in the longitudinal direction on the other side edge.

Each LED substrate 51 is formed with four first positioning holes 51h, four second positioning holes 51i, and two third positioning holes 51j. The first positioning hole 51h, the second positioning hole 51i, and the third positioning hole 51j penetrate the LED substrate 51 in the thickness direction, respectively.

On the mounting surface 51a (lower surface) and the back surface 51m (upper surface) of the LED substrate 51, conductors (copper foil) electrically connected to the plurality of LED elements 52a, 52b, 53a, 53b are formed. If necessary, the conductor of the mounting surface 51a and the conductor of the back surface 51m may be electrically connected to each other by a through hole provided in the LED substrate 51.

Then, the LED substrate 51 is attached to the lower surface of the second case 32 by screws inserted into each of the four first positioning holes 51h.

Further, a receptacle connector 541a and a receptacle connector 542a are mounted on the mounting surface 51a of the LED substrate 51, respectively. The receptacle connector 541a and the receptacle connector 542a are arranged side by side in the lateral direction of the LED substrate 51 with the mounting area 51g interposed therebetween. The receptacle connectors 541a and 542a are electrically connected to the conductors of the LED substrate 51, respectively.

First, the receptacle connector 541a is electrically and mechanically connected to the plug connector 541b, which has a one-to-one correspondence with the receptacle connector 541a, so that it can be inserted and removed. The two plug connectors 541b are electrically connected to each other by a plurality of electric wires 54, and the two LED substrates 51 are electrically connected to each other via a plurality of electric wires 54. One connector 541 is composed of one receptacle connector 541a and one plug connector 541b.

In this embodiment, four electric wires 54 are provided. The plurality of LED elements 52a, 52b, 53a, 53b mounted on one LED board 51 and the plurality of LED elements 52a, 52b, 53a, 53b mounted on the other LED board 51 are 4 They are electrically connected in series by the electric wires 54 of the book. That is, the plurality of LED elements 52a mounted on the two LED boards 51 are electrically connected in series, and the plurality of LED elements 52b mounted on the two LED boards 51 are electrically connected in series. Further, the plurality of LED elements 53a mounted on the two LED boards 51 are electrically connected in series, and the plurality of LED elements 53b mounted on the two LED boards 51 are electrically connected in series.

Of the two LED boards 51, the receptacle connector 542a of one of the LED boards 51 is electrically and mechanically connected to the plug connector 542b to which the plurality of electric wires 461 are connected so that it can be inserted and removed. Of the two LED boards 51, the receptacle connector 542a of the other LED board 51 is electrically and mechanically connected to the plug connector 542b to which the plurality of electric wires 462 are connected so that it can be inserted and removed. One connector 542 is composed of one receptacle connector 542a and one plug connector 542b.

That is, one of the two LED boards 51 is electrically connected to each positive potential of the load voltage V21-V24 output by the step-down chopper circuit PS1-PS4 via a plurality of electric wires 461. .. The other LED substrate 51 is electrically connected to each negative potential of the load voltage V21-V24 output by the step-down chopper circuit PS1-PS4 via a plurality of electric wires 462. That is, each of the step-down chopper circuits PS1-PS4 can pass a load current through each closed loop via the electric wire 461, one LED substrate 51, the electric wire 54, the other LED substrate 51, and the electric wire 462.

Hereinafter, the lens block 6 will be described with reference to FIG.

The two lens blocks 6 each have a substantially rectangular plate-shaped base 60 and a plurality of lenses 61, respectively. The plurality of lenses 61 are mounted in four rows so as to be arranged along the longitudinal direction of the base 60 on the lower surface 60e of the base 60. It is preferable that the base 60 and the plurality of lenses 61 are integrally formed of a molded body of glass or a synthetic resin (acrylic resin or polycarbonate resin) having translucency. The base 60 is formed with a pair of triangular ribs 601 protruding outward from the centers of both side edges, and a cylindrical positioning protrusion 602 projects upward on the lower surface of the ribs 601. Then, the lens block 6 is positioned with the LED substrate 51 by engaging the two protrusions 602 one-to-one with the two third positioning holes 51j formed in the LED substrate 51.

