JP7327261B2 - virtual image display - Google Patents

Description

The present disclosure relates to displaying virtual images.

Conventionally, a virtual image display device configured to be mounted on a vehicle displays a virtual image by projecting display light onto a projection unit. For example, in the virtual image display device disclosed in Patent Literature 1, the rotating reflector changes the reflection direction of the display light directed from the reflecting surface to the projection unit by rotating the rotating shaft of the rotating reflector.

In the virtual image display device disclosed in Patent Document 1, a pair of rotating shafts provided on both outer sides of the rotating reflector across the reflecting surface in the axial direction are urged radially by individual elastic members. In addition, it is radially bearing-supported by a separate support member from the side opposite to the elastic member.

JP 2019-78966 A

In the virtual image display device disclosed in Patent Literature 1, one of the rotating shafts is restricted from moving relative to one side in the axial direction by urging the spherical portion, which is radially bearing, from one side in the axial direction by an elastic member. ing. On the other hand, the other rotating shaft is thrust-beared on the root side of the spherical portion, which is radially supported, so that the one rotating shaft moves relative to the side urged by the elastic member, that is, in the opposite axial direction. Relative movement to the side is restricted. This means that the restoring force of the elastic member that biases one rotating shaft propagates to the other rotating shaft via the reflecting surface. As a result, there is a risk of display distortion due to stress deformation of the reflective surface.

Here, in the support member of the virtual image display device disclosed in Patent Literature 1, the concave portion that radially bears the spherical portion of the rotating shaft does not contribute to the thrust bearing. In order to prevent interference between the opening edges of the recesses on both axial sides of the spherical portion of the rotating shaft that is thrust-bearing, it is assumed that the spherical portion and the supporting member will be enlarged.

An object of the present disclosure is to provide a virtual image display device that achieves both display distortion suppression and miniaturization.

Technical means of the present disclosure for solving the problems will be described below. It should be noted that the symbols in parentheses described in the claims and this column indicate the correspondence with specific means described in the embodiments described in detail later, and limit the technical scope of the present disclosure. not something to do.

This disclosure is
A virtual image display device (100) configured to be mounted on a vehicle (1) and displaying a virtual image (VRI) by projecting display light onto a projection unit (3a),
a rotating reflecting mirror (40) having a rotating shaft (44R) axially outside the reflecting surface (41a) and changing the reflection direction of display light from the reflecting surface toward the projection unit by rotating the rotating shaft;
an elastic member ( 51R ) that urges the rotating shaft with a restoring force along the line of action (LR) in the radial direction;
a bearing portion (61R) for thrust-bearing the rotating shaft from the opposite side of the radial elastic member and restricting relative movement of the rotating shaft to both sides in the axial direction;
The axis of rotation is
an extending portion (46R) extending in the axial direction and forming a recessed portion (46Rd) on the bearing portion side in the radial direction;
a projecting portion (47R) projecting in a partially spherical shape from the extending portion into the recessed portion;
The bearing is
Bearing recesses (61Rc) that bear the projection and that are located on both sides of the projection in the axial direction with the opening edge (61Ro) recessed into the recess ,
The extension presents in cross section a partial circular shape centered on the rotation axis (A1) of the rotation axis with a central angle (φ1) of less than 180°.

In the rotating shaft of the present disclosure, the protruding portion protrudes in a partially spherical shape from the extending portion extending in the axial direction into the concave portion formed on the bearing portion side in the radial direction. Therefore, in the bearing portion that thrust-beares the projecting portion from the side opposite to the elastic member in the radial direction, the opening edge of the bearing recess is recessed into the recess and positioned on both sides of the projecting portion in the axial direction. According to this, in the rotary shaft which is urged on the outer side of the reflection surface in the axial direction by the restoring force of the elastic member whose line of action extends in the radial direction, the protruding portions formed with as small a diameter as possible are thrust-beared from both sides in the axial direction. By doing so, the relative movement to both sides in the axial direction can be restricted. Therefore, it is possible to reduce the size of the bearing portion and suppress the display distortion due to the stress deformation of the reflecting surface caused by the biasing force from the elastic member.

