JP2019087467A - Lighting device - Google Patents

Abstract

To provide a lighting device which prevents cutting of wiring while securing sealability.SOLUTION: In a lighting device A, a device body 1 which houses a light emitting part in a cylindrical body and a one-end part component 2 which is fitted on a one-end part of the device body 1, detachably attached thereto, and has a cylindrical shape with a lid are connected by an electric cable. The device body 1 has protruding parts 83a in an area on which the one-end part component 2 is fitted. The one-end part component 2 has a groove 20, which allows the protruding part 83a to enter thereinto from an opening end 21q opposite to a lid wall 21a and engages with a portion of the protruding part 83a which is located at the other end side of the device body 1, at a cylinder wall 21b.SELECTED DRAWING: Figure 12

Description

  The present invention relates to a lighting device including an instrument main body for housing a light emitting unit in a cylindrical body, and a covered cylindrical end portion component detachably attached to an end of the instrument main body in an externally fitted state.

  As a rod-like illumination device, for example, in Patent Document 1, “A light source that moves relative to the object to be detected in a state facing the object to be detected and irradiates light to the object to be detected, In the defective portion detection illumination for detecting a defective portion such as a flaw or a distortion on the to-be-detected body by confirming reflected light of light emitted to the to-be-detected body from the light source, heat generated in the substrate A heat sink for dissipating heat, a substrate having a lighting circuit held by the heat sink, a flat LED light source portion provided on the front surface of the substrate, the heat sink, the substrate, and the LED light source portion LED light source comprising a long semi-tubular body made of a translucent material, and covering the LED light source, and irradiating light from the LED light source linearly along the longitudinal direction of the semi-tubular body Aiming hand A switch button for controlling ON / OFF of the LED light source, and a chargeable power supply unit for supplying power to the LED light source, and a cylindrical grip portion extended from one end of the LED light source And a defect detection illumination having the The grip portion includes a housing and a lid portion, and the power supply portion is accommodated inside.

JP 2017-68897 A

In recent years, the number of electrical devices provided with charging terminals has increased. It is difficult to provide such a charging terminal on the lid of the grip of the document 1.
That is, the lid portion needs to ensure hermeticity with the housing, and in the case where it is fixed (screwed) by rotating like a screw with respect to the housing, the wiring can be cut by twisting. There is sex.
This invention is made in view of such a situation, Comprising: It aims at providing the illuminating device which can eliminate what a wiring cut | disconnects, ensuring airtightness.

  In order to solve the above-mentioned subject, a lighting installation concerning one mode of the present invention has a lid which is removably attached to an appliance main body which stores a light emitting part in a cylindrical body, and one end of the appliance main body in an outside fitting state. In a lighting device in which a tubular one end part component is connected by an electric cable, the fixture body has a projection in a region externally fitted by the one end part component, and the one end part component includes the projection A groove is provided in the cylinder wall which can be entered from the open end opposite to the lid wall and engaged with a portion of the convex portion located on the other end side of the instrument body.

  According to the present invention, since the one-end component is externally fitted to the instrument body, sealing can be ensured, and the convex portion of the instrument body engages with the groove of the one-end component, so that the amount of rotation can be reduced and the wiring is cut. You can get rid of something.

It is a perspective view of a lighting installation concerning this embodiment. It is a cross-sectional perspective view of an illuminating device. It is an exploded perspective view of a lighting installation. It is a perspective view of a cylindrical cover body, and is notching one part so that an inside may be known. It is a section perspective view of a power supply side cylinder. (A) is a cross-sectional perspective view which shows the connection part of a power supply side cylinder body and a cylindrical cover body, (b) is a cross-sectional perspective view which shows the connection part of a power supply side housing and one end part components. (A) is the figure which looked at the cross section in the position where the power supply part of the power supply side cylinder in an illuminating device is seen from one end side, (b) is the cross section expansion perspective of the side where the power supply part of the power supply side cylinder exists. FIG. It is a disassembled perspective view of the other end part side. (A) is a disassembled perspective view of a fixture, (b) and (c) is a cross-sectional perspective view of a ring body. It is an exploded perspective view of one end part side. (A) is a (horizontal) cross-sectional view of the one-end component, and (b) is a (longitudinal) cross-sectional perspective view of the one-end component. It is an enlarged plan view of one end part side. It is a circuit block diagram of a circuit part. It is a figure explaining mounting of an end part part.

<Overview>
A lighting device according to one aspect, an appliance main body for housing a light emitting unit in a cylindrical body, and an open cylindrical tubular end part part detachably mounted on an end of the appliance main body by an electric cable by an electric cable In the illumination device, the fixture body has a convex portion in a region externally fitted by the one end component, and the one end component is capable of entering from the open end opposite to the lid wall. The cylinder wall has a groove that engages with a portion of the convex portion located on the other end side of the instrument body.
In the illumination device according to another aspect, the groove has a groove extending in a circumferential direction of the cylindrical wall or a direction intersecting the circumferential direction in a region within 3/4 circumference of the circumferential direction. Thereby, the twist of the electric cable can be reduced.
In the illumination device according to another aspect, the groove extends from the opening end toward the lid portion of the one-end component toward the lid portion of the one-end component, and the lid portion in the axial groove portion And a circumferential groove extending in a circumferential direction from an end of the side, and the groove is the circumferential groove. This makes it possible to make it difficult for the one-end part to come off the instrument body.
In the illumination device according to another aspect, the circumferential groove portion has a width change area in which the groove width becomes narrower as the axial groove portion is separated. Thereby, it is possible to smoothly move in the groove of the convex portion.
In the illumination device according to another aspect, in the width change area of the circumferential groove, one of the surfaces forming the groove and located on the opening end side is the groove as it is separated from the axial groove. It approaches the other surface to be formed, which is located on the lid side. This can be easily implemented.
In the lighting device according to another aspect, the circumferential groove portion has a constant width region having a constant groove width on the opposite side of the axial direction groove portion with respect to the width change region. This makes it possible to make it difficult for the one-end part to come off the instrument body.
In the lighting device according to another aspect, the circumferential dimension of the constant width region is larger than the circumferential dimension of the convex portion. Thus, the convex portion can be accommodated in the constant width region.
In the illumination device according to another aspect, the one-end component has an abutment portion that abuts on a portion of the convex portion located in the constant width region that is located on the axial groove side. This makes it possible to make it difficult for the one-end part to come off the instrument body.

