JP5546417B2 - lighting equipment - Google Patents

Description

  The present invention relates to a lighting fixture including a replaceable lens unit, for example.

  Conventionally, a lens is used as a technique for condensing light from an LED light source. As an easy lens replacement method, there is a structure in which a lens unit that can be attached to and detached from a lamp of an LED lighting apparatus is used, and the lens unit is fixed to the lamp using a fixing member that is a separate part.

JP 2004-327138 A JP 2002-304903 A

  In the structure in which the lens unit is fixed to the lamp using the fixing member, a component different from the lens unit is used as the fixing member. For this reason, when exchanging a lens unit after installing a lighting fixture on a ceiling or the like, it is necessary to perform an attaching / detaching operation while pressing the lens unit, resulting in poor workability.

  The present invention has been made, for example, in order to solve the above-described problems, and provides a lighting device with high workability that allows a lens unit to be easily attached and detached.

The lighting fixture according to the present invention is:
An instrument body that houses a light source, and has a groove formed on an inner periphery of an opening periphery that forms the opening while the irradiation direction side of the light source is open;
A lens unit that includes a lens through which light from the light source passes and a frame portion formed by a flexible soft member, and the frame portion is fitted into the groove portion and attached to the instrument body. Features.

  A lighting fixture according to the present invention houses a light source, the fixture main body having a groove portion formed on the inner periphery of the opening periphery forming the opening while the irradiation direction side of the light source is open, and the light of the light source passes therethrough. A lens unit and a frame unit formed by a soft member having flexibility, and the lens unit is fitted into the groove unit and attached to the instrument body. By pushing into the opening, the lens unit can be easily attached to the instrument body.

1 is a perspective view of a lighting fixture 1000 (lamp 100) according to Embodiment 1. FIG. FIG. 3 is an exploded perspective view of the lighting apparatus 1000 (lamp 100) according to Embodiment 1 with the lens unit 120 removed from the lamp body 110. 2 is a cross-sectional view of a lamp body 110 according to Embodiment 1. FIG. 2 is an exploded perspective view of a lens unit 120 according to Embodiment 1. FIG. (A) is sectional drawing of the lens unit 120 which concerns on Embodiment 1, (b) is an exploded sectional view of the lens unit 120 which concerns on Embodiment 1. FIG. 1 is an exploded cross-sectional view of a lamp 100 according to Embodiment 1. FIG. It is sectional drawing of the lamp 100 (state in which the lens unit 120 was attached to the lamp main body 110) which concerns on Embodiment 1. FIG. 2A and 2B are perspective views of lens units 120 and 120b, in which FIG. 1A illustrates the lens unit 120 described in the first embodiment, and FIG. 2B illustrates the lens unit 120b according to the second embodiment.

Embodiment 1 FIG.
FIG. 1 is a perspective view of a lighting fixture 1000 (lamp 100) according to Embodiment 1. FIG. FIG. 2 is an exploded perspective view of the lighting apparatus 1000 (lamp 100) according to Embodiment 1 with the lens unit 120 removed from the lamp body 110. FIG. The outline | summary of a structure of the lighting fixture 1000 (lamp 100) is demonstrated using FIG.1 and FIG.2.

  As shown in FIG. 1, the lighting fixture 1000 includes a lamp 100 and a power supply unit (not shown). The lamp 100 includes a lamp main body 110 and a lens unit 120. As shown in FIG. 2, the lens unit 120 is configured to be detachable from the lamp body 110. The luminaire 1000 is, for example, a downlight that is attached by being inserted into an embedded hole such as a ceiling surface.

  As shown in FIG. 2, the lamp main body 110 (apparatus main body) accommodates four LEDs 112a (light sources) therein. The four LEDs 112a are arranged in a circular shape at equal intervals. The LEDs 112a may be four or more or three or less, for example, two, three, five, six, seven, or eight LEDs 112a, and are preferably arranged in a circular shape at equal intervals.

