JP7464507B2 - LAMP SUPPORT STRUCTURE AND SMALL ELECTRICAL DEVICE COMPRISING LAMP SUPPORT STRUCTURE - Google Patents

Description

The present invention relates to a lamp support structure in which a filament is supported by a power supply rod inside a bulb made of a glass tube, and to a small electrical device equipped with this lamp support structure.

Lamps such as halogen lamps are attached to devices via support members such as sockets, and an example of a support structure for this type of lamp is the Patent Document 1. In the small light bulb socket of Patent Document 1, the lamp support structure is composed of a socket body and a pin terminal protruding from a wiring board. Specifically, the socket body is made of elastic heat-resistant rubber or silicone rubber, and has an annular protrusion protruding from its front surface. The annular protrusion has a light bulb insertion hole, into which a small light bulb is attached, and two parallel lead wire insertion holes, which are continuous with the inner peripheral surface of the annular protrusion. A notched step portion for shock absorption is formed on the bottom surface at the tip of the socket body. The pin terminal is provided on a wiring board provided with the device, and the socket with the small light bulb attached is fixed to the wiring board by inserting the pin terminal into a lead wire lead hole that opens into the bottom surface of the notched step portion provided at the base end of the socket body.

Japanese Patent Application Laid-Open No. 10-269830

According to the miniature light bulb socket of Patent Document 1, even if a miniature light bulb mounted in a light bulb insertion hole receives an impact due to device vibration or the like, the socket body elastically deforms to absorb the impact and prevent the power supply rod and filament of the miniature light bulb from breaking. However, the impact absorption capacity of the socket of Patent Document 1 comes from the material (silicon rubber) from which the socket body is made, and this impact absorption capacity is not very large. Therefore, when an impact that exceeds the impact absorption capacity acts on the miniature light bulb (lamp), there is a risk that the filament or power supply rod will break, and there is room for improvement in this regard.

The present invention aims to provide a lamp support structure that can more reliably prevent lamp breakage, and a small electrical device equipped with this lamp support structure.

The present invention is directed to a support structure for mounting a lamp 15, which includes a bulb portion 31 having a filament 34 supported by a pair of power supply rods 35 and a connection portion 33 provided at one end of the bulb portion 31, to a mounting object D. This support structure includes a support portion 38 provided on the mounting object D, and a lamp holder 39, one side of which is supported by the support portion 38 and the other side of which includes a mounting portion 41 that allows the connection portion 33 of the lamp 15 to be inserted and mounted. When the mounting direction of the lamp 15 to the lamp holder 39 is defined as the front-rear direction, the support portion 38 includes a clamping body 51 that clamps and supports the lamp holder 39 so that it can swing in one direction, the up-down direction perpendicular to the front-rear direction, between a neutral position in which the extension direction of the lamp 15 coincides with the front-rear direction and a displaced position in which the extension direction of the lamp 15 does not coincide with the front-rear direction. A buffer body 64 that holds the lamp holder 39 in a neutral position is provided between the clamping body 51 and the lamp holder 39.

The clamping body 51 is equipped with upper and lower clamping bodies 52 and 53 that clamp and support the lamp holder 39 from above and below. The buffer body 64 can be configured to include an upper buffer body 61 provided between the upper clamping body 52 and the lamp holder 39, and a lower buffer body 62 provided between the lower clamping body 53 and the lamp holder 39.

When the plane defined by the front-to-rear and left-to-right directions is defined as a horizontal plane, the axis of the power supply rod 35 and the filament 34 can be arranged on the horizontal plane.

The clamping body 51 is located at a position offset in the front-rear direction from the center of gravity of the lamp holder 39.

Multiple clamping bodies 51 are arranged side by side in the left-right direction.

The buffer 64 includes a connector 63 that connects the upper buffer 61 and the lower buffer 62, and has a through hole 65 that passes from the upper buffer 61 to the lower buffer 62. A support shaft 56 that extends toward the other buffer 52/53 and is inserted into the through hole 65 is formed in one of the upper and lower clamps 52/53, and a bearing hole 57 with which the support shaft 56 engages is formed in the other clamp 52/53.

Each of the buffer bodies 61 and 62 is made of a cylindrical block-shaped elastic body. Each of the clamping bodies 52 and 53 has a clamping boss 54 formed of a cylindrical block with a smaller diameter than each of the buffer bodies 61 and 62, and a plurality of auxiliary ribs 55 formed radially from the periphery of the clamping boss 54.

The small electrical device according to the present invention has a heat source constituted by a lamp 15 that emits light including infrared rays, and the lamp 15 is supported by the lamp support structure configured as described above.

As in the present invention, when the lamp holder 39 is configured to be supported by being clamped so as to be swingable in the vertical direction, with the clamped portion by the clamping body 51 as a fulcrum, even when an impact is applied to the mounting object D, the lamp holder 39 can be effectively dissipated by being displaced by swinging in the vertical direction. This prevents the impact from being directly applied to the lamp 15 attached to the lamp holder 39, and prevents the power supply rod 35 and filament 34 arranged inside the bulb portion 31 from breaking.