Embodiment
1. Overall Configuration An example of a lighting device will be described with reference to the drawings.
The lighting apparatus A, as shown in FIG. 1, includes a cylindrical instrument body 1 and an end component 2 mounted on one end of the instrument body 1, and an electric cable (not shown) is connected to the end component. ing. The lighting device A includes the other end component 3 attached to the other end of the tool body 1.
As shown in FIGS. 2 and 3, the appliance body 1 includes a cylindrical body 4, a light emitting unit 5, a circuit unit 6, and a power supply unit 7. The light emitting unit 5, the circuit unit 6 and the power supply unit 7 are accommodated in the cylindrical body 4.
As shown in FIG. 3, the cylindrical body 4 is composed of a power supply side cylindrical body 8 accommodating the power supply unit 7 and a cylindrical cover body 9 accommodating the light emitting unit 5 and the circuit unit 6.
The instrument body 1 is provided with hooks 14 at both ends in the cylinder axial direction, as shown in FIG. The instrument main body 1 is provided with a bridging portion 11 d at both end portions in the cylinder axis direction. The hook body 14 and the bridging portion 11 d here are provided on the fixture 10 attached to the one-end component 2 and the other-end component 3.
As shown in FIG. 1, the cylindrical body 4 is provided with an operation switch 41 for switching on, dim, and extinguish. In addition, the cylindrical body 4 is provided with a magnet 42 for attaching the lighting device A to a metal material or the like.
Each part will be described below.

2. Configuration of Each Part (1) Light-Emitting Unit As shown in FIG. 2, the light-emitting unit 5 includes a substrate 51 and one or more LED elements 52. The substrate 51 has a rectangular shape, and a plurality of LED elements 52 are arranged at intervals in the longitudinal direction of the substrate 51. The substrate 51 may have a reflective layer on a portion (surface) other than the mounting portion of the LED element 52. In the illumination device A, the side on which the LED element 52 is mounted, that is, the side from which light is emitted is referred to as the front side.

(2) Circuit Unit The circuit unit 6 includes a substrate and a plurality of electronic components 61 as shown in FIG. The board | substrate here is the board | substrate 51 which mounts the LED element 52 on the surface. The plurality of electronic components 61 are mounted on the back surface of the substrate 51. The plurality of electronic components 61 are configured to perform lighting, extinguishing, dimming (light reduction), and the like of the light emitting unit 5 by the operation of the operation switch 41 by the user. The substrate 51 may have a reflective layer in a portion excluding the mounting portion of the electronic component 61.
The circuit unit 6 is connected to the operation switch 41 and the power supply unit 7 by a wire not shown. The circuit unit 6 is connected to the light emitting unit 5 by a contact hole (not shown). In FIG. 2, the plurality of electronic components 61 are shown in two blocks, and the wiring and the like are omitted.

(3) Power Supply Unit As shown in FIG. 2, the power supply unit 7 includes a charge / discharge secondary battery, a so-called rechargeable battery 71, and a case 72 for housing the rechargeable battery 71. The rechargeable battery 71 is connected to the input terminal 22 a (see FIG. 10) for charging the one-end component 2 and the circuit unit 6 by an electric cable (not shown).
The case 72 has a cylindrical shape, and as shown in FIG. 7, the rechargeable battery 71 is inserted in a state where the rechargeable battery 71 is in contact with the inner surface of the case 72. Here, the rechargeable battery 71 has a cylindrical shape, and the rechargeable battery 71 is in contact with portions (upper end and lower end) where the distance between the facing surfaces in the case 72 is maximum. Thereby, the rechargeable battery 71 is positioned in the direction orthogonal to the cylinder axis.

As shown in FIG. 7A, the cross-sectional shape of the case 72 is an annulus in which the bow shape of the upper end portion is removed from the circular shape. That is, the case 72 has a flat portion 73 at the upper end and an arc portion 74 projecting downward from both ends of the flat portion 73 in a circular arc larger than a semicircle, and between the flat portion 73 and the arc portion 74 Is the step 75. The step 75 is a step recessed inward. The rear side rib 85a of the power supply side cylindrical body 8 shown in FIG. That is, the case 72 is supported by the power supply side cylindrical body 8 by fitting the flat portion 73 between the pair of first ribs 85 extending in the lateral direction of the power supply side cylindrical body 8.
As the case 72 and the rechargeable battery 71 are shown in FIG. 7B, the other end in the longitudinal direction is the second rib 86 of the power supply side cylinder 8 and the one end is the inner cylindrical portion of the one end part 2 They are in contact with 21m respectively. Thus, the power supply unit 7 is positioned in the axial direction of the cylindrical body 4.

(4) Power supply-side cylinder As shown in FIG. 5, the power supply-side cylinder 8 includes a cylinder 81 located at one end in the cylinder axial direction and a half cylinder 82 located at the other end in the cylinder axial direction. Have.
The power-supply-side cylinder 8 has an end-side mounting portion 83 for mounting the one-end component 2 (see FIG. 2) at one end of the cylinder portion 81 in the cylinder axial direction. The power-supply-side cylinder 8 has a switch mounting portion 84 for mounting the operation switch 41 (see FIG. 2) at the other end of the cylinder portion 81 in the cylinder axial direction. The power supply side cylindrical body 8 has a first rib 85 and a second rib 86 extending along the cylinder axis on the inner peripheral surface of the cylindrical portion 81.
The power supply side cylindrical body 8 has a magnet mounting portion 87 for housing the magnet 42 (see FIG. 2) at one end in the cylinder axial direction of the half cylindrical portion 82. The power supply side cylindrical body 8 has a cover fixing portion 88 for fixing the cylindrical cover body 9 at a connecting portion between the cylindrical portion 81 and the half cylindrical portion 82.
The total length of the cylindrical portion 81 and the total length of the half cylindrical portion 82 change according to the specification, and here, the total lengths of the cylindrical portion 81 and the half cylindrical portion 82 are substantially the same, and the switch mounting portion 84, the magnet mounting portion 87 and the cover The fixing portion 88 is provided at a connection portion between the cylindrical portion 81 and the semi-cylindrical portion 82 of the power supply side cylindrical body 8 so as to be easily operated by the user.

