JP5859893B2 - Optical unit - Google Patents

Description

  The present invention relates to an optical unit, and more particularly to an optical unit used for a vehicular lamp.

  Conventionally, there is a variable-light-distribution type vehicle headlamp device that forms a low-beam light distribution pattern by shielding light from a light source with a shade and forms a high-beam light distribution pattern when not shaded by a shade. Further, along with the recent improvement in performance of vehicles, there has been proposed a vehicle headlamp device that forms a special light distribution pattern having a shape different from that of a standard low beam or high beam according to the surrounding conditions. . In particular, in the case of a high beam, it is necessary to consider glare for oncoming vehicles and pedestrians while improving the driver's visibility. Therefore, for example, the vehicular lamp disclosed in Patent Document 1 has a structure that can optimally set a high beam irradiation area according to the presence or absence of a pedestrian, a preceding vehicle, or an oncoming vehicle.

JP 2007-179969 A

  Under such circumstances, the present inventor has come to recognize the following problems. In other words, as an optical unit that realizes the switching of the above-described light distribution pattern in the vehicle lamp, for example, it can be displaced between an advance position where a part of the light source light is shielded and a retracted position where a part of the light source light is not shielded. A configuration is possible in which a plurality of shades are provided and the light distribution pattern is switched by switching the position of each shade. Specifically, for example, the first shade is arranged at the light shielding position to form a low beam light distribution pattern, the second shade is arranged at the light shielding position, and the first shade is arranged at the non-light shielding position. A pattern is formed, and the first shade and the second shade are arranged at non-light-shielding positions to form a high beam light distribution pattern. It is conceivable to use a motor such as a DC motor for the displacement of the shade.

  In the optical unit having such a configuration, in order to improve the operation reliability of the optical unit, it is desirable to maintain a predetermined motor mounting posture.

  The present invention has been made in view of these problems, and an object thereof is to provide a technique for improving the operational reliability of the optical unit.

  In order to solve the above problems, an aspect of the present invention is an optical unit. The optical unit is an optical unit used in a vehicular lamp, a shade that can be displaced between an advancing position where a part of the light source light is shielded and a retreat position where the part of the light source light is not shielded, and an output A motor that displaces the shade from one of the advanced position and the retracted position by rotation of a shaft; a wall that forms a housing space for the motor; and an opening for inserting the motor into the housing space. And a cover that closes the opening, and a base that holds the shade and to which the case is fixed. The case has a first wall portion facing a case mounting surface of the base portion, and the cover extends along the first wall portion outside the first wall portion in a state of being attached to the case. An arm portion that is present and snap-fit to the case using the elasticity of the arm portion, and the arm portion is attached to the first wall portion and the case in a state where the case is fixed to the base portion. It is sandwiched between the faces.

  According to this aspect, it can suppress more reliably that a cover remove | deviates from a case. Thereby, since the determined mounting orientation of the motor can be maintained, the operational reliability of the optical unit can be improved.

  In the above aspect, the case includes a second wall portion facing the first wall portion, the second wall portion includes a frame portion protruding from an outer surface, and the arm portion is defined as the first arm portion. When the cover is attached to the case, the cover has a second arm portion extending along the second wall portion outside the second wall portion, and the second arm portion is engaged. The engaging claw portion may be engaged with the frame portion by being inserted into the frame portion. Also by this, since it can suppress more reliably that a cover remove | deviates from a case, the operation | movement reliability of an optical unit can be improved.

  According to the present invention, it is possible to provide a technique for improving the operational reliability of the optical unit.

It is a vertical sectional view showing a schematic structure of a vehicular lamp in which a lamp unit having an optical unit according to an embodiment is mounted. It is a perspective view which shows schematic structure of a lamp unit. It is a disassembled perspective view of a lamp unit. It is a disassembled perspective view of the optical unit which concerns on embodiment. FIG. 5A and FIG. 5B are diagrams for explaining the operations of the first shade and the second shade. It is a perspective view which shows schematic structure of a motor, a case, and a cover. FIG. 7A is a diagram schematically illustrating a shade driving unit when the optical unit according to the comparative example is viewed from the lamp rear side. FIG. 7B is a diagram schematically illustrating a shade driving unit when the optical unit according to the present embodiment is viewed from the lamp rear side. It is a schematic diagram for demonstrating the attachment structure to the case of a cover.

  The present invention will be described below based on preferred embodiments with reference to the drawings. The same or equivalent components, members, and processes shown in the drawings are denoted by the same reference numerals, and repeated descriptions are omitted as appropriate. The embodiments do not limit the invention but are exemplifications, and all features and combinations thereof described in the embodiments are not necessarily essential to the invention.

  FIG. 1 is a vertical sectional view showing a schematic structure of a vehicular lamp in which a lamp unit having an optical unit according to an embodiment is mounted. FIG. 2 is a perspective view showing a schematic structure of the lamp unit. FIG. 3 is an exploded perspective view of the lamp unit. 2 and 3, the second heat sink 18, the second light source module 22, and the cover member 36 are not illustrated in order to facilitate understanding of the internal structure of the lamp unit 10. In FIG. 3, the second reflector 26 is not shown.

