Reflector and optical unit
The resin reflector design with deformation suppression features addresses deformation issues in lamp units by stabilizing components within a defined rectangular region, maintaining consistent light distribution and reducing glare.
Patent Information
- Authority / Receiving Office
- JP · JP
- Patent Type
- Applications
- Current Assignee / Owner
- KOITO MFG CO LTD
- Filing Date
- 2024-12-23
- Publication Date
- 2026-07-03
Smart Images

Figure 2026111432000001_ABST
Abstract
Description
Technical Field
[0001] The present invention relates to a reflector.
Background Art
[0002] Conventionally, a lamp unit mainly including a heat sink, a substrate, a reflector unit, a projection lens, and a holder has been devised (see Patent Document 1). In this lamp unit, the reflector unit presses the substrate against the heat sink, and the substrate is fixed to the heat sink. Further, the reflector unit has an opening through which light emitted from a light-emitting element mounted on the substrate passes forward of the vehicle, and reflecting surfaces provided so as to project forward from both left and right sides of the opening.
Prior Art Documents
Patent Documents
[0003]
Patent Document 1
Summary of the Invention
Problems to be Solved by the Invention
[0004] However, when mounting a plurality of parts including optical parts on a heat sink as in the above-described lamp unit, if the shapes of the respective parts, the portions where the parts abut against each other, the portions where the parts are fastened to each other, etc. are not properly considered, the reflecting surface may be deformed when the lamp unit is assembled.
[0005] The present invention has been made in view of such a situation, and one of its exemplary objects is to provide a new technique for suppressing deformation of a reflector or a unit including a reflector.
Means for Solving the Problems
[0006] To solve the above problems, a reflector according to one aspect of the present invention is a resin reflector that is positioned with its main surface facing the front of the vehicle and fastened to a heat sink, and has an opening formed in the center in the longitudinal direction through which light emitted from a light source passes, a pair of fastening parts formed at both ends in the longitudinal direction and fastened to the heat sink, and a reflective part formed to protrude forward from between the pair of fastening parts and the opening and reflects the light that has passed through the opening, wherein in a front view, the reflective part overlaps at least a portion with a rectangular region with the pair of fastening parts at both ends.
[0007] According to this embodiment, in a front view of the reflector, the reflective portion is included in a rectangular region with a pair of fastening portions at both ends. Therefore, deformation of the reflective portion is suppressed compared to the case where the reflective portion is not included in the rectangular region.
[0008] The reflective section may further be provided with a plate-shaped shade attached to the bottom or top surface. The shade may block some of the light passing through the opening. This suppresses deformation not only of the reflective section but also of the shade.
[0009] The shade may, in a front view from the front of the vehicle, overlap at least part with a rectangular area with a pair of fastening points at both ends. This further reduces deformation of the shade.
[0010] The device may further include a deformation transmission suppression section formed between the fastening section and the reflective section, which suppresses the transmission of the deformation effect at the fastening section to the reflective section. This further suppresses the deformation of the reflective section.
[0011] The deformation transmission suppression section may be a slit formed near the fastening section. This allows the deformation transmission suppression section to be realized with a simple shape.
[0012] A recessed step on the rear side of the vehicle may be provided between the fastening portion and the area where the slit is formed. This reduces the gap between the fastening portion of the reflector and the heat sink before fastening.
[0013] The slits may be provided at four symmetrical positions centered on the rectangular region. This ensures that the effect of the deformation transmission suppression unit is evenly distributed throughout the rectangular region.
[0014] Another aspect of the present invention is an optical unit. This optical unit comprises a heat sink, a substrate on which a light source is mounted and placed at a predetermined position on the heat sink, a lens for polarizing light emitted from the light source, and the above-mentioned reflector fastened to the heat sink with the substrate and lens sandwiched between the heat sink. The lens is a rectangular resin plate and has four contact portions at its four corners that are crushed while in contact with the back surface of the reflector when sandwiched between the substrate and the reflector. The four contact portions are contained within a rectangular area.
[0015] According to this embodiment, when fastening the reflector, the load can be applied relatively evenly to the four contact points of the lens, so that the lens can be fixed in the desired position and orientation.