1 is a configuration diagram showing a mounted state of a virtual image display device in a vehicle according to one embodiment; FIG. 1 is a configuration diagram showing the basic configuration of a virtual image display device according to one embodiment; FIG. 1 is a perspective view showing components of a virtual image display device according to one embodiment; FIG. FIG. 4 is an exploded view showing a rotating reflector of a virtual image display device according to one embodiment; FIG. 4 is a rear view showing a rotating reflector of the virtual image display device according to one embodiment; 1 is an enlarged perspective view showing constituent elements of a virtual image display device according to an embodiment; FIG. 1 is a partial cross-sectional front view showing enlarged components of a virtual image display device according to an embodiment; FIG. FIG. 2 is an enlarged rear view showing constituent elements of the virtual image display device according to the embodiment; 1 is a cross-sectional view showing enlarged components of a virtual image display device according to an embodiment; FIG. 1 is an enlarged side view showing components of a virtual image display device according to an embodiment; FIG. FIG. 4 is an enlarged perspective view showing the first bearing portion of the virtual image display device according to the embodiment; FIG. 4 is a top view showing an enlarged first bearing portion of the virtual image display device according to one embodiment; FIG. 4 is a schematic diagram for explaining the bearing structure in the first bearing portion of the virtual image display device according to one embodiment; FIG. 4 is a schematic diagram for explaining the bearing structure in the first bearing portion of the virtual image display device according to one embodiment; 1 is an enlarged perspective view showing constituent elements of a virtual image display device according to an embodiment; FIG. 1 is a cross-sectional view showing enlarged components of a virtual image display device according to an embodiment; FIG. 1 is an enlarged side view showing components of a virtual image display device according to an embodiment; FIG. FIG. 4 is an enlarged perspective view of the second bearing portion of the virtual image display device according to the embodiment; FIG. 4 is a top view showing an enlarged second bearing portion of the virtual image display device according to the embodiment; FIG. 11 is a schematic diagram for explaining a bearing structure in a first bearing portion of a virtual image display device according to a modification; FIG. 11 is a schematic diagram for explaining a bearing structure in a first bearing portion of a virtual image display device according to a modification; FIG. 11 is a schematic diagram for explaining a bearing structure in a first bearing portion of a virtual image display device according to a modification; FIG. 11 is a schematic diagram for explaining a bearing structure in a first bearing portion of a virtual image display device according to a modification; FIG. 11 is a schematic diagram for explaining a bearing structure in a first bearing portion of a virtual image display device according to a modification; FIG. 11 is a schematic diagram for explaining a bearing structure in a first bearing portion of a virtual image display device according to a modification; FIG. 11 is a schematic diagram for explaining a bearing structure in a first bearing portion of a virtual image display device according to a modification;

An embodiment will be described below with reference to the drawings.

(basic configuration)
First, the basic configuration of the virtual image display device according to one embodiment will be described. As shown in FIGS. 1 and 2 , the virtual image display device is a head-up display (hereinafter referred to as HUD) 100 configured to be mounted on a vehicle 1 and housed within an instrument panel 2 of the vehicle 1 . Here, the vehicle 1 is understood in a broad sense to include various vehicles such as automobiles, railroad vehicles, aircraft, ships, and non-moving game cabinets. Especially the vehicle 1 of this embodiment is a four-wheeled automobile here. In the following description, front, rear, up, down, left, and right directions are indicated with reference to the vehicle 1, which is a four-wheeled vehicle on the horizontal plane HP.

The HUD 100 projects display light of an image toward a projection unit 3 a provided on the windshield 3 of the vehicle 1 . As a result, the display light reflected by the projection unit 3 a reaches the visible area EB set in the interior of the vehicle 1 . An occupant whose eyepoint EP is positioned in the visual recognition area EB by sitting on the seat 4 arranged to face the instrument panel 2 perceives the display light reaching the visual recognition area EB as a virtual image VRI. In this manner, the HUD 100 displays a virtual image VRI that can be visually recognized by the occupant of the vehicle 1, thereby allowing the occupant to recognize various information displayed as the virtual image VRI. Various types of information displayed as a virtual image by the HUD 100 include, for example, information indicating the state of the vehicle 1 such as vehicle speed and remaining amount of fuel, visibility assistance information, road information, navigation information, and the like.

The windshield 3 of the vehicle 1 is made of glass, synthetic resin, or the like, and is formed in a translucent plate shape, and is arranged above the instrument panel 2 . The windshield 3 is slanted away from the instrument panel 2 from the front toward the rear. The windshield 3 forms a projection portion 3a onto which image display light is projected from the HUD 100 in a smooth concave or planar shape. The projection part 3a may not be provided on the windshield 3. For example, a combiner that is separate from the vehicle 1 may be installed in the vehicle 1 and the combiner may be provided with the projection unit 3a.