  The vehicular lamp 1 described in the present embodiment is a vehicular headlamp apparatus having a pair of headlamp units arranged on the left and right sides in front of the vehicle. Since the pair of headlamp units has substantially the same configuration except that they have a symmetrical structure, FIG. 1 shows the structure of the headlamp unit arranged on the right side of the vehicle as the vehicle lamp 1.

  As shown in FIG. 1, the vehicular lamp 1 includes a lamp body 2 having an opening on the front side of the vehicle, and a translucent cover 4 attached so as to cover the opening of the lamp body 2. The translucent cover 4 is made of translucent resin or glass. A lamp unit 10 and a control unit 12 are accommodated in a lamp chamber 3 formed by the lamp body 2 and the translucent cover 4. The lamp unit 10 is attached to the bracket 14. The bracket 14 is fixed to the lamp body 2 by a support mechanism (not shown). A control unit 12 that controls turning on / off of the lamp unit 10 and displacement of a shade to be described later is disposed below the lamp chamber 3. In addition, the position where the control part 12 is provided is not specifically limited.

  As shown in FIGS. 1 to 3, the lamp unit 10 includes a first heat sink 16, a second heat sink 18, a first light source module 20, a second light source module 22, a first reflector 24, a second reflector 26, and a lens holder 32. , A projection lens 34, a cover member 36, and an optical unit 100.

  The first heat sink 16 is formed in a shape having a large number of fins from a metal such as aluminum, and is attached to the bracket 14 by a fastening member 50 such as a screw. The first heat sink 16 has a light source module mounting surface 16 a that faces substantially upward in the vertical direction with respect to the optical axis of the lamp unit 10. The first light source module 20 is mounted on the light source module mounting surface 16a. In addition, a plurality of insertion holes 16 b through which fastening members 51 described later are inserted are provided at predetermined positions of the first heat sink 16. The first heat sink 16 of the present embodiment is provided with unit support portions 16c that protrude to the front side of the lamp at the left and right upper sides of the first reflector 24 and the lower side of the second reflector 26 when viewed from the front side of the lamp. An insertion hole 16b is formed in the unit support portion 16c.

  Note that the vehicular lamp 1 of the present embodiment has a second lamp unit 11 adjacent to the lamp unit 10. The first heat sink 16 of the lamp unit 10 is formed integrally with the heat sink 11 a of the second lamp unit 11.

  The second heat sink 18 is formed in a shape having a large number of fins with a metal such as aluminum, and extends in the front-rear direction of the lamp above the first heat sink 16, and the end on the rear side of the lamp is supported by the first heat sink 16. ing. The end of the second heat sink 18 on the front side of the lamp is located in the vicinity of the lens holder 32. The second heat sink 18 has a light source module mounting surface 18a that faces substantially downward in the direction perpendicular to the optical axis. The second light source module 22 is mounted on the light source module mounting surface 18a.

  The first light source module 20 is disposed so that the light emitting surface faces substantially upward in the vertical direction. The second light source module 22 is disposed such that the light emitting surface faces substantially downward in the vertical direction. The 1st light source module 20 and the 2nd light source module 22 are light emitting diodes (LED), for example, and have a light emitting element and a substrate which supports a light emitting element. The light source used in the lamp unit 10 may be an incandescent bulb, a halogen lamp, a discharge bulb, or the like.

  The first reflector 24 has a substantially dome shape, is disposed above the first light source module 20, and is fixed to the first heat sink 16. The 1st reflector 24 has the reflective surface comprised by a part of spheroid surface inside. The reflecting surface has a first focal point and a second focal point located on the front side of the lamp relative to the first focal point. The positional relationship between the first reflector 24 and the light source module mounting surface 16 a is determined so that the light emitting portion of the first light source module 20 substantially coincides with the first focal point of the first reflector 24.

  The second reflector 26 has a substantially dome shape, is disposed below the second light source module 22, and is fixed to the first heat sink 16. The 2nd reflector 26 has the reflective surface comprised by a part of paraboloid inside. This reflective surface has one focal point. The positional relationship between the second reflector 26 and the light source module mounting surface 18 a is determined so that the light emitting surface of the second light source module 22 substantially coincides with the focal point of the reflecting surface of the second reflector 26.

  A lens holder 32 is disposed on the front side of the lamp relative to the first reflector 24 and the second reflector 26 with the optical unit 100 interposed therebetween. The lens holder 32 is a substantially cylindrical member, and a projection lens 34 is fitted therein. A through hole 32 a is provided at a position corresponding to the insertion hole 16 b of the first heat sink 16 at the end of the lens holder 32 on the rear side of the lamp. The projection lens 34 is a plano-convex aspherical lens having a convex front surface and a flat rear surface. The projection lens 34 uses a light source image formed on the rear focal plane including the rear focal point as a reverse image and a virtual vertical position in front of the lamp. Project on the screen. The projection lens 34 is disposed on the optical axis of the lamp unit 10 by the lens holder 32 and at a position where the rear focal point substantially coincides with the second focal point of the reflecting surface of the first reflector 24.

  The optical unit 100 has a base portion 110 whose overall shape is substantially plate-like. The base part 110 includes an annular frame part 112 as viewed from the front of the lamp, and a substantially plate-like plate part 114 disposed below the frame part 112 so that the main surface faces the lamp front-rear direction. In addition, the base part 110 has an opening 116 constituted by the inner periphery of the frame part 112. The opening 116 is arranged so that the optical axis of the lamp unit 10 passes through the center region thereof, and the opening 116 allows the light source light to enter the projection lens 34.

