Abstract:
A pattern-variable headlamp includes a light source, a reflector, a movable shade that switches a position between a first position, a second position, and a third position to form a first light distribution pattern, a second light distribution pattern, and a third light distribution pattern, respectively, from the light reflected from the reflector, a projection lens that irradiates the light distribution pattern to a road surface, a first solenoid that moves the movable shade to switch from the first position to the second position, a second solenoid that moves the movable shade to switch from the first position to the third position, and an elastic returning unit that returns the movable shade to switch from the second position to either of the first position and the third position, or from the third position to the first position.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     The present document incorporates by reference the entire contents of Japanese priority document, 2003-62131 filed in Japan on Mar. 7, 2003. 
     BACKGROUND OF THE INVENTION 
     1) Field of the Invention 
     The present invention relates to a headlamp to obtain a plurality of different light distribution patterns with one light source by switching a position of a movable shade. 
     2) Description of the Related Art 
     A headlamp is disclosed in, for example, Japanese Patent Application Laid-Open No. H11-240385 and U.S. Pat. No. 5,315,442. In the former, two different light distribution patterns can be obtained with one light source by switching a position of a movable shade using one solenoid. In the latter, four different light distribution patterns can be obtained with one light source by switching a position of a movable shade using two direct-current (DC) motors or stepping motors. 
     However, the former headlamp has a problem that only two light distribution patterns can be obtained; the latter headlamp has a problem that a switching speed of the movable shade is slow because the two DC motors or stepping motors are used. 
     SUMMARY OF THE INVENTION 
     It is an object of the present invention to solve at least the problems in the conventional technology. 
     The pattern-variable headlamp according to one aspect of the present invention includes a light source, a reflector that reflects light from the light source, a movable shade that switches a position between a first position, a second position, and a third position to form a first-light distribution pattern, a second light distribution pattern, and a third light distribution pattern, respectively, from the light reflected from the reflector, a projection lens that irradiates the first light distribution pattern, the second light distribution pattern and the third light distribution pattern to a road surface, a first solenoid that moves the movable shade to switch from the first position to the second position, a second solenoid that moves the movable shade to switch from the first position to the third position, and an elastic returning unit that returns the movable shade to switch from the second position to either of the first position and the third, position, or from the third position to the first position. 
     The other objects, features, and advantages of the present invention are specifically set forth in or will become apparent from the following detailed description of the invention when read in conjunction with the accompanying drawings. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a schematic of a headlamp according to the present invention; 
         FIG. 2  is a cross unit of the headlamp, cut along a line II—II in  FIG. 1 ; 
         FIG. 3  is an exploded view of a movable shade, a first solenoid, and a second solenoid; 
         FIG. 4  is a cross unit of the first solenoid and the second solenoid; 
         FIG. 5  is an assembly diagram of the movable shade, the first solenoid, and the second solenoid; 
         FIG. 6A  is a partial side view of the movable shade located at a first position; 
         FIG. 6B  is a partial side view of the movable shade located at a third position; 
         FIG. 6C  is a partial side view of the movable shade located at a second position; 
         FIG. 7A  is a front view of the movable shade located at the first position; 
         FIG. 7B  is a front view of the movable shade located at the third position; 
         FIG. 7C  is a front view of the movable shade located at the second position; 
         FIG. 8A  is a schematic of a low-beam light distribution pattern; 
         FIG. 8B  is a schematic of a motorway light distribution pattern; and 
         FIG. 8C  is a schematic of a high-beam light distribution pattern. 
     
    
    
     DETAILED DESCRIPTION 
     Exemplary embodiments of a headlamp according to the present invention will be described below in detail with reference to the accompanying drawings. The present invention is not limited to the embodiments, and the constituents in the embodiments include those that can easily be achieved by persons skilled in the art or are substantially the same. 
     The embodiment is of a headlamp for a vehicle of right-hand traffic, but the invention is not limited to this, and the invention can also be applied to a headlamp for a vehicle of left-hand traffic. In such a case, the configuration of the headlamp should be laterally reversed. 