An arcuate notch 60b is formed at the first end 60a of the base 60 in the longitudinal direction. Further, a substantially rectangular translucent window 60d is formed at the second end 60c (the end opposite to the first end 60a) in the longitudinal direction of the base 60. The positioning lens block 6 is arranged on the mounting surface 51a of the LED substrate 51 so that the arc-shaped notch 60b is along the edge of the semicircular notch 51c of the LED substrate 51. .. Therefore, the two lens blocks 6 are attached to the two LED substrates 51 so that their first ends 60a face each other.

Further, the translucent window 60d faces the notch 51f of the LED substrate 51. The translucent window 60d of one of the two lens blocks 6 faces the control circuit 44b of the power supply unit 4 via the notch 51f and the through hole 324.

The lens 61 faces the LED element 52 on a one-to-one basis, and is provided below the mounting area 51g of the LED substrate 51.

The plurality of lenses 61 include a plurality of (8 in this embodiment) condensing lenses 611 and a plurality of (more than the number of condensing lenses 611) diffusing lenses 612. The eight condenser lenses 611 are located on the first end 60a side of the base 60, and the plurality of diffuser lenses 612 are located on the second end 60c side of the base 60. The eight condensing lenses 611 face each of the eight first LED elements 521. Further, the plurality of diffusion lenses 612 face each of the plurality of second LED elements 522.

Further, the eight condensing lenses 611 are divided into four first condensing lenses 611a and four second condensing lenses 611b. The four first condensing lenses 611a are condensing lenses 611 located first from the first end 51b in each row of the eight condensing lenses 611. The four second condensing lenses 611b are condensing lenses 611 located second from the first end 51b in each row of the eight condensing lenses 611. That is, the four first condensing lenses 611a are closer to the first end 60a of the base 60 than the four second condensing lenses 611b, and are arranged in an arc shape along the arc-shaped notch 60b. .. The four second condensing lenses 611b are located closer to the second end 60c of the base 60 than the four first condensing lenses 611a, and are arranged in an arc shape next to the four first condensing lenses 611a. Has been done.

The plurality of diffusing lenses 612 are located farther from the first end 60a of the base 60 and closer to the second end 60c of the base 60 than the four second condensing lenses 611b.

Hereinafter, the light distribution characteristics of the lens 61 will be described with reference to FIG.

The first condensing lens 611a has a convex shape protruding downward on the lower surface of the base 60, and is formed in a substantially droplet shape. Specifically, the surface of the first condensing lens 611a is a curved surface, and the surface of the first condensing lens 611a viewed from the lateral side of the base 60 has a radius of curvature on the first end 60a side on the second end 60c side. Is smaller than the radius of curvature of. That is, in the first condensing lens 611a, the surface rising on the first end 60a side is steeper than the rising surface on the second end 60c side, and the surface on the second end 60c side rises gently. In other words, on the surface of the first condensing lens 611a, the radius of curvature on the side in the condensing direction is smaller than the radius of curvature on the side opposite to the condensing direction.

The first condensing lens 611a described above has a light distribution characteristic that condenses light toward the first end 60a, which is steeper than the rising edge of the lens surface. Therefore, the light emitted from the first condensing lens 611a is focused on the first end 60a side, and the amount of light distributed by the first condensing lens 611a to the first end 60a side is the first condensing lens 611a. The amount of light is greater than the amount of light distributed to the second end 60c side. That is, the condensing direction of the first condensing lens 611a is the direction toward the first end 60a in the longitudinal direction of the base 60.

Next, the second condenser lens 611b has a convex shape protruding downward on the lower surface of the base 60, and is formed in a substantially droplet shape on the lower surface of the base 60. Specifically, the surface of the second condensing lens 611b is a curved surface, and the surface of the second condensing lens 611b viewed from the lateral side of the base 60 has a radius of curvature on the first end 60a side on the second end 60c side. Is smaller than the radius of curvature of. That is, in the second condenser lens 611b, the surface rising on the first end 60a side is steeper than the rising surface on the second end 60c side, and the surface on the second end 60c side rises gently. In other words, on the surface of the second condensing lens 611b, the radius of curvature on the side in the condensing direction is smaller than the radius of curvature on the side opposite to the condensing direction.

