JP2004265619A - Rotary socket for card led light source - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a rotary socket for a card LED light source for improving the replacement work and heat radiation of a card LED module. <P>SOLUTION: One end side of an upper frame 232 is pivotally supported with a lower frame 231 and a locking part 233 to be engaged with a locking protrusions 2323 of the upper frame 232 is provided. A pressing part 2321, pressing a card LED module 8 inserted into the groove of an arm part 2320b toward lower frame 231 side, is arranged at the upper frame 232. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a socket and a lighting device used for a card type LED module in which an LED bare chip is mounted on a metal substrate.
[0002]
[Prior art]
In recent years, for use as a light source of an illuminating device, a card-type LED module in which a number of LED bare chips are mounted on a metal base substrate (this card-type LED module does not include a through-hole type). Has been done. This card-type LED module is considered to be able to obtain a light source with high brightness by further improving the luminous efficiency of the LED bare chip or improving the mounting density by future research and development.
[0003]
When such a card-type LED module is used as a light source of a lighting device, it can be considered that the card-type LED module is fixed to the lighting device 9 using a socket 920 as shown in FIG.
As shown in FIG. 8, the lighting device 9 includes a base 91 that is screwed into a general incandescent light bulb socket, and a case 92 to which the card-type LED module 8 is attached.
[0004]
In the case 92, a socket 920 that holds the card-type LED module 8 is attached to the bottom surface facing the surface on which the base 91 is attached.
The socket 920 is formed with an engaging groove 921 that engages with the side portion 801 of the card type LED module 8. When the user attaches the card type LED module 8, the side portion 801 is engaged with the socket 920. It is inserted into the groove 921 and further slid from the peripheral edge of the case 92 toward the center. Since it is desired that the illuminating device is arranged with the light source in the center, the card type LED module 8 serving as the light source can be arranged in the center of the illuminating device by the socket.
[0005]
There is no accumulation of technology related to the claimed invention, and there is no prior art document information to be described.
[0006]
[Problems to be solved by the invention]
By the way, since a relatively large current flows in the card type LED module in order to ensure luminance for illumination, the amount of heat generation is very large, and the life is likely to be shortened as compared with the case where it is used for other than illumination. Therefore, in the socket, it is required to improve the heat dissipation of the card-type LED module and to facilitate the replacement work at the end of the life.
[0007]
However, in the case of using the socket 920 as described above, it is considered that heat dissipation is still insufficient, and further improvement in heat dissipation is demanded. Furthermore, when replacing the card-type LED module 8 due to its life, it may be difficult for the user to perform the replacement work. For example, when removing the card-type LED module 8, the user needs to slide the card-type LED module 8 along the engagement groove 921 from the center of the case 92 to the peripheral edge. Since the engaging groove 921 continues from the light source part to the end of the case 92, the appearance of the lighting device may be impaired, and the side part 801 may be caught with the engaging groove 921 to burden the user in replacement work. May increase.
[0008]
Here, in order to facilitate the replacement work, it is considered that the socket 920 having a reduced sliding distance can be attached to the bottom surface of the case 92 so as to be placed. However, in that case, since the socket is arranged in the center of the case, when installing the card type LED module, the card type LED module cannot be operated while being pinched with the thumb and forefinger or the like. It is necessary to insert the socket into the socket while sliding with the thumb pressed against the bottom surface, which makes the replacement work difficult.
[0009]
In such a case, in the lighting device, since the socket protrudes from the case, an aesthetic problem also arises. That is, in the lighting device, it is desirable to arrange the socket in a recess formed in the case. Even if the socket is arranged in such a recess, it is desirable that the card type LED module can be easily replaced. It is rare.
[0010]
An object of this invention is to provide the card | curd type LED light source socket and illuminating device which use the card | curd type LED module suitable for actual use as a light source in view of the said subject.
[0011]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, a card type LED light source rotating socket according to the present invention is a card type LED light source socket for storing a card type LED module having a light emitting part formed on a substrate, and comprising a heat sink. When the second frame having a window portion facing the light emitting portion of the card-type LED module is pivotally supported with respect to the first frame arranged on the first frame, the first frame is in a closed state. The second frame includes a locking portion that is directly or indirectly locked with the second frame, and the second frame has a first peripheral edge of the card-type LED module when being locked to the first frame by the locking portion. A pressing portion that presses the frame side is provided.
[0012]
According to this, when the second frame is locked to the first frame by the locking portion, the card-type LED module is pressed to the first frame side by the pressing portion, so the heat generated by the card-type LED module. Can be efficiently radiated to the first frame or the heat sink. Moreover, if the latching portion is opened, the second frame rotates, so that the card-type LED module can be easily removed, and the exchange workability is improved.