  A first shade 130 and a second shade 140 capable of closing a part of the periphery of the opening 116 are connected to the lower end side of the frame portion 112. The first shade 130 and the second shade 140 are held so as to be independently swingable by the frame portion 112, and can take a position where the upper end edge of each shade approaches the optical axis and a retracted position. . The optical unit 100 is disposed so that the upper edge of each shade overlaps the second focal point of the reflecting surface of the first reflector 24 when each shade is at a position close to the optical axis. The frame portion 112 and the plate portion 114 are provided with through holes 118 at positions corresponding to the insertion holes 16 b of the first heat sink 16. The structure of the optical unit 100 will be described in detail later.

  When the lens holder 32 and the optical unit 100 are inserted into the through-hole 32a of the lens holder 32, the through-hole 118 of the optical unit 100, and the insertion hole 16b of the first heat sink 16, the fastening member 51 such as a screw is inserted into the first. It is fixed to the heat sink 16.

  The cover member 36 has an opening 36a for allowing the irradiation light from the lamp unit 10 to pass through, and is fixed to the first heat sink 16 by a fastening member 52 such as a screw. The cover member 36 covers the area excluding the area where the projection lens 34 exists in the lamp unit 10 when viewed from the front of the lamp.

  Next, the structure of the optical unit 100 according to the embodiment will be described in detail. FIG. 4 is an exploded perspective view of the optical unit according to the embodiment. As shown in FIG. 4, the optical unit 100 according to the present embodiment is an optical unit used for a vehicular lamp, and includes a base 110, a first shade 130, a second shade 140, a first motor 150A, a second It has a motor 150B, a case 170, a first cover 190A and a second cover 190B. Hereinafter, when the first motor 150A and the second motor 150B are not particularly distinguished, they are collectively referred to as the motor 150. In addition, when the first cover 190A and the second cover 190B are not particularly distinguished, they are collectively referred to as a cover 190.

  The base part 110 has the frame part 112, the plate part 114, the opening part 116, and the some through-hole 118 as mentioned above. Furthermore, the base portion 110 has a first shade support shaft 120A that protrudes forward of the lamp in the lower end region on the right side (in the vehicle width direction) of the frame portion 112 when viewed from the front of the lamp, and the left side ( A second shade support shaft 120B that protrudes forward of the lamp is provided in the lower end region of the vehicle width direction outer side. Further, the base portion 110 has a single case fixing through-hole 121 in the central region of the plate portion 114 in the vehicle width direction. The base portion 110 has a positioning fitting portion 122A and an output shaft through-hole 123A in a region on the right side of the plate portion 114 when viewed from the front of the lamp, and a positioning fitting in the left region of the plate portion 114. It has a portion 122B and an output shaft through hole 123B. In the present embodiment, positioning fitting portions 122A and 122B are through holes. The positioning fitting portion 122A has a substantially perfect circle shape, and the positioning fitting portion 122B has a substantially elongated hole shape.

  The base portion 110 has a first shade second stopper 124A at the right side end of the plate portion 114 when viewed from the front of the lamp, and the second shade second stopper 124A at the left side end of the plate portion 114. 2 stopper 124B. Each stopper protrudes forward of the lamp. Furthermore, the base 110 has a return spring first locking portion 126A and a return spring second locking portion 127A at a predetermined position in the right region, and a return spring first locking portion 126B at a predetermined position in the left region. And a return spring second locking portion 127B. The return spring second locking portions 127A and 127B are disposed above the return spring first locking portions 126A and 126B.

  Each of the first shade 130 and the second shade 140 has a substantially L shape, extends in a substantially horizontal direction, and extends from one end of the horizontal portions 132 and 142 to block light source light. The vertical portions 134 and 144 extend substantially downward in the vertical direction and receive the rotational force of the motor 150. The edge 132a of the horizontal portion 132 of the first shade 130 is processed so as to form a cut-off line of the low beam light distribution pattern when the first shade 130 is in an advanced position described later. The edge 142a of the horizontal portion 142 of the second shade 140 is processed so as to form a cut-off line of the one-high light distribution pattern when the second shade 140 is in the advanced position described later. At the lower ends of the vertical portions 134 and 144, groove portions 135 and 145 that mesh with connection portions 160 described later provided on the output shaft of the motor 150 are provided. In addition, a first shade stopper 136 that protrudes rearward of the lamp is provided on the right side end surface of the vertical portion 134 when viewed from the front of the lamp, and a left side end surface of the vertical portion 144 is provided behind the lamp. A projecting second shade first stopper 146 is provided.

  The 1st shade 130 and the 2nd shade 140 have cylinder parts 138 and 148 which protrude ahead of a lamp in the field where horizontal parts 132 and 142 and vertical parts 134 and 144 cross, respectively. The first shade 130 is held by the base portion 110 with the first shade support shaft 120 </ b> A inserted through the tube portion 138. Accordingly, the first shade 130 is disposed on the inner side in the vehicle width direction. The horizontal portion 132 extends toward the second shade support shaft 120B. When viewed from the front of the lamp, the vertical portion 134 extends to the left side of the first shade second stopper 124A, and the groove portion 135 is disposed in the vicinity of the output shaft through hole 123A. An output shaft 152 of a first motor 150A that protrudes from the lamp rear side to the lamp front side is connected to the groove portion 135 through the output shaft through hole 123A. The first shade first stopper 136 is disposed on the right side of the right end surface of the plate portion 114, that is, on the outside of the plate portion 114.

