JP4523657B2 - Lamp unit - Google Patents

Description

  The present invention relates to a lamp unit for illumination, and more particularly to a lamp unit suitable for a case where a high-intensity discharge lamp is used as a vehicle headlamp.

  Until now, halogen lamps have been the mainstream of vehicle headlamps, but in recent years, high-intensity discharge lamps (so-called HID lamps: High Intensity Discharge lamps) have been adopted. The HID lamp is characterized by high luminous efficiency and brighter light. And when the halogen lamp is employ | adopted as the headlamp of the vehicle already purchased, many people hope to replace this with a HID lamp.

  However, the H4 type halogen lamp has two filaments, each of which serves as a light emitting point in a low beam (passing beam) and a high beam (running beam). On the other hand, it is currently difficult for HID lamps to provide two light emitting points. Therefore, when the HID lamp is used in place of an existing halogen lamp, it is necessary to use one HID lamp by moving one light emitting point between the low beam position and the high beam position.

  When an HID lamp is used instead of an H4 type halogen lamp, it is necessary to satisfy the requirements defined in JIS C 7506-1 (hereinafter simply referred to as JIS). In this JIS, the position of the light emitting point at the time of low beam and high beam is defined using the front surface of the flange portion of the mounting member attached to the rear end opening of the reflector as a reference plane. Specifically, the position of the light emitting point at the time of the low beam is 29.5 mm ahead of the reference plane, and the position of the light emitting point at the time of the high beam is 23.5 mm ahead of the reference plane. Further, the position of the light emitting point at the time of high beam is set to be 0.8 mm lower than the position of the light emitting point at the time of low beam.

Therefore, Patent Document 1 proposes a lamp unit that moves the HID lamp in the axial direction (front-rear direction of the vehicle) using a solenoid. This lamp unit has a guide member (rod) arranged along the moving direction of the HID lamp (discharge tube), and a lamp holding member (socket) that moves along the guide member while holding the HID lamp. Yes. The lamp holding member is biased to the low beam position by the biasing force of the compression spring. On the other hand, when the lamp holding member is pulled by the solenoid (driving means), the lamp moves to the high beam position.
JP 2001-35211 A

  However, the lamp unit described in Patent Document 1 (hereinafter referred to as a conventional lamp unit) is formed by integrating a HID lamp and a solenoid in series. For this reason, the conventional lamp unit has a very long portion protruding rearward from the flange. Therefore, since the conventional lamp unit interferes with other parts provided in the vehicle when attached to the reflector, there are many vehicle types that cannot be attached. In addition, since the conventional lamp unit only moves the HID lamp back and forth on its axis, the center position of light emission when the light emitting unit is moved to the high beam position is the same height as the low beam position. Therefore, it does not completely satisfy the requirements of JIS. In order to satisfy the requirements of JIS, it is necessary to move the HID lamp diagonally up and down. And in order to implement | achieve this, the structure which moves an HID lamp | ramp by a link mechanism is proposed. However, when the HID lamp is moved by the link mechanism, the structure is complicated, the size is increased, the cost is increased, and the possibility of failure is increased.

  In addition, the HID lamp is characterized in that it generates heat at a high temperature during light emission. Thereby, in the lamp unit, the temperatures of the lamp holding member and the guide member also rise, and these members expand. The lamp unit has a sufficient clearance between the guide member and the lamp holding member in advance so that the lamp holding member can be moved along the guide member even when the lamp holding member and the guide member are thermally expanded. It is necessary to secure it. In particular, when the lamp holding member is formed of a resin material or the like having a large linear expansion coefficient, and the guide member is formed of a metal material or the like having a small linear expansion coefficient, it is necessary to ensure a large clearance between them.

  However, when a large clearance is provided between the two, variation occurs in the position of the lamp holding member with respect to the guide member. In particular, if the position of the lamp holding member at the time of low beam and high beam varies, the position of the light emitting part of the HID lamp also varies. As a result, the reflected light from the reflector cannot be obtained sufficiently, and the planned low beam and high beam cannot be formed.

The present invention has been made to solve the above-mentioned drawbacks of the prior art, and is intended to be able to be mounted on H4 type lamps of many types of vehicles.
Another object of the present invention is to make it possible to move the lamp in an oblique direction with a simple structure.

An object of the present invention is to obtain good light distribution characteristics at the time of high beam and at the time of low beam.
Furthermore, an object of the present invention is to enable reduction in size and energy saving.

  Another object of the present invention is to ensure that the light emitting part of the HID lamp can be disposed at predetermined low beam positions and high beam positions.

