JP7394335B2 - lenses and lighting equipment - Google Patents

Description

The present disclosure relates to a lens and a lighting fixture equipped with the lens.

2. Description of the Related Art Conventionally, lighting equipment including a lens that controls the distribution of incident light is widely known. For example, Patent Document 1 describes a lighting device in which an annular protrusion is formed on a light incident surface facing the light source, and a diffusion process is applied to a flat surface located at the tip of the protrusion to diffuse the light. lenses are disclosed. Further, Patent Document 2 discloses a lighting fixture in which a lens is configured to be movable along the optical axis direction.

JP2017-67831A JP 2019-61814 Publication

By the way, in lighting equipment equipped with a lens, a so-called dropout may occur in which the center of the irradiation area becomes dark. In particular, when the distance between the lens and the light source is short, the light distribution angle generally becomes large, making it more likely that dropout will occur. Furthermore, in a lighting fixture in which the lens is configured to be movable along the optical axis direction, the closer the lens is to the light source, the more likely it is that the lens will fall out.

An object of the present disclosure is to provide a lens that can suppress the occurrence of dropout, and a lighting fixture equipped with the lens.

A lens that is an aspect of the present disclosure is a lens that controls the distribution of incident light, and includes a reflective surface formed in a cylindrical shape with the optical axis as the center, and the reflective surface is on the optical axis side. It includes a convex inner convex region and a convex outer convex region on the opposite side to the optical axis.

A lighting fixture that is one aspect of the present disclosure includes the above lens and a light source, and is configured to be able to change the distance between the lens and the light source along the optical axis direction of the lens.

According to the lens according to the present disclosure, it is possible to suppress the occurrence of drop-off in which the center of the irradiation area becomes dark, and it is possible to provide a lighting fixture that can uniformly irradiate light even when the light distribution angle is increased.

FIG. 1 is a perspective view of a lighting fixture that is an example of an embodiment, viewed diagonally from above. FIG. 1 is a perspective view of a lighting fixture that is an example of an embodiment, viewed diagonally from below. FIG. 1 is an exploded perspective view of a lighting fixture that is an example of an embodiment. FIG. 1 is a cross-sectional view of a lighting fixture that is an example of an embodiment. FIG. 2 is a diagram illustrating a lens moving mechanism along an optical axis direction in a lighting fixture that is an example of an embodiment. FIG. 2 is a perspective view of a lens that is an example of an embodiment, viewed from a light incident surface side. FIG. 2 is a perspective view of a lens, which is an example of an embodiment, viewed from a light exit surface side. FIG. 2 is a cross-sectional view of a lens that is an example of an embodiment. FIG. 2 is a diagram for explaining the function of a lens that is an example of an embodiment. FIG. 2 is a diagram for explaining the function of a lens that is an example of an embodiment.

Hereinafter, an example of an embodiment of a lighting fixture according to the present disclosure will be described in detail with reference to the drawings. 1 and 2 are perspective views of a lighting fixture 10 that is an example of an embodiment, and FIG. 3 is an exploded perspective view of the lighting fixture 10. FIG. 4 is a cross-sectional view of the lighting fixture 10 taken along the optical axis direction of the lens 30.

Here, the optical axis X (FIG. 8) of the lens 30 is an axis passing through the center of the lens 30, and is an axis passing through the centers of the light entrance surface 32 and the light exit surface 33. In this specification, for convenience of explanation, when the lighting fixture 10 is attached to the ceiling, the vertically upper side of the lighting fixture 10 and each component will be referred to as "upper", and the vertically lower side will be referred to as "lower". In this embodiment, the optical axis of the lens 30 coincides with the central axis of the instrument body 11, and in the state shown in FIG. 1, the optical axis is along the vertical direction.

As illustrated in FIGS. 1 to 4, the lighting fixture 10 includes a fixture body 11 in which the light source module 1 is housed, and a cylindrical frame 20 fixed to the lower part of the fixture body 11. The fixture main body 11 is a ceiling-embedded lighting fixture that includes a cylindrical portion 12 and a radiation fin 13, and is inserted into a hole in a ceiling board with the opening of the cylindrical portion 12 facing vertically downward. The lighting fixture 10 is generally called a downlight. The lighting fixture 10 includes a power supply unit (not shown) that supplies power to the light source module 1. Note that the power supply unit may be integrated with the appliance main body 11.