[0016] Any combination of the above components, or any conversion of the expression of the present invention between manufacturing methods, devices such as luminaires and lighting fixtures, light-emitting modules, light sources, etc., are also valid embodiments of the present invention. [Effects of the Invention]
[0017] According to the present invention, deformation of the reflector or the unit including the reflector can be suppressed. [Brief explanation of the drawing]
[0018] [Figure 1] This is a perspective view of a vehicle light fixture according to this embodiment. [Figure 2] Figure 1 is an exploded perspective view of a vehicle lighting fixture. [Figure 3] This is a front view of the reflector according to this embodiment. [Figure 4] This is a horizontal cross-sectional view of the optical unit according to this embodiment. [Figure 5]FIG. 5(a) is an enlarged cross-sectional view showing the state before the fastening portion in region A of FIG. 4 is fastened with a screw, and FIG. 5(b) is an enlarged cross-sectional view showing the state after the fastening portion in region A of FIG. 4 is fastened with a screw. [Figure 6] It is a schematic diagram for explaining the state where the resin plate according to the present embodiment is abutted against the back surface of the reflector. [Figure 7] It is an enlarged view of region B in FIG. 4.
Embodiments for Carrying Out the Invention
[0019] Hereinafter, the present invention will be described with reference to the drawings based on preferred embodiments. The same or equivalent components, members, and processes shown in each drawing are denoted by the same reference numerals, and redundant explanations will be omitted as appropriate. Further, the embodiments are illustrative and not restrictive of the invention, and not all the features described in the embodiments and their combinations are necessarily essential to the invention.
[0020] FIG. 1 is a perspective view of a vehicle lamp according to the present embodiment. FIG. 2 is an exploded perspective view of the vehicle lamp shown in FIG. 1. The vehicle lamp shown in FIGS. 1 and 2 is a vehicle headlamp and is configured to be able to form both a low-beam and a high-beam light distribution pattern.
[0021] The vehicle lamp 10 includes a projection lens 12, a lens holder 14, a reflector 16, a circuit board 18, and a heat sink 20. The projection lens 12 is attached to a predetermined position of the lens holder 14. Further, the projection lens 12 is manufactured by injection molding using a resin material having high transparency and high heat resistance, such as acrylic or polycarbonate. The lens holder 14 is fastened to the heat sink 20 with screws 22.
[0022] Figure 3 is a front view of a reflector according to this embodiment. The reflector 16 is made of a resin material. The reflector 16 has a horizontally elongated base surface portion 16a facing in the front-rear direction, an opening 16b formed in the center of the reflector 16, and lateral reflective portions 16d provided so as to protrude forward from both the left and right sides of the opening 16b.
[0023] A plate-shaped member, a shade 24, is attached to the lower surface of the lateral reflector 16d, and it protrudes forward from the opening 16b. The shade 24 is held by the reflector 16 so that its plate surface is aligned with the horizontal direction of the vehicle.
[0024] The circuit board 18 includes a first light source 30a having multiple light-emitting elements 28a arranged in a horizontal row for forming a light distribution pattern for low beams, a second light source 30b having multiple light-emitting elements 28b arranged in a horizontal row for forming a light distribution pattern for high beams, and a drive circuit (not shown) for driving each light-emitting element.
[0025] The second light source 30b is positioned adjacent to the first light source 30a. The first light source 30a is located on the upper side, and the second light source 30b is located on the lower side. Here, the light source located on the upper side refers to the light source located on the upper vertical side of the vehicle when the vehicle lighting equipment is mounted on the vehicle, among the multiple stages of light sources, and the lower side refers to the light source located on the lower vertical side of the vehicle when the vehicle lighting equipment is mounted on the vehicle. The drive circuit is a combination of passive elements such as capacitors and coils, active elements such as transistors and diodes, IC chips, memory, etc., and functions as a control unit that controls the on / off switching of the first light source 30a and the second light source 30b. The circuit board 18 is the mounting section on which each light source is mounted, and is fixed to a predetermined position on the heat sink 20.
