JP2015028872A - Lighting fitting - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lighting fitting that is provided with a pivot part for a support member in a fitting body while avoiding a power circuit in the fitting body, and has the fitting body made compact.SOLUTION: A lighting fitting includes: a cylindrical fitting body 21; an LED substrate 102 which is arranged on one axial end side of the fitting body 21 in the fitting body 21; a power circuit 103 which is arranged at a position offset from an axis C of the fitting body 21 on the other axial end side of the fitting body 21 in the fitting body 21, and electrically connected to the LED substrate 102; and an arm part 115 which supports the fitting body 21 rotatably by a pivot part 116. The pivot part 116 is arranged in a space S on the opposite side of the direction in which the power circuit 103 is offset in the fitting body 21.

Description

  The present invention relates to an LED board on which an LED element is mounted in a fixture body, and a lighting fixture including a power supply circuit that supplies power to the LED board.

  In recent years, indirect illumination has come to be frequently used. For example, in order to improve the atmosphere of a space, a spotlight that can illuminate with a part of an object emphasized is used. A spotlight is a lamp that illuminates a local area, and it can be installed on the ceiling or wall of a building by attaching a support member such as a rotatable and rotatable arm to the main body of the lamp so that the direction of light irradiation can be changed. Has been. As such a spotlight-type lighting fixture, a lighting fixture including an LED board on which an LED element is mounted in the fixture body and a power supply circuit for supplying power to the LED substrate is known (for example, Patent Document 1). reference).

  Patent Document 1 discloses a spotlight-type lighting fixture that is attached to a ceiling via a variable bracket that is a support member and can change the direction of light irradiation. In this spotlight type lighting fixture, an LED substrate and a power supply circuit (a power supply unit indicated by reference numeral 23 in Patent Document 1) are mounted in a fixture main body (lamp). In this spotlight-type lighting fixture, the fixture body is suspended from the ceiling by a variable bracket, and a shaft support portion (movable portion) for changing the light irradiation direction in the vertical direction is provided at the lower end of the variable bracket. Is. In this spotlight type lighting fixture, when the user tries to change the light irradiation direction, the fixture main body pivots up and down around the shaft support portion by gripping and moving the fixture main body, and the light irradiation direction Can be changed.

JP 2011-170990 A

  However, as in the lighting fixture disclosed in Patent Document 1, a device in which a power circuit is mounted in the fixture body (lamp) is provided with a shaft support portion outside the fixture body because the space in the fixture body is limited. There are many. On the other hand, when considering a configuration in which a shaft support portion is provided inside the fixture body in order to reduce the size of the lighting fixture, the rear portion of the power supply circuit is avoided by avoiding the power supply circuit mounted in the fixture body (in Patent Document 1, reference numeral Although the structure which provides a shaft support part in the rear part of the power supply unit shown by 23 is considered, in such a structure, the full length of an instrument main body becomes long and becomes disadvantageous when aiming at compactization of an instrument main body.

  Accordingly, the present invention has been made in view of the above problems, and a lighting device that avoids a power supply circuit in the fixture body and provides a shaft support portion of the support member in the fixture body, and is designed to be compact. The purpose is to provide.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

That is, the lighting fixture disclosed in this application is
A tubular instrument body;
A light source unit disposed on one end side in the axial direction of the instrument body in the instrument body;
A power supply circuit that is disposed at a position offset from the axis of the instrument body on the other axial end side of the instrument body in the instrument body, and is electrically connected to the light source unit;
A support member that rotatably supports the instrument body by a shaft support,
The shaft support is
It is arrange | positioned in the said instrument main body in the position offset from the axis line of the said instrument main body.

In the lighting fixture disclosed in the present application,
The shaft support portion is preferably arranged at a position facing the power supply circuit across the axis of the instrument body.

In the lighting fixture disclosed in the present application,
It is preferable that the light source unit is an LED substrate on which an LED element is mounted.

In the lighting fixture disclosed in the present application,
An end plate portion fixed by closing the other axial end of the instrument body;
The shaft support is
It is preferable that the end plate portion is provided.

In the lighting fixture disclosed in the present application,
One end of the support member is attached to the end plate part via the shaft support part, and the other end of the support member is attached to the attached part,
When the instrument body is rotated and the axial direction of the instrument body is arranged along the axial direction of the other end of the support member, the axis of the instrument body and the axis of the other end of the support member are the same. A configuration that is on the axis is preferable.