       FIG. 1  is a schematic of a headlamp according to the present invention;  FIG. 2  is a cross unit of the headlamp, cut along a line II—II in FIG. A headlamp  1  is of a two-lamp projector type. It also includes at least a light source  2 , a reflector  3 , a projection lens (condensing lens)  4 , a movable shade  5 , a fixed shade  6 , a first solenoid  7 , and a second solenoid  8 . A sign  9  represents a holder (frame or housing) which fixes and holds the reflector  3 , the projection lens  4 , and the like. 
     The light source  2  is a discharge lamp such as a high pressure metal vapor discharge lamp and a high intensity discharge (HID) lamp such as a metal hydride lamp. The light source  2  is detachably mounted on the reflector  3  through a socket mechanism  10 . The light source  2  is disposed on a predetermined location with respect to the reflector  3  by mounting the light source  2  on the reflector  3 . A connector (not shown) of the socket mechanism  10  is detachably connected to the light source  2 . The connector supplies a power from a ballast (not shown) to the light source  2 . The ballast supplies high voltage required for starting the discharge lamp or the light source  2 , and supplies stable voltage when the discharge lamp comes ON. A light-emitting unit  2   a  of the light source  2  is located near a first focus F 1  of the reflector  3 . 
     The reflector  3  has aluminum-evaporated or silver-coated inner concave surface as a reflection surface. This reflection surface is basically a rotating elliptical surface. The reflection surface includes the first focus F 1  and a second focus F 2 . The reflector  3  is fixed and held by the holder  9  through an optical axis adjusting unit (not shown). 
     Although it is not shown in the drawing, the projection lens  4  has a focal plane (meridional image surface) on the side of an object space near the second focus F 2  of the reflector  3  and forward of the second focus F 2  (a forward direction of the vehicle and light-emitting direction of the headlamp  1 ). 
     The movable shade  5  is a thin steel plate such as a Special Use Stainless Steel (SUS). The movable shade  5  includes two movable shade bodies  5   a  and  5   b , a leaf spring  5   c  which is an elastic returning unit, a first fixing unit  5   d  for mounting the two movable shade bodies  5   a  and  5   b  on a first plunger  7   a  of the first solenoid  7 , and a second fixing unit  5   e  which allows a holder  9  to fix and hold the leaf spring  5   c . As illustrated in  FIG. 2 , central portion of the two movable shade bodies  5   a  and  5   b  are curved toward the light source  2  in a convex manner as viewed from above. Each of the two movable shade bodies  5   a  and  5   b  vertically moves and switches to any of a first position (low-beam position), a third position (motorway position), and a second position (high-beam position) by the first solenoid  7 , the second solenoid  8 , and the leaf spring  5   c . The front movable shade body  5   a  is integrally formed on the first fixing unit  5   d . An edge  5   f  is provided on an upper edge of a central portion of the front movable shade body  5   a . The front movable shade body  5   a  is provided at its opposite ends with fixing holes  5   g  through which the rear movable shade body  5   b  is fixed to the movable shade body  5   a . An edge  5   h  is also provided on an upper edge of a central portion of the rear movable shade body  5   b . The rear movable shade body  5   b  is provided at its opposite ends with fixing holes  5   i  through which the front movable shade body  5   a  is fixed to the movable shade body  5   b . Substantially intermediate portions of the edges  5   f  and  5   h  of the two movable shade bodies  5   a  and  5   b  are formed with steps which are inclined at an angle of 45 degrees (or 30 degrees). 
     The leaf spring  5   c  as the elastic returning unit is formed into a band-like shape, and is integrally provided between the first fixing unit  5   d  and the two second fixing units  5   e . A central portion of the leaf spring  5   c  is curved such that the central portion is convex laterally as viewed from front (front of the headlamp  1 ) when the headlamp is assembled. As a result, the leaf spring  5   c  is curved when the movable shade  5  is assembled and thus, a returning force, that is, elastic force is generated. This elastic returning force acts in a direction vertically pushing and spreading the first fixing unit  5   d  and the two second fixing units  5   e  as illustrated by a solid arrow in FIG.  3 . 