[0026] In front of the first light source 30a and the second light source 30b, a resin plate 32 is positioned which functions as a lens that deflects the light emitted from the first light source 30a and the second light source 30b. Specifically, the resin plate 32 has lens portions formed laterally, corresponding to the number of light sources in the first light source 30a and the second light source 30b, which deflect the light from the light sources in a predetermined direction. The light transmitted through the resin plate 32 forms the light distribution pattern of the vehicle lamp by a component that directly enters the projection lens 12 and a component that is reflected by the shade 24 or the side reflector 16d before entering the projection lens. The resin plate 32 is sandwiched between the reflector 16 and the circuit board 18. In this state, the positional relationship of each component is determined by fastening the reflector 16 to the heat sink 20 with screws 36.
[0027] The optical unit 40 according to this embodiment comprises, among the components constituting the above-described vehicle lighting device 10, a metal heat sink 20, a circuit board 18 on which a first light source 30a and a second light source 30b are mounted and placed at a predetermined position on the heat sink 20, a resin plate 32 on which light emitted from each light source is transmitted as a lens and placed at a predetermined position on the circuit board 18, and a resin reflector 16 having a seating portion that sits on the circuit board 18 with the resin plate 32 in between. Here, "on the circuit board 18" is in the direction perpendicular to the main surface on which the light source 30a and the second light source 30b are mounted (in this embodiment, the direction toward the front of the vehicle), and does not necessarily coincide with the vertical direction of the vehicle.
[0028] Figure 4 is a horizontal cross-sectional view of the optical unit according to this embodiment. Figure 5(a) is an enlarged cross-sectional view showing the state of the fastening portion in area A of Figure 4 before it is fastened with screws, and Figure 5(b) is an enlarged cross-sectional view showing the state of the fastening portion in area A of Figure 4 after it has been fastened with screws.
[0029] As shown in Figure 4, the reflector 16 has a seating portion 16e on the side opposite to the side on which the lateral reflecting portion 16d is provided. The seating portion 16e is seated on the upper surface of the circuit board 18. The reflector 16 also has a pair of fastening portions 16c formed outside the longitudinal end (left-right direction in Figure 4) of the resin plate 32. In other words, the lateral reflecting portion 16d is formed between the pair of fastening portions 16c and reflects light that has passed through the resin plate 32.
[0030] Next, the fastening portion 16c will be described in detail. As shown in Figure 5(a), each of the pair of fastening portions 16c is configured to have a gap G between it and the heat sink 20 when the seating portion 16e is seated on the circuit board 18 and before fastening with the screws 36. When such fastening portions 16c are fastened to the heat sink 20 with screws 36 (see Figure 5(b)), the contact surface 16f on the back side of the fastening portion 16c comes into contact with the heat sink 20. At that time, the fastening portion 16c deforms in the direction of arrow B, so the lateral reflecting portion 16d in the center of the reflector 16 may be displaced in the direction of arrow C. If the lateral reflecting portion 16d is displaced in the direction of arrow C, the light reflected by the lateral reflecting portion 16d will be deviated from the desired direction, which may cause glare to pedestrians or oncoming vehicles.
[0031] Therefore, in the reflector 16 according to this embodiment, a deformation transmission suppression section is formed between the fastening section 16c and the lateral reflective section 16d to suppress the transmission of the deformation effect at the fastening section 16c to the lateral reflective section 16d. This suppresses the transmission of the deformation effect at the fastening section 16c when the reflector 16 is fastened to the heat sink 20 to the lateral reflective section 16d, and suppresses the influence of the shift in the direction of light reflected by the lateral reflective surface 16d on the light distribution pattern. Specifically, the deformation transmission suppression section according to this embodiment is a slit 16g formed near the fastening section 16c. This allows the deformation transmission suppression section to be realized with a simple shape. The deformation transmission suppression section can also be realized by providing a thin-walled section or a hollowed-out section between the fastening section 16c and the lateral reflective section 16d.
[0032] Furthermore, the reflector 16 is provided with an arc-shaped step 16h recessed on the contact surface 16f side between the fastening portion 16c and the region where the slit 16g is formed. This reduces the gap G between the fastening portion 16c of the reflector 16 and the heat sink 20 before fastening. In other words, it reduces the amount of deflection of the reflector 16 in the B direction when fastened.