[0013]
Specifically, the second frame includes a base portion that is pivotally supported by the first frame, and includes arm portions that are respectively extended from both ends of the base portion. A window portion is formed in a region surrounded by each of the arm portions, and each arm portion includes a groove portion that guides the side end portion of the card type LED module along the longitudinal direction of the arm portion on the side of the window portion side, and the pressing portion is Further, when the card type LED module is guided to the groove portion, the card type LED module can be configured to be formed inside the groove portion so as to press the end portion of the card type LED module toward the first frame side. If such a rotation type is used, the sliding distance of the card-type LED module can be shortened compared to a conventionally considered socket, and the burden of replacement work on the user can be reduced.
[0014]
If the first frame has an opening in the area of the first frame facing the stored card-type LED module when the second frame is locked by the locking portion, the card-type LED Since it is not necessary to interpose the first frame between the module and the heat sink, the heat radiation efficiency can be further improved.
In addition, as a specific configuration of the locking portion, the locking portion includes a slide portion arranged to be slidable in the longitudinal direction of the arm portion when the second frame is in the closed state in the first frame, Configuration in which the second frame is indirectly locked via the card-type LED module by being locked to the end of the card-type LED module housed between the arms when the slide portion is slid It can be.
[0015]
Further, the locking portion rotates to the first frame in conjunction with the locking projection that locks with the locking projection pivotally supported on the second frame in conjunction with the lock lever, or the locking lever. A locking projection that is pivotally supported and that engages with a locking projection formed on the second frame, and the second frame locking projection or the covering by pressing the locking lever of the first frame or the second frame. It can also comprise so that latching with a latching protrusion may be open | released.
[0016]
The first frame includes a positioning projection for positioning the card-type LED module, the second frame includes a pressing portion on the periphery of the window, and the card-type LED module is positioned by the positioning projection and the second frame. When the card-type LED module is replaced, it is inserted by sliding when the card-type LED module is stored in the first frame and the second frame. Therefore, the replacement workability can be improved. Here, for example, the card-type LED module can be pressed in a well-balanced manner by providing a power supply terminal made of an elastic body on one side of the window periphery and providing pressing portions on the remaining three sides.
[0017]
Here, if the first frame is provided with an opening in a region surrounded by the positioning protrusions, the card-type LED module can be configured to be in direct contact with the heat sink, thereby further improving the heat dissipation efficiency. can do. Here, if the positioning protrusion is provided with a spring property and its height is set smaller than that of the card type LED module, the card type LED module is firmly fixed and does not fall due to gravity even if it is mounted upside down. .
[0018]
Further, if the pressing portion is formed by integrally cutting and bending a part of the second frame, the number of parts of the socket can be suppressed, so that there is a cost advantage.
Further, if the rotation shaft of the locking portion is arranged right above the locking portion between the locking protrusion and the locked protrusion, it is difficult to cause an erroneous operation in which the locking is erroneously released.
[0019]
Furthermore, the lighting device according to the present invention is a lighting device using a card-type LED module, wherein the first frame serving as a base is fixed to the case and has a window portion facing the light-emitting portion of the card-type LED module. One end of the frame is pivotally supported by the first frame, and when the second frame is closed, the first frame has a locking portion that engages with the second frame so that it can be locked directly or indirectly. If the card-type LED light source rotating socket is provided with a concave portion in the case, and the socket is arranged in the concave portion, the socket is hidden in the concave portion. Even if it is hidden, the replacement workability of the card type LED module can be improved.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment in which a card type LED light source rotating socket (hereinafter referred to as “socket”) using a card type LED module according to the present invention as a light source is applied to a lighting device will be described with reference to the drawings. To do.
[First Embodiment]
(1) Overall configuration of lighting device
FIG. 1 is a schematic perspective view of a lighting apparatus 1 according to the first embodiment of the present invention.
[0021]
As shown in the figure, the lighting device 1 includes a base 11, a case 12, and a socket 13, so that the card type LED module 8 serving as a light source can be exchanged in the socket 13. Yes.
The base 11 is the same as the standard used for a general incandescent bulb, and supplies an alternating current supplied from an external commercial power source to a power circuit (not shown) of the case 12.
[0022]
The case 12 has a trapezoidal shape in a side view as if a cone is cut in a direction orthogonal to the central axis, and a base 11 is attached to the upper surface, and a bottom surface facing the upper surface is A heat sink 122 in which a recess 121 is formed is provided. The case 12 accommodates a known power supply circuit (not shown) for converting an alternating current supplied from the base 11 into a direct current and supplying it to the socket 13.