(4-1) Tubular Portion As shown in (a) of FIG. 7, the tubular portion 81 has a substantially annular cross-sectional shape. As shown in FIG. 5, the cylindrical portion 81 has a plurality of projecting streak portions 81 a that project outward from the outer periphery between the one end side mounting portion 83 and the switch mounting portion 84. As shown in FIG. 3, the ridge portions 81 a extend in the circumferential direction, and are provided on the front and back portions of the cylindrical portion 81 at intervals in the axial direction of the cylinder. As shown in FIG. 5, the portion in which the plurality of ridge portions 81a are formed is recessed from the portion 81b (see FIG. 3) in which the ridge portions 81a are formed. As shown in FIG. 5, the area where the plurality of ridge portions 81a are formed is a gripping area 81c that the user grips.

As shown in FIG. 5, the cylindrical portion 81 has an overhanging portion that protrudes to the outer periphery between the one end side mounting portion 83 and the gripping area 81c. The overhanging portion is composed of a first overhanging portion 81 d and a second overhanging portion 81 e projecting outward from the first overhanging portion 81 d from the one end side mounting portion 83 side.
The overhanging amount of the first overhanging portion 81d is larger than the thickness of the cylindrical wall 21b of the one-end component 2, as shown in FIG. 6B, and the surface of the first overhanging portion 81d is the cylinder of the one-end component 2. It is located on the outer peripheral side of the surface of the wall 21b. As a result, the one-end component 2 is positioned on the other end side in the cylinder axial direction.
The stepped portion 11e of the cylindrical portion 11a of the fixture 10 is fitted to the end surface and the surface of the first overhang portion 81d, and the end surface of the cylindrical portion 11a of the fixture 10 is on the end surface of the second overhang portion 81e. Contact (face). Thereby, the fixture 10 is positioned on the other end side of the cylindrical body 4 in the cylinder axial direction.

(4-2) Semi-cylindrical part As shown in FIG. 3, the semi-cylindrical part 82 extends in a semi-cylindrical shape from the other end in the axial direction of the cylindrical part 81 to the other end in the axial direction. The cylinder axes of the half cylinder portion 82 and the half cylinder portion 82 are the same straight line.
As shown in FIG. 2, the cylindrical cover body 9 is disposed in the semi-cylindrical portion 82, and light is emitted from a region where the semi-cylindrical portion 82 does not exist in the cylindrical cover body 9.

(4-3) One End Side Mounting Section The one end side mounting section 83 is cylindrical as shown in FIG. 5 and has one or a plurality of convex portions 83a at one end in the cylinder axial direction. Here, there are two convex portions 83a, and the two convex portions 83a are provided at portions facing each other across the cylinder axis. In addition, the convex part 83a is corresponded to an example of the convex part of this invention, and the one end part components 2 fit outside in the one end part in which the convex part 83a is provided.
The amount of protrusion of the convex portion 83a is substantially the same as the thickness of the cylindrical wall 21b of the one-end component 2, as shown in (b) of FIG. In other words, the convex portion 83a is configured not to project from the cylindrical wall 21b. Thereby, rotation with respect to the one-end-part 2 of the fixture 10 becomes smooth.
The convex portion 83a has a rectangular shape whose short side is in the cylinder axial direction as shown in FIG. As shown in FIG. 5, the convex portion 83 a is provided to be separated from one end to the other end of the power supply side cylindrical body 8. As a result, the portion of the one-end mounting portion 83 positioned closer to the one end than the convex portion 83a and the inner peripheral surface of the cylindrical wall 21b or the outer collar 21p of the one-end component 2 abut (face) And sealing can be improved.

(4-4) Switch Mounting Unit Here, a push button switch is used as the operation switch 41. More specifically, it is a three-step push button switch. The switch mounting portion 84 is provided on the front side portion of the cylindrical portion 81, as shown in FIG. As a result, the user can operate while holding the lighting device A, and operability can be improved.
The switch mounting portion 84 has a thick portion 84 a and a stepped hole 84 b provided in the thick portion 84 a. The step of the stepped hole 84b is larger at the opening on the front side. The operation switch 41 is disposed in the stepped hole 84b.
The switch mounting portion 84 has a convex portion at the peripheral portion of the stepped hole 84b. The convex portion here is the one end side convex portion 84c existing on one end side in the cylinder axial direction with respect to the stepped hole 84b and the other end side convex portion 84d existing on the other end side. The heights of the one end side convex portion 84c and the other end side convex portion 84d are substantially the same as the height of the operation switch 41, as shown in FIG. As a result, it has a function of preventing an erroneous operation of touching the operation switch 41 by mistake and a function of protecting the operation switch 41.

(4-5) First Rib As shown in (a) of FIG. 7, the first rib 85 is an inner peripheral surface of the cylindrical portion 81 and is orthogonal to the front and back direction when viewed from one end side in the cylindrical axial direction. It extends from the part facing in the direction. In the plane orthogonal to the cylinder axis, the direction orthogonal to the front and back direction is taken as the lateral direction.
The first rib 85 has a back side rib 85 a that extends from a substantially central portion in the front and back direction and abuts on the step 75 of the case 72 of the power supply unit 7. The distance between the pair of back side ribs 85 a corresponds to the lateral dimension of the flat portion 73 of the case 72.
The first rib 85 has a front side rib 85b which extends parallel to the back side rib 85a at an interval on the front side. The space | interval respond | corresponds to the magnitude | size of the fixing tool (screw) 44 for fixing the power supply side cylinder 8 and the cylindrical cover body 9, as shown to (a) of FIG.
The first rib 85 has a connecting portion 85c that connects the back side rib 85a and the front side rib 85b in the front and back direction. The first rib 85 has a lateral "H" shape when viewed from one end side in the cylinder axial direction. Thereby, the first rib 85 is reinforced.