Lamp unit according to the present invention is a lamp unit having a guide unit arranged along the moving direction of the lamp, and a lamp holding portion which moves along the guide portion while holding the lamp, the lamp holder Providing a sufficient clearance between the lamp holding part and the guide part so that the lamp holding part can move along the guide part even when thermally expanded. A tapered lamp-side inclined surface is provided on the lamp holding portion, and a tapered shape that holds the lamp holding portion in a predetermined position by being in surface contact with the lamp-side inclined surface at the movement limit of the lamp holding portion. A guide-side inclined surface is provided. In this case, the power supply cord of the lamp is guided to the side of the guide portion by a code guide, and the code guide is a displacement that allows displacement of the power supply cord caused by the movement of the lamp holding portion. It can be set as the structure in which the allowance part was provided. The guide portion may be configured such that the rear end side is inclined at a predetermined angle toward the lower side. In addition, a tapered lamp-side inclined surface may be provided at three or more locations so that the entire circumference of the peripheral edge portion of the lamp holding portion or the adjacent interval in the circumferential direction is less than 180 degrees, or the guide The guide side inclined surface on the taber may be provided at three or more locations so that the entire circumference of the peripheral portion of the portion or the adjacent interval in the circumferential direction is less than 180 degrees. In addition, the lamp holding portion is provided with a lamp-side inclined surface formed with a protrusion instead of the tapered lamp-side inclined surface, and the lamp-side inclined surface and the guide side are provided at the movement limit of the lamp holding portion. You may make it hold | maintain the said lamp holding | maintenance part in a predetermined position by making point contact or line contact with an inclined surface instead of surface contact.

  In the present invention configured as described above, since the lamp-side inclined surface and the guide-side inclined surface are provided, when the lamp holding portion moves along the guide portion, the lamp-side inclined surface is guided by the guide-side inclined surface. The When the ramp-side inclined surface and the guide-side inclined surface come into surface contact, the lamp holding portion is held at a predetermined movement limit position. Therefore, the lamp unit of the present invention can accurately arrange the light emitting part of the HID lamp at a predetermined low beam position and high beam position even when a large clearance is secured between the guide part and the lamp holding part. Light distribution characteristics.

A preferred embodiment of a lamp unit according to the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 is a sectional view of a lamp unit according to a first reference example of the present invention, and FIG. 2 is an exploded view thereof. In these drawings, the lamp unit 10 has a mounting member 12 to be mounted in a rear opening of a reflector (lamp) (not shown). The attachment member 12 has an ashtray shape with a flange when viewed from the side, and is formed so as to satisfy the requirements of an attachment fitting provided on a base of an H4 type automobile light bulb defined by JIS. In the mounting member 12, the front surface of the flange portion 14 is a reference surface 16 that defines the filament position (light emission position) of the light bulb defined in JIS. Further, the attachment member 12 is provided with an opening 18 in the center for arranging the HID lamp 20 as a lamp. A light shielding member 22 is attached to the opening 18 so as to protrude to the front side of the vehicle (the right side in FIG. 1).

  The light shielding member 22 is for enabling selection of a traveling beam (high beam) and a passing beam (low beam), which will be described later, when the HID lamp 20 is turned on. The light shielding member 22 includes a first light shielding member 24 and a second light shielding member 26 provided at the tip of the first light shielding member 24. The first light shielding member 24 has a front end portion and a rear end portion formed in a cylindrical shape, and an intermediate portion formed on a semi-cylinder. The first light shielding member 24 has an intermediate portion on the semi-cylinder arranged below the HID lamp 20 along the axis of the HID lamp 20, and the light emitted by the HID lamp 20 reaches the lower reflecting surface of the reflector. Prevents reflection to the front of the vehicle. The first light shielding member 24 has a cylindrical rear end upper portion inserted into the opening 18 of the mounting member 12.

  The second light shielding member 26 is attached to the front end ring portion 25 of the first light shielding member 24, covers the front end portion of the HID lamp 20, and prevents light emitted from the HID lamp 20 from being emitted forward of the vehicle. ing. The first light shielding member 24 is formed with a traveling beam window 28 in the middle in the longitudinal direction. As will be described later, the traveling beam window 28 transmits light emitted from the light emitting unit 30 to the lower reflective surface of the reflector when the light emitting unit 30 of the HID lamp 20 moves to a position corresponding to the traveling beam window 28. Guide and get a running beam.

  Further, a guide portion 32 protrudes rearward from the opening 18 of the attachment member 12. In the embodiment, the guide portion 32 is formed in a cylindrical shape, and the rear end side is inclined at a predetermined angle downward. In the embodiment, when the HID lamp 20 is moved 6 mm rearward from the passing beam position shown in FIG. 1 to the traveling beam position, the center position of the light emitting unit 30 is the passing beam. The angle is 0.8 mm below the position. That is, the axis b of the guide portion 32 is inclined 7.56 degrees with respect to the axis a of the mounting member 12. The inclination angle φ can be allowed in the range of (7.56 ± 1) degrees. When the inclination angle φ is in the range of 6.56 to 7.56 degrees, the light emitting unit 30 is obtained when the HID lamp 20 is moved forward to obtain a passing beam or moved backward to obtain a traveling beam. Is disposed at the passing beam position or the traveling beam position almost defined in JIS, and a relatively good light distribution characteristic of the passing beam or the traveling beam can be obtained.