In addition, as in the present invention, if a buffer 64 is provided between the clamp 51 and the lamp holder 39 to hold the lamp holder 39 in a neutral position, even if the lamp holder 39 is swung and displaced due to an impact, the buffer 64 can gradually attenuate the swinging displacement speed of the lamp holder 39, allowing the lamp holder 39 to slowly return to the neutral position. This can prevent the power supply rod 35 and filament 34 arranged inside the bulb section 31 from breaking due to an increase in the swinging displacement speed of the lamp holder 39 or due to the lamp holder 39 swinging and displacing over a long period of time. Furthermore, the buffer 64 can buffer the impact acting on the lamp holder 39, which can also prevent the power supply rod 35 and filament 34 from breaking.

As described above, the lamp support structure of the present invention allows the lamp holder 39 to be oscillated and displaced in the vertical direction, preventing direct impact on the lamp 15; a buffer 64 is provided between the clamp 51 and the lamp holder 39, allowing the oscillated lamp holder 39 to slowly return to a neutral position; and the buffer 64 cushions the impact, thereby more reliably preventing the lamp 15 from breaking.

When the buffer 64 is configured to include an upper buffer 61 provided between the upper clamp 52 constituting the clamp 51 and the lamp holder 39, and a lower buffer 62 provided between the lower clamp 53 constituting the clamp 51 and the lamp holder 39, the two buffers 61 and 62 provided above and below can more reliably buffer the impact acting on the lamp holder 39. Since the damping force borne by each buffer 61 and 62 can be distributed, the swing displacement speed of the lamp holder 39 can also be more reliably damped gradually. As described above, according to the present invention, it is possible to more reliably prevent the lamp 15 from breaking.

When the plane defined by the front-rear and left-right directions is defined as the horizontal plane, if the axes of the power supply rod 35 and the filament 34 are arranged on the horizontal plane, the movement direction of the filament 34 caused by the elastic deformation of the power supply rod 35 can be made to coincide with the swing direction of the lamp holder 39. This makes it possible to suppress the impact on the filament 34 caused by the elastic deformation of the power supply rod 35 in addition to the swing displacement of the lamp holder 39, and therefore makes it possible to greatly reduce the impact acting on the filament 34, which is particularly prone to breakage.

When the clamping body 51 is provided at a position shifted in the front-rear direction from the center of gravity of the lamp holder 39, it is easier to swing and displace the lamp holder 39 compared to when the clamping body 51 clamps and supports the center of gravity of the lamp holder 39. Therefore, the function of preventing the lamp 15 from breaking due to the swinging displacement of the lamp holder 39 is more effectively exerted.

When multiple clamping bodies 51 are arranged side by side in the left-right direction, the number of fulcrums can be increased compared to a configuration with one clamping body 51, and the lamp holder 39 can be more accurately clamped and supported by the support section 38. Also, in a configuration with one clamping body 51, there is a risk that the lamp holder 39 will rotate around an axis in the vertical direction, but by providing multiple clamping bodies 51, this rotation can be prevented, and the lamp holder 39 can be displaced to a more appropriate position.

If the buffer 64 has a connector 63 that connects the upper buffer 61 and the lower buffer 62 between them, the support structure can be constructed more easily than in a configuration in which each of the buffers 61 and 62 is assembled to the clamping body 51 individually. Since the number of parts can be reduced, the cost of the support structure can also be reduced. In addition, if a support shaft 56 that extends toward the other clamping body 52 and 53 and is inserted into a through hole 65 formed in the buffer 64 is formed in one of the upper and lower clamping bodies 52 and 53, and a bearing hole 57 with which the support shaft 56 engages is formed in the other clamping body 52 and 53, it is possible to reliably prevent the occurrence of positional deviation between the clamping body 51 and the buffer 64. Therefore, the shock absorbing effect of the upper and lower buffers 61 and 62 can be obtained more accurately. Since the buffer 64 can be assembled to the clamping body 51 simply by inserting the support shaft 56 into the through hole 65, the support structure can also be constructed more easily.

If each of the clamping bodies 52 and 53 is provided with a clamping boss 54 formed of a cylindrical block with a smaller diameter than the upper and lower buffer bodies 61 and 62, and a plurality of auxiliary ribs 55 formed radially from the periphery of the clamping boss 54, each of the buffer bodies 61 and 62 can deform not only in the outer circumferential direction, but also in the outer end direction of the buffer body 61 and 62 that is not in contact with the clamping boss 54 and the auxiliary ribs 55. This allows each of the buffer bodies 61 and 62 to deform more greatly, so that each of the buffer bodies 61 and 62 exerts a greater shock-absorbing effect. Incidentally, when the entire end face of each of the buffer bodies 61 and 62 is in contact with the clamping body 51, each of the buffer bodies 61 and 62 deforms only in the outer circumferential direction, so the amount of deformation of each of the buffer bodies 61 and 62 is small.