The lighting fixture 10 is installed, for example, on a horizontal ceiling indoors in a residence, but it can also be installed on a ceiling that is inclined with respect to the horizontal and vertical directions. Furthermore, the lighting fixture 10 can be attached to the ceiling of a hallway or entrance of a residence, or to the ceiling of a public facility such as a library, a commercial facility such as a department store, an office, a store, a factory, etc. The ceiling to which the lighting fixture 10 is attached may be any ceiling that partitions the upper surface of the architectural space, and may be, for example, the ceiling of an entrance porch, terrace, or the like. Note that the lighting fixture according to the present disclosure may be attached to a duct rail or the like, and may be fixed to an installation target in a form other than being embedded in the ceiling.

The lighting fixture 10 is provided with a plurality of attachment springs 23. The lighting fixture 10 is fixed to the ceiling by the attachment spring 23 coming into contact with the periphery of the embedded hole in the ceiling in the attic space. In this embodiment, three attachment springs 23 are fixed at equal intervals in the circumferential direction of the frame 20. The lighting fixture 10 is attached to a ceiling plate, for example, with the flange 22 of the frame 20 in contact with the peripheral edge of the embedded hole in the ceiling surface.

The lighting fixture 10 includes a light source module 1 including a light source 2 and a lens 30 that controls the distribution of light emitted from the light source 2. Configured to be changeable. In the lighting fixture 10, by changing the distance between the light source 2 and the lens 30, the distribution angle of the irradiated light can be adjusted. The lens 30, like the light source module 1, is housed in the cylindrical portion 12 of the instrument body 11. In this embodiment, when the lens 30 is brought closer to the light source 2, the light distribution angle widens, and when the lens 30 is moved away from the light source 2, the light distribution angle becomes narrower.

The lighting fixture 10 includes a lens holder 40 attached to a lens 30 and a cylindrical baffle 50 that supports the lens holder 40. The baffle 50 has an outer diameter smaller than the inner diameter of the cylindrical part 12 of the instrument main body 11, is inserted into the cylindrical part 12, and is rotatably supported with respect to the cylindrical part 12. The lens 30 is attached to the inside of the cylindrical portion 12 via a lens holder 40 and a baffle 50.

The lighting fixture 10 may include a translucent cover 60 disposed below the lens 30. The cover 60 is a disc-shaped member made of resin or glass, and in this embodiment is fixed within the cylinder of the baffle 50 using a substantially C-shaped cover fixing member 61. The cover fixing member 61 supports the cover 60 from below by coming into contact with the peripheral edge of the cover 60, and has at least three parts protruding outside the C shape and being inserted into the side holes 53 formed in the baffle 50. It is fixed to the baffle 50.

In the lighting fixture 10, the fixture body 11 and the frame 20 are connected to each other via a connecting member 15. Although FIG. 1 shows a state in which the central axis of the instrument body 11 and the central axis of the frame body 20 coincide, the central axis of the instrument body 11 is at a predetermined angle with respect to the central axis of the frame body 20. It is configured to tilt within a range. That is, the lighting fixture 10 has a swinging function of the fixture body 11. The lighting fixture 10 can change the angle of the fixture body 11 while being attached to the ceiling board.

Each component of the lighting fixture 10 will be explained in detail below.

The light source module 1 includes, for example, a light source 2 and a substrate 3 on which the light source 2 is arranged. The light source 2 is preferably a semiconductor light emitting element such as an LED (Light Emitting Diode), although it is not particularly limited. The LED may be encapsulated with an encapsulation layer containing phosphor. In this case, for example, a part of the blue light of the LED is converted into light with a longer wavelength by the phosphor, and white light is emitted by mixing the color with the remaining part of the blue light. The light source module 1 may include a heat sink that diffuses the heat of the light source 2.

The instrument body 11 has a bottomed, substantially cylindrical cylindrical portion 12 and radiation fins 13 erected on the cylindrical portion 12 . The cylindrical portion 12 includes a substantially cylindrical wall portion 12a and a substantially circular top portion 12b. The device main body 11 is preferably made of a metal material, and is manufactured by drawing, die-casting, or the like. The radiation fin 13 is formed by a plurality of metal plates standing upright on the top surface portion 12b. Note that the shape of the device main body is not particularly limited, and, for example, it may not have heat radiation fins.