     The first fixing unit  5   d  is provided at its central portion with a mounting hole  5   j  for fixing the movable shade  5  to the first plunger  7   a  of the first solenoid  7 . Each of the two second fixing units  5   e  is provided with fixing holes  5   k  (two in  FIG. 3 ) for fixing the two second fixing units  5   e  to each other and with mounting holes  5   l  (two in  FIG. 3 ) for fixing the leaf spring  5   c  and the holder  9  to each other. 
     The fixed shade  6  is a thin steel plate such as SUS, and includes a shade unit  6   a  and a mounting unit  6   b  which are integrally formed together. The shade unit  6   a  projects from a central portion of the mounting unit  6   b  rearward (toward the light source  2 ). The fixed shade  6  is fixed and held by mounting a mounting unit  6   b  on the holder  9  by a screw or the like (not shown). At that time, the shade unit  6   a  is disposed at a position lower than the light source  2  in a space  3   a  formed in the reflector  3 . The shade unit  6   a  has a function of shielding reflection light from the reflector  3 , a function of protecting the first solenoid  7  and the second solenoid  8  from radiation heat from the light source  2 , and a stopper function of allowing the two movable shade bodies  5   a  and  5   b  to, stay at the first position. A thickness of the thin steel plate constituting the fixed shade  6  is thicker than a thin steel plate constituting the movable shade  5 . 
     The first solenoid  7  is a pull-type solenoid, and includes a cylindrical first plunger  7   a , a coil  7   b , and a solenoid yoke  7   c  as illustrated in FIG.  3  and FIG.  4 . An end surface of a tip end of the first plunger  7   a  is provided with a mounting hole  7   d  to which a first fixing unit  5   d  of the movable shade  5  is mounted. The tip end of the first plunger  7   a  is provided with a trench  11   a  in a moving direction (switching direction) of the movable shade  5 . The trench  11   a  abuts against the other end of a connecting plate  11   b  of a connecting mechanism  11  described later. The coil  7   b  is provided in the solenoid yoke  7   c  such as to surround the first plunger  7   a . When the coil  7   b  of the first solenoid  7  is energized, a magnetic force is generated in the coil  7   b , and the first plunger  7   a  is attracted in a direction of arrow B and is moved. A stroke amount h 1  of the first plunger  7   a  at that time is set to such a length that the movable shade  5  can move from the first position to the second position. The first solenoid  7  is mounted on the holder  9  together with the movable shade  5  by a fixing hole  7   e  formed in the solenoid yoke  7   c.    
     The second solenoid  8  is a pull-type solenoid, and includes a cylindrical second plunger  8   a , a coil  8   b , and a solenoid yoke  8   c . A connecting plate hole  8   d  is provided near a tip end of the second plunger  8   a . One end of the connecting plate  11   b  of the connecting mechanism  11  is inserted into the connecting plate hole  8   d  and is fixed therein. The coil  8   b  is provided in the solenoid yoke  8   c  such as to surround the second plunger  8   a . When the coil  8   b  of the second solenoid  8  is energized, a magnetic force is generated in the coil  8   b  and the second plunger  8   a  is attracted in a direction of arrow C and is moved. A stroke amount h 2  of the second plunger  8   a  at that time is set to such a length that the movable shade  5  can move from the first position to the third position. The second solenoid  8  is fixed to and held by the first solenoid  7  by a fixing unit (not shown) such as a screw or welding. That is, the first solenoid  7  and the second solenoid  8  are disposed side-by-side, and a center line of the first plunger  7   a  of the first solenoid  7  and a center line of the second plunger  8   a  of the second solenoid  8  are substantially in parallel to each other.  FIG. 4  is a cross unit of the first solenoid and the second solenoid. H 1  to h 4  may be different from actual values. 