  ADVANTAGE OF THE INVENTION According to this invention, while avoiding the power supply circuit in an instrument main body, while providing the axial support part of a supporting member in an instrument main body, size reduction of an instrument main body can be achieved.

The perspective view which shows the lighting fixture which concerns on one Embodiment of this invention. The perspective view which similarly shows a lighting fixture. The perspective exploded view which shows the state which attaches an end plate part and an arm part to an instrument main body. Side surface sectional drawing which shows the lighting fixture (when a fixture main body is a state perpendicular | vertical with respect to the axis line D) which concerns on one Embodiment of this invention. Side surface sectional drawing which similarly shows a lighting fixture (when a fixture main body is a state parallel to the axis line D). The perspective view which shows an instrument main body. (A) is the figure which looked at the instrument main body from A direction in FIG. 6, (b) is the partial side sectional view of an instrument main body.

  Next, embodiments of the invention will be described.

  First, the whole structure of the lighting fixture 100 which concerns on this embodiment is demonstrated using FIGS. 1-7. In the following description, the “front side” of the luminaire 100 will be described as the light irradiation side, and the “rear side” will be described as the opposite side of the front side.

As shown in FIG.1 and FIG.2, the lighting fixture 100 is a spotlight used by attaching to attachment wall parts, such as a ceiling, for example. The lighting fixture 100 includes an LED board 102 on which the LEDs 102a are mounted, a power supply circuit 103 that supplies power to the LED board 102, a fixture body 21 that houses the LED board 102 and the power supply circuit 103, an end plate portion 22, The arm part 115 which is a support member for supporting the instrument main body 21, a shaft support part 116 which pivotally supports one end of the arm part 115, and a mounting plug 117 are provided. The appliance body 21 includes an LED casing portion 104 that houses the LED substrate 102, and a power casing portion 105 that is configured as a separate section from the LED casing portion 104 via the partition wall 25 and that houses the power circuit 103. . The attachment plug 117 is an example of a part to be attached. The attached portion may be realized by an attachment component (a component called a stud or a flange) that can be directly fixed to the ceiling or wall.
In the present embodiment, the LED casing portion 104, the partition wall 25, and the power supply casing portion 105 are formed as integral parts as the instrument main body 21, but are not particularly limited. For example, the LED casing part, the partition wall 25, and the power supply casing part may be formed as separate parts and assembled to form an instrument body.

  The LED substrate 102 is a light source unit disposed on one end side in the axial direction of the instrument main body 21 in the instrument main body 21 (in the present embodiment, on the front end side). The LED substrate 102 is mounted with an LED (light emitting diode) 102a disposed in the center of a printed wiring board processed into a disk shape. The LED 102a can be composed of, for example, a COB (Chip on Board) element. The LED 102a includes, for example, an LED element directly formed on a printed wiring board, an anode electrode, and a cathode electrode. A lens 106 is attached to the LED 102a. The LED 102a may be configured such that LED chip components are mounted on a printed wiring board by soldering.

As shown in FIGS. 6 and 7, the instrument main body 21 is a cylindrical body whose both ends in the axial direction of the instrument main body 21 are open, and whose inner space is closed by a partition wall 25. The instrument body 21 is a container-shaped molded body that is integrally molded by, for example, impact molding. That is, the instrument main body 21 has a structure in which a first container that is a cylindrical front cylinder and a second container that is a cylindrical rear cylinder are opposed to each other via a disk-shaped partition wall 25. Yes. The first container is an LED casing part 104 that houses the LED substrate 102, and the second container is a power supply casing part 105 that houses the power circuit 103 and a shaft support part 116 described later. When the instrument main body 21 is a container-shaped molded body molded by using impact molding, for example, the LED casing 104 and the power casing casing 105 have a uniform wall thickness in the axial direction of the instrument main body 21. It is. The instrument main body 21 is comprised with the heat conductive material which consists of metal materials (this embodiment pure aluminum or aluminum alloy), for example. In addition, the shape of the instrument main body 21 and the shape of each part (partition 25 etc.) included in it are an example. In the following description, the direction along the cylindrical axis of the instrument body 21 is referred to as “the axial direction of the instrument body 21”, and the direction orthogonal to the cylinder axis is referred to as “the radial direction of the instrument body 21”.
Moreover, although the instrument main body 21 of this embodiment was shape | molded as an integral part by the impact molding, the manufacturing method of the instrument main body 21 is not specifically limited. As a manufacturing method of the instrument main body 21, the instrument main body 21 can be manufactured also by the drawing process etc. from a thin plate, for example.
Further, in the present embodiment, as shown in FIG. 4, the thickness of the peripheral wall of the LED casing portion 104 is configured to be thicker than the thickness of the peripheral wall of the power supply casing portion 105, but is particularly limited. is not. For example, what is necessary is just to set the thickness of each surrounding wall of the LED casing part 104 or the power supply casing part 105 suitably according to a use, a shape, and a function.