In this embodiment, a part of the wall part 12a of the cylindrical part 12, the top part 12b, and the radiation fins 13 are formed of one integrally molded member, and the remaining part of the wall part 12a is a wall part that is a separate member. It is composed of a cover 12c. The wall cover 12c is fixed to the integrally molded member using screws 18.

An annular groove 12d is formed in the inner peripheral surface of the cylindrical portion 12. The annular groove 12d is formed at the same height along the circumferential direction of the cylindrical portion 12 on the inner surfaces of the wall surface portion 12a and the wall surface cover 12c. The flange 51 of the baffle 50 is inserted into the annular groove 12d. Further, the light source module 1 is fixed to the inner surface of the top surface portion 12b using the holder 4. Since the light source module 1 is connected to the cable 5 leading to the power supply unit, a cable insertion hole is formed in the top surface portion 12b. Further, a cylindrical cable guide 6 for passing the cable 5 pulled out from the cylindrical portion 12 may be attached to the top surface portion 12b.

The frame 20 is a cylindrical body having an inner diameter one size larger than the outer diameter of the cylindrical part 12 of the instrument main body 11, and is connected to the cylindrical part 12 via the connecting member 15 so as to surround the cylindrical part 12. Fixed at the bottom. The frame 20 includes a substantially cylindrical cylindrical wall 21 and a flange 22 extending radially outward from the lower end of the cylindrical wall 21 . Further, a fixing ring 24 for fixing the connecting member 15 to the upper end portion of the cylinder wall 21 is attached to the cylinder wall 21 . A plurality of screw holes are formed in the cylinder wall 21 to which screws 25 for fixing the fixing ring 24 are fastened.

The fixing ring 24 is an annular member disposed at the upper end of the cylindrical wall 21, and includes a spring fixing portion 24a that extends toward the flange 22 (downward) along the outer surface of the cylindrical wall 21, and a spring fixing portion 24a opposite to the spring fixing portion 24a. A stopper 24b that projects in the direction (upward) is included. The spring fixing parts 24a are parts that hold the attachment springs 23, and are provided in plurality at intervals in the circumferential direction of the fixing ring 24. The stopper 24b is a portion of the connecting member 15 that is contacted by a locking piece 15d, which will be described later, and regulates the swing angle of the instrument body 11 with respect to the frame 20.

The connecting member 15 includes an annular portion 15a, a first fixing piece 15b extending upward from the inner edge of the annular portion 15a, and a second fixing piece 15c extending downward from the inner edge of the annular portion 15a. Furthermore, the connecting member 15 includes a locking piece 15d that extends upward from the inner edge of the annular portion 15a and is bent halfway toward the outside in the radial direction of the annular portion 15a. The annular portion 15a is arranged at the upper end of the cylindrical wall 21 of the frame body 20, and is fixed to the cylindrical wall 21 by being pressed down from above by a fixing ring 24. In this embodiment, one first fixing piece 15b and two second fixing pieces 15c arranged in the radial direction of the annular portion 15a are provided. The connecting member 15 is manufactured, for example, by processing a single metal plate.

The first fixing piece 15b and the second fixing piece 15c are parts that are screwed to the instrument body 11, and the first fixing piece 15b is fixed to the center of the instrument body 11 in the vertical direction using a screw 16, The two fixing pieces 15c are fixed to the lower part of the instrument body 11 using screws 17. The first fixing piece 15b is longer than the second fixing piece 15c in the vertical direction, and has a shape whose upper part is largely widened. A gently curved elongated hole 15e into which the screw 16 is inserted is formed in the widened portion of the first fixing piece 15b. Note that the screw insertion hole formed in the second fixing piece 15c is a round hole corresponding to the shaft diameter of the screw 17.

In the state shown in FIG. 1, the screw 16 is located at one end of the elongated hole 15e, and the central axis of the instrument body 11 and the center axis of the frame 20 are aligned. The screw 16 rotates so as to move toward the other end of the elongated hole 15e. According to the lighting fixture 10, for example, with the frame body 20 fixed to the ceiling, by applying a force exceeding the static friction force generated due to the tightening force of the screws 16 to the fixture body 11, the center of the fixture body 11 can be adjusted. The axis can be tilted with respect to the vertical direction (the central axis of the frame 20). Note that the central axis of the instrument body 11 and the optical axis X (FIG. 8) of the lens 30 match regardless of the swing angle.

