JP2013247032A - Lighting fixture - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lighting fixture capable of preventing failure and shorter life of a lamp and a lighting-up device caused by output voltage rise by surely stopping an operation of the lighting-up device when the lamp is not connected.SOLUTION: A socket (lamp connection section) 12 is connected with the lamp 90. The lighting-up device built in a body 11 supplies power for lighting up the lamp 90 to the lamp 90 connected with the socket 12. A lamp holding section 13 having a holding condition and a releasing condition holds the lamp 90 in a non-detachable state during the holding condition, and detachably holds the lamp 90 during the releasing condition. The lighting-up device can operate when the lamp holding section 13 is under the holding condition, and stops the operation when the lamp holding section 13 is under the releasing condition.

Description

  The present invention relates to a lighting fixture to which a lamp can be attached and detached.

There is a lighting fixture that is lit by connecting a lamp (light source device) having a light source such as an LED. Some lighting devices for lighting fixtures that light a light source such as an LED operate (constant current operation) so that an output current matches a predetermined target current.
When the lighting device operates at a constant current in a state where the lamp is not connected, the output voltage may become abnormally high in an attempt to match the output current with the target current.
For this reason, there is a technique for detecting whether or not the lamp is electrically connected and stopping the operation of the lighting device when the lamp is not connected. If the lamp is removed while the lamp is connected and lit, it is detected that the lamp is not connected and the lighting device stops operating.

JP 2010-192229 A JP 2010-55824 A

  When a smoothing capacitor is connected to the output stage of the lighting device, the smoothing capacitor may be charged and the output voltage of the lighting device may rise after the lamp is removed and before the lighting device stops operating. . Then, after a certain amount of time, the smoothing capacitor discharges and the output voltage decreases, but when the lamp is immediately reconnected, the increased output voltage is applied to the lamp, and an overcurrent flows, causing the lamp and In some cases, the lighting device may fail or its life may be shortened.

  An object of the present invention is to prevent a lamp or a lighting device from being damaged or shortened due to an increase in output voltage by reliably stopping the operation of the lighting device when a lamp is not connected, for example.

  The luminaire according to the present invention includes a lamp connecting portion that connects a lamp, a lighting device that supplies power for lighting the lamp to the lamp connected to the lamp connecting portion, and a lamp connected to the lamp connecting portion. A lamp holding portion having a holding state in which the lamp is held in a non-detachable manner and a release state in which the lamp is detachable at the lamp connecting portion, and the lighting device has the lamp holding portion in the holding state. The operation is stopped when the lamp holding portion is in the released state.

  According to the lighting apparatus according to the present invention, when the lamp is not connected, the operation of the lighting device is surely stopped, so that the failure of the lamp and the lighting device due to the increase of the output voltage and the shortening of the life can be prevented.

FIG. 3 is a perspective view illustrating an appearance of the lighting fixture 10 according to the first embodiment. FIG. 3 is a perspective view showing when the lamp 90 of the lighting fixture 10 in Embodiment 1 is replaced. FIG. 3 is a front sectional view showing the structure of the lamp holding unit 13 according to the first embodiment. FIG. 3 is a front sectional view showing a holding state of the lamp holding unit 13 according to the first embodiment. FIG. 3 is a circuit diagram illustrating circuit configurations of the lighting fixture 10 and the lamp 90 in the first embodiment. FIG. 3 is a flowchart showing the operation of the lighting fixture 10 in the first embodiment. FIG. 9 is a side sectional view showing the structure of the lamp holding unit 13 according to the second embodiment. FIG. 6 is a front view showing the structure of a lamp 90 in the third embodiment. FIG. 10 is a front view showing the structure of the socket 12 in the third embodiment. FIG. 6 is a front view showing the structure of a rotating unit 24 in the third embodiment. FIG. 6 is a front view and a cross-sectional view showing the structure of the socket body 21 in the third embodiment. FIG. 6 is a front view showing the structure of the lamp holding unit 13 according to the third embodiment. FIG. 10 is a diagram showing the movement of the socket 12 in the third embodiment. FIG. 7 is a front cross-sectional view showing the structure of a socket 12 and a lamp holding part 13 in a fourth embodiment. FIG. 7 is a front cross-sectional view showing the structure of a socket 12 and a lamp holding part 13 in a fourth embodiment.

Embodiment 1 FIG.
The first embodiment will be described with reference to FIGS.

  FIG. 1 is a perspective view showing an external appearance of a lighting fixture 10 in this embodiment.

  The luminaire 10 is used with a replaceable lamp 90 attached. The luminaire 10 includes, for example, a main body 11, a socket 12, and a lamp holding unit 13. The main body 11 incorporates a lighting device, for example. The socket 12 (lamp connection portion) fixes the lamp 90 so as to be detachable. The lamp holding unit 13 holds the lamp 90.