  The partition wall 25 is integrally formed on the front surface and the rear surface so as to have an LED casing portion 104 that is a front cylindrical body and a power supply casing portion 105 that is a rear cylindrical body, and the LED casing portion 104 and the power supply casing portion 105. And a disc-shaped portion having a predetermined thickness. In addition, “integral” means a state formed as a single part by molding. As shown in FIG. 7A, the partition wall 25 is provided with a through hole 25 a in the vicinity of the front end portion of the first parallel rib 111 for passing the wiring. A cord extending from the LED board 102 accommodated in the LED casing portion 104 is inserted into the through hole 25a. This cord is electrically connected to the power circuit 103 housed in the power casing portion 105. Note that the cords extending from the LED substrate 102 are not shown in this specification.

  The material which comprises the instrument main body 21 is not specifically limited, A metal material, a resin material, and these can be combined and used. When the LED substrate 102 is used as the light source unit as in the present embodiment, it is preferable that the material constituting the instrument body 21 has high thermal conductivity, and in the present embodiment, it is composed of pure aluminum (JISA 1000 series) or an aluminum alloy. Is done. When the instrument main body 21 is formed by impact molding, for example, the present invention is not limited to these aluminum-based materials, and other materials capable of molding the material constituting the instrument main body 21 by impact molding can be used. Examples of such other materials include copper, magnesium, iron, nickel, and alloys thereof.

  The end plate portion 22 is attached to the other axial end side (the rear end side in the present embodiment) of the instrument main body 21 (the power supply casing portion 105), and the open end portion of the power supply casing portion 105 is opened. It is a substantially disk-shaped member for closing and fixing. The end plate portion 22 has an arm insertion port 105 c through which one end of an arm portion 115 having a built-in power cord 119 connected to the power supply circuit 103 is inserted. The arm insertion port 105 c is formed with a predetermined width along the radial direction of the end plate portion 22 from the center of the end plate portion 22 in the rear view. The end plate portion 22 includes a housing portion 22a that is a substantially dome-shaped space formed to protrude forward at a position offset from the axis C that is the central axis of the end plate portion 22 (the instrument body 21), and the housing portion 22a. And a tapered portion 22b, which is a space formed to protrude forward in the vicinity of the axis C of the end plate portion 22 in a tapered manner. The accommodating portion 22a has a substantially arc shape in sectional view, and is a portion that accommodates and supports the shaft support base portion 115b that is one end of the arm portion 115. The end plate portion 22 has an outer edge portion 22c that protrudes rearward at the outer peripheral portion of the end plate portion 22, and a U-shaped cutout 22d is formed in the outer edge portion 22c. The notch 22d is in a state perpendicular to the axis D, which is the central axis of the cylindrical portion 115a where the instrument body 21 is the other end of the arm portion 115 (see FIG. 4, the axis C of the instrument body 21 and the axis D of the arm portion 115). And the cylindrical portion 115a of the arm portion 115 is engaged therewith. In the taper portion 22b, the instrument main body 21 is parallel to the axis D of the cylindrical portion 115a of the arm 115 (see FIG. 5, the angle between the axis C of the instrument main body 21 and the axis D of the arm 115 is approximately 0 °). In this state, the arm taper portion 115c of the arm portion 115 comes into contact with and is supported. The tapered portion 22 b is a portion that limits the rotation range of the instrument main body 21 relative to the arm portion 115. That is, when the instrument main body 21 is rotated with respect to the axis D of the arm portion 115 to a predetermined angle (about 0 ° in the present embodiment), the arm taper portion 115c of the arm portion 115 ends as shown in FIG. The arm portion 115 is restricted from rotating more than a predetermined angle by contacting the tapered portion 22b provided on the plate portion 22. In the accommodating portion 22a, a pair of screw holes (not shown) are formed at positions corresponding to a pair of screw holes 114 described later in order to insert a mounting screw serving as a shaft support portion 116 described later.