The lens 30 is formed into a cylindrical shape with the optical axis X as the center, and has a light entrance surface 32 through which the light from the light source 2 mainly enters, a light exit surface 33 through which the light that enters from the light entrance surface 32 mainly exits. It is an optical member including a reflective surface 34, and controls the light distribution of incident light. The light entrance surface 32 has a substantially perfect circular shape in a plan view, and similarly, the light exit surface 33 has a substantially perfect circular shape in a bottom view. The lens 30 has a shape in which the diameter gradually increases from the light incidence surface 32 side toward the light output surface 33 side, and the circumferential length of the reflective surface 34 gradually increases toward the end.

The lens 30 is made of highly transparent resin such as acrylic resin, polycarbonate, and silicone, or glass. The lens 30 includes a flange 35 whose lower end protrudes outward in the radial direction, and a plurality of recesses 36 formed at the peripheral edge of the light exit surface 33. For example, three recesses 36 are formed at equal intervals in the circumferential direction of the lens 30. Further, the lens 30 has an engaging portion 37 formed adjacent to the recessed portion 36 .

The lens holder 40 includes an annular base portion 41, a hook portion 42 extending downward from the lower end of the base portion 41 and bent radially inward of the base portion 41, and a hook portion 42 extending radially outward from the outer peripheral surface of the base portion 41. It has a protruding claw part 43. The lens holder 40 is attached to the lens 30 from the light incidence surface 32 side (upper side), and after the hook portion 42 is inserted into the recess 36, the hook portion 42 is engaged by rotating it toward the engaging portion 37 side. It fits into the section 37.

The lens holder 40 is fixed to the lens 30 by, for example, at least a portion of the base portion 41 abutting the upper surface of the flange 35 and the hook portion 42 fitting into the engaging portion 37 . In this embodiment, three hook parts 42 are formed at equal intervals in the circumferential direction of the base part 41, and two claw parts 43 are formed side by side in the radial direction of the base part 41. Further, the lens holder 40 has a guide section 44 that stands up on the upper surface of the base section 41 . For example, three guide parts 44 are formed at equal intervals in the circumferential direction of the base part 41. As will be described in detail later, the guide portion 44 engages with a rib 14 formed inside the instrument main body 11 and guides vertical movement of the lens holder 40 (in the optical axis direction of the lens 30) along the rib 14. do.

FIG. 5 is a diagram showing a state in which the wall cover 12c and the frame 20 of the instrument main body 11 are removed, and is a diagram for explaining a mechanism for moving the lens 30 along the optical axis direction. In this embodiment, the lens 30 moving mechanism is mainly composed of the lens holder 40 and the baffle 50. The inner peripheral surface of the baffle 50 preferably has a low reflectance of light, and is, for example, black. In this case, glare from the lighting fixture 10 can be reduced.

As illustrated in FIGS. 3 to 5, the lens 30 is supported by a baffle 50 via a lens holder 40. The baffle 50 is a substantially cylindrical member, and the lens 30 and the lens holder 40 are disposed within the cylinder of the baffle 50 so as to be movable in the optical axis direction of the lens 30. The baffle 50 has a flange 51 formed along the circumferential direction on the outer peripheral surface of the cylinder wall. The baffle 50 is rotatably supported with respect to the cylindrical portion 12 by fitting the flange 51 into an annular groove 12d formed in the inner peripheral surface of the cylindrical portion 12 of the instrument main body 11.

The baffle 50 is formed with inclined grooves 52 penetrating the cylinder wall at at least two locations spaced apart in the circumferential direction of the cylinder wall. The inclined groove 52 extends in a direction that is perpendicular to the circumferential direction and the axial direction of the cylinder wall, and is inclined so that one longitudinal end of the groove is located higher in the cylinder wall than the other end. The claw portion 43 of the lens holder 40 is inserted into the inclined groove 52 . The claw portion 43 has an inclined shape corresponding to the shape of the inclined groove 52 and is movable along the inclined groove 52.