The second condensing lens 611b described above has a light distribution characteristic that condenses light toward the first end 60a, which is steeper than the rising edge of the lens surface. Therefore, the light emitted from the second condensing lens 611b is focused on the first end 60a side, and the amount of light distributed by the second condensing lens 611b to the first end 60a side is the second condensing lens 611b. The amount of light is greater than the amount of light distributed to the second end 60c side. That is, the condensing direction of the second condensing lens 611b is the direction toward the first end 60a in the longitudinal direction of the base 60.

Comparing the first condensing lens 611a and the second condensing lens 611b, the radius of curvature on the surface of the first condensing lens 611a on the side of the first end 60a is the first on the surface of the second condensing lens 611b. It is smaller than the radius of curvature on the end 60a side. That is, the rise of the surface of the first condenser lens 611a on the first end 60a side is steeper than the rise of the surface of the second condenser lens 611b on the first end 60a side. As a result, the condensing direction of the first condensing lens 611a is downward from the condensing direction of the second condensing lens 611b.

Next, the diffusion lens 612 has a convex shape protruding downward on the lower surface of the base 60, and is formed in a disk shape on the lower surface of the base 60. Further, above the second condenser lens 611b, a recess 6121 is formed on the upper surface of the base 60, and the second LED element 522 is housed in the recess 6121. The recess 6121 is formed in a chevron shape having a radius of curvature line-symmetrical when viewed from the lateral side of the base 60.

The diffuser lens 612 described above has a light distribution characteristic that diffuses light substantially evenly around the diffuser lens 612. Therefore, the light emitted by the second LED element 522 is diffused substantially evenly around the diffusion lens 612.

The first ends 51b of each of the two LED substrates 51 described above face each other. The condensing lens 611 of the lens block 6 provided on each of the two LED substrates 51 condenses light in the direction toward the first end 51b in a plan view. That is, of the two lens blocks 6, the condensing direction of the condensing lens 611 of one lens block 6 and the condensing direction of the condensing lens 611 of the other lens block 6 are the longitudinal directions of the LED substrate 51. In opposite directions. Therefore, the condensing lens 611 of the lens block 6 provided on each of the two LED substrates 51 condenses light in the direction toward the through hole 51d in a plan view.

Then, by attaching the above-mentioned lighting device 2 to the fixture main body 9, the lighting fixture 1 shown in FIGS. 11A and 11B is configured. The instrument body 9 has a cover 91, a frame 92, a glove 93, and a pair of light guide members 94.

A frame 92 is screwed to the lower surface of the case 3 of the lighting device 2. The frame 92 includes a rectangular frame-shaped main frame 92a and a reinforcing frame 92b that connects the centers of a pair of side frames along the longitudinal direction of the main frame 92a in the lateral direction. Then, the protrusion protruding upward at the longitudinal edge of the main frame 92a meshes with the positioning hole 51i of the LED substrate 51, so that the frame 92 is positioned with the LED substrate 51.

Further, the light guide members 94 are screwed to the pair of side frames along the longitudinal direction of the main frame 92a. As shown in FIGS. 1 and 2, the light guide member 94 has a light guide panel 94a, a guide portion 94b, and a plurality of (four in the illustrated example) mounting pieces 94c. The light guide panel 94a, the guide portion 94b, and the plurality of mounting pieces 94c are preferably formed of a translucent synthetic resin such as an acrylic resin or a polycarbonate resin. Then, the mounting piece 94c is screwed to the main frame 92a.

When the light guide member 94 is screwed to the main frame 92a, the LED element 53a is located above the guide portion 94b. The guide unit 94b has a reflector that reflects light, and the light emitted by the LED element 53a is guided into the light guide panel 94a through the guide unit 94b and emitted from the light guide panel 94a.

Further, of the two lens blocks 6, a square tubular body 325 is arranged on the upper surface of the translucent window 60d of one lens block 6, and the tubular body 325 has a notch 51f and a through hole 324. It is stored inside. The translucent window 60d of one lens block 6 faces the control circuit 44b of the power supply unit 4 via the tubular body 325. Specifically, the light-transmitting window 60d of one lens block 6 faces the LED element for the nightlight and the infrared light receiving element provided in the control circuit 44b. That is, the light emitted by the nightlight is radiated below the illuminating device 2 through the translucent window 60d. Further, the infrared light receiving element can receive an infrared signal transmitted from an infrared remote controller through the translucent window 60d. It is preferable that the lighting device 2 controls the lighting of the LED module 5 in response to a command included in the infrared signal received by the infrared light receiving element.