  The end plate portion 22 includes a mounting hole (not shown) provided at the peripheral portion of the end plate portion 22 and a screw provided at the rear end portion of the first parallel ribs 111 and 111 of the power casing portion 105. The end plate portion 22 and the instrument main body 21 (power supply casing portion 105) are assembled by screwing screws into the grooves 112 and 112. For example, if the cylindrical plate is fitted to the first parallel ribs 111 and 111 and the end plate portion 22 is fixed to the instrument main body 21, the screw groove 112 can be omitted.

The arm portion 115 is a support member that rotatably supports the instrument body 21 by the shaft support portion 116. As shown in FIGS. 3 and 4, the arm portion 115 is a hollow member that communicates from one end to the other end of the arm portion 115. The arm portion 115 includes a shaft support base portion 115b and an arm taper portion 115c located on one end side of the arm portion 115, and a cylindrical portion 115a located on the other end side of the arm portion 115. The cylindrical portion 115a communicates with a shaft support base portion 115b having a substantially arc shape (a shape including at least part of an arc shape portion) in a sectional view. The arm taper portion 115c is formed so as to obliquely block one end of the cylindrical portion 115a. As shown in FIG. 3, the shaft support base 115 b is formed with a pair of screw holes 114. The shaft support base portion 115b is rotated by a pair of screw holes (not shown) formed in the housing portion 22a of the end plate portion 22 and a pair of screw holes 114 formed in the shaft support base portion 115b by mounting screws that are the shaft support portions 116. It is linked movably. The arm taper portion 115c is in a state in which the instrument body 21 is parallel to the axis D of the arm section 115 (see FIG. 5, the axis C of the instrument body 21 is about 0 ° with respect to the axis D of the arm section 115). In this case, the end plate portion 22 is in contact with and supported by the tapered portion 22b. A plurality of cords 119 that connect between the mounting plug 117 and the power supply circuit 103 can be inserted into the arm portion 115, and the shaft support portion 116 is used as a fulcrum with the plurality of cords 119 inserted in the arm portion 115. The arm part 115 can be rotated. As described above, when the end plate portion 22 on which the shaft support base portion 115 b of the arm portion 115 is pivotally supported is attached to the rear end portion of the instrument main body 21, the shaft support base portion 115 b of the arm portion 115 is located inside the power supply casing portion 105. The instrument main body 21 is rotated about the mounting screw as the pivotal support portion 116 in the movable range of about 0 ° to 90 ° with respect to the axis D of the arm portion 115. Can do. Thereby, the irradiation direction of the illumination light derived | led-out from the outlet 104a of the instrument main body 21 can be changed to an up-down direction. The cylindrical portion 115a of the arm portion 115 is attached to the attachment plug 117 so as to be capable of rotating 360 degrees around the axis D of the arm portion 115.
In addition, it can replace with the axial support part 116 of this embodiment, and can also use the ball joint which is an example of the hinge which can be bent as an axial support part.

  The attachment plug 117 is a plug that holds the cylindrical portion 115a of the arm portion 115 and is attached to a wiring device embedded in an attachment wall portion such as a ceiling. The attachment plug 117 is attached to a wiring device embedded in an attachment wall such as a ceiling so that the appliance body 21 is attached to the attachment wall such as a ceiling and power is supplied from an external commercial power source. It is configured.

  The diameter and length of the appliance main body 21, the thickness of the side surface of the LED casing portion 104 that is the front cylinder, the thickness of the side surface of the power supply casing portion 105 that is the rear cylinder, and the thickness of the partition wall 25 are arbitrary dimensions. Any value can be appropriately set for each value according to the specifications (strength, weight, thermal conductivity, designability, etc.) required for the main body 21 and the application.

  Moreover, in this embodiment, although the cylindrical part was mentioned as the instrument main body 21, the instrument main body 21 is not restricted to a cylindrical shape. For example, a cylindrical part having a polygonal cross section can be used.