  In the second shade 140, the second shade support shaft 120 </ b> B is inserted into the cylindrical portion 148 and held by the base portion 110. Accordingly, the second shade 140 is disposed on the outer side in the vehicle width direction. The horizontal portion 142 extends toward the first shade support shaft 120A. When viewed from the front of the lamp, the vertical portion 144 extends to the right side of the second shade second stopper 124B, and the groove portion 145 is disposed in the vicinity of the output shaft through hole 123B. The groove 145 is connected to the output shaft 152 of the second motor 150B that protrudes from the lamp rear side to the lamp front side through the output shaft through hole 123B. The second shade first stopper 146 is disposed on the left side of the left end surface of the plate portion 114, that is, on the outer side of the plate portion 114.

  Return springs 104 </ b> A and 104 </ b> B are fitted on the outer circumferences of the cylindrical portions 138 and 148, respectively. The return springs 104A and 104B are constituted by, for example, torsion coil springs, and have coil portions whose both ends extend in an arm shape. With the first shade 130 held by the base portion 110, one end of the return spring 104A is locked by the return spring first locking portion 126A, and the other end is locked by the return spring second locking portion 127A. The In the state where the second shade 140 is held by the base portion 110, one end of the return spring 104B is locked by the return spring first locking portion 126B, and the other end is locked by the return spring second locking portion 127B. Stopped.

  The first shade 130 and the second shade 140 are rotated by a motor 150. FIG. 5A and FIG. 5B are diagrams for explaining the operations of the first shade and the second shade. 5A and 5B show the optical unit 100 viewed from the front of the lamp.

  The first shade 130 and the second shade 140 have the first shade support shaft 120A and the second shade support shaft 120B as rotation axes, respectively, and the advance position where a part of the light source light is shielded and the part of the light source light that is not used. It can be displaced to the retracted position for light shielding. When each shade is in the advanced position, the edges 132 a and 142 a of the horizontal portions 132 and 134 are disposed in the vicinity of the second focal point of the first reflector 24. Thereby, a part of the light emitted from the first light source module 20 is shielded. Further, substantially all of the light emitted from the second light source module 22 is shielded. On the other hand, when each shade is in the retracted position, a part of the irradiation light of the first light source module 20 and the entire irradiation light of the second light source module 22 that are shielded by the shade in the advanced position are transferred to the projection lens 34. Incident light.

  The first shade 130 is displaced from one of the advanced position and the retracted position by the rotation of the output shaft 152 of the first motor 150A (see FIG. 4). The second shade 140 is displaced from one of the advanced position and the retracted position by the rotation of the output shaft 152 of the second motor 150B (see FIG. 4). Further, when the motor 150 is turned off, each shade is displaced from the other to the one by the urging force of the return springs 104A and 104B.

  In the present embodiment, the force from the output shaft 152 of the first motor 150 </ b> A is transmitted to the first shade 130 through the connection portion 160 provided on the output shaft 152, and the first shade 130 is moved from the advanced position by the rotation of the output shaft 152. Displacement to the retracted position (state shown in FIG. 5B). The first shade 130 that is displaced toward the retracted position stops at the retracted position when the vertical portion 134 abuts against the first shade second stopper 124A. Further, when the first motor 150A is turned off, the first shade 130 is displaced from the retracted position to the advanced position by the urging force of the return spring 104A (state shown in FIG. 5A). The first shade 130 that is displaced toward the advanced position stops at the advanced position when the first shade stopper 136 strikes the plate portion 114. In this manner, the first shade 130 for forming the low beam light distribution pattern is configured to return to the advanced position by the return spring 104A, so that the optical unit 100 can generate the high beam light distribution pattern or the single high light distribution pattern. A fail-safe function can be realized by reliably avoiding being fixed in the forming posture.

  On the other hand, in the second shade 140, the force from the output shaft 152 of the second motor 150B is transmitted through the connection portion 160 provided on the output shaft 152, and is displaced from the retracted position to the advanced position by the rotation of the output shaft 152. (The state shown in FIG. 5B). The second shade 140 that is displaced toward the advanced position stops at the advanced position when the second shade first stopper 146 hits the plate portion 114. Further, when the second motor 150B is turned off, the second shade 140 is displaced from the advanced position to the retracted position by the urging force of the return spring 104B (state shown in FIG. 5A). The second shade 140 that is displaced toward the retracted position stops at the retracted position when the vertical portion 144 abuts against the second shade second stopper 124B.

  As shown in FIG. 5A, the lamp unit 10 can form a low beam light distribution pattern with the first shade 130 in the advanced position and the second shade 140 in the retracted position. In addition, as shown in FIG. 5B, the lamp unit 10 has a high beam area only on the opposite lane side when left-handed when the first shade 130 is in the retracted position and the second shade 140 is in the advanced position. A so-called right-side high light distribution pattern can be formed. In addition, the lamp unit 10 can form a high-beam light distribution pattern in a state where the first shade 130 and the second shade 140 are in the retracted position. Further, when the lamp unit 10 is in the formation state of the high beam light distribution pattern, the irradiation light of the second light source module 22 is irradiated forward of the lamp. Thereby, the illuminance of the high beam light distribution pattern can be increased.