  In the case of the embodiment, as shown in FIG. 2, the guide portion 32 has a halved structure, and is composed of a semi-cylindrical upper guide piece 32 a and a lower guide piece 32 b. A lamp support portion 34 is movably disposed inside the guide portion 32. The lamp support portion 34 is made of an insulating material such as plastic, and includes a lamp holding portion 36 and a shaft mounting portion 38. The shaft attachment portion 38 is integrally provided at the rear portion of the lamp holding portion 36. The lamp holding portion 36 includes a holding hole 40 for inserting the proximal end side of the HID lamp 20 on the distal end side. The axis of the holding hole 40 intersects with the axis of the guide portion 32 and is parallel to the axis of the attachment member 12. Therefore, the HID lamp 20 held in the holding hole 40 is supported by the lamp support portion 34 in a state orthogonal to the reference surface 16 and protrudes from the front surface of the mounting member 12. For this reason, when the lamp unit 10 is mounted on a reflector of a vehicle headlamp (not shown), the HID lamp 20 is held horizontally in parallel with the axis of the reflector.

  The shaft attachment portion 38 has a screw hole 42 on the rear end surface. The tip of the solenoid shaft 44 is screwed into the screw hole 42. The solenoid shaft 44 includes a small-diameter portion on the front end side and a large-diameter portion on the rear end side, and a spring receiver 46 is fitted on the base end portion of the small-diameter portion. A compression spring 48 is provided between the rear end surface of the shaft attachment portion 38 and the spring receiver 46 so as to penetrate the small diameter portion of the solenoid shaft 44.

  As shown in FIG. 2, the lower guide piece 32b of the guide portion 32 has a flange portion 50 for screwing the attachment member 12 at the front end portion, and is fastened to the upper guide piece 32a at the rear end portion. The connecting portion 52 is provided. The spring receiver 46 described above is disposed inside the connecting portion 52. For this reason, the compression spring 48 urges the lamp support portion 34 forward. Further, a plurality of locking claws 54 formed in an L shape are provided concentrically on the rear end surface of the lower guide piece 32b. A solenoid 56 as a drive unit is detachably attached to these locking claws 54. Note that a stopper portion 55 that determines the forward limit position of the lamp support portion 34 is provided at the front end portion of the mounting member 12.

  As shown in FIG. 2, the solenoid 56 includes a casing 58, a solenoid body 60, and a cover 62. And the casing 58 has the cylindrical convex part 64 integrally formed in the front surface. As shown in FIG. 2B, a central hole 66 through which the large diameter portion of the solenoid shaft 44 penetrates is formed in the front end surface of the cylindrical convex portion 64. A plurality of claw holes 68 that can receive the locking claw 54 provided in the lower guide piece 32 b are formed around the center hole 66 so as to communicate with the center hole 66. Therefore, by inserting the locking claw 54 of the lower guide piece 32b into the claw hole 68 provided in the casing 58 of the solenoid 56 and rotating the solenoid 56, the solenoid 56 is detachably attached to the lower guide piece 32b. Be able to.

  The lower guide piece 32b has a notch 72 in which the code guide 70 is disposed at the lower part on the rear side. The code guide 70 includes a semi-cylindrical guide body 74 and a pair of sleeve portions 76. In the case of the embodiment, the sleeve portion 76 is formed downward. Each of the sleeve portions 76 is provided with a power feeding cord 78 drawn from the lamp support portion 34 for lighting the HID lamp 20. Guided below the guide portion 32. These power supply cords 78 are covered with silicon rubber, and a male connector 80 and a female connector 82 are attached to the ends.

  In the embodiment, the cord guide 70 is movable along the power feeding cord 78. A displacement allowing portion 84 is provided below the guide body 74 (see FIG. 1). The displacement allowance portion 84 is formed by cutting out the guide main body 74, and the power supply moves integrally with the lamp support portion 34 when the HID lamp 20 is moved in the front-rear direction to switch between the traveling beam and the passing beam. It has a length in the front-rear direction that allows displacement of the cord 78 for use. Further, the sleeve portion 76 of the cord guide 70 has an inner diameter that is sufficiently larger than the outer shape of the power feeding cord 78 to facilitate the displacement of the power feeding cord 78. That is, the inner diameter of the sleeve portion 76 is 6 to 7 mm, for example, when the outer shape of the power supply cord 78 is 3.5 mm.