  The LED casing portion 104 is a cylindrical member for housing the LED substrate 102. The LED casing portion 104 is formed in a cylindrical shape with an open front end, and the LED substrate 102 is accommodated in the hollow portion of the cylinder. The front surface of the partition wall 25 formed integrally with the LED casing portion 104 is formed flat, and the LED substrate 102 is disposed on the front surface of the partition wall 25 of the LED casing portion 104 via an electrical insulating member (not shown). It is fixed. A lead-out port 104a for leading out the light of the LED 102a is opened on the front surface of the LED casing 104. The outlet 104a is larger than the diameter of the lens 106 and is formed in a circular shape in front view. In addition, you may provide the cover which has translucency or transparency in the position which plugs out the outlet 104a.

  The power casing portion 105 is a cylindrical member for housing the power circuit 103. The power casing part 105 is a part formed integrally with the LED casing part 104 via the partition wall 25. The power casing part 105 is formed in a cylindrical shape with an open rear end, and the power circuit 103 is accommodated in the hollow part of the cylinder. A rear surface of the partition wall 25 formed integrally with the power casing portion 105 is formed flat. The power casing portion 105 is formed integrally with the LED casing portion 104 and the partition wall 25, is formed in a cylindrical shape having substantially the same cross-sectional shape as the LED casing portion 104, and has the same axis as the LED casing portion 104. Thus, it is formed so that it becomes one cylindrical body.

  The power supply circuit 103 is disposed at a position offset from the axis C of the instrument main body 21 on the other end side in the axial direction of the instrument main body 21 in the instrument main body 21 (the rear end side in the present embodiment), and is electrically connected to the LED substrate 102. Connected to. The power supply circuit 103 is for converting the AC voltage into a predetermined DC voltage, or reducing the high-voltage DC voltage to the low-voltage DC voltage, and supplying power to the LED substrate 102. The printed circuit processed into a rectangular plate shape It is mounted on the wiring board. The power supply circuit 103 inserts a printed wiring board included in the power supply circuit 103 from a rear end portion of a second parallel rib 122, which will be described later, formed in the power supply casing portion 105, and puts it at a predetermined position in the power supply casing portion 105. Retained. By providing the second parallel rib 122 on the inner wall surface 105 a of the power casing portion 105, the power circuit 103 can be held at a predetermined position in the power casing portion 105 without using a mounting member such as a screw. Thereby, the process of assembling the power supply circuit 103 to the instrument main body 21 can be omitted.

  As shown in FIG. 4, the power supply circuit 103 is offset from the axis C of the instrument body 21 on the other end side in the axial direction of the instrument body 21 in the instrument body 21 (in this embodiment, the rear end side) (FIG. 4). Then, a predetermined space S is formed on the side opposite to the direction in which the power supply circuit 103 is offset in the instrument main body 21. The accommodating portion 22a and the tapered portion 22b of the end plate portion 22 described above are accommodated in the rear portion of the space S formed on the side opposite to the direction in which the power supply circuit 103 is offset in the instrument main body 21. That is, the accommodating portion 22 a and the tapered portion 22 b of the end plate portion 22 are disposed at positions facing the power supply circuit 103 across the axis C of the instrument main body 21. Thereby, the shaft support part 116 is disposed in the rear part in the space S of the instrument main body 21. Specifically, the shaft support portion 116 is disposed in the instrument main body 21 at a position offset from the axis C of the instrument main body 21. That is, the shaft support 116 is disposed at a position facing the power supply circuit 103 with the axis C of the instrument body 21 interposed therebetween. Thus, the power supply circuit 103 arranged in the instrument main body 21 can be avoided, and the shaft support part 116 of the arm part 115 as a support member can be provided in the instrument main body 21.

  As shown in FIG. 4, the shaft support portion 116 disposed in the space S of the instrument main body 21 has a distance between the shaft support portion 116 and the instrument main body 21 that is the shortest, and the shaft support portion 116 and the end plate portion 22. It is preferable that the intervals at which the intervals are the shortest are arranged at positions where the intervals are substantially equal. By placing the pivot support 116 at such a position. When the axis C of the instrument body 21 is perpendicular to the axis D of the arm part 115, the arm part 115 protrudes from the end plate part 22 (notch 22d) L1 (see FIG. 4) and the arm part 115 The distance L2 (see FIG. 5) at which the arm portion 115 projects from the end plate portion 22 (arm insertion port 105c) when the axis C of the instrument body 21 is parallel to the axis D is substantially the same distance. The arm structure is suitable in terms of design and functionality.