[0023]
The socket 13 is screwed in the recess 121 of the heat sink 122 by a screw 123 so that the light source is arranged in the center, and holds the card-type LED module 8 so that the card-type LED module 8 can be inserted and removed. Supply. Note that the recess 121 is set to a height such that the socket 13 does not protrude from the recess, and a U-shaped cover 121a is inserted in an area excluding the socket 13, as shown in FIG. It is also better in appearance than the lighting device.
[0024]
Here, as shown in FIG. 2, the card type LED module 8 has 25 pieces (5 pieces in length) on a metal base substrate 80 (28.5 mm long × 23.5 mm wide, 1.2 mm thick) based on aluminum. (× 5 horizontal) LED bare chips 81 are arranged in a matrix and are resin-sealed, and the metal base substrate 80 is provided with a power supply pattern 82 for receiving power supply from the socket 13 on the surface end. . The detailed configuration of the card type LED module 8 is described in Japanese Patent Application No. 2001-242857. The card-type LED module 8 may have a light emission color other than white light, and various LED bare chip arrangement patterns can be used. However, a through-hole type using a bullet-type LED is not included.
[0025]
(2) Configuration of socket 13
Next, the configuration of the socket 13 will be described.
FIG. 2 is a perspective view of the socket 13 according to the first embodiment.
As shown in the figure, the socket 13 is fixed to a lower frame 131 that serves as a base for mounting on the heat sink 122 (FIG. 1) and one end side of the lower frame 131 that is rotatable about a rotation shaft 132a. The upper frame 132 urged in the opening direction by the spring 132 b and the lower frame 131 is engaged with the card-type LED module 8 housed in the upper frame 132, and the upper frame 132 is attached to the lower frame 131. On the other hand, a locking portion 133 is provided to be fixed in a closed state.
[0026]
The lower frame 131 includes, for example, a locking portion support portion 1311 and an upper frame support portion 1312 that are partially cut out and bent on a substrate 1310 made of a nickel-plated metal on a brass substrate having excellent thermal conductivity. It is erected.
A screw hole 1310 a for screwing to the heat sink 122 shown in FIG. 1 is formed at the end of the substrate 1310.
[0027]
A pair of locking portion support portions 1311 are provided on one of the two opposing sides of the substrate 1310, and hold the locking portion 133 in a slidable manner. The locking portion support portion 1311 is formed with guide holes 1311a for holding the locking portion 133 so as to be slidable. The locking portion 133 is guided along the guide holes 1311a so as to reciprocate in a certain direction. To do.
[0028]
A pair of upper frame support portions 1312 is provided on the side of the substrate 1310 opposite to the locking portion support portion 1311 and rotatably supports one end side of the upper frame 132. The upper frame support portion 1312 is formed with holes (not shown), and the holes support the rotating shaft 132 a protruding from the upper frame 132.
[0029]
Here, the substrate 1310 has a function of transferring the heat generated by the card type LED module 8 to the heat sink 122 to dissipate the heat, and when the card type LED module 8 is mounted in order to improve the heat dissipation efficiency thereof, A heat radiating sheet 1313 is affixed to the opposing region. Since the heat dissipation sheet 1313 prevents air having a very low thermal conductivity from passing between the lower frame 131 and the upper frame 132, the heat dissipation efficiency of the card-type LED module can be improved.
[0030]
The upper frame 132 is formed in a holding portion 1320 for holding the card-type LED module 8 and an arm portion 1320b in the holding portion 1320, and the end of the card-type LED module 8 inserted into the holding portion 1320 is A pressing portion 1321 that is pressed and fixed, and a power feeding portion 1322 that is formed on the base portion 1320a of the holding portion 1320 and supplies power to the inserted card-type LED module 8 are provided.
[0031]
The holding portion 1320 includes a base portion 1320a and arm portions 1320b extending from both ends thereof, and has a shape obtained by bending a U-shaped frame in a sectional view into a U-shape in a plan view. Thus, a groove is formed in the longitudinal direction on the opposite side of each arm portion 1320b. Here, a portion of the holding portion 1320 cut to have a U-shape in plan view, that is, a portion surrounded by the base portion 1320a and both arm portions 1320b serves as a window portion facing the light emitting portion of the LED module 8. The side end portion of the card type LED module 8 is fitted in the groove of the arm portion 1320b, and the arm portion 1320b is configured not to block light emitted from the light emitting portion on which each LED bare chip 81 is formed.
[0032]
FIG. 3 is a side sectional view of the socket 13 with the card-type LED module 8 inserted and the upper frame 132 closed.
As shown in the figure, the base portion 1320a is provided with a power supply portion 1322 for supplying power supplied from the outside to the card type LED module 8.