     The first plunger  7   a  of the first solenoid  7  and the second plunger  8   a  of the second solenoid  8  are connected to each other through the connecting mechanism  11 . The connecting mechanism  11  includes a connecting plate  11   b . One end of the connecting plate  11   b  is inserted into the connecting plate hole  8   d  of the second plunger  8   a  and fixed therein, and the other end of the connecting plate  11   b  abuts against one of the end surfaces  11   d  and  11   e  of the trench  11   a  of the first plunger  7   a , thereby switching the movable shade  5 . 
     A length of the connecting plate  11   b  is set such that when the second solenoid  8  is fixed to the first solenoid  7 , one end of the connecting plate  11   b  is inserted into the connecting plate hole  8   d  of the second plunger  8   a  and fixed therein and the other end  11   c  of the connecting plate  11   b  is located in the trench  11   a  of the first plunger  7   a . That is, the length of the connecting plate  11   b  bis such a value that the one end  11   c  of the connecting plate  11   b  can abut against the end surface  11   d  or  11   e  in the moving direction of the first plunger  7   a  which forms the trench  11   a.    
     The connecting plate  11   b  is made of metal or the like. It is preferable that a thickness h 3  of the connecting plate  11   b  is such a value that when the first solenoid  7  is moved by the second solenoid  8  through the connecting mechanism  11 , the connecting plate  11   b  is not bent. A length h 4  obtained by subtracting the thickness h 3  of the connecting plate  11   b  from a height of the trench  11   a  is such a value that the movable shade  5  can move from the third position to the second position. That is, h 4  is set such that a sum length of h 2  and h 4  is equal to a length of h 1 . 
     The assembling manner of the movable shade  5 , the first solenoid  7 , and the second solenoid  8  will be explained with-reference to FIG.  3  and FIG.  5 . First, rivets  12  are inserted into the fixing holes  5   k  of the two second fixing units  5   e  of the movable shade  5 , and the rivets  12  are fastened on a back surface (upper surface of the second fixing unit  5   e  in  FIG. 3 ) of one of the second fixing units  5   e  thereby fixing the second fixing units  5   e . Next, the two fixing holes  5   i  of the rear movable shade body  5   b  are superposed on the two fixing holes  5   g  of the front movable shade body  5   a  of the movable shade  5 , rivets  13  are inserted into the superposed fixing holes  5   g  and  5   i , and the rivets  13  are fastened on front surface (left surface of the front movable shade body  5   a  in  FIG. 3 ) of opposite ends of the front movable shade body  5   a . The fixing units of the two second fixing units  5   e  and the two movable shade bodies  5   a  and  5   b  are not limited to the rivets  12  and  13 , and they may be fixed by caulking or spot welding: 
     Next, the second solenoid  8  is fixed to the first solenoid  7 , and the connecting plate  11   b  of the connecting mechanism  11  is inserted into the connecting plate hole  8   d  of the second plunger  8   a  from opposite side where the first plunger  7   a  is located. At that time, the connecting plate  11   b  is inserted into the connecting plate hole  8   d  until the one end  11   c  of the connecting plate  11   b  comes into the trench  11   a  of the first plunger  7   a . The connecting plate  11   b  inserted into the connecting plate hole  8   d  is fixed to and held by the second plunger  8   a  by a fixing unit (not shown). An end surface of the tip end of the second plunger  8   a  may be provided with a screw hole as this fixing unit (not shown) which is in communication with the connecting plate hole  8   d , a bolt is threadedly inserted into this screw hole, and the connecting plate  11   b  in the connecting plate hole  8   d  may be fixed to and held by the second plunger  8   a.    