The power casing portion 105 protrudes from the inner wall surface 105 a of the power casing portion 105 in the radial direction of the instrument body 21 and extends from the partition wall 25 along the axial direction of the instrument body 21 to the open end 105 b of the power casing portion 105. A pair of first parallel ribs 111 and 111 and a pair of second parallel ribs 122 and 122 formed continuously are provided.
In the present embodiment, the power supply casing 105, which is the second container, is provided with a pair of parallel ribs first parallel ribs 111 and 111 and second parallel ribs 122 and 122, but is not particularly limited. That is, it can be set as the structure which provides a pair of parallel rib in at least one container among the LED casing part 104 which is a 1st container, and the power supply casing part 105 which is a 2nd container.

  A pair of first parallel ribs 111 and 111 and a pair of second parallel ribs 122 and 122 are integrally formed on the power casing portion 105. The first parallel ribs 111 and 111 are extended from the front end to the rear end of the power supply casing 105 in the axial direction of the instrument main body 21 on the inner wall surface 105 a of the power supply casing 105. The first parallel ribs 111 and 111 protrude from the inner wall surface 105 a of the power supply casing portion 105 in the radial direction of the instrument main body 21. The first parallel ribs 111 and 111 face each other with a minute gap therebetween. The first parallel ribs 111 and 111 are disposed at positions facing each other on a substantially diameter line segment in the cross section of the power supply casing portion 105. The 1st parallel rib 111 * 111 is a part in which the rear-end part was provided with the screw groove 112 formed by tapping in order to fix the end plate part 22 with a screw. The second parallel ribs 122 have a predetermined rib interval (same dimension as the thickness of the printed wiring board included in the power supply circuit 103), and the power supply circuit 103 is interposed between a pair of ribs erected in parallel. The second parallel rib 122 is inserted from the rear end portion of the power supply casing portion 105 to hold the power supply casing portion 105 at a predetermined position. The second parallel rib is provided with a predetermined length apart from the first parallel rib in a direction perpendicular to the axis (axis C). The pair of first parallel ribs 111 and 111 are not necessarily parallel to each other. It is not essential that the pair of second parallel ribs 122 and 122 are parallel to each other. Further, the screw groove 112 can be omitted.

  As shown in FIG. 4, the LED substrate 102 is disposed on one side surface 25 c of the partition wall 25 in the LED casing portion 104 that is the first container. As shown in FIGS. 4 to 7, the pair of second parallel ribs 122 and 122 is arranged at a position where the line segment connecting the second parallel ribs 122 and 122 does not overlap the LED facing portion in the partition wall 25. . The LED facing portion is a portion facing the LED element 102 a on the upper surface 25 b of the partition wall 25. The LED facing portion is a portion where heat from the LED element 102a is most easily transmitted on the upper surface 25b of the partition wall 25, and is a portion where the temperature rises most on the upper surface 25b of the partition wall 25 (heat point). When the power supply circuit 103 is inserted and held in the pair of second parallel ribs 122 and 122 arranged in this way, the result is as shown in FIG. By providing the second parallel ribs 122 and 122 for inserting the power supply circuit 103 at such a position, the power supply circuit 103 is moved from the LED element 102a serving as a heat source in the radial direction of the fixture main body 21 (surface direction of the partition wall 25). The power supply circuit 103 is not easily affected by the heat of the LED element 102a, and is in a preferable temperature state for the power supply circuit 103. In the present embodiment, since the LED element 102 a is arranged at the center of the partition wall 25, the second parallel ribs 122 and 122 are displaced from the center of the partition wall 25 in the radial direction of the instrument body 21. It is formed in the position arrange | positioned at the position.

In the lighting fixture 100 configured as described above, the shaft support base portion 115 b of the arm portion 115 is attached to the end plate portion 22 via the shaft support portion 116, and the cylindrical portion 115 a of the arm portion 115 is attached via the attachment plug 117. It is attached to the mounting wall. When the instrument body 21 is rotated and the axial direction (direction along the axis C) of the instrument body 21 is arranged along the axial direction (direction along the axis D) of the cylindrical portion 115a of the arm 115, The axis C of the instrument body 21 and the axis D of the cylindrical portion 115a of the arm 115 are on the same axis (see FIG. 5). Thereby, even if the instrument main body 21 is rotated around the arm portion 115, the instrument main body 21 is not eccentric with respect to the attachment plug 117, so that the instrument main body 21 can be arranged at an arbitrary position.
Furthermore, in the lighting fixture 100 of this embodiment, when the axis C of the fixture body 21 and the axis D of the cylindrical portion 115a of the arm 115 are thus on the same axis, the LED substrate 102 (LED element) is further provided. The optical axis 102a) is also on the same axis as the axes C and D. Thereby, since the position of the center of the optical axis can be easily grasped, the instrument main body 21 can be easily directed in an arbitrary light distribution direction.