  The lens unit 120 is provided with a plurality of lenses 121 corresponding to the plurality of LEDs 112a. In the present embodiment, the lens unit 120 is provided with four lenses 121 corresponding to the four LEDs 112a.

  The lamp body 110 has a substantially circular opening 111a on the irradiation direction side of the LED 112a, and the lens unit 120 is attached in the vicinity of the opening 111a of the lamp body 110 so as to close the opening 111a. Although details of the attachment method will be described later, in the lamp 100 according to the present embodiment, the lens unit 120 is easily attached to the lamp body 110 while the operator holds the knob portion 123d provided at the substantially center of the lens unit 120. It has a configuration that can.

  The lighting fixture 1000 (lamp 100) of the present embodiment uses a lens 121 as a method of distributing (or condensing or diffusing) light emitted from the LED 112a (light source). An operator attaches the lens unit 120 on which an appropriate lens 121 is arranged to the lamp body 110 in order to realize a desired light distribution (condensation and diffusion). For example, when it is desired to replace the lens 121 in order to change the light distribution, the operator removes the lens unit 120 from the lamp body 110, replaces the lens 121 of the lens unit 120 with an appropriate lens 121, The operation of attaching the lens unit 120 to the lamp body 110 again is performed.

  FIG. 3 is a cross-sectional view of the lamp body 110 according to the first embodiment. The configuration of the lamp body 110 according to Embodiment 1 will be described with reference to FIG. As shown in FIG. 3, the lamp body 110 includes a housing 111, an LED substrate 112, an LED substrate holder 113, and an attachment spring 114.

  The housing 111 houses the LED substrate 112 on which the LEDs 112a (see FIG. 2) are arranged, and the irradiation direction P side of the LEDs 111a is open. The casing 111 has a concave shape on the irradiation direction P side, and the LED substrate 112 is attached to the attachment surface 111e which is the bottom of the concave portion. This recessed portion is referred to as an LED substrate storage portion 160. The LED board storage portion 160 has a substantially cylindrical shape, and includes a mounting surface 111e at a position facing the opening 111a. Further, a side surface portion 111c is provided from the opening peripheral portion 111f forming the opening portion 111a toward the mounting surface 111e.

  The casing 111 includes an annular collar portion 115 (see FIG. 1) formed outward from the opening peripheral edge portion 111f. When the lamp body 110 is inserted into an embedding hole such as a ceiling, the collar portion 115 is caught by the edge of the embedding hole, and the surface on the ceiling surface side (contact surface 115a) contacts the ceiling surface. Further, the surface of the collar portion 115 opposite to the contact surface 115a is exposed on the ceiling surface or the like and plays a design role.

  On the side opposite to the irradiation direction P side of the casing 111 (that is, the back surface side of the opening 111a), the radiation fins 111b are provided. The radiation fins 111b radiate heat generated by the LEDs 112a.

  The attachment spring 114 is attached to the side surface of the housing 111 with a screw 170. When attaching the lamp 100 to the embedding hole, the attachment spring 114 engages with the embedding hole and fixes the lamp 100.

  The LED substrate 112 is attached to the attachment surface 111 e that is the bottom of the concave shape of the LED substrate storage portion 160. The LED substrate 112 is attached to the attachment surface 111e together with the LED substrate holder 113 using screws 171. The LED board holder 113 fixes the LED board 112 to the mounting surface 111e.

  The lamp body 110 (housing 111) includes a mounting groove 111d (groove) formed on the inner periphery in the vicinity of the opening peripheral edge 111f (that is, the inner periphery of the side surface 111c). The mounting groove 111d is, for example, a groove formed in an annular shape on the inner periphery on the LED substrate 112 side (upward) from the opening peripheral edge 111f. The diameter of the mounting groove 111d is L1. The mounting groove 111d is a groove for mounting the lens unit 120.

  Further, the portion from the opening periphery 111f to the lower end of the mounting groove 111d is a cylindrical portion having a diameter of L3. In the side surface portion 111c, the side surface portion 111c of the cylindrical portion below the mounting groove 111d (irradiation direction P side) is referred to as a side surface portion A111ca.