[0033] Furthermore, the reflector 16 can also be considered as a component having the following characteristics. For example, the reflector 16 according to this embodiment is a resin component fastened to the heat sink 20, with its main surface, the base surface portion 16a, facing forward of the vehicle, and includes an opening 16b formed in the center of the longitudinal direction through which light emitted from each light source passes, a pair of fastening portions 16c formed at both ends in the longitudinal direction and fastened to the heat sink 20, a lateral reflecting portion 16d formed to protrude forward from between the pair of fastening portions 16c and the opening 16b and reflect light that has passed through the opening 16b, and a slit 16g formed between the fastening portion 16c and the lateral reflecting portion 16d to suppress the transmission of the effect of deformation at the fastening portion 16c to the lateral reflecting portion 16d.
[0034] It can also be considered as a method for manufacturing the optical unit 40 equipped with the reflector described above. For example, the method for manufacturing the optical unit 40 according to this embodiment includes the steps of: placing a circuit board 18 on which each light source is mounted in a predetermined position on a metal heat sink 20; placing a resin plate 32 through which light emitted from each light source is transmitted in a predetermined position on the circuit board 18; seating a resin reflector 16 on the circuit board 18 with the resin plate 32 in between; and fastening the reflector 16 to the heat sink 20 with screws 36. The fastening step involves fastening the reflector 16 to the heat sink 20 while bending the fastening portion 16c toward the heat sink. By doing so, the resin plate 32 can be firmly fixed between the reflector 16 and the heat sink 20 by fastening the reflector 16 to the heat sink 20 while bending the fastening portion 16c of the reflector 16.
[0035] Furthermore, the reflector 16 can be considered as a component having the following characteristics. For example, as shown in Figure 3, the lateral reflective portion 16d of the reflector 16 according to this embodiment overlaps at least a portion of a rectangular region S with a pair of fastening portions 16c at both ends when viewed from the front. Here, the rectangular region S includes the entire region (a track shape) sandwiched between the pair of fastening portions 16c, which have semicircular outer edges, as shown in Figure 3, and the lateral reflective portion 16d partially overlaps with this rectangular region S. In addition, the rectangular region S' of other forms may include the entire region sandwiched between the through holes 16k through which the screws 36 of the fastening portion 16c pass. Furthermore, although the outer shape of the pair of fastening portions 16c is semicircular in this embodiment, the outer shape is not limited to a semicircle. The outer shape of the pair of fastening portions 16c is not limited to a semicircle as long as a region of a predetermined diameter can be secured from the center of the head of the screw 36. For example, the outer shape may be a rectangle formed by two 90-degree vertices. Here, the region of a predetermined diameter can be, for example, a region with a diameter approximately 1.0 to 2.0 times the outer diameter of the head of the screw 36.
[0036] As a result, in a front view of the reflector 16, the lateral reflector 16d is included in the rectangular region S (hereinafter, the rectangular region S and the rectangular region S' are collectively referred to as the rectangular region S) with the pair of fastening portions 16c at both ends. Therefore, compared to the case where the lateral reflector 16d is not included in the rectangular region S, deformation of the lateral reflector 16d during fastening is suppressed.
[0037] Furthermore, the reflector 16 is further equipped with a plate-shaped shade 24 attached to the lower surface of the lateral reflector 16d. The shade 24 blocks a portion of the light passing through the opening 16b. If the lateral reflector 16d is provided in the lower half of the reflector, the shade 24 may be attached to the upper surface of the lateral reflector 16d. In this embodiment, the shade 24 overlaps with the aforementioned rectangular region S in a front view from the front of the vehicle, at least in part. This further suppresses deformation not only of the lateral reflector 16d but also of the shade 24.
[0038] Furthermore, the slits 16g in this embodiment are provided at four symmetrical positions centered on the rectangular region S. This ensures that the effect of the deformation transmission suppression unit is evenly transmitted to the rectangular region S.
[0039] Figure 6 is a schematic diagram illustrating the state in which the resin plate 32 according to this embodiment is in contact with the back surface of the reflector 16. Figure 7 is an enlarged view of area B in Figure 4.