The power supply part 1322 is made of a plurality of strip-shaped power supply terminals 1322a that respectively contact the power supply pattern 82 of the card-type LED module 8 and an insulating resin, and is fixed in a state where the power supply terminals 1322a are arranged in a row on the base part 1320a. Terminal holding portion 1322b.
[0033]
The power supply terminal 1322a is made of phosphor bronze having excellent springiness, one end side is projected outward from the base portion 1320a and connected to a power supply wiring (not shown), the other end side is bent in a bow shape, and the other end The power supply pattern 82 of the card-type LED module 8 is pressed against the substrate 1310 side by the side elasticity so that power can be supplied. By this pressing, the electrical connection of the power supply terminal 1322a is improved with the power supply pattern 82, and the card-type LED module 8 can be brought into close contact with the heat dissipation sheet 1313, so that the heat dissipation of the card-type LED module 8 is improved. be able to.
[0034]
As shown in FIG. 2, the pressing portion 1321 is formed integrally with the upper frame 132 by cutting a part of the arm portion 1320b into a T shape and bending it into a leaf spring shape. As shown by a broken line in FIG. 5, the peripheral edge portion of the inserted card type LED module 8 is pressed toward the lower frame 131 side. Since the number of parts is reduced by integrally forming the pressing portion 1321 in this way, the cost can be suppressed as compared with the case of separate components. Here, the force by which the pressing portion 1321 presses the card-type LED module 8 is 0.05 to 1.00 kg / cm so that the card-type LED module 8 is not damaged and can be inserted and removed by a human hand. ² It is preferable to set it as the range.
[0035]
Also, at the tip of the arm portion 1320b, the upper surface side is folded back to the base portion 1320a side to form a pressing portion 1320c that facilitates insertion of the card type LED module 8 and presses the inserted card type LED module 8. ing.
As shown in FIG. 2, the locking portion 133 includes a slide plate 1330 having a non-slip hole, and a slide protrusion 1331 engaged with a guide hole 1311 a formed by bending a side portion of the slide plate 1330. With.
[0036]
When the user slides the slide plate 1330 in the direction of the arrow shown in FIG. 3, the locking portion 133 is locked to the upper surface of the card-type LED module 8 by the slide protrusion 1331 being guided by the guide hole 1311 a. Thus, the upper frame 132 can be indirectly locked to the lower frame 131 via the card type LED module 8.
[0037]
(3) Mounting method of card type LED module 8
A method of attaching the card type LED module 8 to the socket 13 will be described with reference to FIGS.
As shown in FIG. 2, when the upper frame 132 is in an open state, that is, in a state where the arm portion 1320b is lifted, the user has the cross section formed in the longitudinal direction of each arm portion 1320b. Insert to engage the mold groove.
[0038]
When the card-type LED module 8 is inserted into the innermost part, that is, until it comes into contact with the base part 1320a, both side surfaces are pressed toward the lower frame 131 by the pressing parts 1320c and 1321, and power is supplied as shown in FIG. The power supply pattern 82 in the card type LED module 8 is pressed and electrically connected by the terminal 1322a.
[0039]
Next, the user rotates this arm portion 1320b around the rotation shaft 132a and presses it toward the lower frame 131 as shown in FIG.
Then, as shown by the broken line in FIG. 3, the slide plate 1330 is moved in the direction of the arrow and is locked to the end of the card type LED module 8. Here, the slide plate 1330 is set to a height that is substantially the same as or slightly lower than the sum of the height of the card-type LED module 8 and the thickness of the heat dissipation sheet 1313. 1330 can hold the state where the card-type LED module 8 is pressed toward the lower frame 131. Thereby, since the back surface of the card-type LED module 8 is pressed by the heat radiating sheet 1313 and is in close contact with the heat radiating sheet 1313 without passing through air having a very low thermal conductivity, the heat radiation efficiency can be improved.
[0040]
In addition, what is necessary is just to perform the said attachment procedure reversely, when removing the card-type LED module 8. FIG.
As described above, the upper frame 132 in which the card type LED module 8 is accommodated can be fixed while maintaining the state in which the upper frame 132 is pressed to the lower frame 131 side by the engaging portion 133, so that the heat generated by the card type LED module 8 is efficiently performed. It can dissipate heat well. Further, when the card type LED module 8 is replaced, the distance by which the card type LED module 8 is slid can be made shorter than that described in the prior art, thereby reducing the burden imposed on the user in the replacement work. be able to. Furthermore, as shown in FIG. 1, since the socket 13 is buried and attached in the recess of the case 12, the lighting device can easily replace the card-type LED module 8, and has an aesthetic appearance. Can keep good.