In this embodiment, by rotating the baffle 50, the claw portion 43 is pushed up by the lower edge of the inclined groove 52 and moved toward one end (upper end side) in the longitudinal direction of the groove, or is pushed down by the upper edge of the inclined groove 52. and moves to the other end (lower end) of the groove in the longitudinal direction. Thereby, the lens holder 40 moves in the vertical direction. Then, the lens 30 moves in the optical axis direction, and the distance between the light source 2 and the lens 30 changes. Note that since the guide portion 44 of the lens holder 40 engages with the rib 14 of the instrument body 11, the lens holder 40 is prevented from rotating along with the lens holder 40, and the lens holder 40 moves in the vertical direction along the rib 14.

For example, since the baffle 50 is rotated by being gripped at its lower part, the lower part of the baffle 50 may be provided with anti-slip irregularities, grooves, etc. Furthermore, a scale indicating the position of the lens 30, the distance between the light source 2 and the lens 30, etc. may be provided at the bottom of the baffle 50.

The configuration of the lens 30 will be explained in more detail below with reference to FIGS. 6 to 8. 6 is a perspective view of the lens 30 seen from the light entrance surface 32 side, and FIG. 7 is a perspective view of the lens 30 seen from the light exit surface 33 side. FIG. 8 is a cross-sectional view of the lens 30.

As illustrated in FIGS. 6 to 8, the lens 30 has a shape that widens toward the end and has a larger diameter on the light exit surface 33 side than on the light entrance surface 32 side. As described above, the lens 30 has a light entrance surface 32 through which the light from the light source 2 mainly enters, a light exit surface 33 through which the light incident from the light entrance surface 32 mainly exits, and a cylindrical shape centered on the optical axis X. and a reflective surface 34 formed on the surface. The reflective surface 34 is a side surface of the lens 30 that totally reflects incident light at a critical angle or more. When light that is less than the critical angle is incident on the reflective surface 34, for example, the light is transmitted through the reflective surface 34 and absorbed by the baffle 50 surrounding the lens 30. The lens 30 is preferably formed rotationally symmetrically about the optical axis X.

The lens 30 has a flange 35, a recess 36, and an engaging portion 37, which are used for attaching the lens holder 40. In the lens holder 40, at least a portion of the annularly formed base portion 41 presses the flange 35 from above, and the hook portion 42 fits into the engaging portion 37, thereby holding the peripheral edge of the lens 30 from above and below. . The engaging part 37 is arranged adjacent to the recessed part 36 in the circumferential direction of the lens 30, and a step is formed on the lower surface of the engaging part 37, on which the hook part 42 is caught.

The lens 30 has a recess 31 formed at one end in the optical axis direction. The lens 30 is arranged so that the recess 31 faces the light source module 1 side, and the surface formed at the bottom of the recess 31 becomes the light entrance surface 32. Further, one end in the optical axis direction is the upper end of the lens 30, and the other end in the optical axis direction is the lower end of the lens 30. Preferably, the recess 31 is formed rotationally symmetrically about the optical axis X. The recess 31 is formed, for example, from the upper end of the lens 30 in the optical axis direction to a depth of 30% to 70% of the length (thickness) in the optical axis direction.

In the lens 30, the light from the light source 2 mainly enters through the light entrance surface 32, and the light whose distribution has been controlled exits from the light exit control surface 33a of the light exit surface 33. Most of the light emitted from the light source 2 is introduced into the recess 31 and enters the lens 30 from the light entrance surface 32. On the other hand, a part of the light introduced into the recess 31 enters, for example, from the side surface 31 a of the recess 31 , is reflected by the reflective surface 34 , and is emitted from the light exit surface 33 .

The light entrance surface 32 is the bottom surface of the recess 31 and is formed substantially perpendicular to the optical axis, that is, substantially parallel to the radial direction of the lens 30. Further, the side surface 31a of the recess 31 is formed into a substantially cylindrical shape, and its diameter gradually decreases from the upper end of the recess 31 toward the lower end. Dimples 32x, which are fine irregularities, may be formed on the light incident surface 32 to reduce light unevenness. The dimples 32x are formed, for example, over the entire area of the light entrance surface 32. Note that the light entrance surface 32 may be a curved surface that bulges toward the light source module 1 side.