  In the lamp unit of the headlamp unit disposed on the left side of the vehicle, the first shade 130 is disposed on the left side (in the vehicle width direction) and the second shade 140 is disposed on the right side (the vehicle width direction outer side) when viewed from the front of the lamp. Placed in. Then, the lamp unit can form a low beam light distribution pattern, a high beam light distribution pattern, and a so-called left-side high light distribution pattern having a high beam region only on the own lane when passing on the left side. Since the shape of each light distribution pattern mentioned above is well-known, detailed description is abbreviate | omitted.

  The motor 150 is accommodated in the case 170 and fixed to the base portion 110 via the case 170. A cover 190 is attached to the case 170 in a state where the two motors 150 are accommodated. The cover 190 prevents the motor 150 from dropping from the case 170. The motor 150, the case 170, and the cover 190 constitute a shade drive unit.

  Next, the structure of the motor 150, the case 170, and the cover 190 will be described in detail. FIG. 6 is a perspective view illustrating a schematic structure of the motor, the case, and the cover. FIG. 7A is a diagram schematically illustrating a shade driving unit when the optical unit according to the comparative example is viewed from the lamp rear side. FIG. 7B is a diagram schematically illustrating a shade driving unit when the optical unit according to the present embodiment is viewed from the lamp rear side. FIG. 8 is a schematic diagram for explaining a structure for attaching the cover to the case. FIGS. 7A and 7B schematically show a cross section of the shade driving unit along a plane perpendicular to the output shaft 152. FIG. 8 schematically shows a cross section of the shade driving unit along a plane parallel to the output shaft 152 and passing through the first arm part 190b and the second arm part 190c of the cover 190. In FIG. 7A, FIG. 7B, and FIG. 8, the internal structure of the motor 150 is not shown.

  As shown in FIGS. 6 to 8, the motor 150 is configured by a DC motor, for example, and includes a housing 151, an output shaft 152, and terminal connection portions 153 </ b> A and 153 </ b> B. The housing 151 includes a top surface 151a from which the output shaft 152 protrudes, a bottom surface 151b facing the top surface 151a, substantially flat first side surfaces 151c and second side surfaces 151d facing each other, curved third side surfaces 151e facing each other, and And a fourth side surface 151f. The upper surface 151a and the bottom surface 151b are provided with boss portions 154a and 154b that protrude slightly outward and house the bearings therein.

  The output shaft 152 is provided with a connecting portion 160 formed of a gear such as a spur gear. The output shaft 152 is connected to the first shade 130 or the second shade 140 via the connection unit 160. The power supply terminal connection portions 153A and 153B are provided in the vicinity of the bottom surface 151b of the first side surface 151c of the housing 151. The terminal connection portion 153A corresponds to one of the anode and the cathode, and the terminal connection portion 153B corresponds to the other of the anode and the cathode.

  The motor 150 has a length dimension L, a height dimension H, and a width dimension W of the housing 151. When the dimension in the extending direction of the output shaft 152 is a length dimension L, the height dimension H and the width dimension W are One is larger than the other. In the present embodiment, the direction in which the first side surface 151c and the second side surface 151d, which are planes, are aligned is the height dimension H, and the direction in which the third side surface 151e, which is a curved surface, and the fourth side surface 151f are aligned, is the width dimension W ( The major axis dimension). Therefore, the motor 150 has a width dimension W larger than the height dimension H. In addition, although the dimension of the housing 151 is demonstrated here, when the dimension of the extending direction of the output shaft 152 is made into the length dimension L, the height dimension H and the width dimension W are the motor 150 and the housing 151. In order to match, the height dimension H and the width dimension W of the housing 151 may be replaced with the height dimension H and the width dimension W of the motor 150.

  The case 170 has a first housing space 171A for housing the first motor 150A and a second housing space 171B for housing the second motor 150B. Therefore, in the optical unit 100 according to the present embodiment, the first motor 150A and the second motor 150B are accommodated in a single case 170. Therefore, according to the present embodiment, it is possible to reduce the number of parts of the optical unit 100 as compared with the case where the first motor 150A and the second motor 150B are accommodated in separate cases.

  The case 170 includes a wall 172A that forms the first housing space 171A, a wall 172B that forms the second housing space 171B, an opening 176A for inserting the first motor 150A into the first housing space 171A, And an opening 176B for inserting the second motor 150B into the second housing space 171B. The case 170 includes a connector 178A and a pair of terminal members 180A for the first motor 150A, and a connector 178B and a pair of terminal members 180B for the second motor 150B. Hereinafter, when the first accommodation space 171A and the second accommodation space 171B are not particularly distinguished, they are collectively referred to as the accommodation space 171. Moreover, when not distinguishing especially the wall part 172A and the wall part 172B, these are named the wall part 172 generically. Further, when the opening 176A and the opening 176B are not particularly distinguished, they are collectively referred to as the opening 176.