  The lamp unit 10 of the embodiment thus configured is attached to a reflector of a vehicle headlamp (not shown). When attaching to the reflector, as shown in FIG. 3, the solenoid 56 is removed from the lower guide piece 32b, and the solenoid shaft 44 is exposed. In the case of the embodiment, the length from the rear surface of the flange portion 14 of the mounting member 12 to the rear end of the solenoid shaft 44 is almost the same as that when a socket is attached to an H4 type bulb specified in JIS. It is.

  Thereafter, the cord guide 70 is moved rearward along the power feeding cord 78, and the sockets 80, 82 and the cord guide 70 are attached to the waterproof rubber cover 90 from the front side of the genuine waterproof rubber cover 90 equipped on the vehicle. Pass through the hole. Further, the guide portion 32 is passed through the hole of the waterproof rubber cover 90, and the tip of the waterproof rubber cover 90 is brought into contact with the rear end of the light shielding member 22 and attached to the peripheral surface of the guide portion 32. As described above, in the lamp unit 10 of the embodiment, since the code guide 70 is movable, the waterproof rubber cover 90 can be easily attached to the lamp unit 10.

  Thereafter, as shown in FIG. 3, the code guide 70 is moved upward and fitted into the notch 72 of the lower guide piece 32b. Then, the lamp unit 10 to which the waterproof rubber cover 90 is attached is attached to the rear opening of the reflector by a pressing spring (not shown). At this time, since the solenoid 56 is removed, the lamp unit 10 has a small protruding amount from the rear surface of the mounting member 12 and can be easily mounted without interfering with other components provided in the vehicle. Therefore, it can be attached to almost all vehicle types.

  Next, the solenoid 56 is attached to the rear end portion of the guide portion 32. That is, the locking claw 54 provided on the lower guide piece 32 b is inserted into the claw hole 68 provided in the casing 58 of the solenoid 56, and the solenoid 56 is rotated to be locked to the locking claw 54.

  In the lamp unit 10 thus attached to the reflector, the lamp support 34 is urged forward by the compression spring 48, so that the lamp unit 10 is in the forward limit position as schematically shown in FIG. is there. As shown in FIGS. 1 and 3, the HID lamp 20 has the light emitting unit 30 positioned in front of the traveling beam window 28. Therefore, if the HID lamp 20 is turned on at this time, light does not reach the lower reflecting surface of the reflector, and a low beam is obtained.

  In the lamp unit 10, the HID lamp 20 is held parallel to the axis of the mounting member 12, that is, orthogonal to the reference surface 16, parallel to the axis of the reflector, and held horizontally. Therefore, the lamp unit 10 can easily and surely obtain the light distribution characteristic of the passing beam defined in JIS shown in FIG. In addition, the code | symbol 101 shown in FIG. 5 is a horizontal line of a lamp (reflector), and the code | symbol 103 is a vertical line of a lamp. Reference numeral 105 in the figure indicates the irradiation range of the passing beam, and reference numeral 107 indicates the shadow range.

  That is, when the HID lamp 20 is held horizontally, the arc 30c generated between the electrodes 30a and 30b of the light emitting unit 30 has a hollow spheroid shape as shown in part in FIG. Eggplant. For this reason, when the HID lamp 20 is tilted, unexpected shadows and uneven light may occur. Further, when the HID lamp 20 is tilted, as shown in FIG. 6B, the shape of the arc 30c is deformed, the heat generation is not uniform, the glass of the HID lamp 20 is adversely affected, and the vibration of the vehicle There is a risk of falling.

  On the other hand, when a current is supplied to the solenoid 56 and excited, the solenoid shaft 44 is pulled rearward by the solenoid 56 and is moved rearward against the urging force of the compression spring 48 as shown in FIG. Moving. For this reason, the lamp support part 34 moves to the rear side along the guide part 32 integrally with the solenoid shaft 44 to reach the backward limit position. Further, the HID lamp 20 moves backward together with the lamp support portion 34, and the light emitting portion 30 is located at a position corresponding to the traveling beam window 28 provided in the light shielding member 22. At this time, since the light emitting unit 30 is inclined such that the rear side of the guide unit 32 is lower than the front side, the light emitting unit 30 moves backward obliquely. As described above, in the lamp unit 10 of the embodiment, the axis b of the guide portion 32 is inclined 7.56 degrees with respect to the axis a (horizontal plane) of the mounting member 12, so that the light emitting portion 30 is moved from the passing beam position. When it is retracted 6 mm to the traveling beam position, the height is reduced by 0.8 mm. Therefore, the requirements defined in JIS are completely satisfied, and good light distribution characteristics can be obtained.

  Further, since the power supply cord 78 is provided with the displacement allowance portion 84 in the cord guide 70, it is easily bent and displaced when the lamp support portion 34 is retracted. For this reason, it is possible to reduce the resistance associated with the displacement of the power supply cord 78 when the lamp support portion 34 is moved backward or forward, and the solenoid 56 that is the drive portion can be reduced in size and energy can be saved.