Further, a rectangular flat plate glove 93 is attached to the lower surface of the frame 92. The main frame 92a includes a fixture 95 on a side frame along the longitudinal direction. The glove 93 is formed of a translucent synthetic resin material such as acrylic into a rectangular box shape having an open upper surface, and is attached to the lower surface side of the frame 92 via a fixture 95. Further, the glove 93 has a diffusion structure for diffusing the light emitted from the lighting device 2. The diffusion structure is realized by, for example, a white coating film formed on the surface of the glove 93, a diffusing material mixed in the synthetic tree material forming the glove 93, or irregularities formed on the surface of the glove 93. Will be done. Since the glove 93 is provided with the diffusion structure in this way, the uniformity of the light radiated to the illumination space can be further improved.

A cover 91 is screwed to the upper surface of the case 3. The cover 91 is formed in a rectangular box shape with an opening on the lower surface, and has an opening 911 on the upper surface for exposing the recess 311. Further, a pair of elastic protective members 912 are provided on the upper surface of the cover 91.

In the present embodiment, the technical idea of the present invention is applied to a ceiling-mounted lighting fixture (so-called ceiling light). However, the lighting fixtures to which the technical idea of the present invention can be applied are not limited to ceiling lights, but can be used for hanging type (so-called pendant type) lighting fixtures, embedded lighting fixtures (so-called downlights), and the like. Is also applicable.

As described above, in the lighting device 2 of the first aspect according to the embodiment, the power supply device 42 for supplying load power to the LED module 5 (light source) to light the LED module 5 and the power supply device 42 are housed in the lighting device 2. The case 3 and the case 3 are provided. Inside the case 3, there is an insertion space 403 into which the hook sealing adapter 102 (feeding unit) that supplies input power from the outside to the power supply device 42 is inserted. The power supply device 42 has a first power supply board 431 and a second power supply board 441 housed in the case 3 with the insertion space 403 interposed therebetween. The first power supply board 431 includes a receptacle connector 430a (input connection portion) that receives the input voltage Vac from the hook sealing adapter 102, and a power factor improving circuit 43a that outputs the boosted voltage V1 that boosts the input voltage Vac to the second power supply board 441. (Boost circuit) is provided. The second power supply board 441 includes a step-down circuit 44a that outputs a load voltage V21-V24, which is a step-down of the step-up voltage V1, to the LED module 5.

In the above-mentioned lighting device 2, the first power supply board 431 is arranged in the first space 3a, and the second power supply board 441 is arranged in the second space 3b, so that the first power supply board 431 and the second power supply board 441 are combined. There is an insertion space 403 between them. Therefore, the insertion space 403 weakens the thermal coupling between the first power supply board 431 and the second power supply board 441 as compared with the case where the power supply device 42 is composed of one power supply board. As a result, the lighting device 2 can suppress a temperature rise (particularly a local temperature rise) due to heat generation of the power supply device 42.

Further, in the lighting device 2 of the second aspect according to the embodiment, in the first aspect, the second power supply board 441 further includes a power factor improving circuit 43a (boost circuit) and a control circuit 44b for controlling the step-down circuit 44a. It is preferable to prepare.

In the above-mentioned lighting device 2, the influence of noise on the control circuit 44b can be suppressed.

Further, in the lighting device 2 of the third aspect according to the embodiment, in the second aspect, of the first space 3a and the second space 3b located across the insertion space 403 in the case 3, the first space 3a The first power supply board 431 is housed in the space. Further, the second power supply board 441 is housed in the second space 3b. The first power supply board 431 is arranged closer to the insertion space 403 in the first space 3a, and the power factor improving circuit 43a (boost circuit) of the second power supply board 441 is closer to the insertion space 403 than the control circuit 44b. It is preferable that it is arranged in.

In the above-mentioned lighting device 2, the physical distance between the first power supply board 431 and the second power supply board 441 can be shortened. As a result, it is possible to suppress the influence of noise generated during the operation of the power supply device 42 on the voltage and electrical signals transmitted between the first power supply board 431 and the second power supply board 441. Further, since the control circuit 44b can be separated from the power factor improving circuit 43a as much as possible, the influence of the noise of the power factor improving circuit 43a on the control circuit 44b can be suppressed. Further, since the control circuit 44b can be separated from the insertion space 403 as much as possible, it is possible to suppress the influence of the noise generated from the hook sealing adapter 102, which is the feeding portion, on the control circuit 44b.