  In this example, the lamp 90 has a straight tube shape. There are two sockets 12, which engage with bases provided at both ends of the lamp 90. One of the two sockets 12 has a power supply terminal that supplies power to the lamp 90. The power supply terminal is movable in the axial direction of the lamp 90, and is pressed against the base pin (terminal portion) of the lamp 90 by an elastic body such as a spring. The lamp holding part 13 is U-shaped and holds a light emitting part provided at the center of the lamp 90. The lamp holding unit 13 is provided on the side farther from the socket 12 having the power feeding terminal than the center in the longitudinal direction of the lamp 90.

  FIG. 2 is a perspective view showing the lamp 90 of the luminaire 10 in this embodiment when the lamp 90 is replaced.

For example, the lamp holding portion 13 is provided to be slidable in the vertical direction. The lamp holder 13 is provided with a lock mechanism that restricts sliding.
When removing the lamp holder 13, first, the lock mechanism of the lamp holder 13 is released, and the lamp holder 13 is slid downward (in the released state). As a result, there is a space in which the lamp 90 can be moved as shown in FIG. Thereafter, the lamp 90 is pushed into the socket 12 having the power supply terminal to release the engagement between the socket 12 on the opposite side and the base of the lamp 90, and the lamp 90 is removed.
When the lamp holder 13 is attached, the lamp 90 is passed through the lamp holder 13 at the position shown in this figure, and the socket 12 having the power supply terminal and the base of the lamp 90 are engaged. Next, the lamp 90 is pushed into the socket 12 having the power supply terminal, and the socket 12 on the opposite side and the base of the lamp 90 are engaged. Thereafter, the lamp holder 13 is slid upward to the position shown in FIG. The lock mechanism works to limit the sliding of the lamp holding portion 13 (holding state). Thus, the lamp 90 cannot be removed unless the lock mechanism is released. The lock mechanism may be a structure that is automatically set, or may be a structure that is manually set.

  FIG. 3 is a front sectional view showing the structure of the lamp holding portion 13 in this embodiment.

  For example, three slits 112 to 114 are provided in the main body 11. A switch 14 is provided inside the main body 11. The switch 14 includes, for example, a switch body 41 and a push button 42. The switch body 41 is fixed to the body 11. The switch 14 is turned on by pressing the push button 42.

The lamp holding part 13 (light source detection part) has, for example, a sliding part 31 and a locking part 32.
The sliding part 31 is, for example, a plate shape bent into a substantially U shape. The sliding part 31 has, for example, a body part 311 and two arm parts 312 and 313. Each of the arm portions 312 and 313 has two retaining portions 314 and 315 and two shoulder portions 316 and 317.
The locking part 32 includes, for example, a locking plate part 321 and an operation part 324. The locking plate portion 321 has, for example, a rectangular plate shape. The locking plate portion 321 has two slits 322 and 323. The operation unit 324 passes through the slit 114 and is exposed to the outside of the main body 11. A force is applied to the locking plate portion 321 in the direction of the arrow 328 by an elastic body such as a spring (not shown).

  The body portion 311 has a semi-cylindrical side shape. The two arm portions 312 and 313 are provided symmetrically on the left and right sides of the body portion 311. The arm 312 is inserted through the slits 112 and 322. The arm portion 313 is inserted through the slits 113 and 323. The retaining portions 314 and 315 are provided at the tips of the arm portions 312 and 313, respectively. The retaining portions 314 and 315 prevent the arm portions 312 and 313 from falling off the slits 112, 113, 322 and 323. The shoulder portions 316 and 317 are provided in the middle of the arm portions 312 and 313. The arm portions 312 and 313 are wider at the portion ahead of the shoulder portions 316 and 317, and the width of the portion closer to the body portion 311 than the shoulder portions 316 and 317 is narrower.

  FIG. 4 is a front sectional view showing a holding state of the lamp holding portion 13 in this embodiment.

When the sliding portion 31 is slid upward until the shoulder portions 316 and 317 are above the slits 112, 113, 322 and 323, the locking portion 32 moves in the direction of the arrow 328. Thereby, the positions of the slits 112 and 113 are shifted from the positions of the slits 322 and 323. The shoulder portion 316 is caught by the main body 11 and the shoulder portion 317 is caught by the locking plate portion 321, so that the sliding portion 31 cannot be slid downward. The end of the locking plate portion 321 pushes the push button 42, and the switch 14 becomes conductive.
To release the locked state, the operation unit 324 is operated to align the positions of the slits 112 and 113 with the positions of the slits 322 and 323. Thereby, the sliding part 31 can be slid downward.