(4-6) Second Rib As shown in (a) and (b) of FIG. 7, the second rib 86 has an inner circumferential surface close to the rear end of the cylindrical portion 81 when viewed from the one end side in the cylinder axial direction. And extend toward the cylinder axis. As shown in (b) of FIG. 7, the second rib 86 is provided on the other end side of the power supply unit 7 in the cylinder axial direction. One end of the second rib 86 abuts on the power supply unit 7. The other end of the second rib 86 in the cylinder axial direction is connected to the cover fixing portion 88, as shown in FIG.

(4-7) Magnet Mounting Unit Here, a neodymium magnet is used as the magnet 42. The magnet 42 here has a disk shape having a through hole at the center. As shown in FIG. 5, the magnet mounting portion 87 has a projecting portion 87 a that protrudes from the back surface on one end side of the half cylindrical portion 82 to the back side. And a screw hole 87c provided at the bottom of the recessed portion 87b. The recessed portion 87b is recessed from the back side of the protruding portion 87a. As shown in FIG. 2, a screw 43 passing through the through hole 42a (see FIG. 3) of the magnet 42 is screwed into the screw hole 87c.

(4-8) Cover Fixing Portion The cover fixing portion 88 is, as shown in FIG. 5, a plate-like portion 88a extending toward the cylinder axis from the inner peripheral surface of the boundary portion between the cylindrical portion 81 and the half cylindrical portion 82. The outer peripheral edge of the plate portion 88a has a groove portion 88b recessed on one end side in the cylinder axial direction, and through holes 88c and 88d formed in the plate portion 88a.
In other words, as shown in FIG. 6, the cover fixing portion 88 has an abutting portion (88 a) that abuts on the bottom wall 91 of the cylindrical cylindrical cover body 9 with a bottom and the bottom wall 91 of the cylindrical cover body 9. And a through hole (88c) formed in the contact portion (88a) and for fixing the cylindrical cover body 9, the groove portion (88b) to which the round flange portion 91e of the outer peripheral edge is fitted. 5) and a through hole (88d) which is formed in the abutment portion (88a) and for positioning the cylindrical cover body 9 and does not appear in FIG. And.

As shown in FIG. 5, the plate-like portion 88a has a disk shape having a through hole 88e at the center. The through hole 88 e is for inserting an electric cable (not shown) connecting the power supply unit 7 and the circuit unit 6 or an electric cable connecting the operation switch 41 and the circuit unit 6.
The groove portion 88 b is formed by a step which is recessed from the circular peripheral edge of the plate-like portion 88 a to one end side in the cylinder axial direction.
The through hole 88 c is for the screw 44 shown in FIG. 6 and, as shown in FIG. 5, a portion located on the back end side in the front and back direction passing through the cylinder axis and a lateral direction with respect to the pair of first ribs 85. It is provided in a total of three places with the part located inside. The three parts are located at each vertex of the isosceles triangle when viewed from the cylinder axis direction.
The through holes 88d are for the pin portion 91d of the cylindrical cover body 9 shown in FIG. 6, and are provided at two positions on the outside located in the lateral direction with respect to the pair of second ribs 86 as shown in FIG. ing.

(5) Cylindrical Cover Body The cylindrical cover body 9 has a bottomed cylindrical shape as shown in FIG. The cylindrical cover body 9 has a bottom wall 91 and a cylindrical wall 92. The cylindrical cover body 9 is a so-called milky white cover. In the assembled state, as shown in FIG. 1, a portion not facing the half cylinder portion 82 of the power supply side cylinder 8 is a light emission area 9 a from which the light from the light emission unit 5 is emitted. In other words, the lighting device A is a so-called single-sided (surface) irradiation type in which light is emitted from the cylindrical cover body 9 exposed to the outside. As a result, the back side becomes dull and easy for the user to use. Further, it is not necessary to prevent the light from being emitted from other than the light emitting region 9a in the cylindrical cover body 9, and single side irradiation can be performed with a simple structure.

The bottom wall 91 has a through hole 91a at the center, three bosses 91b projecting inward, a screw hole 91c formed corresponding to the boss 91b, and an outward extending in the axial direction of the cylinder. And an annular flange portion 91e which protrudes outward in the axial direction of the cylinder from the outer peripheral edge.
The through hole 91 a is for inserting an electric cable (not shown) connecting the power supply unit 7 and the circuit unit 6 or an electric cable connecting the operation switch 41 and the circuit unit 6.
When the cylindrical cover 9 is incorporated into the power source side cylinder 8, as shown in FIG. 2, the cylindrical cover 9 is supported by the half cylinder 82 on the back side of the light emitting unit 5. Thereby, the coupling between the cylindrical cover body 9 and the power supply side cylindrical body 8 can be strengthened.
When the cylindrical cover body 9 is incorporated into the power source side cylinder body 8, as shown in FIG. 6, the round flange portion 91e is inserted into the groove portion 88b of the cover fixing portion 88, and the boss portion 91b and the screw hole 91c are power sources. The pin portion 91 d is fitted in the through hole 88 d of the cover fixing portion 88 so as to face the through hole 88 c (see FIG. 5) of the cover fixing portion 88 of the side cylindrical body 8. In addition, as shown in FIG. 6, the screw 44 which penetrates the through-hole 88c (refer FIG. 5) of the cover fixing | fixed part 88 is screwed together to the screw hole 91c.

As shown in FIG. 4, the cylindrical wall 92 has a screw portion 92 b at one end side except for the other end portion 92 a in the cylinder axial direction. The screw portion 92 b is formed on the outer peripheral surface. The other end component 3 shown in FIG. 3 is screwed into the screw portion 92b.
The cylindrical wall 92 has an outer collar portion 92c projecting outward on the other end side of the screw portion 92b. As shown in FIG. 2, the stepped portion 11 e of the fixture 10 is fitted to the outer collar portion 92 c. As shown in FIG. 4, the cylindrical wall 92 has a groove 92 e recessed along one end of the cylindrical wall 92 in the back portion of the outer collar portion 92 c (which is the back side of the light emitting area 9 a). As shown in FIG. 2, the other end 82 a of the half cylindrical portion 82 of the power supply side cylindrical body 8 is inserted into the groove 92 e. The groove 92e has a semicircular shape when viewed from one end side in the cylinder axial direction. Thereby, the other end 82a of the half cylindrical portion 82 can be supported and fixed.