In a small electrical device in which the lamp 15, which is configured as a heat source, is supported by the lamp support structure described above, it is possible to effectively prevent the lamp 15 from breaking due to the impact of dropping the small electrical device when it is dropped. Examples of small electrical devices of the present invention include hair dryers and beauty devices that warm the skin surface.

1 is a vertical sectional side view of a main part of a hair dryer to which a lamp support structure according to a first embodiment of the present invention is applied; 1 is a vertical sectional side view of a hair dryer to which a lamp support structure according to a first embodiment of the present invention is applied; FIG. 2 is an exploded perspective view of the lamp support structure according to the first embodiment of the present invention. 2 is a cross-sectional view taken along line AA in FIG. 1 showing a cross-sectional plan view of the lamp support structure according to the first embodiment of the present invention. 2 is a cross-sectional view taken along line BB in FIG. 1 showing a longitudinal front view of the support portion. FIG. 11 is an exploded perspective view of a lamp support structure according to a second embodiment of the present invention. FIG. 11 is an exploded perspective view of a lamp support structure according to a third embodiment of the present invention.

(Example 1) Figures 1 to 5 show Example 1 in which the lamp support structure according to the present invention is applied to a hair dryer using a halogen lamp that emits light including infrared rays as a heat source. In this example, front, back, left, right, and up and down refer to the crossed arrows shown in each figure and the indications of front, back, left, right, and up and down written near each arrow. In Figure 2, a hair dryer (attachment object) D has a horizontally elongated cylindrical main body case 1 and a grip 2 formed on the lower surface near the rear of the main body case 1 and protruding downward. The main body case 1 and the grip 2 are formed by joining a pair of left and right cases 3 and 4 that have opposite shapes (see Figure 5). Inside the grip 2, a slide switch is arranged to start or stop the operation of the hair dryer and to switch between hot and cold air modes, and the switch is switched by a slide knob provided on the front of the grip 2.

The main body case 1 has an air inlet 5 at its rear end and a dry air outlet 6 at its front end. The inlet 5 has an inlet grill 7 made of punched metal, and the outlet 6 has an outlet grill 8 made of metal mesh. Both grills 7 and 8 are clamped and fixed between the left and right cases 3 and 4, and both prevent hair, clothing, fingers, etc. from getting inside the main body case 1.

Inside the main body case 1, there are provided an axial flow type blower fan 11 that generates dry air, a fan motor 13 that is supported by a fan case 12 and drives the blower fan 11 to rotate, a heater 14 made of nichrome wire as a heat source, and a halogen lamp (lamp) 15 that emits light including infrared rays. The blower fan 11, the fan motor 13, the heater 14, and the halogen lamp 15 are arranged in the order shown from the intake port 5 toward the exhaust port 6. The heater 14 is a heat source for heating the dry air, and the halogen lamp 15 is a heat source for directly heating the object to be dried with radiated light. The fan case 12 is composed of an outer cylinder 16 and an inner cylinder 17 made of a round cylinder, a radial connecting rib 18 that connects both cylinders 16 and 17 together, and the like, and is fastened and fixed to the left case 3 with screws. The fan motor 13 is fixed inside the inner cylinder 17, and the blower fan 11 is fixed to the rotating shaft of the fan motor 13 that protrudes backwards.

An air guide tube 21 is arranged on the front side of the fan case 12, and the air guide tube 21 is formed in a tapered cylindrical shape with the diameter of the rear end being approximately the same as the diameter of the outer tube 16. The outer tube 16 and the air guide tube 21 form a main flow path 22 for dry air from the intake port 5 to the exhaust port 6 inside the main body case 1. An insulating frame 23 made of mica plates arranged in a cross shape is provided inside the air guide tube 21, and the heater 14, which is one of the heat sources, is wound spirally around the insulating frame 23. The upper wall of the air guide tube 21 is open in front of and behind the part where the heater 14 is arranged, and the rear opening is an outlet 24 that outputs a part of the dry air between the main body case 1 and the air guide tube 21, and the front opening is an inlet 25 that reintroduces the dry air output from the outlet 24 into the air guide tube 21. As a result, a secondary flow path 26 for dry air is formed between the upper wall of the main body case 1 and the upper wall of the air guide tube 21.

As shown in FIG. 2, the halogen lamp 15 is disposed in the secondary flow path 26, and an irradiation window 27 that irradiates the light of the halogen lamp 15 forward is opened above the air outlet 6. An optical filter 28 that blocks the light in the visible light range emitted by the halogen lamp 15 is attached to the irradiation window 27, and the optical filter 28 prevents the user from feeling dazzled. The halogen lamp 15 is cooled by the dry air flowing through the secondary flow path 26.