  FIG. 5 is a circuit diagram showing circuit configurations of the lighting fixture 10 and the lamp 90 in this embodiment.

The lamp 90 includes, for example, a light source circuit 91, a connection detection circuit 92, and a connection unit 93.
The connection unit 93 is electrically connected to the lighting fixture 10 and inputs power supplied from the lighting fixture 10. The connection part 93 has two base pins 931 and 932, for example.
The light source circuit 91 is a circuit in which a plurality of light source elements 911 are electrically connected in series, for example. The light source element 911 is, for example, an LED. The light source circuit 91 is electrically connected between the two cap pins 931 and 932.
The connection detection circuit 92 is a circuit for the lighting apparatus 10 to detect that the lamp 90 is connected. The connection detection circuit 92 includes, for example, a connection detection resistor 921. The connection detection resistor 921 is electrically connected in parallel with the light source circuit 91 between the two base pins 931 and 932.

The luminaire 10 includes, for example, a power supply circuit 15, a lighting device 16, and a connection unit 17.
The connection unit 17 is electrically connected to the connection unit 93 of the lamp 90 and outputs power supplied to the lamp 90. For example, the connection unit 17 includes two power supply terminals 171 and 172.
The power supply circuit 15 outputs DC power. For example, the power supply circuit 15 receives power from an external power supply such as a commercial power supply, and converts the input power to DC power.
The lighting device 16 converts the DC power output from the power supply circuit 15 into DC power supplied to the lamp 90. For example, the lighting device 16 adjusts the power supplied to the lamp 90 so that the current flowing through the light source circuit 91 matches a predetermined target current. The lighting device 16 includes, for example, a DC / DC conversion circuit 61, a control circuit 62, a current detection resistor 63, a holding detection circuit 64, and a connection detection circuit 65.

The DC / DC conversion circuit 61 is a main part of the lighting device 16. The DC / DC conversion circuit 61 converts DC power into DC power having a different voltage value. The DC / DC conversion circuit 61 is, for example, a buck converter circuit having a switching element 611, a rectifying element 612, a choke coil 613, and a smoothing capacitor 614. The switching element 611 is, for example, an enhancement type nMOSFET.
The control circuit 62 operates the DC / DC conversion circuit 61 by turning on and off the switching element 611 at a high frequency.
The current detection resistor 63 is a circuit for detecting the current output from the lighting device 16 (current flowing through the light source circuit 91). The control circuit 62 detects the current output from the lighting device 16 based on the voltage across the current detection resistor 63.

The holding detection circuit 64 (detection unit) is a circuit for detecting the state of the switch 14. The holding detection circuit 64 includes, for example, two voltage dividing resistors 641 and 642 and the switch 14. The two voltage dividing resistors 641 and 642 are electrically connected in series with each other and electrically connected to the output of the power supply circuit 15. The switch 14 is electrically connected in parallel with the voltage dividing resistor 642. The control circuit 62 detects the state of the switch 14 based on the voltage across the voltage dividing resistor 642.
When the lamp holding unit 13 is in the holding state, the switch 14 is turned on. When the switch 14 is turned on, the voltage across the voltage dividing resistor 642 becomes almost zero. When the switch 14 is not conductive, the voltage across the voltage dividing resistor 642 is a voltage obtained by dividing the output voltage of the power supply circuit 15 by the voltage dividing ratio of the voltage dividing resistors 641 and 642. Thereby, the control circuit 62 detects whether the lamp holding unit 13 is in the holding state or in the released state.

The connection detection circuit 65 is a circuit for detecting whether or not the lamp 90 is electrically connected. The connection detection circuit 65 includes, for example, two resistors 651 and 653 and a rectifying element 652.
The resistor 651 and the rectifier element 652 are electrically connected in series with each other, for example, in parallel with the switching element 611. The resistor 653 is electrically connected in parallel with the smoothing capacitor 614 between the two power supply terminals 171 and 172.
Even when the control circuit 62 continuously turns off the switching element 611 and stops the operation of the DC / DC conversion circuit 61, the resistor 651 and the rectifying element 652 are electrically connected in parallel with the switching element 611. Therefore, there is a current that flows through the resistor 651 and the rectifying element 652. This current flows through the choke coil 613, the resistor 653, and the current detection resistor 63. In the case where the lamp 90 is not connected, a current obtained by dividing the output voltage of the power supply circuit 15 by the combined resistance value of the resistor 651, the resistor 653, and the current detection resistor 63 flows. When the lamp 90 is connected, the connection detection resistor 921 is electrically connected in parallel with the resistor 653, so that the combined resistance value is reduced and the flowing current is increased. The control circuit 62 detects whether or not the lamp 90 is connected by detecting this current based on the voltage across the current detection resistor 63.
The values of the resistors 651 and 653 are set such that the voltage across the resistor 653 is lower than the lighting voltage of the lamp 90 when the DC / DC conversion circuit 61 stops operating. The values of the resistors 651 and 653 are set so that the current flowing when the DC / DC conversion circuit 61 stops operating is sufficiently smaller than the current flowing through the light source circuit 91 when the lamp 90 is lit. To do.