The light exit surface 33 is a surface facing away from the light source module 1, and is formed to have a larger area than the light entrance surface 32. The light exit surface 33 includes a light exit control surface 33a including at least one convex portion. The light emission control surface 33a is a curved surface or a surface inclined with respect to the radial direction of the lens 30, and light distribution is controlled by transmitting light through this surface. The light emission control surface 33a is formed at the center of the light emission surface 33 with an area of 30% to 70%, preferably 40% to 60%, of the light emission surface 33. Note that the lower surface of the flange 35 is not included in the light exit surface 33.

A surface substantially parallel to the radial direction of the lens 30 is formed around the light emission control surface 33a. In this embodiment, dimples 33x, which are fine irregularities, are formed on the surface along the radial direction. The dimples 33x may be formed over the entire surface of the light exit surface 33 that is substantially parallel to the radial direction of the lens 30. It is preferable that the light exit surface 33 is formed rotationally symmetrically about the optical axis X, similarly to the recess 31.

For example, an annular groove centered on the optical axis X is formed on the light emission control surface 33a, thereby forming an annular convex portion. A plurality of annular grooves (annular protrusions) may be formed concentrically. It is preferable that the lens 30 is a so-called Fresnel lens in which the light exit surface 33 has a sawtooth cross section. In this embodiment, a convex portion 38 that is curved outward and has a perfect circular shape when viewed from the bottom is formed in the center of the light exit surface 33, and two concentric grooves are formed to surround the convex portion 38. This annular groove forms an annular protrusion 39 on the light exit surface 33 so as to surround the protrusion 38 .

The light output control surface 33a includes a slope region 33b that is inclined from the reflective surface 34 side toward the optical axis X side, that is, from the outside in the radial direction of the lens 30 to the inside so as to approach the light entrance surface 32. The slope region 33b surrounds the convex portions 38 and 39 and is formed in an annular shape with a constant width. In this embodiment, a slope region 33b is formed along the outer peripheral edge of the light emission control surface 33a. As shown in FIG. 9, which will be described later, the slope area 33b is generated by reflecting the light incident from the peripheral edge of the light incident surface 32 toward the reflecting surface 34, and causing the light to fly outside the target irradiation area. Suppresses light unevenness.

Preferably, the slope region 33b is inclined at an angle of 20° to 40° with respect to a plane perpendicular to the optical axis X. In a cross-sectional view of the lens 30, the angle θ between the imaginary line extending the slope region 33b and the imaginary line perpendicular to the optical axis X is preferably 20° to 40°, more preferably 25° to 35°. . If the angle θ is within this range, it is easy to suppress light unevenness that occurs when light enters from the peripheral edge of the light entrance surface 32 and flies to the outside of the target irradiation area. The slope area 33b may be a gently curved surface or a flat slope.

In the lens 30, the diameter of the light incident surface 32 is φ1, the inner diameter of the slope region 33b (the diameter across the inner periphery of the slope region 33b) is φ2, and the outer diameter of the slope region 33b (the diameter across the outer periphery of the slope region 33b). When φ3 is satisfied, the relationship φ2<φ1<φ3 is satisfied. Note that both the light incidence surface 32 and the light emission control surface 33a are formed rotationally symmetrically about the optical axis X. The light exit control surface 33a has a larger projected area than the light entrance surface 32, and is formed so as to overlap the entire light entrance surface 32 in the optical axis direction of the lens 30.

Since the lens 30 satisfies the relationship φ2<φ1<φ3, the annularly formed slope region 33b is formed at a position overlapping the peripheral edge of the light incident surface 32 in the optical axis direction of the lens 30. The slope region 33b has an inner peripheral edge located on the radially inner side of the lens 30 than the peripheral edge of the light entrance surface 32, and an outer peripheral edge located on the radial outside of the lens 30 than the peripheral edge of the light entrance surface 32. Therefore, light entering from the peripheral portion of the light entrance surface 32 is more likely to enter the slope region 33b.