  The wall portion 172 includes a substantially rectangular bottom wall portion 172a, a first wall portion 172b, a second wall portion 172c, a third wall portion 172d, and a fourth wall portion 172e. The first wall portion 172b and the second wall portion 172c face each other. The third wall portion 172d and the fourth wall portion 172e face each other and extend substantially perpendicular to the first wall portion 172b and the second wall portion 172c. The first wall portion 172b, the second wall portion 172c, the third wall portion 172d, and the fourth wall portion 172e constitute a side wall portion, and an accommodation space 171 is formed by the four side wall portions and the bottom wall portion 172a. . The lower ends of the four side wall portions are connected to the peripheral edge portion of the bottom wall portion 172a, but the wall portion 172 is not provided on the upper end side. That is, the opening 176 is provided on the upper end side of the four side walls that form the accommodation space 171.

  Connectors 178A and 178B to which terminals of an external power source are connected are provided on the outer surface of the second wall portion 172c. The pair of terminal members 180A and 180B are members in which a connector terminal, a power feeding terminal, and a wiring portion are integrally formed. One end of each of the pair of terminal members 180A and 180B is disposed in the connector and functions as a connector terminal. Further, the other end side is exposed in the accommodation space 171 and functions as a power supply terminal inserted into the terminal connection portions 153A and 153B of the motor 150. The region excluding the one end side and the other end side functions as a wiring portion that is routed from the connectors 178A and 178B to the accommodation space 171 and connected to the connector terminal and the power supply terminal. The electric power sent from the external power source is supplied to the motor 150 from the connectors 178A and 178B via the pair of terminal members 180A and 180B.

  The opening 176A for the first storage space 171A and the opening 176B for the second storage space 171B face in opposite directions. Accordingly, the first motor 150A is pressed in a direction approaching the second storage space 171B from a region opposite to the region where the second storage space 171B exists with the first storage space 171A interposed therebetween, and the first storage space 171A. Inserted into. Further, the second motor 150B is pressed in a direction approaching the first storage space 171A from a region opposite to the region where the first storage space 171A exists with the second storage space 171B interposed therebetween, so that the second storage space 171B. Inserted into. Therefore, in the case 170 of the present embodiment, the space that should be secured around the opening 176, which is necessary when the motor 150 is inserted into the accommodation space 171 is formed between the first accommodation space 171A and the second accommodation space 171B. There is no need to provide it in between. Therefore, the distance between the bottom wall portion 172Aa and the bottom wall portion 172Ba can be reduced. Thereby, the case 170 can be reduced in size, and by extension, the optical unit 100 can be reduced in size.

  The motor 150 is disposed such that the first side surface 151c faces the bottom wall portion 172a, is in a direction substantially perpendicular to the axial direction of the output shaft 152, and is a distance between the first side surface 151c and the bottom wall portion 172a. Is pushed in the direction of approaching and inserted into the accommodating space 171 through the opening 176. With the motor 150 housed in the case 170, the top surface 151a and the first wall portion 172b, the bottom surface 151b and the second wall portion 172c, the first side surface 151c and the bottom wall portion 172a, the third side surface 151e and the third wall portion 172d. The fourth side surface 151f and the fourth wall portion 172e face each other. A pair of terminal members 180A and 180B are inserted into the terminal connection portions 153A and 153B in a state where the motor 150 is inserted into the accommodation space 171.

  The second wall portion 172c of the case 170 is provided with a slit 172c1 into which the boss portion 154b of the motor 150 is inserted. The second wall portion 172c has two frame portions 172c2 that protrude from the outer surface. The two frame portions 172c2 are arranged so as to sandwich the slit 172c1 when viewed from a direction orthogonal to the outer surface of the second wall portion 172c. The first wall 172b is provided with a slit 172b1 into which the boss 154a of the motor 150 is inserted. The first wall portion 172b is provided with two concave portions 172b2 on the outer surface. The two concave portions 172b2 are disposed so as to sandwich the slit 172b1 when viewed from a direction orthogonal to the outer surface of the first wall portion 172b. The first wall 172b is provided with a positioning projection 172b3 at a predetermined position on the outer surface.

  When the motor 150 is inserted into the case 170, the boss portion 154b slides in the slit 172c1 of the second wall portion 172c from the opening portion 176 side toward the bottom wall portion 172a side. Further, the boss portion 154a slides in the slit 172b1 of the first wall portion 172b from the opening portion 176 side toward the bottom wall portion 172a side. In a state where the motor 150 is accommodated in the case 170, the output shaft 152 protrudes outside from the accommodation space 171 via the slit 172b1.

  As shown in FIG. 7B, the first motor 150A and the second motor 150B are housed in the first housing space 171A and the second housing space 171B so that the output shafts 152 are parallel to each other. Yes. Further, the first motor 150A and the second motor 150B are configured so that the direction of the width dimension W thereof is substantially perpendicular to the direction in which the first storage space 171A and the second storage space 171B are arranged. It is accommodated in 171A and the second accommodating space 171B. That is, in the first motor 150A and the second motor 150B, of the width dimension W and the height dimension H perpendicular to the axial direction of the output shaft 152, the direction of the larger width dimension W is perpendicular to the vehicle width direction. Thus, the smaller height dimension H is arranged in parallel to the vehicle width direction.