  Further, the lamp body 110 (housing 111) includes a storage groove 111g in which a part of a lens unit 120 described later is stored above the mounting groove 111d. The diameter of the storage groove 111g is L2. The mounting groove 111d and the storage groove 111g are grooves for mounting the lens unit 120. The storage groove 111g is an annular groove formed on the LED substrate 112 side of the mounting groove 111d, and is continuous with the mounting groove 111d. The diameter of the storage groove 111g is L2. As shown in FIG. 3, it is formed so that L1> L2. A method of attaching the lens unit 120 to the lamp body 110 will be described later.

  Further, a portion from the upper end portion of the storage groove 111g to the mounting surface 111e is a cylindrical portion having a diameter of L4. The side part 111c of the cylindrical part whose diameter is L4 is defined as a side part B111cb.

  The shape of the LED board storage portion 160 is such that the size relationship of the diameters of the portions is L1> L3> L2> L4.

  FIG. 4 is an exploded perspective view of the lens unit 120 according to the first embodiment. 5A is a cross-sectional view of the lens unit 120 according to the first embodiment, and FIG. 5B is an exploded cross-sectional view of the lens unit 120 according to the first embodiment. The configuration of the lens unit 120 will be described with reference to FIGS. 4 and 5.

  The lens unit 120 includes a lens holder 122, a lens 121, and a lens holder 123. The lens holder 122 includes a lens attachment portion 122a (lens insertion hole) that is a hole into which the lens 121 is inserted, and supports the lens inserted into the lens attachment portion 122a. The lens retainer 123 includes a lens exposure hole 123 c that exposes the lens supported by the lens holder 122, and is attached to the lens holder 122 while pressing the lens 121 against the lens holder 122. The lens holder 123 is a frame portion 125 formed of a flexible member (soft member) having flexibility, and includes a frame portion 125 that is fitted into the mounting groove 111d of the lamp body 110 described above.

  The lens unit 120 includes four lenses 121, a lens holder 122 that houses the four lenses 121, a lens holder 123 that is attached to the irradiation direction P side of the lens holder 122, and a lens holder 123 that holds the lens 121. And a screw 124 to be fixed to the holder 122.

  The lens 121 has a conical shape, and includes a positioning convex portion 121a that protrudes outward from the periphery of the bottom surface of the conical shape. The lens 121 is provided on the top side of the conical shape, and includes a light incident concave portion (not shown) into which the light emitting portion of the LED 112a is inserted.

  The lens holder 122 has a substantially disc shape, and includes four lens attachment portions 122a that are lens insertion holes into which the lenses 121 are inserted. A positioning recess 122b used for positioning when the lens 121 is inserted is formed at the periphery of the lens mounting portion 122a (lens insertion hole). When the lens 121 is inserted into the lens mounting portion 122a, the positioning of the lens 121 is facilitated by fitting the positioning convex portion 121a of the lens 121 into the positioning concave portion 122b of the lens holder 122.

  The lens holder 122 is formed of a resin member such as an acrylic resin or a polycarbonate resin. A holder positioning portion 122 c that is a notch for positioning when the lens unit 120 is mounted on the lamp body 110 is formed on the periphery of the lens holder 122. A method for positioning the lens holder 122 using the holder positioning unit 122c will be described later.

  The lens retainer 123 includes four lens exposure holes 123c that expose the lens 121 to the irradiation direction P side. The lens holder 123 has a disk shape (or a dish shape) in which the surface on the irradiation direction P side is slightly recessed. Further, the rear surface of the surface of the lens holder 123 on the irradiation direction P side has a recessed portion in which the lens holder 122 is accommodated when attached to the lens holder 122 (see FIG. 5). The side surface forming the recessed portion of the lens presser 123 is referred to as a lens presser side surface portion 123g.