The visual recognition area EB is a spatial area that can be visually recognized by the occupants of the vehicle 1 when the virtual image VRI displayed by the HUD 100 satisfies a predetermined standard (for example, the entire virtual image VRI has a predetermined brightness or more). Also called an eyebox. The visual recognition area EB is typically set so as to overlap the eyelip set on the vehicle 1 . The eyelip is set in a virtual ellipsoidal shape based on an eye range that statistically represents the spatial distribution of eye points EP of the occupant in the interior of the vehicle 1 .

The HUD 100 comprises a housing 10, a display 20, a fixed mirror 30, a rotating reflector 40, a biasing unit 50, a support unit 60, an actuator 70, and a control unit 80, as shown in FIGS.

A housing 10 shown in FIGS. 1 and 2 has a hollow box shape that accommodates other elements of the HUD 100 and is installed within the instrument panel 2 of the vehicle 1 . The housing 10 has a window portion 11 above the projection portion 3a. The window 11 may be physically opened, or may be covered with a dustproof sheet capable of transmitting display light.

The display 20 shown in FIG. 2 is, for example, a transmissive liquid crystal display. The display device 20 is formed by housing a liquid crystal panel and a backlight in a casing. The display device 20 projects display light that contributes to display by transmissively illuminating a screen 21 of a liquid crystal panel with a backlight. As the display 20, for example, a reflective liquid crystal system, a micro LED system in which self-emitting micro LEDs are arranged, a laser scanner system, and a DLP (Digital Light Processing; registered trademark) system using a DMD (Digital Micromirror Device). Various display devices, such as, may be adopted. The screen 21 of the display device 20 emits display light upward, for example, by facing upward.

The fixed mirror 30 and the rotary reflecting mirror 40 are reflecting mirrors that reflect the display light emitted from the display device 20 to the projection unit 3a. The fixed mirror 30 is made of synthetic resin, glass, or the like, and is shaped like a rectangular plate. The fixed mirror 30 has a reflective surface 31 formed on its surface by, for example, depositing a reflective film of aluminum. As the fixed mirror 30, a flat mirror having a smooth flat reflecting surface 31, a convex mirror having a smooth convex reflecting surface 31, or the like is adopted. The fixed mirror 30 is positioned above the display device 20 and directs the reflecting surface 31 forward and downward in an oblique direction. The display light incident on the fixed mirror 30 from the display device 20 is reflected by the reflecting surface 31 toward the rotary reflecting mirror 40 .

As shown in FIG. 3, the rotating reflector 40 includes a reflector 41 and a holder 42 . The reflector 41 is made of, for example, synthetic resin or glass, and is formed into a rectangular plate shape. The reflector 41 has a reflective surface 41a formed by depositing a reflective film of aluminum on its surface. As the rotary reflecting mirror 40, for example, a concave mirror having a smooth concave reflecting surface 41a is employed. As shown in FIG. 2, the rotary reflecting mirror 40 is positioned in front of the indicator 20 and the fixed mirror 30, and the reflecting surface 41a is oriented obliquely upward and rearward.

The display light incident on the rotary reflecting mirror 40 from the fixed mirror 30 is reflected by the reflecting surface 41a upward toward the projection unit 3a. It is possible to magnify the virtual image VRI by reflection on the concave reflecting surface 41a having a concave central portion. Furthermore, the distortion of the enlarged virtual image VRI can be reduced by forming the reflecting surface 41a into a free-form surface.

The display light reflected by the reflecting surface 41a of the rotary reflecting mirror 40 passes through the window 11 as shown in FIGS. Incident. As a result, the display light reflected by the projection unit 3a reaches the occupant's eye point EP, so that the occupant can visually recognize the virtual image VRI.

As shown in FIGS. 3-5, holder 42 holds and protects reflector 41 . The holder 42 is made of, for example, synthetic resin or metal, and has a holding frame 43 , a holding base 49 , a pair of rotating shafts 44 R and 44 L, and a drive transmission shaft 48 . Of these, the holding base 49, the rotating shafts 44R and 44L, and the drive transmission shaft 48 are integrally formed as a single component and fastened to the holding frame 43 with screws.

The holding frame 43 is formed in a rectangular frame shape that surrounds the entire periphery of the reflector 41 so that the reflecting surface 41 a is exposed to the outside of the rotary reflecting mirror 40 . The holding base 49 is arranged on the back side of the reflector 41 with the reflecting surface 41a exposed facing the front side, so as to sandwich the reflector 41 with an insertion member, and reinforce the reflector 41 from the back side. It is formed in a rectangular plate shape.