The cylindrical wall 92 has a support portion for supporting the substrate 51 on the inner circumferential surface, as shown in FIG. The support portion is constituted by a groove 92d formed between a pair of convex portions projecting in the lateral direction from the inner circumferential surface. As shown in FIG. 2, the lateral end of the substrate 51 is inserted into the groove 92d. Thereby, the substrate 51 can be supported in a stable state.
The groove 92 d is continuously provided across the longitudinal ends of the substrate 51. This can prevent light from leaking between the substrate 51 and the groove 92 d to the back side. In addition, the heat at the time of light emission of the light emitting portion 5 is transmitted from the substrate 51 to the cylindrical cover body 9 in a wide range via the groove 92 d.

(6) Other end part component As shown in (b) of FIG. 8, the other end part component 3 is in the shape of a covered cylinder. Here, it has a cylindrical shape. The other end part component 3 has a lid wall 31 and a cylinder wall 32.
The lid wall 31 is shaped such that the central portion protrudes outward. The lid wall 31 has an annular lid portion 31 a and a projecting portion 31 b which protrudes from the inner peripheral edge of the lid portion 31 a in a bottomed cylindrical shape. The protrusion 31 b has a lid portion 31 c and a cylindrical portion 31 d.
The lid wall 31 has, on the inner surface of the lid 31a, an outer cylinder portion 31e extending cylindrically toward one end side in the cylinder axial direction, as shown in FIG. A ring-shaped packing 34 shown in FIG. 8 is disposed between the outer cylinder portion 31 e and the cylinder wall 32.
As shown in FIG. 8A, the lid wall 31 has an extending portion 31f extending toward one end side in the cylinder axial direction on the inner surface of the lid portion 31c. The extended portion 31 f here has a cylindrical shape, and the extended end abuts on the other end surface of the substrate 51 as shown in FIG. 2. When the other end component 3 is attached to the other end of the cylindrical cover 9, one end surface of the substrate 51 abuts on the bottom wall 91 of the cylindrical cover 9. Thereby, the substrate 51 is positioned in the instrument body 1.

The cylindrical wall 32 has, on its inner circumferential surface, a screw portion 32 a which is screwed to the screw portion 92 b (see FIG. 2) on one end side of the cylindrical cover body 9. The cylindrical wall 32 has an outer collar portion 32b projecting outward at the other end. As shown in FIG. 2, the outer collar portion 32 b protrudes higher than the cylindrical wall 32 of the other-end component 3 screwed to the screw portion 92 b. Thus, the other end component 3 is placed on one end side in the cylinder direction.
As shown in FIG. 2, the stepped portion 11 e of the fixture 10 is fitted to the end surface and the surface on the other end side of the outer collar portion 32 b. Thereby, the fixture 10 is positioned in the cylinder axis direction.

(7) One-End Component As shown in FIG. 10, the one-end component 2 includes a covered cylindrical main body 21 and an input terminal portion 22 attached to the main body 21. Here, the one-end component 2 includes a cap 23 that covers the input terminal 22 a of the input terminal unit 22. In addition, although the fixture 10 is attached like the other end part components 3, since the structure of the fixture 10 is the same, the description here is abbreviate | omitted. In addition, the input terminal here is demonstrated as a terminal for charge.

(7-1) Main Body As shown in FIGS. 10 and 11, the main body 21 has a lid wall 21a and a cylindrical wall 21b. The main body 21 has a through hole 21c for the input terminal 22a in the lid wall 21a. The main body 21 has a mounting portion 21 d for mounting the cap 23 shown in FIG. 10 on the outer surface of the lid wall 21 a. The mounting portion 21d is erected on one end side from the central portion of the lid wall 21a.
The lid wall 21a has a thick portion 21e at its central portion as shown in FIG. 11 (b). The inner surface of the lid wall 21a is substantially flat. The lid wall 21a has a fixing portion for fixing the input terminal portion 22 in the thick portion 21e. As shown in FIG. 10, a screw 24 is used for fixing, and as shown in FIG. 11, the fixing portion is configured by a screw hole 21f into which a screw 24 inserted through the through hole 22c of the substrate 22b of the input terminal portion 22 is screwed. Be done.

As shown in FIG. 10, the main body 21 has a cylindrical portion 21g extending from the periphery of the thick portion 21e of the lid wall 21a to one end side. A screw 21 h is provided on the outer peripheral surface of the cylindrical portion 21 g. The screw portion 23c of the inner peripheral surface of the cap 23 is screwed into the screw 21h as shown in (b) of FIG. That is, the mounting portion 21d of the cap 23 is configured by the cylindrical portion 21g and the screw 21h.
As shown in (b) of FIG. 11, the main body 21 has an extending plate portion 21 j extending outward from the entire periphery of the thick portion 21 e, and between the extending plate portion 21 j and the lid wall 21 a. The large ring portion 26 a of the fall prevention device 26 of the cap 23 shown in FIG. 10 is fitted in the groove. The fall prevention tool 26 is made of a rubber material or the like.

As shown in FIG. 11, the main body 21 has an outer cylindrical portion 21l extending toward the other end side in the cylinder axial direction on the inner surface of the lid wall 21a. A ring-shaped packing 25 shown in FIG. 10 is disposed between the outer cylindrical portion 21 l and the cylindrical wall 21 b.
As shown in FIG. 11, the main body 21 has an inner cylindrical portion 21m extending toward the other end side in the cylinder axial direction on the inner surface of the lid wall 21a. An input terminal portion 22 is disposed in the inner cylindrical portion 21m. The inner circumferential surface of the inner cylindrical portion 21m has a convex portion 21n extending toward the central axis. The convex portion 21 n is fitted to the notch 22 d of the substrate 22 b of the input terminal portion 22 shown in FIG. 10. Thus, the rotation of the substrate 22b is restricted, and the torsional load acting on the input terminal 22a can be reduced.

  As shown in (b) of FIG. 10 and FIG. 6, the main body 21 has an outer collar portion 21 p projecting outward at one end of the cylindrical wall 21 b. The surface of the outer collar portion 21 p is configured to be higher than the surface of the ring body 11 of the fixture 10. Outside smaller than thickness. Thereby, the fixture 10 is positioned on one end side in the cylinder axial direction.