  The light emitted by the light emitting unit 30 that has moved back to the traveling beam position enters the lower reflecting surface of the reflector through the traveling beam window 28 and is reflected toward the front of the vehicle to form a traveling beam (high beam). . When the power supply to the solenoid 56 is stopped, the HID lamp 20 is automatically advanced to the passing beam position via the lamp support portion 34 by the spring force of the compression spring 48.

  Thus, in the lamp unit 10 according to the first reference example, the guide portion 32 that guides the lamp support portion 34 that holds the HID lamp 20 is inclined at a predetermined angle with the rear end side directed downward. By simply moving the lamp support 34 by the solenoid 56, the light emitting part 30 of the HID lamp 20 can be disposed at the passing beam position and the traveling beam position specified in JIS, without requiring a link mechanism or the like. The structure can be simplified.

  In addition, the said embodiment is 1 aspect of this invention, Comprising: It is not limited to this. For example, in the above embodiment, the case where the drive unit is the solenoid 56 has been described, but the drive unit may be a stepping motor, an electromagnet, a cam, a cylinder, or the like. When a solenoid is used as the drive unit, as a method of holding the solenoid shaft at the forward limit position and the reverse limit position, a self-holding type using a magnet may be used, or a current may be supplied to the solenoid to be held. It may be. In the above-described embodiment, the case where the cord guide 70 is movable along the power feeding cord 78 has been described. However, the cord guide is fixed to the guide portion 32 and the sleeve portion 76 can be deformed flexibly. You may comprise by something. Furthermore, although the case where the power feeding cord 78 is guided below the guide portion 32 has been described in the above embodiment, it can be guided in any direction as necessary.

  FIG. 7 is a side sectional view of a lamp unit according to a second reference example. The basic configuration of the lamp unit 10A according to the second reference example is substantially the same as the lamp unit 10 of the first reference example. However, in the lamp unit 10A of the second reference example, tapered lamp-side inclined surfaces 37a and 37b are provided on the lamp holding member (lamp holding portion) 36a, and the lamp-side inclined surface 37a, Tapered guide-side inclined surfaces 13 and 33 for holding the lamp holding member 36a in a predetermined position by surface contact with 37b are provided.

  In addition, the guide member (guide part) 32a in the embodiment includes a front large-diameter cylindrical part and a rear small-diameter cylindrical part, and is formed by aluminum die casting or the like. The lamp holding member 36a disposed inside the guide member 32a is composed of a front large-diameter portion and a rear small-diameter portion, and is formed of an insulating material such as plastic.

  The lamp holding member 36a is movably disposed along the guide member 32a. On the other hand, the opening 18 of the attachment member 12 is formed smaller than the large diameter portion of the lamp holding member 36a. Therefore, when the lamp holding member 36a moves forward along the guide member 32a, the lamp holding member 36a comes into contact with the peripheral edge of the opening 18 in the mounting member 12 and stops. At the forward limit position of the lamp holding member 36 a, the light emitting unit 30 of the HID lamp 20 is disposed at the passing beam position 21. When the lamp holding member 36a moves rearward along the guide member 32a, the lamp holding member 36a comes into contact with the rear end surface of the large diameter portion of the guide member 32a and stops. The light emitting unit 30 of the HID lamp 20 is disposed at the traveling beam position 23 at the retreat limit position of the lamp holding member 36a.

  On the other hand, the entire periphery of the peripheral edge portion of the front end surface of the large-diameter portion of the lamp holding member 36a is chamfered to form a lamp-side forward inclined surface 37a. A tapered guide-side forward inclined surface 13 is also formed on the entire periphery of the peripheral edge of the opening 18 in the attachment member 12. The lamp-side front inclined surface 37a and the guide-side front inclined surface 13 are in surface contact at the forward limit of the lamp holding member 36a, and the lamp holding member 32a can be held at a predetermined position.

  Further, the entire periphery of the peripheral edge portion of the rear end face of the large diameter portion of the lamp holding member 36a is chamfered to form a lamp side rear inclined surface 37b. Further, a tapered guide-side rearward inclined surface 33 is also formed on the entire periphery of the corner portion between the rear end surface and the side surface of the large-diameter cylindrical portion in the guide member 32a. The lamp-side rear inclined surface 37b and the guide-side rear inclined surface 33 are in surface contact with each other at the retreat limit of the lamp holding member 36a, and the lamp holding member 36a can be held at a predetermined position.

  The ramp-side inclined surfaces 37a and 37b and the guide-side inclined surfaces 13 and 33 are not necessarily formed with tapered inclined surfaces on the entire circumference. If the tapered inclined surfaces are formed at three or more locations on the circumference, Good. However, the interval between adjacent inclined surfaces is less than 180 °. Alternatively, only the guide-side inclined surfaces 13 and 33 may be tapered, and protrusions may be formed on the lamp-side inclined surfaces 37a and 37b so as to make point contact or line contact therebetween.