FIG. 9 is a diagram for explaining the effect of suppressing light unevenness by the slope region 33b. As illustrated in FIG. 9, when the lens 30 satisfies the relationship φ2<φ1<φ3 and the annularly formed slope region 33b overlaps the peripheral edge of the light incident surface 32 in the optical axis direction, the light Light incident from the peripheral edge of the entrance surface 32 is reflected radially outward of the lens 30, for example, by the slope region 33b. This light then passes through the reflective surface 34 and is absorbed by the baffle 50. Note that the light incident from the peripheral portion of the light incidence surface 32 may spread greatly outside the lens 30 and be irradiated outside the intended irradiation area. Furthermore, the light that is reflected by the reflective surface 34 and passes near the periphery of the light incidence surface 32 is transmitted through the slope area 33b and is irradiated. Note that when the light that is reflected by the reflective surface 34 and passes near the periphery of the light incidence surface 32 passes through the light emission control surface 33a and is irradiated, the light may be irradiated outside the intended irradiation area. According to the lens 30 that satisfies the relationship φ2<φ1<φ3, it is possible to suppress light unevenness caused by light flying outside the target irradiation area.

It is preferable that the lens 30 satisfy at least one of the following relationships (1) and (2) regarding the diameter φ1 of the light incident surface 32, the inner diameter φ2 of the slope area 33b, and the outer diameter φ3 of the slope area 33b. It is particularly preferable that both relationships 1) and (2) are satisfied.
(1) 0.95×φ1<φ2<0.99×φ1
(2) 1.04×φ1<φ3<1.07×φ1
When the conditions (1) and (2) are satisfied, the occurrence of the light unevenness can be more effectively suppressed.

As described above, the reflecting surface 34 is a side surface of the lens 30 formed in a substantially cylindrical shape with the optical axis Improve efficiency. The reflective surface 34 is a so-called total reflection surface, and totally reflects incident light at an angle equal to or greater than the critical angle. The reflective surface 34 gradually increases in diameter from the upper end toward the lower end. Note that the upper end of the reflective surface 34 is located at the upper end of the lens 30, and the boundary with the flange 35 is the lower end of the reflective surface 34.

The reflective surface 34 includes an inner convex region 34a that is convex on the optical axis X side (inside the lens 30), and an outer convex region 34b that is convex on the side opposite to the optical axis X (outside the lens 30). The inner convex region 34a and the outer convex region 34b are each formed in an annular shape with a constant width (length in the optical axis direction). The reflective surface 34 including the inner convex region 34a and the outer convex region 34b is preferably formed rotationally symmetrically about the optical axis X. In this embodiment, regular irregularities are formed on the reflective surface 34 by the inner convex region 34a and the outer convex region 34b.

FIG. 10 is a diagram for explaining the effect of suppressing center drop due to the reflective surface 34. As illustrated in FIG. 10, when an inner convex region 34a and an outer convex region 34b are formed on the reflective surface 34, the light reflected by the reflective surface 34 is efficiently irradiated directly below the lighting fixture 10, and the center of the irradiated region It is possible to suppress the occurrence of darkening in the middle of the image. Particularly, when the distance between the light source 2 and the lens 30 is brought close and the light distribution angle is set large, dropout is likely to occur. It can be reflected directly below the instrument 10. Further, the outer convex region 34b can efficiently reflect light directly below the lighting fixture 10, especially when the light source 2 and the lens 30 are separated and the light distribution angle is set small.

The reflective surface 34 includes a plurality of inner convex regions 34a and a plurality of outer convex regions 34b, and may be formed in a waveform, but preferably includes one each. The inner convex region 34a is preferably formed closer to the light exit surface 33 than the outer convex region 34b, that is, closer to the lower end of the lens 30. In this embodiment, the reflective surface 34 includes one inner convex region 34a and one outer convex region 34b, and the continuous inner convex region 34a and the continuous outer convex region 34b are formed over the entire reflective surface 34.

The inner convex region 34a and the outer convex region 34b are preferably curved surfaces having no bent portions, and are formed in an annular shape with the optical axis X as the center. In this embodiment, the inner convex region 34a is gently curved toward the inner side of the lens 30, and the outer convex region 34b is gently curved toward the outer side of the lens 30. The inner convex region 34a and the outer convex region 34b may be curved surfaces with constant curvature or may be curved surfaces with varying curvature. In this embodiment, the radius of curvature R2 of the outer convex region 34b is larger than the radius of curvature R1 of the inner convex region 34a.

In this embodiment, the width (length in the optical axis direction) of the outer convex region 34b is wider than the width of the inner convex region 34a, and the area S2 of the outer convex region 34b is larger than the area S1 of the inner convex region 34a. Note that the area ratio between the inner convex region 34a and the outer convex region 34b is preferably changed as appropriate depending on the curvature of each region, etc., and may be S1≧S2, as will be described later.