[0041]
[Second Embodiment]
Next, a second embodiment of the socket according to the present invention will be described.
FIG. 4 is a perspective view of the socket 23 according to the second embodiment.
In the second embodiment, the configurations of the lighting device and the like are the same except that the configurations of the lower frame 231, the upper frame 232, and the locking portion 233 of the socket 23 are different from those of the first embodiment. Therefore, mainly the different parts of the socket will be described.
[0042]
As shown in the figure, unlike the first embodiment, the lower frame 231 is provided with an opening 2312 that is slightly larger than the upper frame 232 at the center of the substrate 2310. Thereby, when the upper frame 232 is closed to the lower frame 231 side, the lower frame is not interposed between the card type LED module 8 and the heat sink to which the lower frame 231 is attached. That is, as shown in FIG. 1, when the lower frame 231 is screwed to the heat sink 122 via the screw hole 2310 a, the bottom surface of the card type LED module 8 is exposed above the heat sink 122. However, as it is, the distance between the card type LED module 8 and the heat sink is increased by the thickness of the plate constituting the base portion 2320a and the arm portion 2320b in the upper frame 232, and therefore a heat dissipation sheet (not shown) is provided in the gap. What is necessary is just to go through. Thus, the number of members interposed between the card type LED module 8 and the heat sink to which the socket 23 is attached can be reduced by the amount of the board 2310 as compared with the first embodiment. It is considered that heat can be efficiently transferred to the heat sink 122 and heat dissipation efficiency can be improved.
[0043]
The locking portion 233 includes a rotating portion 2330 fixed to the locking portion support portion 2311 in the lower frame 231, and an arm-like engagement protruding from both ends of the locking portion and bent into an L shape on the upper frame 233 side. The locking projection 2331 includes a locking projection 2331 and a locking lever 2333 protruding in a direction opposite to the bending of the locking projection 2331. After the locking projection 2331 once bends the tip of the arm portion 2320b in the upper frame 232 downward It is configured to engage with a locking projection 2323 formed by bending upward.
[0044]
The rotating portion 2330 is provided with rotating shafts 2332 projecting from both side ends, and this is rotatably held by a locking portion support portion 2311 in the lower frame 231.
Further, the rotating portion 2330 is arranged so that the engaging portion between the engaging protrusion 2331 and the engaging protrusion 2323 in the arm portion 2320b is almost directly above the central axis of the rotating shaft 2332 when viewed from the side. Has been. The rotating portion 2330 is elastically biased by a spring body (not shown) so as to rotate in the bending direction of the locking projection 2331 so that the locking portion comes directly above the central axis of the rotating shaft 2332. As a result, even if the upper frame 232 is opened and the locking projection 2323 of the arm portion 2320b is pushed up, the rotating portion 2330 is difficult to rotate and the locking with the locking projection 2331 is difficult to release. , Can be locked more reliably.
[0045]
When attaching the card-type LED module 8 to the socket 23, first, the card-type LED module 8 is inserted into the groove of the arm portion 2320b of the upper frame 232 by sliding. At this time, as in the first embodiment, the pressing portion 2321 of the arm portion 2320b presses the periphery of the card type LED module 8 toward the lower frame 231 and the card type LED module 8 is electrically connected by the power supply terminal 2322a. Connected to.
[0046]
Next, as in the first embodiment, the upper frame 232 is pushed down to the lower frame 231 side to lock the locking projection 2331 in the locking portion 233 and the locking projection 2323 in the arm portion 2320b. The upper frame 232 and the lower frame 231 are directly locked.
Here, due to the pushing-down action of the locking projection 2323 of the upper frame 232, the locking projection 2331 of the pivoting portion 2330, which has been elastically biased, returns to its original position after being rotated. Under the protrusion 2331, the locking protrusion 2323 in the upper frame 232 is positioned. As a result, the locking protrusion 2331 is locked with the locking protrusion 2323, and the upper frame 232 is locked with the lower frame 231.
[0047]
When the card-type LED module 8 is removed, when the user pushes down the lock lever 2333, the locking projection 2331 in the lower frame 231 rotates and the locking projection 2323 is unlocked. As a result, the upper frame 232 that is elastically biased by the spring 232b rises and one side is opened, so that the card-type LED module 8 can be extracted.
[0048]
Even with such a configuration, as in the first embodiment, it is possible to reduce the burden imposed on the user when replacing the card-type LED module. Furthermore, since the member interposed between the card-type LED module 8 and the heat sink side can be reduced as compared with the first embodiment, the heat dissipation can be further improved. The same effect as that of the first embodiment can also be obtained in the lighting device using the socket according to the second embodiment.