  On the other hand, a connecting portion (connecting plate) 52 to the solenoid 56 is formed at the rear end portion of the guide member 32a. Further, a screw hole 42 into which a small diameter portion of the solenoid shaft 44 is screwed is formed in the rear end surface of the lamp holding member 36a. The solenoid shaft 44 includes a front small-diameter portion and a rear large-diameter portion, and the small-diameter portion is fixed to the lamp holding member 36 a through a through hole in the central portion of the connecting plate 52. On the other hand, a spring receiver 46 is disposed on the front side of the connecting plate 52, and a compression spring 48 is interposed between the spring receiver 46 and the rear end surface of the lamp holding member 36a. As a result, the compression spring 48 urges the lamp support portion 34 forward, and the light emitting portion 30 of the HID lamp 20 is disposed at the low beam position 21.

  Further, a solenoid 56 is mounted on the connecting portion 52 as a drive portion of the solenoid shaft 44. The solenoid 56 moves the solenoid shaft 44 and the lamp support portion 34 rearward against the urging force of the compression spring 48, and arranges the light emitting portion 30 of the HID lamp 20 at the traveling beam position 23. The solenoid 56 is preferably detachable from the connecting plate 52. Since the length of the lamp unit 10 can be shortened by removing the solenoid 56, it is possible to eliminate the interference with the in-vehicle component when the lamp unit 10 is mounted on the reflector 8. Therefore, the lamp unit 10 can be easily attached to many vehicle types.

  The lamp unit 10A according to the second reference example configured as described above is used by being attached to the reflector 8 of the vehicle headlamp. When the solenoid 56 is detachably formed, the solenoid 56 is detached from the guide member 32a, and the solenoid shaft 44 is exposed and attached to the reflector 8. In the case of the embodiment, the length from the front surface (reference surface 16) of the flange portion 14 of the mounting member 12 to the rear end of the solenoid shaft 44 is the length of the socket mounted on the H4 type halogen lamp defined in JIS. It is designed to be equivalent.

  FIG. 8 (1) shows the lamp unit 10A in the low beam state. The lamp holding member 36a in FIG. 8 (1) is urged forward by the compression spring 48 and is in the forward limit position. Here, the light emitting unit 30 of the HID lamp 20 is located in front of the high beam window 28. In this case, the light from the light emitting unit 30 in the HID lamp 20 is reflected by the first light shielding member 24 and does not reach the lower reflecting surface of the reflector. Thereby, a passing beam is obtained.

  FIG. 8 (2) shows the lamp unit 10A in the traveling beam state. When current is supplied to the solenoid 56 and excited, the solenoid shaft 44 moves rearward against the urging force of the compression spring 48. Further, the lamp holding member 36a coupled to the solenoid shaft 44 also moves to the retreat limit position along the guide member 32a. Here, the light emitting unit 30 of the HID lamp 20 is located above the high beam window 28. In this case, the light from the light emitting unit 30 passes through the high beam window 28, reaches the lower reflecting surface of the reflector, and is reflected forward of the vehicle. Thereby, a traveling beam is obtained.

  On the other hand, since the lamp side rear inclined surface 37b and the guide side rear inclined surface 33 are formed in a taper shape, when the lamp holding member 36a moves rearward, the lamp side rear inclined surface 37b is guided by the guide side rear inclined surface 33. (See FIG. 8 (1)). When the lamp-side rearward inclined surface 37b and the guide-side rearward inclined surface 33 come into surface contact, the lamp holding member 36a is held at a predetermined retreat limit position. That is, the lamp holding member 36a is held concentrically with the guide member 32a at the retreat limit position. Thereby, the light emitting unit 30 of the HID lamp 20 is arranged at the predetermined traveling beam position 23.

  When the current supply to the solenoid 56 is stopped and demagnetized, the lamp holding member 36a is urged forward by the compression spring 48, and returns to the forward limit position as shown in FIG. Here, since the lamp-side front inclined surface 37a and the guide-side front inclined surface 13 are formed in a tapered shape, when the lamp holding member 36a moves forward, the lamp-side front inclined surface 37a is moved by the guide-side front inclined surface 13. Guided (see FIG. 2 (2)). When the lamp-side forward inclined surface 37a and the guide-side forward inclined surface 13 come into surface contact, the lamp holding member 36a is held at a predetermined forward limit position. That is, the lamp holding member 36a is held concentrically with the guide member 32a at the forward limit position. Thereby, the light emitting unit 30 of the HID lamp 20 is arranged at the predetermined high beam position 22.