  In the structure of the comparative example shown in FIG. 7A, the direction of the width dimension W of the first motor 150A and the second motor 150B is parallel to the direction in which the first storage space 371A and the second storage space 371B are arranged. In the posture, it is accommodated in each accommodating space of the case 370. In contrast, in the present embodiment, motor 150 is accommodated such that the direction of width dimension W, which is a larger dimension, is substantially perpendicular to the direction in which the two accommodation spaces are arranged. Thereby, the dimension of the direction in which the two motors of the shade driving unit are arranged can be reduced as compared with the structure of the comparative example. In the present embodiment, the dimension of the shade driving unit in the vehicle width direction can be reduced. Specifically, the dimension can be reduced by a length (2 · (W−H)) twice the difference between the width dimension W and the height dimension H. Thereby, the freedom degree of the installation place of the lamp unit 10 can be raised.

  A cover 190 is attached to the opening 176 of the case 170. The first cover 190A is locked to the wall portion 172A and closes the opening 176A for the first accommodation space 171A. On the other hand, the second cover 190B is locked to the wall portion 172B and closes the opening 176B for the second accommodation space 171B.

  The cover 190 includes a main body portion 190a, two first arm portions 190b (arm portions), and two second arm portions 190c. The main body 190a faces the second side surface 151d of the motor 150 in a state where the cover 190 is attached to the case 170, and extends from the end on the top surface 151a side to the end on the bottom surface 151b side of the second side surface 151d. Therefore, the opening 176 is mainly covered by the main body 190 a of the cover 190.

  The two first arm portions 190b protrude from the end portion of the main body portion 190a on the upper surface 151a side in a direction substantially perpendicular to the extending direction of the main body portion 190a. The two first arm portions 190b are arranged so as to sandwich the slit 172b1 in a state where the cover 190 is attached to the case 170 when viewed from a direction orthogonal to the outer surface of the first wall portion 172b. A convex portion 190b1 is provided at the tip of the first arm portion 190b on the surface facing the case 170 in a state where the cover 190 is attached to the case 170.

  The two second arm portions 190c protrude in parallel with the first arm portion 190b from the end portion of the main body portion 190a on the bottom surface 151b side in the same direction as the protruding direction of the first arm portion 190b. The two second arm portions 190c are arranged so as to sandwich the slit 172c1 in a state where the cover 190 is attached to the case 170 when viewed from a direction orthogonal to the outer surface of the second wall portion 172c. A convex portion 190c1 as an engaging claw portion is provided on the front end portion of the second arm portion 190c on the surface facing the direction opposite to the case 170 when the cover 190 is attached to the case 170.

  As shown in FIG. 8, when the cover 190 is attached to the case 170, the second arm portion 190c is inserted into the frame portion 172c2, and the convex portion 190c1 engages with the frame portion 172c2. As a result, the second arm 190 c side of the cover 190 is attached to the case 170. In a state where the cover 190 is attached to the case 170, the second arm portion 190c extends along the second wall portion 172c outside the second wall portion 172c.

  Subsequently, the cover 190 is pressed so that the first arm 190 b side of the cover 190 approaches the case 170. At this time, the first arm portion 190b goes around the outside of the first wall portion 172b and is elastically deformed in a direction away from the second arm portion 190c by being pressed by the first wall portion 172b. Then, the first arm 190 b side of the cover 190 is further pushed in, the main body 190 a becomes parallel to the second side surface 151 d of the motor 150, and the first arm 190 b becomes parallel to the first wall 172 b of the case 170. In this process, the first arm portion 190b is released from being pressed by the first wall portion 172b, and returns to the state before deformation by elasticity. Then, the convex portion 190b1 of the first arm portion 190b is fitted into the concave portion 172b2 of the first wall portion 172b, and the first arm portion 190b side of the cover 190 is attached to the case 170. In a state where the cover 190 is attached to the case 170, the first arm portion 190b extends along the first wall portion 172b outside the first wall portion 172b. That is, the cover 190 is snap-fit coupled to the case 170 using the elasticity of the first arm portion 190b.

  Thus, the first cover 190A and the second cover 190B are snap-fit coupled to the case 170 using the elasticity of the cover. According to this, the motor 150 accommodated in the case 170 can be fixed in the accommodation space 171 by the cover 190. Therefore, it is not necessary to form a structure for fixing the motor 150 such as a retaining lance on the case 170 side. Therefore, it is not necessary to provide a space for inserting and removing a mold, which is necessary when forming the structure for fixing the motor on the case 170 side, between the first accommodation space 171A and the second accommodation space 171B. The first accommodation space 171A and the second accommodation space 171B can be brought closer to each other. As a result, the optical unit 100 can be downsized. Further, since the cover 190 is fixed to the case 170 by snap fitting, the manufacturing process of the optical unit 100 can be simplified.

  As shown in FIGS. 4, 6, and 7, the case 170 is provided with a fixing mechanism 182 for fixing the case 170 to the base portion 110 between the first storage space 171 </ b> A and the second storage space 171 </ b> B. ing. In the present embodiment, fixing mechanism 182 is an insertion hole through which a fastening member such as a screw is inserted. A cylindrical member 184 is fitted into the fixing mechanism 182. The case 170 is attached to the base portion 110 such that the first wall portion 172b faces the case attachment surface 114a (see FIG. 8) of the plate portion 114 of the base portion 110, that is, the main surface on the rear side of the lamp. Therefore, the motor 150 is disposed such that the output shaft 152 is substantially perpendicular to the case mounting surface 114a. The case 170 is attached to the base part 110 with the fixing mechanism 182 as a through hole aligned with the case fixing through hole 121 of the plate part 114.