  FIG. 6 is a flowchart showing the operation of the lighting fixture 10 in this embodiment.

  In the lighting process 620, the luminaire 10 lights the connected lamp 90. The lighting process 620 includes, for example, a holding determination process 621, a connection determination process 622, a lighting process 623, and a turn-off process 624.

In the holding determination step 621, the control circuit 62 determines the state of the lamp holding unit 13. When the lamp holding unit 13 is in the holding state, the control circuit 62 advances the process to the connection determination step 622. When the lamp holding unit 13 is in the released state, the control circuit 62 proceeds to the extinguishing step 624.
In the connection determination step 622, the control circuit 62 determines whether or not the lamp 90 is electrically connected. If the lamp 90 is electrically connected, the control circuit 62 proceeds to the lighting process 623. If the lamp 90 is not electrically connected, the control circuit 62 proceeds to the extinguishing step 624.
In the lighting process 623, the control circuit 62 operates the DC / DC conversion circuit 61 to light the lamp 90. The control circuit 62 returns the processing to the holding determination step 621 and determines the state of the lamp holding unit 13.
In the light extinction step 624, the control circuit 62 stops the operation of the DC / DC conversion circuit 61 and turns off the lamp 90. The control circuit 62 returns the processing to the holding determination step 621 and determines the state of the lamp holding unit 13.

When the lamp 90 is not connected, the control circuit 62 stops the operation of the DC / DC conversion circuit 61 regardless of the state of the lamp holding unit 13.
In order to attach the lamp 90, the lamp holder 13 needs to be in a released state. For this reason, the control circuit 62 stops the operation of the DC / DC conversion circuit 61. Even if the connecting portion 93 and the connecting portion 17 are in contact with each other and electrically connected, the control circuit 62 remains stopped as long as the lamp holding portion 13 is in the released state. After the lamp 90 is connected and the lamp holding unit 13 is in the holding state, the control circuit 62 operates the DC / DC conversion circuit 61.

In order to remove the lamp 90, it is necessary to release the lamp holder 13 again. Even when the lamp holder 13 is held, the power supply terminal of the socket 12 moves, so that the lamp 90 can be moved in the axial direction. However, since the force that presses against the cap pin is applied to the power supply terminal, the lamp 90 and the lighting fixture 10 are kept in an electrically connected state.
When the lamp holding unit 13 is released to remove the lamp 90, the control circuit 62 stops the operation of the DC / DC conversion circuit 61. Therefore, when the electrical connection between the connection portion 93 and the connection portion 17 is released, the DC-DC conversion circuit 61 reliably stops its operation.

  In this way, when the lamp 90 is electrically connected to the lighting fixture 10 and when the electrical connection between the lamp 90 and the lighting fixture 10 is released, the operation of the DC / DC conversion circuit 61 is stopped. It is possible to ensure the safety of the installation / removal work. In addition, it is possible to prevent an overvoltage from being applied to the lamp 90 and the lamp 90 and the lighting device 16 from being damaged or shortened.

For comparison, consider a case where the electrical connection between the lamp 90 and the lighting fixture 10 is released while the DC / DC conversion circuit 61 is operating.
In this case, since there is no current flowing through the light source circuit 91, the control circuit 62 increases the output voltage of the lighting device 16 in order to match the current output from the lighting device 16 with the target current. Thereafter, the control circuit 62 detects that the lamp 90 has been removed by some means, and stops the operation of the light source circuit 91.
For this reason, immediately after the electrical connection between the lamp 90 and the lighting fixture 10 is released, the output voltage of the lighting device 16 may be higher than that during lighting. In this state, when the lamp 90 is reconnected, a voltage higher than that at the time of lighting is applied to the lamp 90.

  On the other hand, in the lighting fixture 10 in this embodiment, the operation of the DC / DC conversion circuit 61 is stopped and then the electrical connection between the lamp 90 and the lighting fixture 10 is released, so that the output voltage of the lighting device 16 is turned on. It will never be higher than time. Therefore, even when the lamp 90 is immediately reconnected, it is possible to prevent an overvoltage from being applied to the lamp 90.

  Note that the body portion 311 of the sliding portion 31 may be formed of a transparent material such as a resin so as not to block light emitted from the lamp 90. Or the lamp | ramp holding | maintenance part 13 may be linear or mesh | network formed, for example with the metal.