  The lens pressing side surface portion 123g is provided with a positioning portion 123f used for positioning when attached to the lens holder 122 (that is, when the lens holder 122 is housed in the recessed portion). The positioning portion 123f of the lens pressing side surface portion 123g is a recessed portion provided at a position corresponding to the holder positioning portion 122c of the lens holder 122.

  The positioning portion 123f is used for positioning the lens holder 122 and the lens holder 123, and is also used for positioning when the lens unit 120 is attached to the lamp body 110.

  The lens holder 123 is formed of a resin member such as acrylic resin or polycarbonate resin. The lens presser 123 includes four lens exposure holes 123c and a knob portion 123d provided at substantially the center of the four lens exposure holes 123c. The lens holder 123 includes a knob portion 123d that protrudes toward the irradiation direction P in the vicinity of the center. The knob portion 123d has a cylindrical shape that can be picked by an operator (user) from the irradiation direction P side, and has a screw mounting hole 123e into which the screw 124 is screwed on the back surface side (the opposite side to the irradiation direction P side). Provide (see FIG. 5).

  A frame portion 125 is formed around the lens holder 123. The frame portion 125 is formed of a flexible member (elastic member) such as silicon having flexibility, and is fitted into the mounting groove 111d of the lamp body 110 described above. The frame portion 125 is formed in an annular shape around the lens presser 123.

  The lens holder 123 and the frame part 125 formed around the lens holder 123 are formed by, for example, two-color molding in which a resin member (lens holder 123 part) and a flexible member (frame part 125 part) are integrally formed. Is done. Alternatively, the resin member (the lens holding member 123 portion) and the flexible member (the frame portion 125 portion) may be formed as separate parts, and the frame member 125 may be attached to the lens holding member 123. In the present embodiment, the lens press 123 having the frame portion 125 formed around the lens press 123 may be called.

  All of the unit parts other than the lens 121 may be made of a flexible material such as silicon. That is, the lens holder 122 and the lens holder 123 (including the frame portion 125) may be formed of a flexible material such as silicon. In this case, the lens presser 123 including the frame portion 125 can be integrally formed.

  In addition, the lens unit 120 may have an integrated structure (one component) by two-color injection molding of a lens and a unit part (lens holder 122, lens holder 123 (including the frame part 125)).

  As described above, at least a part of the lens unit 120 is formed of a flexible material. Further, the lens unit 120 changes its hardness between the inside and outside of the lens holder 123. The lens unit 120 has a part made of a flexible material such as silicon attached to the outer shell.

  In the lens retainer 123, a concave bottom surface (a dish-shaped bottom surface) is defined as a central portion 123b. Further, in the lens presser 123, the edge of the recessed opening (the edge of the dish-shaped opening) is defined as a lens presser edge 123a. The frame part 125 is a fringe-shaped (collar-shaped) frame formed on the outer side from the lens pressing edge part 123a. The fringe-shaped (collar-shaped) frame of the frame portion 125 is formed substantially parallel to the central portion 123b.

  FIG. 5B is a diagram of the lens unit 120 with the frame portion 125 removed. As shown in FIG. 5B, the lens retainer 123 from which the frame portion 125 has been removed includes a frame attachment portion 123h for attaching the frame portion 125 to the periphery. The frame attaching portion 123h is an annular projecting portion formed by projecting the periphery (end of the circumference) of the lens presser 123 (in a state where the frame portion 125 is removed) outward.

  The frame portion 125 has an annular shape, and a peripheral portion 125b (groove fitting portion) that is fitted into the mounting groove 111d of the lamp body 110 described above and the periphery (end of the circumference) of the lens presser 123 (a state in which the frame portion 125 is removed). And a lens pressing attachment portion 125a that holds the frame attachment portion 123h.

  As shown in the cross-sectional view of the frame portion 125 in FIG. 5B, the frame portion 125 has two stages. The step on the irradiation direction P side (downward) of the frame portion 125 is a peripheral portion 125b (groove fitting portion) in which a peripheral end portion is fitted into the mounting groove 111d.