In the rotary reflecting mirror 40, a pair of rotating shafts 44R and 44L are provided coaxially with each other on both sides of the reflecting surface 41a in the axial direction. Each of the rotating shafts 44R and 44L protrudes from the holding base 49 to opposite sides, which are the left and right outer sides of the reflecting surface 41a in the axial direction. Each rotating shaft 44R, 44L is supported by a support unit 60 at individual support points. By being supported by these support points, the rotating shafts 44R and 44L are integrated with each other and also with other elements of the rotating reflecting mirror 40, and are rotatable around a common centerline of rotation A1. The rotation of the rotating shafts 44R and 44L integrally changes the orientation of the reflecting surface 41a, thereby changing the direction in which the display light is reflected from the reflecting surface 41a toward the projection unit 3a.

As indicated by the solid line in FIG. 2, when the reflecting surface 41a faces upward (that is, when the rotating reflecting mirror 40 is tilted), the direction in which the display light is reflected toward the projection unit 3a and the projection of the display light on the projection unit 3a also increases. As the position shifts further forward, the display position of the virtual image VRI moves upward. Accordingly, the position of the visible area EB moves downward. On the other hand, as shown by the dashed line in FIG. 2, when the reflecting surface 41a faces downward (that is, when the rotary reflecting mirror 40 stands up), the direction of reflection of the display light toward the projection unit 3a and the display on the projection unit 3a change. The display position of the virtual image VRI moves downward as the projection position of the light shifts further rearward. Accordingly, the position of the visible area EB moves upward. As described above, the spatial display condition of the virtual image VRI is changed according to the change in the direction of the reflecting surface 41a.

The drive transmission shaft 48 shown in FIGS. 3 and 5 converts the drive force (for example, tensile force) from the actuator 70 into force in the rotational direction with respect to the rotary shafts 44R and 44L, and transmits the force to the rotary reflecting mirror 40. FIG. For this reason, in the rotary reflecting mirror 40, the drive transmission shaft 48 protrudes from the holding base 49 in the shape of a regular cylinder to the right, which is the axially outer side of the reflecting surface 41a. A cylinder centerline of the drive transmission shaft 48 is set as an eccentric line A2 substantially parallel to the rotation centerline A1 of the rotary shafts 44R and 44L. As shown in FIGS. 6 to 8, the drive transmission shaft 48 is provided with an extension groove 48a. The extension groove 48a is recessed radially inward from the cylindrical surface of the drive transmission shaft 48 with respect to the eccentric line A2. The extension groove 48a is formed in a V-shaped groove curved and extended around the eccentric line A2.

As shown in FIGS. 3 to 5, the biasing unit 50 includes elastic members 51R, 51L, and 57. As shown in FIG. The elastic members 51R, 51L, and 57 are each made of metal, for example.

A pair of elastic members 51R and 51L are arranged on both axial sides of the elements 41, 43 and 49 of the rotary reflecting mirror 40 on both sides. Each of the elastic members 51R and 51L is a metal compression coil spring. One end of each of the elastic members 51R and 51L is held by the housing 10 (see FIGS. 9 and 16 described later) via a support unit 60. As shown in FIG. The other ends of the elastic members 51R and 51L are located above the rotating shafts 44R and 44L on the same side of the rotating reflecting mirror 40 (i.e., on the alphabetical side with the same suffix). are in contact with Under such holding and contacting conditions, the elastic members 51R and 51L exert a restoring force on the corresponding rotating shafts 44R and 44L, thereby urging the corresponding rotating shafts 44R and 44L in the radial direction. there is

An elastic member 57 different from these elastic members 51R and 51L is arranged on the right side of the elements 41, 43 and 49 in the rotary reflecting mirror 40, on the outside in the axial direction. The elastic member 57 is a metal torsion coil spring. One end of each elastic member 51R, 51L is held by the housing 10. As shown in FIG. The other ends of the elastic members 51R and 51L are connected to the holding base 49 of the rotary reflecting mirror 40. As shown in FIG. Under such holding and connection, the elastic member 57 exerts a restoring force on the holding base 49, thereby urging the rotary reflecting mirror 40 in the rotation direction of the rotary shafts 44R and 44L.

As shown in FIG. 5, the support unit 60 includes bearing portions 61R, 61L and holding portions 62R, 62L. The bearing portions 61R, 61L and the clamping portions 62R, 62L are made of, for example, synthetic resin or metal.

The pair of bearings 61R, 61L are arranged on both sides in the axial direction, sandwiching the elements 41, 43, 49 of the rotary reflecting mirror 40 on the left and right sides. The bearings 61R and 61L are individually fixed to the separate housing 10 (see FIGS. 9 and 16). Each of the bearings 61R and 61L bears the rotation shafts 44R and 44L on the same side (that is, on the alphabetical side where the symbols have the same suffix) among left and right common to the support unit 60 and the rotary reflecting mirror 40 . The bearing portions of these bearing portions 61R and 61L constitute support points that rotatably support the corresponding rotary shafts 44R and 44L. At least one of the bearings 61R and 61L may be integrally formed with the housing 10. As shown in FIG.