3 and 4, the halogen lamp 15, which is one of the heat sources, comprises a bulb portion 31 made of a stepped glass tube, a rectangular block-shaped sealing portion 32 provided at the rear end (one end) of the bulb portion 31, and a pair of parallel connection pins (connection portions) 33 protruding rearward from the rear end (one end) of the sealing portion 32. Halogen gas is sealed in the bulb portion 31, and a coil-shaped filament 34 is provided inside. The filament 34 is supported by a pair of left and right power supply rods 35 formed in a long and short L shape extending from the sealing portion 32, and is disposed at approximately the center of the bulb portion 31. Each power supply rod 35 is supported in a cantilevered manner by the sealing portion 32, and the left power supply rod 35 and connection pin 33, and the right power supply rod 35 and connection pin 33 are connected inside the sealing portion 32.

As shown in Figures 1, 3, and 4, the axis of the filament 34 in this embodiment extends in the front-to-rear direction. The axis of the filament 34 and the axis of the pair of power supply rods 35 are arranged on a horizontal plane defined by the front-to-rear direction and the left-to-right direction. The axis of the connection pin 33 extends in the front-to-rear direction and is also arranged on the horizontal plane.

The halogen lamp 15 is supported by the lamp support structure in the secondary flow path 26. The lamp support structure includes a support portion 38 provided on the hair dryer D and a lamp holder 39 supported by the support portion 38 (see Figs. 1 and 4). The lamp holder 39 is formed of a holder base 40 made of a printed circuit board having a rectangular shape in a plan view, and a socket portion (mounting portion) 41 into which the connection pin 33 of the halogen lamp 15 is inserted and mounted is provided on the front side (one side) of the holder base 40. The holder base 40 is formed with a stepped socket notch 43 having a middle step portion 42 on the front edge, and the socket portion 41 composed of a pair of left and right socket bodies 44 is arranged in the socket notch 43. Each socket body 44 is formed by folding a conductive metal plate in half, and a circular socket hole 45 into which the connection pin 33 is inserted is provided in the folded portion. Each socket body 44 has the opposite end of the socket hole 45 fastened and fixed to the holder base 40 with a rivet 46, with the socket hole 45 facing the socket notch 43. The holder base 40 is formed with printed wiring that connects to the socket body 44. The socket hole 45 is oriented in the front-to-rear direction, and the halogen lamp 15 is inserted and installed from the front to the rear in the front-to-rear direction of the socket part 41.

As shown in Figures 1 and 3, a support base 49 with a flat upper surface is formed midway through the upper wall of the air guide tube 21, and the support base 49 is covered by a rectangular box-shaped base cover 50 with an open bottom. The support section 38 is provided in the space surrounded by the support base 49 and base cover 50, and is equipped with a clamping body 51 that clamps and supports the lamp holder 39 in a direction perpendicular to the mounting direction (front-to-back direction) of the halogen lamp 15, which in this embodiment is in the vertical direction. In this embodiment, the clamping body 51 is composed of a pair of upper and lower clamping bodies 52 and 53, and the two clamping bodies 51 are arranged side by side in the left-right direction.

As shown in FIG. 3, each of the clamping bodies 52 and 53 has a flat cylindrical clamping boss 54 and four auxiliary ribs 55 formed radially at equal intervals around the clamping boss 54. The lower clamping body 53 is integrally protruded from the upper surface of the support base 49, and a support shaft 56 is protruded upward from the center of the clamping boss 54. The upper clamping body 52 is integrally protruded from the inner surface of the base cover 50, and a bearing hole 57 is formed in the center of the clamping boss 54 to engage with the support shaft 56. The upper and lower clamping bodies 52 and 53 can be connected in the appropriate positions by engaging the support shaft 56 with the bearing hole 57. In FIG. 3, the reference numeral 58 indicates a positioning protrusion for determining the fixed position of the base cover 50. The support shaft 56 may be protruded downward from the upper clamping body 52, and the bearing hole 57 to engage with the support shaft 56 may be formed in the lower clamping body 53. In FIG. 3, the reference numeral 59 denotes a relief notch 59 for preventing interference with the halogen lamp 15, and the relief notch 59 is formed by cutting out a part of the front wall of the base cover 50 and the upper wall that is continuous with the front wall.

As shown in FIG. 5, an upper buffer 61 is provided between the upper clamp 52 and the upper surface of the holder base 40, and a lower buffer 62 is provided between the lower clamp 53 and the lower surface of the holder base 40. As described above, the holder base 40 is supported by a pair of upper and lower clamps 52 and 53 via the upper and lower buffers 61 and 62. The upper buffer 61 and the lower buffer 62, together with the clamp 51 (upper clamp 52 and lower clamp 53), constitute the support section 38.