  The step (upper side) of the frame portion 125 that is not on the irradiation direction P side has an end portion formed inward, and has a key shape in cross section. A frame attaching portion 123h of the lens retainer 123 (with the frame portion 125 removed) is sandwiched between the key-shaped space portion (lens retainer sandwiching portion 125c) (see FIG. 5A). As described above, the lens holder 123 (the state in which the frame portion 125 is removed) is attached to the frame portion 125.

Here, the assembly process (assembly method) of the lens unit 120 will be described.
(1) The four lenses 121 are inserted into the lens mounting portion 122 a of the lens holder 122 so that the positioning convex portion 121 a of the lens 121 fits into the positioning concave portion 122 b of the lens holder 122.
(2) A lens holder 123 (a state in which the frame portion 125 is formed) is attached to the irradiation direction P side of the lens holder 122 (the insertion surface side where the lens is inserted), and then the screw 124 is screwed from the lens holder 122 side. The lens holder 123 is fixed to the lens holder 122 by screwing into the mounting hole 123e. At this time, the holder positioning part 122c of the lens holder 122 and the positioning part 123f of the lens holder 123 are attached in correspondence with each other.

  FIG. 6 is an exploded cross-sectional view of the lamp 100 according to the first embodiment. FIG. 7 is a cross-sectional view of the lamp 100 according to the first embodiment (a state in which the lens unit 120 is attached to the lamp main body 110).

  As shown in FIG. 6, the LED substrate 112 is screwed to the attachment surface 111 e using screws 171 together with the LED substrate holder 113. In the central portion of the LED substrate holder 113, a recess (screw head storage portion 113a) for storing the screw head of the screw 124 of the lens unit 120 is formed.

Further, the diameter L3 of the side surface portion A111ca portion, the diameter L1 of the mounting groove 111d, the diameter L2 of the storage groove 111g, the diameter L4 of the side surface portion B111cb portion, and the peripheral portion 125b of the lens unit 120 in the LED board storage portion 160 of the lamp body 110. The relationship between the diameter L5 of the outer end portion of the lens, the diameter L6 of the outer end portion of the lens pressing attachment portion 125a, and the diameter L7 of the upper surface portion 120a of the lens unit 120 is configured as follows.
(1) Relationship between the diameter L1 of the mounting groove 111d and the diameter L5 of the outer end portion of the peripheral portion 125b of the lens unit 120: L1≈L5. L1 may be slightly larger than L5, but L1 and L5 are substantially the same in order to prevent the lens unit 120 from shifting, and the peripheral portion 125b is filled in the mounting groove 111d (adhesion). Is preferable.
(2) The diameter L2 of the storage groove 111g and the diameter L6 of the end portion of the lens pressing attachment portion 125a: L2≈L6. Although L2 may be slightly larger than L6, L2 and L6 are substantially the same in order to prevent the lens unit 120 from shifting, and the lens pressing attachment portion 125a is filled in the storage groove 111g. It is preferable to adhere (adhere).
(3) The diameter L3 of the side surface portion A111ca, the diameter L5 of the outer end portion of the peripheral portion 125b, and the diameter L6 of the outer end portion of the lens pressing attachment portion 125a: L6 <L3 <L5.
(4) The diameter L7 of the upper surface portion 120a of the lens unit 120 and the diameter L4 of the side surface portion B111cb: L7≈L4. Here, on the side surface (that is, the side surface portion B111cb) of the portion surrounded by the side surface portion B111cb of the LED substrate housing portion 160, the side surface (lens pressing side surface portion 123g) of the lens unit 120 (lens pressing member 123) shown in FIG. Positioning protrusions (not shown) are formed at positions corresponding to the positioning portions 123f that are formed grooves. Since the lens unit 120 is positioned by engaging the positioning portion 123f of the lens unit 120 (lens presser 123) and the positioning protrusion of the side surface portion B111cb, the diameter L7 of the upper surface portion 120a and the side surface portion B111cb of the lens unit 120 are aligned. It is preferable that the diameter L4 of the side surface B111cb is substantially the same as or slightly larger than the diameter L4.