     Next, the assembled first solenoid  7  and second solenoid  8  are disposed between the first fixing unit  5   d  and the two second fixing units  5   e  of the movable shade  5 . A bolt  14  is inserted into the mounting hole  5   j  of the first fixing unit  5   d , and if the bolt  14  is threadedly inserted into the mounting hole  7   d  of the first plunger  7   a , the first fixing unit  5   d  of the movable shade  5  and the first plunger  7   a , that is, the movable shade  5  can be fixed to the first solenoid  7 . The movable shade  5 , the first solenoid  7 , and the second solenoid  8  are fixed by the holder  9  by the screw  15  through the mounting hole  5   l  of the second fixing units  5   e  of the movable shade  5  and the fixing hole  7   e  of the first solenoid  7 . With the above operation, the assembling of the movable shade  5 , the first solenoid  7 , and the second solenoid  8  is completed as illustrated in FIG.  5 . At that time, the leaf spring  5   c  as the elastic returning unit which is integral with the movable shade  5  is disposed while avoiding the first solenoid  7  and the second solenoid  8 . 
     After the assembling is completed, when the first solenoid  7  and the second solenoid  8  are not energized, the first plunger  7   a  and the second plunger  8   a  are free. Since the second fixing units  5   e  are fixed to the holder  9 , the first fixing unit  5   d  is biased upward by elastic force of the two leaf springs  5   c  together with the two movable shade bodies  5   a  and  5   b , the first plunger  7   a , the connecting plate  11   b , and the second plunger  8   a . The upward biasing motions of the first fixing unit  5   d , the two movable shade bodies  5   a  and  5   b , the first plunger  7   a , the connecting plate  11   b , and the second plunger  8   a  are limited by the stopper function of the shade unit  6   a.    
     As a result, the two movable shade bodies  5   a  and  5   b  are located in the first position. The edges  5   f  and  5   h  of the two movable shade bodies  5   a  and  5   b  of the movable shade  5  are disposed near the second focus F 2  by the elastic force of the two leaf springs  5   c . The one end  11   c  of the connecting plate  11   b  of the connecting mechanism  11  abuts against one end surface  11   e  of the trench  11   a  of the first plunger  7   a  (the lower end surface lie closer to a direction in which the movable shade  5  is switched from the first position to the second position or the third position). The first plunger  7   a  has a gap corresponding to a length h 1  between the lower end surface of the first plunger  7   a  and an upper surface of a bottom of the solenoid yoke  7   c . The second plunger  8   a  has a gap corresponding to a length h 2  between the lower end surface of the second plunger  8   a  and an upper surface of a bottom of the solenoid yoke  8   c.    
     Light distribution patterns illustrated in  FIG. 8A ,  FIG. 8B , and  FIG. 8C  are projected on a screen located forwardly away from the headlamp  1  by 1 meter to 25 meters. The HL-HR indicates a lateral horizontal line of the screen, and the VU-VD indicates a vertical line of the screen.  FIG. 6A  to  FIG. 7C  are schematics for illustrating operation of the headlamp  1 . H 2  and h 3  may be different from actual lengths. 
     When the coil  7   b  of the first solenoid  7  and the coil  8   b  of the second solenoid  8  are not energized, the two movable shade bodies  5   a  and  5   b  are located in the first position as illustrated in FIG.  6 A and  FIG. 7A  by the elastic forces of the two leaf springs  5   c  and the stopper function of the shade unit  6   a , and they are not deviated from the first position by vibration of the vehicle. The light source  2  comes ON by supplying electricity to the ballast (not shown). Light from the light source  2  staying illuminated is reflected by the reflector  3 . At that time, a portion of the reflection light from the reflector  3  is shielded by the shade unit  6   a  of the fixed shade  6 . 
     Remaining reflection light from the reflector  3  passes near the second focus F 2 . A portion of the reflection light passing near the second focus F 2  is shielded by the two movable shade bodies  5   a  and  5   b . Reflection light which is not shielded by the two movable shade bodies  5   a  and  5   b  is emitted outside of the headlamp  1  through the projection lens  4 . By the reflection light emitted outside of the headlamp  1 , a predetermined low-beam light distribution pattern LP (first light distribution pattern) as illustrated in  FIG. 8A  can be obtained. The low-beam light distribution pattern LP includes a terminator LP 1  for limiting dizzy light. This LP 1  includes a horizontal line portion LP 2  which does not give dizzy light to an oncoming car, a horizontal line portion LP 4  which does not give dizzy light to the oncoming car and which allows a driver to visually identify a road shoulder pedestrian, and a gently inclining portion LP 3  connecting the LP 2  and LP 3  to each other. The terminator LP 1  is formed by shielding reflection light from the reflector  3  by the edges  5   f  and  5   h  of the two movable shade bodies  5   a  and  5   b . The horizontal line portion LP 2  is inclined downward at an angle of about 0.5° with respect to the lateral horizontal line (HL-HR) of the screen. 