In FIG. 3, the reference numeral 64 denotes a buffer including upper and lower buffers 61 and 62. The buffer 64 is a rubber molded product consisting of upper and lower buffers 61 and 62 and a connector 63 connecting the buffers 61 and 62, which are molded together as a single unit. The upper and lower buffers 61 and 62 are formed of cylindrical blocks of the same diameter and height, and the connector 63 is formed of a cylindrical block of a smaller diameter than the buffers 61 and 62. The buffers 61 and 62 and the connector 63 are formed in a concentric position, and in this embodiment, the thickness of the connector 63 is set to be the same as the thickness of the holder base 40. The buffer 64 has a through hole 65 that penetrates from the upper buffer 61 to the lower buffer 62 along its axis, and the buffer 64 can be attached to the clamping body 51 by inserting the aforementioned support shaft 56 through the through hole 65. The hardness of the rubber that makes up the cushioning body 64 can be selected to provide an appropriate cushioning force according to the weight of the lamp holder 39 and the halogen lamp 15.

Between the buffer body 64 and the holder base 40, a temporary fixing structure is provided to improve the assembly of the lamp support structure. This temporary fixing structure is composed of a holding slit 68 formed by cutting out the left and right edges near the rear end of the holder base 40. Specifically, the holding slit 68 is composed of a linear insertion groove 69 formed with a width dimension smaller than the diameter dimension of the connector 63, and a circular holding groove 70 continuous with the insertion groove 69, and the diameter dimension of the holding groove 70 is set to the same as the diameter dimension of the connector 63 of the buffer body 64. In order to facilitate the insertion of the connector 63 into the holding groove 70, the boundary between the insertion groove 69 and the edge of the holder base 40 is cut obliquely. As described above, the buffer body 64 can be temporarily fixed to the holding slit 68 by inserting the connector 63 into the holding slit 68 through the insertion groove 69. In this temporary fixing state, the opposing surfaces of the upper buffer body 61 and the lower buffer body 62 of the buffer body 64 are in close contact with the upper and lower surfaces of the holder base 40. In addition, from this provisionally fixed state, the shaft 56 of the lower clamping body 53 is inserted into the through hole 65 of the buffer body 64, and the shaft 56 is engaged with the bearing hole 57 of the upper clamping body 52, so that the lamp holder 39 can be clamped and supported by the upper and lower clamping bodies 52 and 53 via the buffer bodies 61 and 62. The provisionally fixed structure can also be configured with a hole that penetrates the holder base 40. As a result, the rear side (other side) of the lamp holder 39 is supported in a cantilevered manner by the support part 38.

As described above, when the lamp holder 39 is clamped and supported by the upper and lower clamping bodies 52 and 53 (clamping body 51), the lamp holder 39 is supported so as to be swingable in one direction, i.e., the vertical direction, with the clamping portion of the clamping body 51 as a fulcrum. More specifically, the lamp holder 39 is clamped and supported so as to be swingable in the vertical direction, with the clamping portion of the upper and lower clamping bodies 52 and 53 as a fulcrum, between a neutral position in which the extension direction of the halogen lamp 15 coincides with the front-to-rear direction, and a displaced position in which the extension direction of the halogen lamp 15 does not coincide with the front-to-rear direction. In this embodiment, the lamp holder 39 is supported in a cantilever manner by the support portion 38 near its rear end, so that when a large impact is applied, such as when the hair dryer D is dropped, the front end side, i.e., the tip side of the halogen lamp 15, swings and displaces significantly. Additionally, the upper and lower cushions 61 and 62 normally hold the lamp holder 39 in a neutral position, and when an impact is applied to the hair dryer D and the lamp holder 39 oscillates out of the neutral position, the upper and lower cushions 61 and 62 gradually reduce the speed of the lamp holder 39's oscillation and then return it to the neutral position.

As shown in FIG. 4, the diameter of the clamping boss 54 constituting each clamping body 52, 53 is smaller than the diameter of the upper and lower buffer bodies 61, 62. When each buffer body 61, 62 is assembled to the clamping body 52, 53, the lower surface of the clamping boss 54 of the upper clamping body 52 and the lower surface of the auxiliary rib 55 are in contact with the upper surface of the upper buffer body 61, and the upper surface of the clamping boss 54 of the lower clamping body 53 and the upper surface of the auxiliary rib 55 are in contact with the lower surface of the lower buffer body 62. Therefore, when the lamp holder 39 is swung and displaced as described above, each buffer body 61, 62 can deform outward at the peripheral portion as well as the portion not in contact with the clamping boss 54 and the auxiliary rib 55.

As shown in Figs. 1 and 4, the lamp holder 39 is supported by the support 38 near its rear end. Therefore, the center of gravity of the lamp holder 39, which is made of a flat printed circuit board and has a socket 41 at its front, is located closer to the halogen lamp 15 (front) than the clamp 51. Therefore, the clamp 51 is provided at a position shifted rearward from the center of gravity of the lamp holder 39. In addition, since the socket holes 45 are arranged side by side, when the halogen lamp 15 is attached to the lamp holder 39, the arrangement plane (horizontal plane) of the filament 34 and power supply rod 35 is perpendicular to the clamping direction (up-down direction) of the upper and lower clamps 52 and 53 (clamping parts 51).