A process (method) for attaching the lens unit 120 to the lamp body 110 will be described with reference to FIGS. 6 and 7.
(1) Insert the lens unit 120 into the opening 111a of the lamp body 110. An operator (user) can pinch the knob portion 123d and easily insert the lens unit 120 in the Q direction with one hand.
(2) When the peripheral portion 125b of the lens retainer 123 is inserted into the opening 111a, the peripheral portion 125b of the lens unit 120 is pressed toward the center by the side surface portion A111ca of the lamp body 110, and the peripheral portion 125b of the lens retainer 123 Is elastically deformed.
(4) When the upper surface portion 120a of the lens unit 120 reaches the lower end portion of the space formed by the side surface portion B111cb, the operator places a positioning protrusion (see illustration) on the positioning portion 123f (see FIG. 4) and the side surface portion B111cb. Position it so that it is engaged.
(3) After the positioning, when the lens unit 120 is further pushed into the lamp body 110 (in the Q direction), the lens pressing attachment portion 125a of the lens pressing member 123 is accommodated in the storage groove 111g, and the peripheral portion 125b of the lens pressing member 123 is attached. It fits into the groove 111d.
(4) The diameter L5 of the peripheral portion 125b of the lens retainer 123 is formed substantially the same as the diameter L1 (see FIG. 3) of the mounting groove 111d. Therefore, the peripheral portion 125b of the lens retainer 123 is not pressed by the side surface portion 111c (the side surface portion 111c of the mounting groove 111d portion), and the elastic deformation is released.
(5) When the peripheral portion 125b of the lens presser 123 is fitted in the mounting groove 111d, the upper end portion of the side surface portion A111ca prevents the peripheral portion 125b from moving in the P direction (downward), and the lens unit 120 is mounted on the lamp body. 110 is fixed.
(6) The screw head of the screw 124 of the lens unit 120 is housed in the screw head housing portion 113 a of the LED board holder 113.

Next, the process of removing the lens unit from the lamp body will be described with reference to FIGS.
(1) When the operator (user) picks the knob portion 123d of the lens presser 123 and pulls it downward (in the irradiation direction P direction), the peripheral portion 125b of the lens presser 123 is elastically deformed, and the peripheral portion 125b becomes the side surface portion A111ca. It gets over the upper end and comes off the mounting groove 111d.
(2) The lens unit 120 moves downward while the peripheral portion 125b is pressed by the side surface portion A111ca and the peripheral portion 125b is elastically deformed.
(3) Further, when the knob portion 123d of the lens holder 123 is pulled downward, the lens unit 120 is detached from the lamp body 110, and the elastic deformation of the peripheral portion 125b of the lens holder 123 is released.

  As described above, in the present embodiment, the method of using the lens unit 120 as a method of easily changing the light distribution has been described. The lens unit 120 is made of a resin material such as acrylic or polycarbonate, and includes a lens, a lens holder 122 for inserting the lens, and a lens holder 123 for holding the lens. In the lens unit 120 of the present embodiment, the lens unit 120 having a different beam angle can be configured with the same basic configuration by replacing the lens with a lens having a different beam angle.

  Further, by configuring the lens unit 120 to be detachable from the lamp body 110, the light distribution of the lighting fixture 1000 can be easily changed.

  In the lens unit 120 of the present embodiment, at least the peripheral frame part (peripheral part 125b) is formed of a material having elastic force (flexibility) such as silicon rubber, so by pushing the lens unit 120 into the lamp body 110, The peripheral portion 125b is inserted into the mounting groove 111d, and the lens unit 120 can be easily fixed to the lamp body 110.

  Since the lens unit 120 includes the knob portion 123d, the process of attaching or removing the lens unit 120 to or from the lamp body 110 by an operator can be facilitated with one hand. Therefore, when it is desired to change the light distribution obtained from the lighting fixture 1000, the lens unit 120 can be easily replaced, and workability is improved.