[0049]
[Third Embodiment]
In the first and second embodiments, the card-type LED module 8 is inserted and fixed in the grooves of the upper frames 132 and 232. However, in the third embodiment, in the configuration of the socket. The difference is that the card-type LED module is fixed by being sandwiched between the lower frame and the upper frame.
[0050]
FIG. 5 is a perspective view of the socket 33 according to the third embodiment.
The socket 33 is fixed to the lower frame 331, the upper frame 332 fixed to the lower frame 331 so as to be rotatable in a state where one end thereof is elastically biased, and the lower frame 331 to be rotatable. And a locking portion 333 that locks the lower frame 331 and the upper frame 332.
[0051]
The lower frame 331 is formed of a substrate 3310 in which brass having excellent thermal conductivity is plated with nickel, and is formed by cutting up a part of one end side thereof and supporting the upper frame 332. 3312, a locking portion support portion 3311 formed by cutting off a part of the side opposite to this, and a locking portion 333 rotatably held by the locking portion support portion 3311 Prepare.
[0052]
The lower frame 331 is provided with a plurality of positioning projections 3313 for positioning the stacking position of the card-type LED module 8 with a part of the frame cut out and bent. The card-type LED module 8 is positioned and stored in an area surrounded by the positioning protrusion 3313.
[0053]
The upper frame 332 is made of stainless steel having excellent strength, and has a square plate-like substrate 3320 with a square opening 332c serving as a window facing the LED mounting portion of the card-type LED module 8 in the center. On the three sides of the four sides of the opening 332c, a pressing portion 3321 is formed by cutting the substrate 3320 into a T shape and bending it inside, and the other side, that is, the rotation shaft 332a side of the opening 332c is formed. A power feeding unit 3322 is disposed in the vicinity of the side.
[0054]
The pressing portion 3321 is bent in a leaf spring shape, and when the upper frame 332 is locked to the lower frame 331, the end portion of the card type LED module 8 is pressed toward the lower frame 331 by its elasticity. ing.
The power supply unit 3322 includes a terminal holding unit 3322a and a plurality of strip-shaped power supply terminals 3322b, as in the case of the power supply unit 1322 of the first embodiment, but is not visible in the drawing but is bent on a plate spring. Due to the elasticity of 3322b, when the upper frame 332 is locked to the lower frame 331, it comes into contact with the power supply terminal of the card-type LED module 8 and can supply electric power from the outside.
[0055]
In the substrate 3320, a locking protrusion 3323 that locks with the locking protrusion 3331 of the locking portion 333 in the lower frame 331 protrudes from the outer periphery on the side facing the power supply terminal 3322 a.
The locking portion 333 includes a rotation portion 3330 pivotally supported by the locking portion support portion 3311, and a locking protrusion 3331 formed by bending a part of the rotation portion 3330 into a cut-out shape. , A rotation shaft 3332 projecting from the side of the rotation unit 3330, and an arm unit 3333 extending from both ends of the rotation unit 3330 in the direction in which the power feeding unit 3322 is arranged.
[0056]
The locking projection 3331 is locked with the locking projection 3323 in the upper frame 332 when the upper frame 332 is closed, so that the upper frame 332 can be locked with the lower frame 331.
The rotation shaft 3332 is pivotally supported by the locking portion support portion 3311 in the lower frame 331.
[0057]
The arm portion 3333 is configured such that its tip moves up and down as the turning portion 3330 rotates. Note that a cutout portion 3310b is formed in the lower frame 331 so as not to hinder the rotation of the arm portion 3333.
FIG. 6 is a partial schematic side view of the socket 33 for explaining the movement of the arm portion 3333 when the card-type LED module 8 is mounted.
[0058]
As shown in FIG. 6A, the arm portion 3333 protrudes from the rotating portion 3330 at an angle that is wider than 90 °, and in a state where the card-type LED module 8 is not mounted. The user rotates the locking portion 333 so that the tip of the arm portion 3333 is lifted. Here, the locking portion 333 is urged in a direction in which the tip of the arm portion 3333 rises by a spring (not shown).
[0059]
When the card-type LED module 8 is inserted so as to be aligned with the positioning protrusion 3313, the bottom of the card-type LED module 8 comes into contact with the arm portion 3333, and then the arm portion 3333 is pushed down as shown in FIG. On the other hand, the rotating part 3330 rises. Here, the arm portion 3333 does not rotate any more because it comes into contact with a heat sink (not shown) through the notch portion 3310b in the substrate 3310.
[0060]
Next, when the user pushes the locking projection 3331 down onto the locking projection 3323 of the substrate 3320 and locks it, the lower frame 331 and the upper frame 332 are locked. At this time, the arm portion 3333 is pressed against a heat sink (not shown).