Further, in the lighting device 2 of the fourth aspect according to the embodiment, in any one of the first to third aspects, the case 3 is formed in a long shape. It is preferable that the first power supply board 431 is housed on one end side of the case 3 in the longitudinal direction, and the second power supply board 441 is housed on the other end side of the case 3 in the longitudinal direction.

In the above-mentioned lighting device 2, when the light emitting surface of the plurality of LED elements 52 has a long shape, it is possible to suppress a temperature rise (particularly a local temperature rise) due to heat generation of the power supply device 42.

Further, in the lighting device 2 of the fifth aspect according to the embodiment, in any one of the first to fourth aspects, the first power supply board 431 and the second power supply board 441 are electrically formed in a plate shape. It is preferably mounted on one mounting base 40 (insulating member) having an insulating property.

In the above-mentioned lighting device 2, the configuration of the lighting device 2 can be simplified as compared with the case where the first power supply board 431 and the second power supply board 441 are attached to separate insulating members.

Further, in the lighting device 2 of the sixth aspect according to the embodiment, in the fifth aspect, the mounting base 40 (insulating member) has a locking claw 407a, which holds the first power supply board 431 and the second power supply board 441. It is preferable to have 407b and 407c (board holding portion).

In the above-mentioned lighting device 2, the holding structures of the first power supply board 431 and the second power supply board 441 can be simplified.

Further, the luminaire 1 of the seventh aspect according to the embodiment includes the luminaire 2 of any one of the first to sixth embodiments and the luminaire main body 9 to which the luminaire 2 is attached.

The above-mentioned luminaire 1 can suppress a temperature rise (particularly a local temperature rise) due to heat generation of the power supply device 42.

1 Lighting equipment 2 Lighting equipment 3 Case 3a 1st space 3b 2nd space 4 Power supply unit 40 Mounting base (insulating member)
403 Insertion space 407a Locking claw (board holding part)
407b Locking claw (board holding part)
407c locking claw (board holding part)
42 Power supply unit 43 1st circuit block 43a Power factor improvement circuit (boost circuit)
430a Receptacle connector (input connection)
431 1st power supply board 44 2nd circuit block 44a Step-down circuit 44b Control circuit 441 2nd power supply board 5 LED module (light source)
9 Instrument body 102 Hook sealing adapter (power supply unit)
Vac Input voltage Vr Rectifier voltage V1 Boost voltage V21-V24 Load voltage

Claims (5)

A power supply that supplies load power to the light source and turns on the light source,
A case for storing the power supply device is provided.
Inside the case, there is an insertion space into which a power supply unit that supplies input power from the outside is inserted into the power supply device.
The power supply device has a first power supply board and a second power supply board housed in the case with the insertion space interposed therebetween.
The first power supply board includes an input connection unit that receives an input voltage from the power supply unit, and a booster circuit that outputs a boosted voltage obtained by boosting the input voltage to the second power supply board.
The second power supply board includes a step-down circuit that outputs a load voltage obtained by stepping down the step-up voltage to the light source, and a control circuit that controls the step-up circuit and the step-down circuit .
Of the first space and the second space located across the insertion space in the case, the first power supply board is housed in the first space, and the second power supply board is housed in the second space. Has been
The first power supply board is arranged closer to the insertion space in the first space, and the second power supply board is arranged so that the step-down circuit is closer to the insertion space than the control circuit. Lighting device. The case is formed in a long shape and has a long shape.
The first power supply board is housed on one end side in the longitudinal direction of the case.
The second power supply board is housed on the other end side in the longitudinal direction of the case.
The lighting device according to claim 1. The lighting device according to claim 1 or 2, wherein the first power supply board and the second power supply board are attached to one insulating member having electrical insulation formed in a plate shape. The lighting device according to claim 3, wherein the insulating member has a substrate holding portion for holding the first power supply board and the second power supply board. A luminaire comprising the illuminating device according to any one of claims 1 to 4 and an appliance main body to which the illuminating device is attached.

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