  According to the lighting apparatus of the present embodiment, when the lens unit 120 is attached to the lamp body 110, a separate fixing member is not required. Therefore, as the number of LEDs increases, the number of lenses used also increases, and the number of components does not increase in the creation of the unit.

Embodiment 2. FIG.
8A and 8B are perspective views of the lens units 120 and 120b. FIG. 8A is a diagram illustrating the lens unit 120 described in the first embodiment, and FIG. 8B is a diagram illustrating the lens unit 120b according to the second embodiment. is there.

  The frame 127 shown in FIG. 8B is different from the frame 125 of the first embodiment (see FIG. 8A) in the shape of the peripheral portion 127b. The frame portion 125 of the lens unit 120 according to the first embodiment has an annular peripheral portion 125b formed around it, but the frame portion 127 of the lens unit 120b according to the present embodiment is fitted in the mounting groove 111d. The peripheral portion 127b is formed at a part of the periphery.

  For example, as shown in FIG. 8B, the frame portion 127 includes peripheral portions 127b at four surrounding locations. At this time, the mounting groove 111d of the lamp body 110 may be an annular groove as described in the embodiment, or may be a groove formed at a position corresponding to the four peripheral portions 127b.

  While the first and second embodiments have been described above, two of these embodiments may be combined. Alternatively, one of these embodiments may be partially implemented. Or you may implement combining two embodiment partially among these.

  100 lamp, 110 lamp body, 111 housing, 111a opening, 111b radiating fin, 111c side surface, 111ca side surface A, 111cb side surface B, 111d mounting groove, 111e mounting surface, 111f opening edge, 111g storage groove, 112 LED board, 112a LED, 113 LED board holder, 113a screw head storage part, 114 mounting spring, 115 collar part, 115a contact surface, 120 lens unit, 120a upper surface part, 120b lens unit, 121 lens, 121a positioning convex part, 122 lens holder, 122a lens mounting portion, 122b positioning recess, 122c holder positioning portion, 123 lens pressing, 123a lens pressing edge, 123b central portion, 123c lens exposure hole, 123d knob portion, 1 3e Screw mounting hole, 123f Positioning portion, 123g Lens pressing side surface portion, 123h Frame mounting portion, 124 Screw, 125 Frame portion, 125a Lens pressing mounting portion, 125b Peripheral portion, 125c Lens pressing holding portion, 127 Frame portion, 127a Lens pressing Attached part, 127b peripheral part, 160 LED board storage part, 170,171 screw, 1000 luminaire.

Claims (6)

A light source is housed inside, and an instrument body having a groove portion formed in an annular shape on the inner periphery of an opening peripheral edge that is open on the irradiation direction side of the light source and forms the opening;
A lens unit including a lens through which light from the light source passes, the frame unit including an annular frame portion formed by a soft member having flexibility and a knob portion protruding toward an irradiation direction side of the light source, And a lens unit that is fitted in the groove and is attached to the fixture body.   The lighting device according to claim 1, wherein the lens unit has the frame portion fitted into the groove portion when the knob portion is pushed inward of the fixture body. Before Symbol lens unit,
A lens holder for inserting a lens, and a lens holder for supporting the lens inserted in the lens insertion hole;
A lens exposure hole that exposes the lens supported by the lens holder, and a lens presser that is attached to the lens holder while pressing the lens against the lens holder;
The lighting device according to claim 1 , wherein the frame portion is formed in an annular shape around the lens presser. The lighting device according to claim 3 , wherein the frame portion includes a lens pressing attachment portion for attaching the lens pressing member by sandwiching the vicinity of the periphery of the lens pressing member.   The lighting fixture according to claim 3 or 4, wherein the lens holder and the frame portion are integrally formed in two colors.   The lighting device according to claim 1, wherein the frame portion includes a groove fitting portion that is fitted into the groove portion.

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