The lamp support structure having the above-mentioned configuration is assembled by first temporarily fixing the buffer body 64 to the left and right holding slits 68 of the holder base 40. Next, the through hole 65 of the buffer body 64 and the support shaft 56 are aligned, and the support shaft 56 is inserted into the through hole 65 to support the holder base 40 on the lower clamping body 53. Next, the support shaft 56 is aligned with the bearing hole 57 of the base cover 50, and the base cover 50 is placed on the support base 49, and the support base 49 and the base cover 50 are adhesively fixed, so that the lamp holder 39 can be clamped and supported by the upper and lower clamping bodies 52 and 53 via the buffer bodies 61 and 62. Finally, the connection pin 33 of the halogen lamp 15 is inserted into the socket hole 45, and the halogen lamp 15 is attached to the lamp holder 39. The rear end of the sealing portion 32 of the halogen lamp 15 attached to the socket portion 41 is received by the middle step portion 42 of the socket notch 43.

As described above, in the lamp support structure according to the embodiment, the lamp holder 39 is configured to be supported by being clamped so that it can swing in the clamping direction, with the clamping portion of the clamping portion 51 (upper and lower clamping bodies 52, 53) of the support portion 38 as a fulcrum. Therefore, when an impact is applied to the hair dryer D, the lamp holder 39 can be displaced by swinging, thereby dissipating the impact and preventing the impact from directly acting on the halogen lamp 15 attached to the lamp holder 39.

In addition, in this embodiment, a buffer 64 is provided between the clamping body 51 and the lamp holder 39, which holds the lamp holder 39 in a neutral position in the normal state and returns the lamp holder 39 to the neutral position when the lamp holder 39 is swung from the neutral position. Even if the lamp holder 39 is swung due to an impact, the buffer 64 gradually attenuates the swinging displacement speed of the lamp holder 39, allowing the lamp holder 39 to slowly return to the neutral position. This prevents the power supply rod 35 and filament 34 arranged inside the bulb section 31 from breaking due to an increase in the swinging displacement speed of the lamp holder 39 or due to the lamp holder 39 swinging over a long period of time. Furthermore, the buffer 64 can buffer the impact acting on the lamp holder 39, which also prevents the power supply rod 35 and filament 34 from breaking.

The buffer 64 is configured to include an upper buffer 61 provided between the upper clamp 52 constituting the clamp 51 and the lamp holder 39, and a lower buffer 62 provided between the lower clamp 53 constituting the clamp 51 and the lamp holder 39, so that the two buffers 61 and 62 provided above and below can more reliably buffer the impact acting on the lamp holder 39. Since the damping force borne by each buffer 61 and 62 can be distributed, the swing displacement speed of the lamp holder 39 can be more reliably attenuated gradually. As described above, the lamp support structure configured in this way can more reliably prevent the lamp 15 from breaking. Compared to a configuration in which only one of the buffers 61 and 62 is used to buffer the impact, the buffer 64 can be prevented from deteriorating, so that the effect of preventing breakage can be maintained for a longer period of time.

When the plane defined by the front-rear and left-right directions is defined as the horizontal plane, the axes of the power supply rod 35 and the filament 34 are arranged on the horizontal plane, so that the direction of movement of the filament 34 caused by the elastic deformation of the power supply rod 35 can be made to coincide with the swing direction of the lamp holder 39. This makes it possible to suppress the impact on the filament 34 caused by the elastic deformation of the power supply rod 35 in addition to the swing displacement of the lamp holder 39, and therefore makes it possible to greatly reduce the impact acting on the filament 34, which is particularly prone to breakage.

The clamping body 51 is provided at a position shifted in the front-rear direction from the center of gravity of the lamp holder 39, so that the lamp holder 39 can be easily swung and displaced compared to when the clamping body 51 clamps and supports the lamp holder 39 at the center of gravity, and the function of preventing the halogen lamp 15 from breaking due to the swinging displacement of the lamp holder 39 can be effectively exerted.

By arranging a pair of clamping bodies 51 side by side in the left-right direction, the number of fulcrums is increased compared to a configuration with a single clamping body 51, allowing the lamp holder 39 to be clamped and supported by the support section 38 more accurately. In addition, with a configuration with a single clamping body 51, there is a risk that the lamp holder 39 will rotate around an axis in the vertical direction, but by providing a pair of clamping bodies 51 on the left and right, this rotation can be prevented, allowing the lamp holder 39 to be displaced to a more appropriate position.

A holding slit 68 into which the connector 63 is inserted is cut out and formed in the lamp holder 39. When the connector 63 is inserted into the holding slit 68, the cushion 64 is attached to the lamp holder 39 with the opposing surfaces of the upper and lower cushions 61 and 62 in close contact with the lamp holder 39. This allows the cushion 64 to be temporarily fixed to the lamp holder 39. In addition, the cushion 64 can be assembled to the cushions 61 and 62 from this temporarily fixed state, making it easy to build a support structure.