As shown in FIG. 12, the main body 21 has a groove 20 in the cylindrical wall 21b in which the convex portion 83a of the tool main body 1 (power supply side cylindrical body 8) engages. The grooves 20 here are through grooves.
The groove 20 engages (abuts) a portion 83b of the convex portion 83a which is capable of entering from the opening end 21q opposite to the lid wall 21a and which is located on the other end side of the instrument body 1 in the convex portion 83a. The groove 20 has a groove (20b) extending in a direction intersecting the cylinder axis in a region within 3/4 of the circumferential direction of the cylindrical wall 21b.
The groove 20 extends in the axial direction from the opening end 21q toward the lid 21a in the axial direction, and in the circumferential groove 20b in the circumferential direction from the end of the axial groove 20a on the lid 21a. And.

  When the one-end component 2 is attached to one end of the tool body 1 as viewed from the front and back (as shown in FIG. 12), the width (the groove width) of the axial groove 20a in the direction orthogonal to the cylinder axis is convex The width of the portion 83a is larger than the width in the direction orthogonal to the cylinder axis. The groove width of the axial groove 20a is constant.

The circumferential groove portion 20b has a width change area 20c in which the groove width which is the dimension in the cylinder axial direction becomes narrower as it is separated from the axial groove portion 20a, and a constant width area 20d having a constant groove width. The constant width region 20d is located on the opposite side of the axial groove 20a with respect to the width change region 20c.
In the width change area 20c of the circumferential groove 20b, the surface forming the groove and located on the opening end 21q side is a surface forming the groove as it is separated from the axial groove 20a, and the lid wall It approaches the other side 20f located on the 21a side.
In the constant width region 20d of the circumferential groove portion 20b, the one surface 20e and the other surface 20f are parallel. That is, the other surface 20f forming the groove of the circumferential groove 20b is orthogonal to the cylinder axis when viewed from the front and back direction.

The circumferential dimension of the constant width region 20d is larger than the circumferential dimension of the convex portion 83a. That is, the constant width region 20 d is a housing portion of the convex portion 83 a after the one-end component 2 is mounted.
The one-end part component 2 has an abutting portion 20g which abuts on a portion 83c located on the axial groove portion 20a side in the convex portion 83a accommodated in the constant width region 20d.
The contact portion 20g here is provided on one surface 20e. The contact portion 20g is provided at the boundary between the width change area 20c and the constant width area 20d. The contact portion 20g is constituted by a convex portion which protrudes from the one surface 20e toward the other surface 20f.
When attaching the one-end component 2 to the instrument main body 1, the packing 25 inside is compressed to be performed, and the one surface 20e presses the convex portion 83a side by its restoring force. Therefore, the one-end part component 2 and the instrument main body 1 are reliably fixed by using the elasticity of the packing 25 by the contact portion 20 g.

(7-2) Cap The cap 23 has a cylindrical shape with a lid, and as shown in (b) of FIG. 6, has a screw portion 23c in the cylindrical wall 23a. The screw portion 23 c is screwed into the screw 21 h on the outer periphery of the cylindrical portion 21 g of the one-end component 2.
The lid wall 23b of the cap 23 has a groove forming portion 23d that forms a groove in which the small ring portion 26b of the fall prevention device 26 fits.
The cap 23 has the cylindrical part 23e extended toward the other end side of a cylinder axial direction on the inner surface of the cover wall 23b, as shown to (b) of FIG. A ring-shaped packing 27 shown in FIG. 10 is disposed between the cylindrical portion 23e and the cylindrical wall 23a.

(7-3) Input Terminal Portion As shown in FIG. 10, the input terminal portion 22 is provided with the input terminal 22a on the substrate 22b. The input terminal 22a is provided upright on the substrate 22b, and the tip end of the input terminal 22a is led out from the through hole 21c of the lid wall 21a of the one-end component 2. Although not shown, an electric cable connected to the circuit unit 6 is connected to the substrate 22b.
The Micro-USB terminal etc. can be utilized for the input terminal 22a, and it can connect with the general purpose USB charger used for charge of a smart phone etc. as a charger, for example. Since it can be connected to a general-purpose USB charger, it is not necessary to sell the charger as an accessory of the lighting device A, and the cost can be reduced.

(8) Fixture The fixture 10 is rotatably attached to the one-end part 2 and the other-end part 3 as shown in FIG. Hereinafter, since the structure of the fixture 10 is the same structure irrespective of the one-end part component 2 or the other-end part component 3, the case where it is attached to the other-end part component 3 will be described as an example.
As shown in (a) of FIG. 9, the mounting tool 10 has a ring body 11 rotatably fitted on the cylindrical wall 32 of the other end part 3 and a direction orthogonal to the central axis of the ring body 11 as a rotation axis The rotary body 12 rotatably provided on the ring body 11 and the hook body 14 pivotally supported by the pin 13 orthogonal to the rotation axis of the rotary body 12 are provided. As a result, the hook body 14 can rotate in three axial directions, and the posture (orientation) of the hook body 14 can be freely changed.
The ring body 11 is rotatably fitted around the cylindrical wall 21 b when the attachment target is the one-end component 2.
Since the fixture 10 is rotatably set by the one-end component 2 and the other-end component 3, the cylindrical cover body 9 can be held horizontally using the pair of ring bodies 11. Moreover, the cylindrical cover body 9 can be freely fixed also to upper side and lower side, and the utilization range of the illuminating device A spreads.

As shown in FIG. 9, the ring body 11 has a cylindrical portion 11a, a protruding portion 11b protruding in a radial direction from the cylindrical portion 11a, and an inwardly-expanded stepped hole 11c penetrating the cylindrical portion 11a and the protruding portion 11b. And an extending portion 11d extending from the portion of the cylindrical portion 11a facing the projecting portion 11b so that a penetrating portion can be formed between the cylindrical portion 11a and the cylindrical portion 11a.
The stepped hole 11c opens in a circular cross section. The erecting portion 11 d is for a strap, and in this case, is erected in a “U” shape.