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

  The appearance of the lighting fixture 10 in this embodiment is the same as that in the first embodiment.

  FIG. 7 is a side sectional view showing the structure of the lamp holding part 13 in this embodiment.

The reflection surface 117 is a surface of the main body 11 (instrument structure) on the lamp 90 (light source device) side. Note that the surface of the main body 11 on the lamp 90 side may not be the reflecting surface 117. The support part 133 attaches and holds the lamp holding part 13 to the main body 11. The operating unit 131 turns the switch 14 on and off. The support portion 133 and the operation portion 131 are fixed and held so as to push down the switch 14 when the lamp 90 is mounted on the main body 11.
The switch 14 (presence detection switch) is, for example, a micro switch. The micro switch includes, for example, an actuator and a built-in switch. The built-in switch is turned on by depressing the actuator. The built-in switch is turned off by releasing the actuator.

  As in the first embodiment, when the switch 14 is off, the control circuit 62 stops the operation of the DC / DC conversion circuit 61. The control circuit 62 operates the DC / DC conversion circuit 61 only when the switch 14 is ON and the connection detection circuit 65 detects that the lamp 90 is electrically connected.

Thereby, when the lamp 90 (light source device) is removed, the output voltage of the DC / DC conversion circuit 61 (light source lighting device) rises unnecessarily, and electrical stress is applied to the lamp 90 and the DC / DC conversion circuit 61 when the lamp 90 is remounted. Can be prevented.
When the lamp 90 is electrically disconnected from the DC / DC converter circuit 61, the power supply from the DC / DC converter circuit 61 to the lamp 90 is stopped in advance, so that the lamp 90 can be safely attached and detached.

Embodiment 3 FIG.
A third embodiment will be described with reference to FIGS.
Note that portions common to Embodiment 1 or Embodiment 2 are denoted by the same reference numerals and description thereof is omitted.

  FIG. 8 is a front view showing the structure of the lamp 90 in this embodiment.

The lamp 90 has, for example, a GX16t-5 type base defined in Japanese Industrial Standard (JIS) C7709-1. The lamp 90 includes, for example, a light emitting unit 94 and two base units 95 and 96. In addition, since the light emission part 94 is elongate shape, the intermediate part is abbreviate | omitted.
The light emitting unit 94 has, for example, a substantially cylindrical shape. The light emitting unit 94 includes, for example, a transparent or translucent cover and a plurality of light source elements 911 (not shown) arranged inside thereof.
The base part 95 is a base on the power input side. The base part 95 includes, for example, an end face part 951, a convex part 952, and two base pins 931 and 932. The end surface portion 951 is circular, for example. The convex portion 952 projects in the longitudinal direction of the lamp 90 along the diameter of the end surface portion 951. The cap pins 931 and 932 further protrude in the longitudinal direction of the lamp 90 from the convex portion 952, and the tips are bent outward.
The base part 96 is a base opposite to the base part 95. The base part 96 includes, for example, an end surface part 961, a shaft part 966, and a tip part 967. The end surface part 961 is circular, for example. The shaft portion 966 protrudes from the approximate center of the end surface portion 961 in the longitudinal direction of the lamp 90. The shaft portion 966 has a columnar shape, for example. The distal end portion 967 is provided at the distal end of the shaft portion 966. The distal end portion 967 has, for example, an oval shape.

  FIG. 9 is a front view showing the structure of the socket 12 in this embodiment.

  The socket 12 shown in this figure is the socket 12 on the side that engages with the base portion 95 of the lamp 90 out of the two sockets 12 of the lighting fixture 10. The socket 12 includes, for example, a socket body 21, a rotating unit 24, and a lamp holding unit 13. The socket body 21 is fixed to the body 11. The rotating part 24 is arranged in the socket body 21. The rotating part 24 engages with the base part 95 of the lamp 90 and rotates around the axis of the lamp 90 together with the lamp 90. The lamp holding unit 13 limits the rotation of the lamp 90 by limiting the rotation of the rotating unit 24 in the holding state.

  FIG. 10 is a front view showing the structure of the rotating unit 24 in this embodiment.

The rotating part 24 includes, for example, a disk part 241, two convex parts 251 and 252, and two locking protrusions 261 and 262.
The disc part 241 has, for example, a substantially disc shape. The disc part 241 has two pin insertion holes 242 and 243. The pin insertion holes 242 and 243 are through holes for inserting the cap pins 931 and 932 of the lamp 90.
The convex portions 251 and 252 are substantially semi-disc-shaped projections provided on the surface of the disc portion 241 (on the side in contact with the end surface portion 951 and the convex portion 952 of the lamp 90). The convex portion 952 of the lamp 90 is engaged between the two convex portions 251 and 252.
The locking protrusions 261 and 262 are protrusions provided on the back side surface of the disc portion 241. The locking projection 261 and the locking projection 262 are in contact with the lamp holding unit 13 to limit the rotation of the rotating unit 24.