Since the upper and lower buffer bodies 61 and 62 and the connecting body 63 connecting the upper and lower buffer bodies 61 and 62 are integrated as the buffer body 64, the support structure can be constructed more easily than a configuration in which each buffer body 61 and 62 is individually assembled to the clamp body 51. Since the number of parts can be reduced, the cost of the support structure can also be reduced. In addition, a through hole 65 is formed in the buffer body 64, penetrating from the upper buffer body 61 to the lower buffer body 62, a support shaft 56 is formed in one clamp body 52, which extends toward the other clamp body 53 and is inserted into the through hole 65, and a bearing hole 57 with which the support shaft 56 engages is formed in the other clamp body 53, so that it is possible to reliably prevent misalignment between the pair of clamp bodies 52 and 53 and the buffer body 64. Therefore, the shock absorbing effect of the upper and lower buffer bodies 61 and 62 can be obtained more accurately. The cushioning body 64 can be attached to the clamping body 51 simply by inserting the support shaft 56 through the through hole 65, making it easier to build a support structure.

Since each of the buffer bodies 61 and 62 is made of a cylindrical block-shaped elastic body of the same diameter and height, it is possible to assemble the buffer body 64 in an upside-down position to the clamping bodies 52 and 53. Therefore, the assembly work of the buffer body 64 is simplified, and the support structure can be constructed more easily. In addition, each of the clamping bodies 52 and 53 is provided with a clamping boss 54 formed of a cylindrical block with a smaller diameter than the upper and lower buffer bodies 61 and 62, and a plurality of auxiliary ribs 55 formed radially from the periphery of the clamping boss 54, so that each of the buffer bodies 61 and 62 can be deformed not only in the outer direction of the periphery, but also in the outer direction of the end face that is not in contact with the clamping boss 54 and the auxiliary rib 55. As a result, each of the buffer bodies 61 and 62 can be deformed more greatly, so that each of the buffer bodies 61 and 62 exerts a greater shock absorbing effect. Incidentally, when the entire end face of each of the buffers 61, 62 is in contact with the clamping body 52, each of the buffers 61, 62 deforms only in the outward direction of its circumference, so the amount of deformation of each of the buffers 61, 62 is small.

(Example 2) FIG. 6 shows Example 2 in which the lamp support structure according to the present invention is applied to a hair dryer using a halogen lamp that radiates light including infrared rays as a heat source. In this example, the configuration of the lamp holder 39 is different from that of Example 1. Specifically, the holder base 40 constituting the lamp holder 39 is composed of an isosceles trapezoidal base portion 73 and a pair of arm portions 74 each extending forward from both ends of the front edge of the base portion 73. A socket notch 43 is formed between the pair of arm portions 74, and a socket portion 41 composed of a pair of left and right socket bodies 44 is arranged in the socket notch 43. In addition, a holding slit 68 is formed at the tip (front end) of each of the pair of arm portions 74. In this example, the holder base 40 is supported by the front end of each arm portion 74, in other words, the lamp holder 39 is supported by the support portion 38 near its front end. Therefore, the center of gravity of the lamp holder 39 having the socket portion 41 on its rear side is located behind the clamping body 51. In this way, the center of gravity of the lamp holder 39 may be located behind the clamping body 51. Since the rest of the embodiment is the same as in Example 1, the same members are given the same reference numerals and their explanations are omitted. The same applies to the following embodiments.

(Example 3) Figure 7 shows Example 3 in which the lamp support structure according to the present invention is applied to a hair dryer using a halogen lamp that emits light including infrared rays as a heat source. In this example, the support section 38 is composed of one clamping body 51 and a pair of buffer bodies 61 and 62, and the lamp holder 39 is supported at one point in the rear left corner by the clamping body 51, which is different from the previous Example 1. Specifically, one holding slit 68 is formed on the left side of the rear edge of the holder base 40, a buffer body 64 is arranged in the holding slit 68, and the lamp holder 39 is supported by the upper and lower clamping bodies 52 and 53 so that it can swing up and down. A socket notch 43 is cut out and formed on the right side of the front edge, which is a diagonal position of the holder base 40, and a socket section 41 composed of a pair of left and right socket bodies 44 is arranged in the socket notch 43.

The upper and lower buffer bodies 61 and 62 are formed of oval blocks, and the connecting body 63 is formed of an oval block having a smaller diameter than the buffer bodies 61 and 62. The buffer bodies 61 and 62 and the connecting body 63 are formed in a concentric position, and a through hole 65 is provided that is an oval hole that penetrates from the upper buffer body 61 to the lower buffer body 62 along the axis. The clamping bosses 54 of the upper and lower clamping bodies 52 and 53 are each formed in an oval shape that is long in the front and rear. In addition, the support shaft 56 of the lower clamping body 53 is formed in an oval shaft shape, and the bearing hole 57 of the upper clamping body 52 is composed of an oval hole that matches the support shaft 56. The holding groove 70 that constitutes the holding slit 68 is formed in an oval shape corresponding to the connecting body 63. As described above, the clamping body 51 may be one, and it is not necessary to provide two (multiple) clamping bodies 51 as in the previous embodiments. The support shaft 56 formed in an oval shaft shape can prevent the lamp holder 39 from rotating around the axis in the vertical direction.