When removing the card-type LED module 8, the arm portion 3333 is lifted by turning the turning portion 3330, and at the same time, the card-type LED module 8 is also lifted away from the positioning protrusion 3313 to be easily taken out.
[0061]
According to such a configuration, it is not necessary to slide and insert when fixing the card type LED module 8, and problems such as catching are less likely to occur.
Furthermore, since the card-type LED module 8 is stacked so as to be in direct contact with the lower frame 331, which has better thermal conductivity than the heat radiating sheet, heat dissipation is further improved as compared with the first and second embodiments. Can do.
[0062]
Further, in the case where such a socket is provided in the lighting device as shown in FIG. 1, as in the first embodiment, heat dissipation and replacement workability can be improved without impairing the aesthetic appearance.
[Fourth Embodiment]
In the third embodiment, the card type LED module 8 is stacked on the lower frame 331. However, in the fourth embodiment, the card type LED module is mounted on the lower frame. The difference is that an opening is provided in which 8 is inserted and positioned, and the back surface of the card-type LED module 8 positioned in the opening is in direct contact with the heat sink. Moreover, the structure of the latching | locking part is also changed.
[0063]
FIG. 7 is a perspective view of the socket 43 according to the fourth embodiment.
As shown in the figure, the lower frame 431 is provided with a rectangular opening 4314 serving as a window facing the LED mounting portion of the card-type LED module 8 in the center of the base 4310. Although not shown here, the lower frame 431 is screwed to the heat sink of the lighting device as shown in FIG.
[0064]
A plurality of positioning projections 4313 are provided on the periphery of the opening 4314 so as to fix the position of the card type LED module 8 so as not to shift.
Further, the base 4310 is formed with a locking portion 4331 that is partly cut and raised so as to be locked to the engaging protrusion 4323 in the upper frame 432.
[0065]
The card-type LED module 8 is inserted into the opening 4314 in the lower frame 431 and positioned so as not to be displaced in the horizontal direction by the positioning protrusion 4313. Thus, the card-type LED module 8 is arranged so that the back side thereof is in direct contact with a heat sink (not shown).
The upper frame 432 has a pivot shaft 432a projecting from one end of the upper frame 432 supported rotatably by an upper frame support portion 4312 in the lower frame 431, and a power feeding section 4322 is disposed on the pivot shaft 432a side. In addition, a locking portion 433 is disposed on the side facing the power feeding portion 4322.
[0066]
The locking portion 433 includes a lock lever 4330 and an engagement protrusion 4323 extending in a direction orthogonal to the lever 4330 and having a locking claw at the tip, and the lock lever 4330 is inserted from the opening 4332 d of the upper frame 432. While being protruded outward, the engaging protrusion 4323 is pivotally supported by a rotation shaft (not shown) so as to protrude inward of the upper frame 432. The locking portion 433 is elastically biased so as to be rotatable by a spring (not shown).
[0067]
When the user installs the card-type LED module 8, the user inserts the card-type LED module 8 into the opening 4314 and performs positioning using the positioning protrusion 4313. Then, by pushing down the upper frame 432, the engaging protrusion 4323 is locked with the locking portion 4331. At this time, the card-type LED module 8 is pressed toward the lower frame 431 by the pressing portion 4321 in the upper frame 432 and directly pressed against a heat sink (not shown), so that the socket 43 is a card compared to the third embodiment. The heat dissipation efficiency of the LED module 8 can be further improved.
[0068]
When the card-type LED module 8 is removed, the user pushes down the lock lever 4330, so that the engagement protrusion 4323 rotates and the engagement with the engagement portion 4331 is released, so that the elastic force is applied. The upper frame 432 is lifted, and the card type LED module 8 can be removed.
Further, in the case where such a socket is provided in the lighting device as shown in FIG. 1, as in the first embodiment, heat dissipation and replacement workability can be improved without impairing the aesthetic appearance.
[0069]
(Modification)
When the card-type LED module is housed in the socket of each of the above embodiments, a detector is provided to detect the insertion by pressing the LED, and power is supplied from the power supply terminal only when it is detected. You may make it be the structure to perform. By providing such a detector, it is possible to safely work even if the user touches the power supply terminal when replacing the card type LED module.
[0070]
In addition, the locking portion in each of the above embodiments may be provided on either the upper frame or the lower frame as long as it can be fixed while maintaining the state in which the upper frame is pressed toward the lower frame. Even with such a configuration, the same effect as in the present embodiment can be obtained.