  FIG. 11 is a front view and a cross-sectional view showing the structure of the socket body 21 in this embodiment.

The socket body 21 includes, for example, an outer surface portion 211, an inner surface portion 212, two side surface portions 213 and 214, a lower surface portion 215, a cylindrical portion 221, a support portion 223, and two contact portions 224 and 225. Two power supply terminals 171 and 172 are provided.
The outer surface portion 211 is a surface on the outer side (opposite side of the lamp 90) of the socket body 21. The outer surface portion 211 is, for example, a plate shape in which a semicircle and a rectangle are combined.
The inner surface portion 212 is a surface on the inner side (the lamp 90 side) of the socket body 21. The inner surface portion 212 is substantially parallel to the outer surface portion 211. The inner surface portion 212 has the same shape as the outer surface portion 211, for example, but has a substantially circular opening at the center and is cut off at the lower side.
The side surface parts 213 and 214, the lower surface part 215, and the cylindrical part 221 are substantially perpendicular to the outer surface part 211 and the inner surface part 212. The side surface portion 213 has, for example, a rectangular plate shape, and connects the right end of the outer surface portion 211 and the left end of the inner surface portion 212. The side surface portion 214 has, for example, a rectangular plate shape, and connects the left end of the outer surface portion 211 and the right end of the inner surface portion 212. The lower surface portion 215 has, for example, a semi-cylindrical plate shape, and connects the lower end of the outer surface portion 211 and the lower end of the inner surface portion 212. The lower surface part 215 has a through hole 216. The cylindrical portion 221 has, for example, a semi-cylindrical plate shape and is continuous with the lower surface portion 215 to form a cylinder as a whole. The cylindrical portion 221 has a notch 222.
The support portion 223 and the contact portions 224 and 225 are provided inside the outer surface portion 211. The support part 223 supports the lamp holding part 13 so as to be slidable in the vertical direction. The abutting portions 224 and 225 abut against the locking protrusions 261 and 262 of the rotating portion 24 and restrict the rotation of the rotating portion 24.

  FIG. 12 is a front view showing the structure of the lamp holder 13 in this embodiment.

The lamp holding part 13 includes, for example, two locking parts 33 and 34, a shaft part 35, and an operation part 36. The locking portion 33 has, for example, a substantially pentagonal prism shape in which a tapered portion 331 is formed by cutting out a part of a rectangular parallelepiped. A switch 14 is provided on the side of the locking portion 33 opposite to the tapered portion 331.
The switch 14 is movable up and down. The switch 14 is in a steady position on the lower side, and enters a conductive state when it is tilted upward by applying some force.
The locking portion 34 has, for example, a substantially pentagonal prism shape in which a tapered portion 341 in which a part of a rectangular parallelepiped is cut out is formed. The tapered portion 341 is provided on the opposite side of the locking portion 33 from the tapered portion 331 and on the same side as the switch 14.
The shaft portion 35 has, for example, a substantially square column shape, and connects between the locking portion 33 and the locking portion 34. The operation portion 36 extends downward from the locking portion 34 as an extension of the shaft portion 35. The distal end of the operation portion 36 protrudes out of the socket body 21 from the through hole 216 of the lower surface portion 215.

  FIG. 13 is a diagram showing the movement of the socket 12 in this embodiment.

  In addition, since the detailed code | symbol was abbreviate | omitted, please refer to FIGS.

In order to connect the lamp 90 to the socket 12, first, the rotating portion 24 is set so that the pin insertion holes 242 and 243 are arranged substantially vertically. After the base 96 is engaged with the opposite socket 12 (not shown), the base pins 931 and 932 are inserted into the pin insertion holes 242 and 243. Thereby, when the base part 95 and the rotating part 24 are engaged and the lamp 90 is rotated about the axial direction of the lamp 90, the rotating part 24 rotates together with the rotating part 24.
The locking projection 261 contacts the tapered portion 331 of the locking portion 33, and the locking projection 262 contacts the tapered portion 341 of the locking portion 34 to move the lamp holding portion 13 upward.
When the rotating unit 24 rotates about 90 degrees, the cap pins 931 and 932 engage with the power supply terminals 171 and 172 to be electrically connected. When the locking protrusions 261 and 262 pass under the locking portions 33 and 34, the lamp holding portion 13 moves downward due to gravity. When the switch 14 comes into contact with the locking projection 261, the switch 14 falls upward, and the switch 14 becomes conductive.