As shown in (b) of FIG. 9, the ring body 11 has a step portion 11 e on the inner periphery of the end portion on the inner side in the cylinder axial direction. As shown in FIG. 2, the stepped portion 11 e of the ring body 11 is fitted to the end face and the surface of the other end side of the outer collar portion 92 c of the cylindrical cover body 9. Thereby, the fixture 10 is positioned at one end side of the cylindrical body 4 in the cylinder axial direction.
When the object to which the ring body 11 is attached is the one-end component 2, as shown in FIG. 6B, the stepped portion 11e of the ring body 11 is on the one end side of the first overhang portion 81d of the power supply side cylinder 8 Fits the end face and the surface. Thereby, the fixture 10 is positioned on the other end side of the cylindrical body 4 in the cylinder axial direction.

The rotating body 12 has a stepped disk portion 12a, and a pair of plate portions 12c protruding in a plate shape from the stepped disk portion 12a and having a through hole 12b. The stepped portion 12 d of the stepped disk portion 12 a is inserted into the stepped hole 11 c of the ring body 11 from the inner peripheral side. The pins 13 are inserted and fixed in the through holes 12 b of the pair of plate portions 12 c. The total length of the pin 13 is larger than that of the stepped hole 11c, and when the pin 13 is fixed to the plate portion 12c, the rotating body 12 is not removed from the ring body 11.
The hook body 14 includes an insertion portion 14a through which the pin 13 is inserted, a first rectilinear portion 14b that rectilinearly moves in a direction orthogonal to the pin 13 from the insertion portion 14a, and a first rectilinear portion 14b and the pin at the tip of the first rectilinear portion 14b. It has a second rectilinear portion 14c which curves in a perpendicular direction and goes straight, and a partially elongated circular portion 14d which extends in a 3⁄4 oval shape from the end of the second rectilinear portion 14c.

When the hook body 14 is turned to the one-end part 2 side, as shown in (b) of FIG. 6, the lack circle portion 14 d is disposed along the cap 23. Since the hook body 14 and the cap 23 are in contact with or close to each other, the hook body 14 can be held on the cap 23 by both frictions. Thereby, when the hook body 14 is not used, the workability and the design of the lighting device A can be improved.
When the hook body 14 is turned to the other end part 3 side, the not-long circle portion 14d is disposed along the cylindrical portion 31d (see FIG. 8B) of the projecting portion 31b. Since the hook body 14 and the projection 31 b are in contact with or close to each other, the hook body 14 can be held on the projection 31 b by both frictions. Thereby, when the hook body 14 is not used, the workability and the design of the lighting device A can be improved.

3. The circuit will be described with reference to FIG.
(1) Block Diagram The circuit 62 includes a microcomputer 63, a charging circuit 64, a booster circuit 65, a protection circuit 66, and an operation switch 41.
The microcomputer 63 performs general control of the lighting device A such as control of charging of the rechargeable battery 71 and control of lighting, dimming and extinguishing of the light emitting unit 5 according to the operation of the operation switch 41. The microcomputer 63 receives power via the protection circuit 66.
Charging circuit 64 includes an input voltage detection unit that detects the voltage of input terminal 22a, a battery voltage detection unit that detects the voltage of rechargeable battery 71, and reverse current prevention that prevents current flow from rechargeable battery 71 to input terminal 22a. And a unit.
The booster circuit 65 boosts the voltage supplied from the power supply unit 7 or the voltage input from the input terminal unit 22. Boosting is performed corresponding to 100% irradiation and 50% irradiation by the operation of the operation switch 41.
The protection circuit 66 has a monitor unit that monitors the state of the rechargeable battery 71, and a shielding unit that blocks conduction with the rechargeable battery 71 when it detects an abnormality in the rechargeable battery 71. The monitor here is the temperature, current value or the like of the rechargeable battery 71.
The switch 67 selectively connects the charging circuit 64 and the booster circuit 65 and connects the protection circuit 66 and the booster circuit 65 according to an instruction from the microcomputer 63. Thereby, it is also possible to simultaneously perform irradiation and charging while charging. When the conduction between the boosting circuit 65 and the protection circuit 66 is disconnected, the power received from the input terminal 22 a is used to charge the rechargeable battery 71.

(2) Operation When the input terminal 22a is not connected to the charger and there is a lighting operation at the operation switch 41, the microcomputer 63 connects the protection circuit 66 and the booster circuit 65 to the changeover switch 67. , And instructs the booster circuit 65 to perform boosting in accordance with the lighting signal from the operation switch 41. When the light-off operation is performed, the microcomputer 63 instructs the changeover switch 67 to disconnect the protection circuit 66 and the booster circuit 65. Further, the operation switch 41 is configured to be operated by the microcomputer 63 so as to be operated by a long press operation at the time of lighting operation, and other operations by a short time operation to prevent malfunction.

  If the input terminal 22a is connected to a charger not shown and there is no operation at the operation switch 41, the microcomputer 63 instructs the charging circuit 64 to charge the rechargeable battery 71. At this time, when the input voltage detected by the input voltage detection unit is lower than the first threshold or when the input voltage is lower than the battery voltage, the microcomputer 63 prevents current from flowing from the rechargeable battery 71 to the input terminal 22a. The charging circuit 64 is instructed to do this. During charging, the LED 68 connected to the charging circuit 64 is lit. For example, as shown in FIG. 10, the LED 68 can be provided around the input terminal 22a on the substrate 22b.

  When input terminal 22a is connected to a charger not shown and there is a lighting operation at operation switch 41, microcomputer 63 determines that charging of rechargeable battery 71 is unnecessary, and from charging circuit 64 to boosting circuit 65. The switch switch 67 is instructed to flow current, and when it is determined that the rechargeable battery 71 needs to be charged, the switch switch 67 is instructed to flow current from the charging circuit 64 to the booster circuit 65 and the protection circuit 66. The microcomputer 63 determines the necessity / unnecessity of charging the rechargeable battery 71 based on the difference between the input voltage detected by the charging circuit 64 and the battery voltage.