  As described above, the lamp unit 10A according to the second reference example is provided with the tapered lamp-side inclined surface on the lamp holding member, and is brought into surface contact with the lamp-side inclined surface at the movement limit of the lamp holding member. Is provided with a tapered guide-side inclined surface for holding a predetermined position. Since it has the taper-shaped ramp side inclined surface and the guide side inclined surface, when the lamp holding member moves along the guide member, the lamp side inclined surface is guided by the guide side inclined surface. When the ramp side inclined surface and the guide side inclined surface come into surface contact, the lamp holding member is held at a predetermined movement limit position. Therefore, even when a large clearance is secured between the guide member and the lamp holding member, the light emitting portion 30 of the HID lamp 20 can be accurately and reliably disposed at the predetermined passing beam position 21 and the traveling high beam position 23. This makes it possible to form a stable passing beam and a traveling beam having good light distribution characteristics, and an H4 type halogen lamp can be replaced with an HID lamp.

Next, a lamp unit according to an embodiment of the present invention will be described.
FIG. 9 is an explanatory diagram of the lamp unit according to the embodiment. FIG. 9 (1) shows a passing beam state, and FIG. 9 (2) shows a traveling beam state. The lamp unit 110 according to the embodiment includes an attachment member 112 attached to the rear end opening of the reflector, a guide member (guide portion) 132 provided in the central opening of the attachment member 112 and protruding rearward. The guide groove 162 provided on the side surface of the guide member 132, the lamp holding member (lamp holding portion) 136 provided movably along the guide member 132, and the guide groove protruding from the side surface of the lamp holding member 136. 162, a pin 166 that engages with the front end of the lamp holding member 136, protrudes from the front surface of the mounting member 112, and is disposed in the reflector. The pin 166 guides the lamp holding member 136 to the guide. A solenoid 156 and a solenoid shaft 144 that are moved along the member 132; A lamp unit 110 having a lamp holding member 136 and a link member 143 for connecting the solenoid shaft 144, wherein the lamp holding member 136 is provided with tapered ramp-side inclined surfaces 137 a and 137 b. Tapered guide side inclined surfaces 113 and 133 for holding the lamp holding member 136 at predetermined positions are provided by making surface contact with the lamp side inclined surfaces 137a and 137b at the movement limit. In addition, the description is abbreviate | omitted about the part which becomes the same structure as the 2nd reference example mentioned above.

  The guide member 132 in the embodiment includes a front large-diameter cylindrical portion and a rear small-diameter cylindrical portion, and is arranged in parallel with the axis of the mounting member 112. A guide groove 162 is formed on the side of the large diameter cylindrical portion of the guide member 132. The guide groove 162 is formed in an oval shape, and two oval fixed points are arranged at positions where the low beam position 121 and the high beam position 122 of the light emitting unit 130 in the HID lamp 120 are horizontally moved. On the other hand, a lamp holding member 136 having a large diameter portion at the front and a small diameter portion at the rear is arranged inside the guide member 132. A pin 166 protruding to the side of the large diameter portion of the lamp holding member 136 is engaged with the guide groove 162 of the guide member 132.

  A solenoid shaft 144 is disposed behind the lamp holding member 136 via a link member 143. The link member 143 is pin-coupled to the side of the small diameter portion of the lamp holding member 136 and the side of the solenoid shaft 144, respectively.

  The lamp holding portion 136 in FIG. 9A is biased forward by the compression spring 148 and is at the forward limit position. Here, when a current is supplied to the solenoid 156 for excitation, the solenoid shaft 144 is pulled backward as shown in FIG. 9B, and the lamp holding member 136 moves to the retreat limit position. At this time, since the pin 166 follows the guide groove 162, the lamp holding member 136 also moves downward. Accordingly, the light emitting unit 130 of the HID lamp 120 is disposed at the high beam position 122. In addition, since the vertical movement of the lamp holding member 136 is absorbed by the link member 143, no bending moment acts on the solenoid shaft 144.

  When the current supply to the solenoid 156 is stopped and demagnetized, the lamp holding portion 136 is urged by the compression spring 148 to return to the forward limit position as shown in FIG. At this time, since the pin 166 follows the guide groove 162, the lamp holding member 136 also moves upward. Accordingly, the light emitting unit 130 of the HID lamp 120 is disposed at the passing beam position 121.

  On the other hand, the entire peripheral edge of the rear end surface of the large diameter portion of the lamp holding member 136 is chamfered in a tapered shape to form a lamp side rear inclined surface 137b. A tapered guide-side rearward inclined surface 133 is also formed on the entire periphery of the corner portion between the rear end surface and the side surface of the large-diameter cylindrical portion of the guide member 132. When the lamp holding member 136 moves rearward, the lamp-side rearward inclined surface 137b is guided by the guide-side rearward inclined surface 133 (see FIG. 9 (1)). Further, when the lamp-side rearward inclined surface 137b and the guide-side rearward inclined surface 133 come into surface contact, the lamp holding member 136 is held at a predetermined retreat limit position. That is, the lamp holding member 136 is held concentrically with the guide member 132 at the retreat limit position. Thereby, the light emitting unit 130 of the HID lamp 120 is arranged at the predetermined traveling beam position 123.