[0040] The optical unit according to this embodiment can be considered as a device having the following features. As shown in Figure 4, the optical unit 40 comprises a heat sink 20, a circuit board 18 on which a light source is mounted and placed at a predetermined position on the heat sink 20, a rectangular resin plate 32 that polarizes light emitted from the light source and is placed at a predetermined position on the circuit board 18, and a reflector 16 that is fastened to the heat sink 20 with the circuit board 18 and the resin plate 32 sandwiched between the heat sink 20.
[0041] As shown in Figures 6 and 7, the resin plate 32 is sandwiched between the circuit board 18 and the reflector 16 and has four contact portions 32a at its four corners that are crushed while in contact with the back surface 16m of the reflector 16. The four contact portions 32a in this embodiment are contained within a rectangular region S. Each contact portion 32a has a projection 32c protruding from the main surface 32b of the resin plate 32 and an annular groove 32d surrounding the projection 32c.
[0042] The resin plate 32 can be made of a material that causes the projections 32c to deform when the reflector 16 is fastened to the heat sink 20 with the projections 32c in contact with the back surface 16m of the reflector 16. Materials that undergo elastic or plastic deformation can be used. Specifically, the resin plate 32 is made of silicone resin. This allows the load to be applied relatively evenly to the four contact points 32a of the resin plate 32 when fastening the reflector 16, enabling the resin plate 32 to be fixed in the desired position and orientation. Furthermore, the projections 32c deform preferentially when the reflector 16 is pressed against the resin plate 32, thereby suppressing deformation of the reflector 16.
[0043] Although the present invention has been described above with reference to the embodiments described above, the present invention is not limited to the embodiments described above, and the present invention also includes combinations and substitutions of the configurations of the embodiments as appropriate. Furthermore, it is possible to appropriately rearrange the combinations and processing order in the embodiments or to make various design changes and other modifications to the embodiments based on the knowledge of those skilled in the art, and such modified embodiments may also be included in the scope of the present invention. [Explanation of Symbols]
[0044] 10 Vehicle lighting fixture, 12 Projection lens, 14 Lens holder, 16 Reflector, 16a Base surface, 16b Opening, 16c Fastening part, 16d Side reflector, 16e Seat part, 16f Contact surface, 16g Slit, 16h Step, 16m Back surface, 18 Circuit board, 20 Heat sink, 30a First light source, 30b Second light source, 32 Resin plate, 32a Contact part, 36 Screw, 40 Optical unit.
Claims
1. A resin reflector positioned with its main surface facing the front of the vehicle and fastened to a heat sink, An opening is formed in the center of the longitudinal direction, through which light emitted from the light source passes, A pair of fastening parts formed at both ends in the longitudinal direction and fastened to the heat sink, It has a reflective portion formed to protrude forward from between the pair of fastening portions and the opening, and which reflects light that has passed through the opening, The reflector is characterized in that, in a front view, the reflective portion overlaps with at least a portion of a rectangular region with the pair of fastening portions at both ends.
2. The reflective portion further comprises a plate-shaped shade attached to the lower or upper surface, The reflector according to claim 1, characterized in that the shade blocks a portion of the light passing through the opening.
3. The reflector according to claim 2, characterized in that the shade overlaps, at least in part, with a rectangular region having the pair of fastening parts at both ends when viewed from the front of the vehicle.
4. The reflector according to claim 1, further comprising a deformation transmission suppression portion formed between the fastening portion and the reflecting portion, which suppresses the transmission of the effects of deformation at the fastening portion to the reflecting portion.
5. The reflector according to claim 4, characterized in that the deformation transmission suppression portion is a slit formed near the fastening portion.
6. The reflector according to claim 5, characterized in that a recessed step is provided between the fastening portion and the region where the slit is formed, on the rear side of the vehicle.
7. The reflector according to claim 5 or 6, characterized in that the slits are provided at four locations symmetrically positioned around the rectangular region.
8. heatsink and A substrate on which a light source is mounted is placed in a predetermined position on the heat sink, A lens that polarizes light emitted from the light source is placed at a predetermined position on the substrate, A reflector according to any one of claims 1 to 6, wherein the substrate and the lens are sandwiched between the heat sink and fastened to the heat sink, The lens is a rectangular resin plate, and has four contact points at its four corners that are crushed while in contact with the back surface of the reflector when sandwiched between the substrate and the reflector. The optical unit is characterized in that the four contact portions are included in the rectangular region.