  Thus, after the base pins 931 and 932 and the power supply terminals 171 and 172 are electrically connected, the switch 14 becomes conductive. As in the first embodiment, the control circuit 62 does not operate the DC / DC conversion circuit 61 unless the switch 14 is in a conductive state. Therefore, before the base pins 931 and 932 and the power supply terminals 171 and 172 are electrically connected. In addition, the DC / DC conversion circuit 61 does not start to operate.

  In order to remove the lamp 90 from the socket 12, first, the lamp holding unit 13 is moved upward by pushing the operation unit 36. The switch 14 becomes non-conductive, and the control circuit 62 stops the operation of the DC / DC conversion circuit 61. Thereafter, the rotating unit 24 is rotated by about 90 degrees in the direction opposite to that at the time of attachment, and the lamp 90 is removed in the reverse order of the attachment.

  The DC / DC converter circuit 61 stops operating before the electrical connection between the cap pins 931 and 932 and the power supply terminals 171 and 172 is released, so that the output voltage of the DC / DC converter circuit 61 becomes higher than that during lighting. Can be prevented.

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

  As in the third embodiment, the lamp 90 in this embodiment has a structure that is electrically connected to the DC / DC converter circuit 61 by being engaged with the socket 12 and then rotated.

  FIG. 14 is a front sectional view showing the structure of the socket 12 and the lamp holding portion 13 in this embodiment.

The socket 12 inserts the base pins 931 and 932 of the lamp 90 into the positions shown in this figure, and rotates the lamp 90 about 90 degrees around the axial direction of the lamp 90 to thereby form the base pins 931 and 932. The power supply terminals 171 and 172 are electrically connected.
The lamp holding part 13 is provided so as to be movable in the axial direction of the lamp 90. The lamp holding unit 13 includes an operating unit 131 and a locking unit 132. The operating unit 131 turns the switch 14 on and off. The locking part 132 limits the rotation of the lamp 90.

  FIG. 15 is a front sectional view showing the structure of the socket 12 and the lamp holding portion 13 in this embodiment.

  When the lamp 90 is rotated and the base pins 931 and 932 are electrically connected to the power supply terminals 171 and 172 and then the lamp holding portion 13 is pushed in, the locking portion 132 protrudes into the socket 12, and the lamp Prevent 90 rotations. Further, the operating part 131 pushes the switch 14 and the switch 14 is turned on.

  As in the first embodiment, when the switch 14 is off, the control circuit 62 stops the operation of the DC / DC conversion circuit 61. The control circuit 62 operates the DC / DC conversion circuit 61 only when the switch 14 is ON and the connection detection circuit 65 detects that the lamp 90 is electrically connected.

  When removing the lamp 90, first, the lamp holder 13 is pulled back to the position shown in FIG. Thereby, the switch 14 is turned off. Since the lamp 90 can be rotated, the electrical connection between the cap pins 931 and 932 and the power supply terminals 171 and 172 is released when the lamp 90 is rotated.

Thereby, when the lamp 90 (light source device) is removed, the output voltage of the DC / DC conversion circuit 61 (light source lighting device) rises unnecessarily, and electrical stress is applied to the lamp 90 and the DC / DC conversion circuit 61 when the lamp 90 is remounted. Can be prevented.
When the lamp 90 is electrically disconnected from the DC / DC converter circuit 61, the power supply from the DC / DC converter circuit 61 to the lamp 90 is stopped in advance, so that the lamp 90 can be safely attached and detached.

  As described above, the configuration described in each embodiment is an example, and another configuration may be used. For example, the structure which combined the structure demonstrated in different embodiment may be sufficient, and the structure which replaced the structure of the non-essential part with the other structure may be sufficient.

  The luminaire 10 includes a DC / DC conversion circuit 61 (LED current supply device), a lamp holding unit 13 (light source detection unit), and a connection detection circuit 65 (connection determination unit). The lighting device 16 supplies a current to a lamp 90 (light source) using an LED or the like. The lamp holding unit 13 physically detects the presence / absence of the lamp 90. The connection detection circuit 65 electrically determines whether or not the lamp 90 is connected. In order to remove the lamp 90, the lamp holder 13 needs to be released. When the lamp holding unit 13 is released, the lighting device 16 stops power supply to the lamp 90 regardless of the connection state of the lamp 90. Further, when the lamp 90 is removed, the connection detection circuit 65 determines that there is no load, and the lighting device 16 stops supplying power to the lamp 90 regardless of the state of the lamp holding unit 13. Only when the connection detection circuit 65 determines that the lamp holding unit 13 is in an operating state and there is a load, the lighting device 16 performs the lighting operation of the lamp 90.