     Next, the coil  8   b  of the second solenoid  8  is energized, by which the second plunger  8   a  starts moving in the direction of arrow C by a magnetic force generated from the coil  8   b  as illustrated in FIG.  6 B and FIG.  7 B. That is, an attraction force for attracting the second plunger  8   a  is generated in the second solenoid  8 , and this attraction force is stronger than the elastic force of the leaf spring  5   c  of the movable shade  5  and the second plunger  8   a  moves in the direction of arrow C. When this second plunger  8   a  moves in the direction of arrow C, the connecting plate  11   b  of the connecting mechanism  11  also moves in the direction of arrow C. At that time, since the coil  7   b  of the first solenoid  7  is not energized, the connecting plate  11   b  which is in abutment against the lower end surface  11   e  of the trench  11   a  of the first plunger  7   a  moves in the direction of arrow C, and the first plunger  7   a  also moves in the direction of arrow C. 
     If the second plunger  8   a  of the second solenoid  8  moves (strokes) to the terminal end, that is, until a lower surface of the second plunger  8   a  abuts against the upper surface of the bottom of the solenoid yoke  8   c , the two movable shade bodies  5   a  and  5   b  are moved and switched to the third position. Since the stroke amount of the second plunger  8   a  is h 2 , the two movable shade bodies  5   a  and  5   b  move to the third position which corresponds to h 2  from the first position. If the two movable shade bodies  5   a  and  5   b  move to the third position, since the stroke amount of the second plunger  8   a  becomes maximum, the two movable shade bodies  5   a  and  5   b  can not further move in the direction of arrow C from the positions illustrated in FIG.  6 B and  FIG. 7B  depending on the attraction force of the second solenoid  8 . 
     Since the coil  7   b  of the first solenoid  7  is not energized, the attraction force or holding force is not generated in the first solenoid  7 . The attraction force of the second solenoid  8  exhibited when the two movable shade bodies  5   a  and  5   b  move to the third position is greater than the elastic force of the leaf spring  5   c  of the movable shade  5 . Therefore, the two movable shade bodies  5   a  and  5   b  can stop at the third position by keeping the energization of the coil  8   b  of the second solenoid  8 . 
     The light source  2  comes ON by supplying the electricity to the ballast (not shown). Light from the illuminated light source  2  is reflected by the reflector  3 . At that time, a portion of the reflection light from the reflector  3  is shielded by the shade unit  6   a  of the fixed shade  6 . Remaining reflection light from the reflector  3  passes near the second focus F 2 . A portion of the reflection light passing near the second focus F 2  is shielded by the two movable shade bodies  5   a  and  5   b  which stop in the third position. Reflection light that is not shielded by the two movable shade bodies  5   a  and  5   b  is emitted outside of the headlamp  1  through the projection lens  4 . By the reflection light emitted outside of the headlamp  1 , a predetermined motorway light distribution pattern MP (third light distribution pattern) as illustrated in  FIG. 8B  can be obtained. 
     The light distribution pattern MP includes a terminator MP 1 . A configuration of the terminator MP 1  is the same as that of the terminator LP 1  of the low-beam light distribution pattern LP. The terminator MP 1  is different from the terminator LP 1  in that the terminator MP 1  is located higher than the terminator LP 1 , that is, higher than HL-HR. With this configuration, the light distribution pattern MP can limit, to some extent, dizzy light with respect to a driver of an oncoming car while enhancing the visibility of a driver of a vehicle at the time of high speed traveling. A portion of the terminator MP 1  corresponding to the horizontal line portion LP 2  of the terminator LP 1  is inclined in a range of about 0.56 degree downward to 0 degree with respect to the lateral horizontal line (HL-HR) of the screen. 