4. Mounting of One-End Part Component Mounting of the one-end part component 2 to the appliance main body 1 (power-supply-side cylinder 8) will be described with reference to FIG.
In addition, in FIG. 14, in order to show the positional relationship of the convex part 83a and the groove | channel 20, the fixture 10 shown in FIG. 1 mounted | worn with the one-end part component 2 is removed.
(1) As shown in (a) of FIG. 14, the convex portion 83a of the power source side cylinder 8 and the groove 20 of the one-end component 2 are aligned, and the convex portion 83a is in the axial groove portion 20a of the groove 20. The end piece 2 is moved relatively in the direction of the arrow so as to enter. This movement is performed until the convex portion 83a reaches the back side of the axial groove portion 20a (one end side of the cylindrical wall 21b) as shown in (b) of FIG.
(2) Next, the one-end component 2 is relatively rotated in the direction of the arrow so that the convex portion 83a travels in the circumferential groove 20b of the groove 20. This rotation is performed until the convex portion 83a reaches the back of the circumferential groove 20b (opposite to the axial groove 20a) as shown in FIG. 14 (d) beyond the state of FIG. 14 (c). It will be. Thereby, the convex part 83a is locked by the contact part 20g.

As mentioned above, although embodiment was described, it is not restricted to this embodiment, For example, the following modifications may be sufficient. In addition, the embodiment, the modification, and the modifications may be combined.
In addition, even if there is an example not described in the embodiment or the modification, or a design change in a range not departing from the gist, the present invention is included.

<Modification>

(1) The groove 20 is formed of the through groove, but may be formed of a concave groove by lowering the convex portion. Thereby, the sealing performance can be improved.
(2) The circumferential groove 20b of the groove 20 extends in the direction orthogonal to the cylinder axis, but may extend in a direction (except 90 degrees) intersecting the cylinder axis, After extending in the intersecting direction, it may extend in the direction orthogonal to the cylinder axis, or after extending in the orthogonal direction, it may extend in the direction intersecting the cylinder axis.
(3) The one-end part component 2 is configured to be externally fitted to one end of the cylindrical body 4 (power source side cylinder 8), but may be configured to be internally fitted to the one-end component. Moreover, although the convex part 83a is each provided in the power supply side cylinder 8 side, and the groove | channel 20 is provided in the one end part components 2 side, you may be reverse.
(4) The one-end component 2 is provided with the cap 23 for protecting the input terminal 22a, but may be a protective member having another structure or may not be provided with the protective member. The provision of the protective member is preferable in terms of defects, breakage, waterproofing, dustproofing, and the like.
(5) The circumferential groove 20b has a length of 1⁄5 of the length of the cylindrical wall 21b. However, considering the sealing property, slippage, etc., the length of the circumferential groove is one-third of that of the cylindrical wall 1/7 lap is preferred. In addition, when the number of convex portions is one, it is preferable that the length of the groove in the circumferential direction is within 3/4 circumference. If it is more than this, there is a possibility that the wiring cable may be cut off by twisting or detached from the terminal.
(6) Although two convex portions 83a are provided, one convex portion may be provided, or three or more convex portions may be provided. Although the shape from the protrusion direction of the convex part 83a is carrying out the rectangular shape, another shape may be sufficient. Other shapes include a circle, an ellipse, an oval, a polygon such as a triangle, and a square.
(7) The cylindrical body 4 has two convex portions 83 a of the same shape, but may have a plurality of convex portions of different shapes and different dimensions. For example, by changing the dimensions of the two convex portions and changing the groove widths of the two grooves, the one-end part component can be attached to the cylindrical body in a predetermined posture.
(8) The circumferential groove portion 20b has the width change area 20c and the constant width area 20d, but for example, it may have only the constant width area or may have only the width change area. In addition, a plurality of constant width regions may be provided, or a plurality of width change regions may be provided. Further, the change rate of the width of the width change area may be constant or may be changed.
(9) In the width change area 20c, one surface is closer to the other surface, but for example, the other surface may be closer to the one surface, or one surface may be closer to the other surface.
(10) The contact portion 20g is constituted by a convex portion projecting from one surface to the other surface. For example, one surface constituting the constant width region 20d is an open end between the width changing region and the constant width region The contact portion may be configured to have a step-like shape that is recessed on the side, and the step may be used to form the contact portion, or the outer surface of the cylindrical wall and radially outside the boundary portion between the width change area and the constant width area. You may comprise by the convex part which protrudes to the direction.
(11) Although the fixture 10 is attached to the one-end part component 2, the fixture 10 may not be provided. In addition, since the groove 20 is closed by the cylindrical portion 11a of the fixture 10, it is preferable to be provided in consideration of waterproofing and dustproofing.

A Lighting device 1 Apparatus body 2 One end part part 4 Tubular body 5 Light emitting part 7 Power source part 8 Power source side tubular body 9 Tubular cover body 10 Mounting fixture

Claims (8)

In a lighting device in which an appliance main body for housing a light emitting unit in a tubular body and a covered cylindrical end part component detachably mounted on an end of the appliance main body in an externally fitted state are connected by an electric cable,
The device body has a convex portion in a region externally fitted by the one-end component,
The one end part part has a groove in a cylinder wall which can enter from the open end opposite to the lid wall and which engages with a part of the convex part located on the other end side of the instrument main body. apparatus. The lighting device according to claim 1, wherein the groove has a groove portion extending in a circumferential direction of the cylindrical wall or a direction intersecting the circumferential direction in a region within 3⁄4 circumference of the circumferential direction. The groove extends in the circumferential direction from an axial groove extending from the open end toward the lid of the one-end component from the open end of the cylindrical body, and an end on the lid side of the axial groove in the circumferential direction And a circumferential groove extending toward the
The lighting device according to claim 2, wherein the groove is the circumferential groove. The lighting device according to claim 3, wherein the circumferential groove has a width change area in which a groove width is narrowed as the axial groove is separated. In the width change area of the circumferential groove, one surface which is the surface forming the groove and located on the opening end side is a surface which forms the groove as it is separated from the axial groove and the lid The lighting device according to claim 4, which approaches the other surface located on the part side. The lighting device according to claim 5, wherein the circumferential groove has a constant width area having a constant groove width on the opposite side to the axial groove with respect to the width change area. The lighting device according to claim 6, wherein the dimension in the circumferential direction of the constant width region is larger than the dimension in the circumferential direction of the convex portion. The lighting device according to claim 7, wherein the one-end part component has an abutting portion that abuts on a portion of the convex portion positioned in the constant width region that is positioned on the axial groove side.

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