  Further, the entire circumference of the peripheral edge portion of the front end surface of the large-diameter portion of the lamp holding member 136 is tapered and a lamp-side forward inclined surface 137a that obliquely crosses the traveling direction of the lamp holding member 136 is formed. . A tapered guide-side forward inclined surface 113 is also formed on the entire periphery of the peripheral edge of the opening in the attachment member 112. When the lamp holding member 136 moves forward, the lamp-side forward inclined surface 137a is guided by the guide-side forward inclined surface 113 (see FIG. 9 (2)). Furthermore, the lamp holding member 136 is held at a predetermined forward limit position when the lamp-side forward inclined surface 137a and the guide-side forward inclined surface 113 come into surface contact. That is, the lamp holding member 136 is held concentrically with the guide member 132 at the forward limit position. Accordingly, the light emitting unit 130 of the HID lamp 120 is disposed at the passing beam position 121.

  As described above, in the present embodiment, the pin protruding from the side surface of the lamp holding member is engaged with the guide groove formed on the side surface of the guide member, and the HID lamp is moved obliquely up and down using the link mechanism. . Even in this case, a tapered lamp side inclined surface is provided on the lamp holding member, and the lamp holding member is held in a predetermined position by making surface contact with the lamp side inclined surface at the limit of movement of the lamp holding member. By providing the inclined surface, the light emitting part of the HID lamp can be arranged at a predetermined passing beam position and traveling beam position. Accordingly, it is possible to form a stable passing beam and a traveling beam having good light distribution characteristics, and the H4 type halogen lamp can be replaced with an HID lamp.

  The present invention can be used for a vehicle headlamp, and in particular, can be used in place of an H4 type halogen lamp.

It is sectional drawing of the lamp unit which concerns on the 1st reference example of this invention. It is an exploded view of the lamp unit which concerns on a 1st reference example. It is sectional drawing when attaching the lamp unit which concerns on a 1st reference example to a reflector. It is a figure explaining the effect | action of the lamp unit which concerns on a 1st reference example. It is a figure explaining the light distribution characteristic of the low beam of a headlamp. It is explanatory drawing of the arc which arises in the light emission part of a HID lamp. It is side surface sectional drawing of the lamp unit which concerns on a 2nd reference example. (1) is explanatory drawing of the low beam state of the lamp unit which concerns on a 2nd reference example, (2) is explanatory drawing of the high beam state of the lamp unit which concerns on a 2nd reference example. (1) is explanatory drawing of the low beam state of the lamp unit which concerns on embodiment of this invention, (2) is explanatory drawing of the high beam state of the lamp unit which concerns on embodiment of this invention.

Explanation of symbols

110 ......... Lamp unit, 112 ......... Installation member, 113, 133 ......... Guide-side inclined surface, 120 ......... HID lamp, 132 ......... Guide part, 136 ...... Lamp holding part, 137a, 137b ......... ramp side inclined surface, 143 ......... link member, 144 ... ... solenoid shaft, 156 ... ... solenoid, 162 ... ... guide groove, 166 ... ... pin.

Claims (3)

A lamp unit having a guide portion arranged along a moving direction of the lamp, and a lamp holding portion that moves along the guide portion while holding the lamp,
A sufficient clearance is provided between the lamp holding part and the guide part so that the lamp holding part can be moved along the guide part even when the lamp holding part is disposed inside the guide part and thermally expands. Provided,
Providing the lamp holding portion with a tapered lamp-side inclined surface;
A lamp unit comprising a tapered guide-side inclined surface that holds the lamp-holding portion in a predetermined position by being in surface contact with the lamp-side inclined surface at a limit of movement of the lamp-holding portion. The lamp unit according to claim 1,
The tapered lamp-side inclined surface is provided at three or more locations so that the entire circumference of the peripheral edge of the lamp holding portion or the adjacent interval in the circumferential direction is less than 180 degrees, and / or
The tapered guide-side inclined surface is provided at three or more places so that the entire circumference of the peripheral edge of the guide part or the adjacent interval in the circumferential direction is less than 180 degrees. . The lamp unit according to claim 1 or 2,
Instead of the tapered lamp side inclined surface, the lamp holding portion is provided with a lamp side inclined surface formed with a protrusion,
In the movement limit of the lamp holding part, the lamp side inclined surface and the guide side inclined surface hold the lamp holding part at a predetermined position by making point contact or line contact instead of surface contact. Lamp unit to be used.

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