     When the coil  7   b  of the first solenoid  7  is energized, the first plunger  7   a  moves in a direction of arrow B by a magnetic force generated from the coil  7   b  as illustrated in FIG.  6 B. That is, attraction force for attracting the first plunger  7   a  is generated in the first solenoid  7 , and the movable shade  5  mounted on the first plunger  7   a  starts moving further downward in the direction of arrow B from the states illustrated in FIG.  6 B and FIG.  7 B. The leaf spring  5   c  provided between the first fixing unit  5   d  of the movable shade  5  and the two second fixing units  5   e  is further bent and the elastic force is further increased. Since the second plunger  8   a  of the second solenoid  8  is located at a terminal end of the stroke, the connecting plate  11   b  of the connecting mechanism  11  is not moved downward from the position illustrated in FIG.  6 B. 
     Thus, if the first plunger  7   a  starts moving in the direction of arrow B, the one end  11   c  of the connecting plate  11   b  is separated from the lower end surface  11   e  of the trench  11   a  and moves in the trench  11   a . With this, the attraction force and holding force generated in the second solenoid  8  do not affect the attraction force of the first solenoid  7  when the movable shade  5  moves from the third position to the second position, that is, the high-beam position. 
     If the first plunger  7   a  of the first solenoid  7  moves (strokes) to the terminal end, that is, until a lower surface of the first plunger  7   a  abuts against the upper surface of the bottom of the solenoid yoke  7   c , the two movable shade bodies  5   a  and  5   b  are moved and switched to the second position. Since the stroke amount of the first plunger  7   a  is h 1  (h 1 =h 2 +h 4 ), the one end  11   c  of the connecting plate  11   b  of the connecting mechanism  11  abuts against the upper end surface lid of the trench  11   a . If the two movable shade bodies  5   a  and  5   b  move to the second position, since the stroke amount of the first plunger  7   a  becomes maximum, the movable shade  5  can not further move in the direction of arrow B from the positions illustrated in FIG.  6 C and  FIG. 7C  depending on the attraction force of the first solenoid  7 . 
     Since the one end  11   c  of the connecting plate  11   b  abuts against the upper end surface  11   d  of the trench  11   a  in a state in which the stroke amount of the second plunger  8   a  is maximum, the movable shade  5  can not further move in the direction of arrow B. The attraction force of the first solenoid  7  exhibited when the two movable shade bodies  5   a  and  5   b  move to the second position is greater than the elastic force of the leaf spring  5   c  of the movable shade  5 . Therefore, the two movable shade bodies  5   a  and  5   b  can stop at the second position by keeping the energization of the coil  7   b  of the first solenoid  7 . 
     The light source  2  comes ON by supplying the electricity to the ballast (not shown). Light from the illuminated light source  2  is reflected by the reflector  3 . At that time, a portion of the reflection light from the reflector  3  is shielded by the shade unit  6   a  of the fixed shade  6 . Remaining reflection light from the reflector  3  passes near the second focus F 2 . A slight portion of the reflection light passing near the second focus F 2  is shielded by the two movable shade bodies  5   a  and  5   b  which stop in the third position. Most of reflection light which is not shielded by the two movable shade bodies  5   a  and  5   b  is emitted outside of the headlamp  1  through-the projection lens. By the reflection light emitted outside of the headlamp  1 , a predetermined high-beam light distribution pattern HP as illustrated in  FIG. 8C  can be obtained. In this light distribution pattern HP, a maximum luminous intensity value and a maximum luminous intensity band are taken into consideration, and this light distribution pattern is suitable when the number of oncoming cars is small at the time of high speed traveling. 