[0071]
【The invention's effect】
As described above, according to the socket according to the present invention, the upper frame is pivotally supported by the lower frame, and the upper frame is directly or indirectly locked to the lower frame. A locking part is provided, and the upper frame is provided with a pressing part that presses the card-type LED module toward the lower frame when the upper frame is locked, so that the heat generated by the card-type LED module can be efficiently generated on the heat sink side. It is possible to transfer heat to the heat and dissipate heat, and to improve the workability of replacing the card type LED module.
[0072]
Furthermore, in an illuminating device in which such a socket is arranged in the recess, the replacement workability can be improved without deteriorating the appearance.
[Brief description of the drawings]
FIG. 1 is a perspective view of a lighting device.
FIG. 2 is a perspective view of the socket according to the first embodiment.
FIG. 3 is a side sectional view of the socket.
FIG. 4 is a perspective view of a socket according to a second embodiment.
FIG. 5 is a perspective view of a socket according to a third embodiment.
FIG. 6 is a side view of a socket according to a third embodiment.
FIG. 7 is a perspective view of a socket according to a fourth embodiment.
FIG. 8 is a perspective view of a conventional lighting device.
[Explanation of symbols]
1 Lighting device
8 Card type LED module
11 base
12 cases
121 recess
122 heat sink
131 Lower frame
132 Upper frame
132a Rotating shaft
132b Spring
133 Locking part
1310 substrate
1311 Locking part support part
1311a Guide hole
1320a Base
1320b Arm part
1320c Pressing part
1322 Feeder
1322a Feeding terminal
1322b Terminal holding part
1330 slide plate

Claims (10)

A card type LED light source socket for storing a card type LED module having a light emitting part formed on a substrate,
A second frame having a window part facing the light emitting part of the card type LED module is pivotally supported with respect to the first frame arranged on the heat sink,
The first frame includes an engaging portion that directly or indirectly engages with the second frame when the second frame is in a closed state,
The card type, wherein the second frame includes a pressing portion that presses a peripheral portion of the card-type LED module toward the first frame when the second frame is locked to the first frame by the locking portion. Rotating socket for LED light source. The second frame includes a base portion that is pivotally supported by the first frame, and includes arm portions that extend from both ends of the base portion, thereby being surrounded by the base portion and both arm portions. The window is formed in a region;
Each of the arm portions includes a groove portion that guides a side end portion of the card type LED module along a longitudinal direction of the arm portion on the side of the window portion side,
The said pressing part is shaped inside the said groove part so that when the said card-type LED module is guided by the said groove part, the edge part of the said module is pressed to the said 1st frame side. Item 2. A rotating socket for a card-type LED light source according to item 1. The said 1st frame has an opening part in the area | region facing the card-type LED module accommodated when the said 2nd frame is latched by the said latching | locking part. Or the rotation socket for card type LED light sources of 2. The locking portion includes a slide portion arranged in the first frame so as to be slidable in a longitudinal direction of the arm portion when the second frame is in a closed state, and when the slide portion is slid, It is latched by the edge part of the said card type LED module accommodated between the arm parts, and the said 2nd frame is latched indirectly via the said card type LED module. Item 4. A rotating socket for a card-type LED light source according to Item 2 or 3. The latching portion pivots to the first frame in conjunction with a latching projection that latches with a latching projection pivotally supported by the second frame that interlocks with the lock lever, or a lock lever. A locking projection that is pivotally supported and that locks with the locked projection formed on the second frame, and when the locking lever is pressed, the locking projection and the locked projection are unlocked. The card-type LED light source rotating socket according to claim 2 or 3, wherein the card-type LED light source rotating socket is provided. The first frame includes a positioning projection for positioning the card-type LED module, the second frame includes the pressing portion on the periphery of the window, and the card-type LED module is positioned by the positioning projection. 2. The card according to claim 1, wherein the card is sandwiched and stored between the first frame and the second frame when the second frame is locked to the first frame by the locking portion. -Type LED light source rotating socket. The card-type LED light source rotating socket according to claim 6, wherein the first frame is provided with an opening in a region surrounded by the positioning protrusions. The card-type LED light source rotating socket according to claim 1, wherein the pressing portion is formed integrally by cutting out and bending a part of the second frame. 6. The rotating socket for a card type LED light source according to claim 5, wherein the rotation shaft of the locking portion is disposed directly above the locking portion between the locking protrusion and the locked protrusion. . An illumination device using a card type LED module,
A first frame serving as a base is fixed to the case, and one end side of a second frame having a window facing the light emitting portion of the card type LED module is pivotally supported by the first frame, and the first frame is A locking portion for directly or indirectly locking with the second frame when the second frame is in a closed state, and a card between the second frame or the first frame and the second frame A lighting device comprising a socket for housing a type LED module.

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