  In the present embodiment, as the instrument main body 21, the structure in which the front cylinder body and the rear cylinder body having the same shape and the same size are connected via the partition wall 25 is described as an example, but is not particularly limited. The front cylinder and the rear cylinder may have different shapes or different sizes through the partition wall. For example, a container-shaped molded body having a stepped shape in the middle in the length direction may be used.

  According to this embodiment, the power supply circuit 103 in the instrument main body 21 is avoided, and the pivotal support 116 of the arm portion 115 as a support member is provided in the instrument main body 21 and the instrument main body 21 can be made compact. . That is, according to the present embodiment, the instrument body 21 can be reduced in size in the axial direction, and the instrument body 21 can be reduced in weight.

  According to the present embodiment, since the shaft support portion 116 is provided in the fixture main body 21, the overall length of the arm portion that is a support member is configured to be shorter than that of a luminaire having a shaft support portion outside as in the prior art. Can do. Thereby, since arm intensity | strength improves and a code | cord | chord etc. can be comprised short, the manufacturing cost of the lighting fixture 100 can be reduced. Moreover, since the axial support part 116 cannot be seen from the exterior of the instrument main body 21, the external appearance of the lighting fixture 100 becomes simple and the design property improves.

  According to the present embodiment, the shaft support 116 is provided not on the instrument main body 21 but on the end plate 22 attached to the instrument main body 21, so that the assembly on the instrument main body 21 side, the arm 115, the end plate 22 and the shaft are provided. Since the assembly of the support part 116 can be performed in a separate process, the assembly process of the lighting apparatus 100 can be configured simply.

  In this embodiment, the instrument main body 21 is rotated, and the axial direction (direction along the axis C) of the instrument main body 21 is set along the axial direction (direction along the axis D) of the cylindrical portion 115a of the arm 115. When arranged, the axis C of the instrument body 21 and the axis D of the cylindrical portion 115a of the arm 115 are on the same axis. Furthermore, in this embodiment, when the axis C of the instrument main body 21 and the axis D of the cylindrical portion 115a of the arm 115 are thus on the same axis, the light of the LED substrate 102 (LED element 102a) is further increased. The axis is also on the same axis as the axes C and D. With this configuration, the lighting engineer can easily control the light distribution of the lighting fixture 100 and can set various lighting plans.

21 fixture body 22 end plate portion 100 lighting fixture 102 LED substrate (light source portion)
102a LED element 103 Electric circuit 115 Arm part (support member)
116 Axle support C axis S space

Claims (5)

A tubular instrument body;
A light source unit disposed on one end side in the axial direction of the instrument body in the instrument body;
A power supply circuit that is disposed at a position offset from the axis of the instrument body on the other axial end side of the instrument body in the instrument body, and is electrically connected to the light source unit;
A support member that rotatably supports the instrument body by a shaft support,
The shaft support is
The lighting apparatus is disposed at a position offset from an axis of the apparatus main body in the apparatus main body.   The lighting fixture according to claim 1, wherein the shaft support portion is disposed at a position facing the power supply circuit across an axis of the fixture main body.   The lighting device according to claim 1, wherein the light source unit is an LED substrate on which an LED element is mounted. An end plate portion fixed by closing the other axial end of the instrument body;
The shaft support is
It is provided in the said end plate part, The lighting fixture as described in any one of Claims 1-3 characterized by the above-mentioned. One end of the support member is attached to the end plate part via the shaft support part, and the other end of the support member is attached to the attached part,
When the instrument body is rotated and the axial direction of the instrument body is arranged along the axial direction of the other end of the support member, the axis of the instrument body and the axis of the other end of the support member are the same. It becomes on an axis line, The lighting fixture as described in any one of Claims 1-4 characterized by the above-mentioned.

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