     When the two movable shade bodies  5   a  and  5   b  stop at the second position, the leaf springs  5   c  of the movable shade  5  are most bent as illustrated in FIG.  7 C. In this state, if the energization of the coil  7   b  of the first solenoid  7  is stopped, the movable shade  5  tries to return to the third position or the first position in the direction of arrow D as illustrated in  FIG. 6C  by the elastic force of the leaf springs  5   c . At that time, the one end of the connecting plate  11   b  which is in abutment against the upper end surface  11   d  of the trench  11   a  of the first plunger  7   a  again abuts against the lower end surface  11   e  illustrated in  FIG. 6B  because the first plunger  7   a  upwardly moves in the direction of arrow D. 
     If the coil  8   b  of the second solenoid  8  is kept energized, the holding force is generated in the second solenoid  8 . Since this holding force is stronger than the elastic force of the leaf springs  5   c , the two movable shade bodies  5   a  and  5   b  return to the third position from the second position and stop at the intermediate position. 
     If the energization of the coil  8   b  of the second solenoid  8  is stopped in the state in which the two movable shade bodies  5   a  and  5   b  return to the third position and stop, as illustrated in  FIG. 7B , since the leaf springs  5   c  of the movable shade  5  are still bent, the first plunger  7   a  and thus the movable shade  5  tries to further return to the first position by the elastic force of the leaf springs  5   c . At that time, since the attraction force and holding force are not generated in the second solenoid  8 , the two movable shade bodies  5   a  and  5   b  can return to the first position. When the two movable shade bodies  5   a  and  5   b  mounted on the first plunger  7   a  are moved from the third position to the first position by the elastic force of the leaf springs  5   c  which are elastic units, since the one end  11   c  of the connecting plate  11   b  remains in abutment against the lower end surface  11   e  of the trench  11   a , the second plunger  8   a  also moves (strokes) from the terminal end to the start end. 
     In the explanation of operation of the headlamp  1 , the two movable shade bodies  5   a  and  5   b  are moved from the first position to the third position and from the third position to the second position. Alternatively, by energizing the coil  7   b  of the first solenoid  7  in a state in which the two movable shade bodies  5   a  and  5   b  stop at the first position, the two movable shade bodies  5   a  and  5   b  may be allowed to move directly to the second position without stopping at the third position. In the explanation of operation of the headlamp  1  in the embodiment, the two movable shade bodies  5   a  and  5   b  returned from the second position to the third position and from the third position to the first position. Alternatively, by stopping the energization of the coil  7   b  of the first solenoid  7  while by not previously energizing the coil  8   b  of the second solenoid  8  or by stopping the energization of the coil  8   b  in the state in which the two movable shade bodies  5   a  and  5   b  stop at the second position, the two movable shade bodies  5   a  and  5   b  may be returned to the first position directly. 
     According to the present embodiment, three different light distribution patterns can be obtained from a single light source with a high switching speed. 
     According to the present embodiment, the light distribution pattern can reliably and swiftly be switched. 
     According to the present embodiment, a required space can be reduced. 
     According to the present embodiment, assembling time of the headlamp and its production cost can further be reduced. 
     According to the present embodiment, it is possible to reduce an abutment noise between parts of the headlamp. 
     In the present embodiment, the length h 4  obtained by subtracting the thickness h 3  of the connecting plate  11   b  from the height of the trench  11   a  is set longer than the stroke amount h 2  of the second plunger  8   a . The present invention is not limited to this configuration. For example, h 2  and h 4  may be the same, and a distance through which the two movable shade bodies  5   a  and  5   b  move from the first position to the third position and a distance through which the bodies  5   a  and  5   b  move from the third position to the second position may be the same. This is because an obtained intermediate light distribution pattern differs depending on the third position where the two movable shade bodies  5   a  and  5   b  stop and thus, it is necessary to change the lengths of h 2  and h 4  depending on a desired intermediate light distribution pattern. 
     Although the invention has been described with respect to a specific embodiment for a complete and clear disclosure, the appended claims are not to be thus limited but are to be construed as embodying all modifications and alternative constructions that may occur to one skilled in the art which fairly fall within the basic teaching herein set forth.