In each of the above embodiments, the halogen lamp 15 in which the connection portion 33 is constituted by a connection pin is applied, but for example, the connection portion 33 may be a connection portion 33 constituted by a screw-in base. In this case, the mounting portion 41 uses a female screw type socket. The halogen lamp 15 may also have a connection portion 33 other than these. The cushioning body 64 may be made of an elastic material such as an elastomer or a foamed resin. Both cushioning bodies 61 and 62 may be cylindrical blocks with different diameters and heights, or may be rectangular parallelepiped blocks. Either one of the upper and lower cushioning bodies 61 and 62 may be omitted. In this case, the omitted side directly clamps the lamp holder 39 with the clamping body 51. The holder base 40 constituting the lamp holder 39 may be made of a heat insulating and non-conductive material, and is not limited to a printed circuit board as in the above embodiments. In the above embodiments, the mounting direction of the lamp 15 to the lamp holder 39 and the extension direction of the main body case 1 coincided in the front-rear direction, but the present invention is not limited to this.

The lamp 15 supported by the lamp support structure of the present invention is not limited to halogen lamps, but can be applied to lamps in which the filament 34 is supported by the power supply rod 35. In addition, the attachment object D can be applied to beauty devices that warm the skin surface in addition to hair dryers.

15 Lamp 31 Bulb portion 33 Connection portion (connection pin)
34 Filament 35 Power supply rod 38 Support portion 39 Lamp holder 41 Mounting portion (socket portion)
51: clamping body 52: upper clamping body 53: lower clamping body 54: clamping boss 55: auxiliary rib 56: support shaft 57: bearing hole 61: upper buffer body 62: lower buffer body 63: connecting body 64: buffer body 65: through hole D: mounting object

Claims (8)

A support structure for fixing a lamp (15) to an object (D) to be attached, the lamp (15) comprising a bulb portion (31) having a filament (34) supported by a pair of power supply rods (35) and a connection portion (33) provided at one end of the bulb portion (31),
A support portion (38) provided on the attachment object (D);
a lamp holder (39) supported on one side by a support portion (38) and having an attachment portion (41) on the other side for allowing a connection portion (33) of a lamp (15) to be plugged in;
Including,
The support portion (38) includes a clamping body (51) that clamps and supports the lamp holder (39) so as to be swingable in one direction, that is, up-down direction, perpendicular to the front-to-rear direction, between a neutral position in which the extension direction of the lamp (15) coincides with the front-to-rear direction and a displaced position in which the extension direction of the lamp (15) does not coincide with the front-to-rear direction, when the mounting direction of the lamp (15) in the lamp holder (39) is defined as the front-to-rear direction;
A lamp support structure characterized in that a buffer body (64) for holding the lamp holder (39) in a neutral position is provided between the clamping body (51) and the lamp holder (39). The clamping body (51) is provided with upper and lower clamping bodies (52, 53) that clamp and support the lamp holder (39) from above and below.
The lamp support structure according to claim 1, wherein the buffer body (64) includes an upper buffer body (61) provided between the upper clamping body (52) and the lamp holder (39), and a lower buffer body (62) provided between the lower clamping body (53) and the lamp holder (39). The lamp support structure according to claim 1 or 2, in which the axis of the power supply rod (35) and the filament (34) are arranged on a horizontal plane when a plane defined by the front-rear direction and the left-right direction is defined as a horizontal plane. A lamp support structure according to any one of claims 1 to 3, in which the clamping body (51) is provided at a position shifted in the front-rear direction from the center of gravity of the lamp holder (39). A lamp support structure according to any one of claims 1 to 4, in which a plurality of clamping bodies (51) are arranged side by side in the left-right direction. The buffer body (64) includes a connector (63) that connects the upper buffer body (61) and the lower buffer body (62) to each other, and a through hole (65) that passes through from the upper buffer body (61) to the lower buffer body (62),
3. A lamp support structure as described in claim 2, wherein a support shaft (56) is formed in one of the upper and lower clamping bodies (52, 53) extending toward the other clamping body (52, 53) and inserted into the through hole (65), and a bearing hole (57) with which the support shaft (56) engages is formed in the other clamping body (52, 53). Each of the buffer bodies (61, 62) is made of a cylindrical block-shaped elastic body.
The lamp support structure according to claim 6, wherein each clamping body (52, 53) is provided with a clamping boss (54) formed of a cylindrical block having a smaller diameter than each buffer body (61, 62), and a plurality of auxiliary ribs (55) formed radially from the periphery of the clamping boss (54). The attachment target (D) is a small electrical device equipped with a heat source,
A small electrical device, the heat source of which is a lamp (15) that emits light including infrared rays, the lamp (15) being supported by the lamp support structure according to any one of claims 1 to 7.

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