  When the case 170 is attached to the base portion 110, the output shaft 152 and the connection portion 160 of the first motor 150A are inserted into the output shaft through hole 123A of the plate portion 114, and the teeth of the connection portion 160 that is a gear are the first shade. 130 is engaged with the groove 135 (see FIG. 3). Further, the output shaft 152 and the connection portion 160 of the second motor 150B are inserted into the output shaft through-hole 123B of the plate portion 114, and the teeth of the connection portion 160 are engaged with the groove portion 145 of the second shade 140 (see FIG. 3). ).

  Further, the positioning convex portion 172b3 of the case 170 is fitted into the positioning fitting portion 122A of the plate portion 114, whereby the case 170 is highly accurately positioned with respect to the base portion 110. The case 170 is fixed to the base portion 110 by inserting a fastening member 186 such as a screw through the fixing mechanism 182 of the case 170 and the case fixing through hole 121 of the plate portion 114. In the present embodiment, the fixing mechanism 182 is provided in a region between the first accommodation space 171A and the second accommodation space 171B that is close to the position of the center of gravity of the shade driving unit in the plane direction orthogonal to the output shaft 152. . Therefore, the shade driving unit can be stably fixed to the base unit 110 with one fixing mechanism 182. Therefore, the number of parts of the optical unit 100 can be reduced.

  In this embodiment, the case fixing through-hole 121A and the fixing mechanism 182 are used as through-holes, and the case 170 is fixed to the base portion 110 using the fastening member 186. It may be adopted.

  As shown in FIG. 8, the first arm 190 b is sandwiched between the first wall 172 b of the case 170 and the case mounting surface 114 a of the plate 114 while the case 170 is fixed to the base 110. . Therefore, the displacement of the first arm portion 190b in the direction in which the convex portion 190b1 of the first arm portion 190b retracts from the concave portion 172b2 of the first wall portion 172b is restricted by the plate portion 114. Therefore, it is possible to more reliably prevent the cover 190 from being removed from the case 170, and as a result, it is possible to more reliably prevent the motor 150 from being removed from the case 170. Therefore, according to the optical unit 100 of the present embodiment, the predetermined mounting posture of the motor 150 can be maintained, and thus the operational reliability of the optical unit 100 can be improved.

  As described above, the optical unit 100 according to the present embodiment includes the single case 170 having the first housing space 171A for housing the first motor 150A and the second housing space 171B for housing the second motor 150B. I have. Therefore, the number of parts of the optical unit 100 can be reduced as compared with the case where the two motors are housed in separate cases and are fixed to the base portion 110. Thereby, the manufacturing cost of the optical unit 100 can be reduced and the manufacturing process can be simplified.

  Further, in the optical unit 100 according to the present embodiment, the cover 190 has a first arm portion 190b extending along the first wall portion 172b outside the first wall portion 172b in a state where the cover 190 is attached to the case 170. And snap-fit to the first wall 172b using the elasticity of the first arm 190b. The first arm portion 190b is sandwiched between the first wall portion 172b and the case mounting surface 114a in a state where the case 170 is fixed to the base portion 110. Therefore, it is possible to more reliably suppress the cover 190 from coming off the case 170. As a result, it is possible to more reliably suppress the motor 150 from dropping from the case 170, so that the operational reliability of the optical unit 100 can be improved.

  The present invention is not limited to the above-described embodiments, and various modifications such as design changes can be added based on the knowledge of those skilled in the art. Embodiments to which such modifications are added Are also included within the scope of the present invention. A new embodiment in which a modification is added to the above-described embodiment has the effects of the combined embodiment and the modification.

  H height dimension, L length dimension, W width dimension, 1 vehicle lamp, 100 optical unit, 110 base portion, 130 first shade, 140 second shade, 150 motor, 150A first motor, 150B second motor, 152 output shaft, 170 case, 171 accommodating space, 171A first accommodating space, 171B second accommodating space, 172, 172A, 172B wall, 172b first wall, 172c second wall, 176, 176A, 176B opening , 182 fixing mechanism, 190 cover, 190A first cover, 190B second cover, 190b first arm, 190c second arm.

Claims (2)

An optical unit used in a vehicle lamp,
A shade that is displaceable between an advancing position where a part of the light source light is shielded and a retreat position where the part of the light source light is not shielded;
A motor for displacing the shade from one of the advanced position and the retracted position by rotation of an output shaft;
A wall having a housing space for the motor, and a case having an opening for inserting the motor into the housing space;
A cover for closing the opening;
Holding the shade, and a base portion to which the case is fixed, and
The case has a first wall portion facing the case mounting surface of the base portion,
The cover has an arm portion extending along the first wall portion outside the first wall portion in a state attached to the case, and is snap-fit coupled to the case by using elasticity of the arm portion. And
The optical unit, wherein the arm portion is sandwiched between the first wall portion and the case mounting surface in a state where the case is fixed to the base portion. The case has a second wall portion facing the first wall portion,
The second wall portion has a frame portion protruding from the outer surface,
When the arm portion is the first arm portion, the cover has a second arm portion extending along the second wall portion outside the second wall portion in a state of being attached to the case,
2. The optical unit according to claim 1, wherein the second arm portion includes an engaging claw portion, and the second arm portion is inserted into the frame portion and the engaging claw portion engages with the frame portion.

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