In the lens 30, the area of the inner convex region 34a is S1, the radius of curvature of the inner convex region 34a is R1, the area of the outer convex region 34b is S2, the radius of curvature of the outer convex region 34b is R2, and the maximum diameter of the reflective surface 34. When is φ, it is preferable that at least one of the following relationships (1) and (2) is satisfied, and it is particularly preferable that both relationships (1) and (2) are satisfied.
(1) R2≧1.5×φ
(2) 5×φ×(S1/S2) ² ≦R1≦25×φ×(S1/S2) ²

When the conditions (1) and (2) are satisfied, the occurrence of the dropout can be more effectively suppressed. For example, when the area S1 of the inner convex region 34a is small, it is preferable to set the radius of curvature R1 of the inner convex region 34a to be small to set a large curvature.

As described above, according to the lighting fixture 10 equipped with the lens 30, it is possible to suppress the occurrence of drop-off in which the center of the irradiation area becomes dark, and even when the light distribution angle is increased, uniform light irradiation is possible. . Due to the presence of the inner convex region 34a and the outer convex region 34b on the reflective surface 34, even in the lighting fixture 10 where the distance between the light source 2 and the lens 30 changes, it is possible to achieve the desired light distribution control while preventing the occurrence of center drop. can be highly suppressed. Furthermore, by satisfying the relationship φ2<φ1<φ3, it is possible to suppress light unevenness caused by light flying outside the target irradiation area.

Note that the above-described embodiments may be modified in design as appropriate without impairing the purpose of the present disclosure. For example, in the above embodiment, the lighting fixture 10 having the swinging function is illustrated, but the lighting fixture does not need to have the swinging function. Further, the slope region 33b does not need to exist on the light emission control surface, and the lens does not need to satisfy the relationship φ2<φ1<φ3.

1 light source module, 2 light source, 3 board, 4 holder, 5 cable, 6 cable guide, 10 lighting fixture, 11 fixture body, 12 cylinder part, 12a wall part, 12b top part, 12c wall cover, 12d annular groove, 13 heat radiation Fin, 14 Rib, 15 Connecting member, 15a Annular portion, 15b First fixing piece, 15c Second fixing piece, 15d Locking piece, 15e Long hole, 16, 17, 18 Screw, 20 Frame, 21 Cylinder wall, 22 flange, 23 mounting spring, 24 fixing ring, 24a spring fixing part, 24b stopper, 25 screw, 30 lens, 31 recess, 32 light incident surface, 33 light exit surface, 33a light exit control surface, 33b slope area, 34 reflective surface , 34a inner convex region, 34b outer convex region, 35 flange, 36 concave portion, 37 engaging portion, 40 lens holder, 41 base portion, 42 hook portion, 43 claw portion, 44 guide portion, 50 baffle, 51 flange, 52 inclination groove, 53 side hole, 60 cover, 61 cover fixing member

Claims (3)

a light source and
a lens that controls the distribution of the incident light from the light source;
A lighting fixture configured to be able to change the distance between the lens and the light source along the optical axis direction of the lens,
The lens is a Fresnel lens having a reflective surface formed in a cylindrical shape centered on the optical axis, and a light exit surface including a plurality of concentric annular grooves,
The reflective surface is a surface that receives part of the light from the light source and reflects it toward the light exit surface, and includes an inner convex region convex toward the optical axis and a convex inner region convex on the opposite side to the optical axis. The inner convex region and the outer convex region are continuously formed curved surfaces, and the inner convex region is farther from the light source than the outer convex region. formed in position,
The light exit surface includes a first convex portion formed in the center thereof and curved toward the outside, a second annular convex portion formed to surround the first convex portion, and the second convex portion. an annular region having a surface parallel to the radial direction of the lens, which is formed to surround the lens;
The radius of curvature R2 of the outer convex region is larger than the radius of curvature R1 of the inner convex region.
lighting equipment. The lighting fixture according to claim 1, wherein dimples are formed in the annular region of the light exit surface. The lighting fixture according to claim 1 or 2 , wherein the length of the outer convex region in the optical axis direction is longer than the length of the inner convex region in the optical axis direction.

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