For example, when the lamp holding unit 13 is released while the lamp 90 is lit, the lighting device 16 stops supplying current to the lamp 90, so that the lamp 90 is turned off. After the lamp 90 has already been turned off, the lamp 90 is actually removed.
Conversely, when the lamp 90 is attached, the lamp 90 is first attached. If the lamp holding unit 13 remains released, the lighting device 16 does not supply current, and the lamp 90 remains off. Next, when the lamp holding unit 13 is operated, the lighting device 16 supplies a current to the lamp 90 and the lamp 90 is lit.

  In this manner, the attachment and detachment of the lamp 90 with respect to the lamp 90 and the lighting device 16 is stopped by stopping the supply of current to the lamp 90 before the connection detection circuit 65 electrically detects the removal of the lamp 90. It is possible to prevent stress due to an excessive current caused by.

As described above, the lighting device 16 does not operate unless the lamp holding unit 13 is in the holding state. The lamp holding unit 13 has a structure that cannot be brought into a holding state unless the lighting device 16 and the lamp 90 are electrically connected. Therefore, the lighting device 16 does not operate unless the lamp 90 is electrically connected.
In addition, the lamp holding unit 13 has a structure in which the electrical connection between the lighting device 16 and the lamp 90 cannot be released unless the lamp holding unit 13 is released. The lighting device 16 stops its operation when the lamp holding unit 13 is released. Therefore, when the electrical connection between the lighting device 16 and the lamp 90 is released, the operation of the lighting device 16 is reliably stopped.

  DESCRIPTION OF SYMBOLS 10 Lighting fixture, 11 Main body, 112-114,322,323 slit, 117 reflecting surface, 12 socket, 13 Lamp holding part, 131 Actuating part, 132,32,33,34 Locking part, 133,223 Support part, 14 Switch, 15 Power supply circuit, 16 Lighting device, 17, 93 Connection part, 171, 172 Feeding terminal, 21 Socket body, 211 Outer part, 212 Inner part, 213, 214 Side part, 215 Lower surface part, 216 Through hole, 221 Cylindrical Part, 222 notch part, 224,225 contact part, 24 rotating part, 241 disc part, 242,243 pin insertion hole, 251,252,952 convex part, 261,262 locking projection, 31 sliding part, 311 Body part, 312,313 Arm part, 314,315 Stopping part, 316,317 Shoulder part, 321 Locking plate part, 324 36 operation part, 328 arrow, 331 taper part, 341 taper part, 35,966 shaft part, 41 switch body, 42 push button, 61 DC / DC conversion circuit, 611 switching element, 612, 652 rectifier element, 613 choke coil, 614 Smoothing capacitor, 62 control circuit, 620 lighting process, 621 holding determination process, 622 connection determination process, 623 lighting process, 624 extinguishing process, 63 current detection resistor, 64 holding detection circuit, 641, 642 voltage dividing resistor, 65, 92 connection Detection circuit, 651, 653 resistance, 90 lamp, 91 light source circuit, 911 light source element, 921 connection detection resistance, 931, 932 base pin, 94 light emitting part, 95, 96 base part, 951, 961 end face part, 967 tip part.

Claims (5)

A lamp connection for connecting the lamp;
A lighting device for supplying power for lighting the lamp to the lamp connected to the lamp connection unit;
A lamp holding portion having a holding state in which the lamp connected to the lamp connecting portion is detachably held; and a release state in which the lamp is detachable from the lamp connecting portion;
The lighting device operates when the lamp holding unit is in a holding state, and stops operating when the lamp holding unit is in a released state. The lighting device operates when the lamp holding unit is in a holding state and the lamp is connected to the lamp connecting unit, and when the lamp holding unit is in a released state, and the lamp connection 2. The luminaire according to claim 1, wherein the operation is stopped when the lamp is not connected to the unit. The lamp holding unit includes a movable unit that is movable, and a detection unit that detects the position of the movable unit,
3. The lighting device according to claim 1, wherein the lighting device determines whether the lamp holding unit is in a holding state or a released state based on the position of the movable unit detected by the detection unit. The lighting fixture as described in. The lamp has a straight tube shape, and has a terminal portion that inputs power supplied from the lighting device by connecting to the lamp connection portion at one end,
4. The lighting apparatus according to claim 1, wherein the lamp holding portion holds the lamp at a position farther from the terminal portion than a center in a longitudinal direction of the lamp. The lamp connecting portion has a structure for attaching and detaching the lamp by rotating the lamp,
The said lamp holding | maintenance part hold | maintains the said lamp | ramp non-rotatably in a holding | maintenance state, The lighting fixture in any one of Claim 1 thru | or 3 characterized by the above-mentioned.

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