The pair of clamping portions 62R and 62L are arranged on both sides in the axial direction sandwiching the elements 41, 43 and 49 of the rotary reflecting mirror 40 on the left and right sides. The clamping portions 62R and 62L are assembled via the housing 10 to the bearing portions 61R and 61L on the same side of the support unit 60 (that is, on the same alphabetical side). The clamping portions 62R and 62L are linked to elastic members 51R and 51L corresponding to the rotating shafts 44R and 44L on the same side (that is, on the alphabetical side where the symbols have the same suffix) among the left and right sides of the rotary reflecting mirror 40. . Under such assembly and connection, the clamping portions 62R and 62L further clamp the corresponding elastic members 51R and 51L between the corresponding rotating shafts 44R and 44L.

As shown in FIGS. 2 and 3, the actuator 70 includes an electric motor 71, a motion converting mechanism 72, a connecting arm 73, and the like. The electric motor 71 is, for example, a stepping motor. The electric motor 71 rotates the motor shaft by the amount of rotation according to the electric signal input from the control unit 80 . The motion conversion mechanism 72 converts rotary motion of the motor shaft into reciprocating linear motion.

The connecting arm 73 is made of synthetic resin, for example, and has a rod shape that connects the motion conversion mechanism 72 with the drive transmission shaft 48 of the rotary reflecting mirror 40 . As shown in FIGS. 6 and 8, on the drive transmission shaft 48 side of the connecting arm 73, bifurcated contact portions 75a and 75b are formed in a partially spherical shape, respectively. These contact portions 75a and 75b are fitted into the extension groove 48a so as to sandwich the drive transmission shaft 48 therebetween. Such fitting causes the actuator 70 to link the connecting arm 73 with the drive transmission shaft 48 of the rotary reflecting mirror 40 .

The motion conversion mechanism 72 converts the amount of rotation of the motor shaft by the electric motor 71, and the connecting arm 73 is pulled by the amount of linear movement resulting from the conversion. In conjunction with this, the pair of contact portions 75a and 75b pull the entire drive transmission shaft 48 while sliding on the extension groove 48a around the eccentric line A2 while sandwiching the drive transmission shaft 48 therebetween. By pulling the drive transmission shaft 48 toward the connecting arm 73 side, the rotary reflecting mirror 40 is driven in the rotational direction. With the above structure, even if the mounting angle of the connecting arm 73 has an error with respect to the vertical angle with respect to the eccentric line A2, the rotary reflecting mirror 40 can be smoothly rotated.

Actuator 70 thus generates a driving force for driving rotary reflecting mirror 40 in the rotational direction. As a result, the orientation of the reflecting surface 41 a of the rotary reflecting mirror 40 is determined according to the balance between the driving force of the actuator 70 and the restoring force of the elastic member 57 .

As shown in FIG. 2, the control unit 80 includes an adjustment switch 81, a control circuit section 82, and the like. The adjustment switch 81 is installed, for example, on a steering handle of the vehicle 1 so as to be operable by the passenger outside the housing 10 . The adjustment switch 81 has two types of push-type operating members 81a and 81b. The up operation member 81a is operated to move the display position of the virtual image VRI upward. The down operation member 81b is operated to move the display position of the virtual image VRI downward. The control circuit unit 82 controls signals to be output to the electric motor 71 for rotating the rotary reflecting mirror 40 based on signals input from the adjustment switch 81 in accordance with the operation of the operation members 81a and 81b. . The allowable rotation angle range of the rotary reflecting mirror 40 is defined so as to correspond to the interval between the upper limit display position and the lower limit display position of the virtual image VRI adjusted by the control of the control circuit section 82 .

(Detailed configuration)
Next, the detailed configuration of the elements 40, 50, 60 will be described. In the following description, the rotating shafts 44R and 44L are referred to as a first rotating shaft 44R and a second rotating shaft 44L, respectively. Moreover, in the following description, the bearing portions 61R and 61L are denoted by a first bearing portion 61R and a second bearing portion 61L, respectively. Furthermore, in the following description, the clamping portions 62R and 62L will be referred to as a first clamping portion 62R and a second clamping portion 62L, respectively. Furthermore, in the following description, the elastic members 51R, 51L, 57 are denoted as a first elastic member 51R, a second elastic member 51L, and a third elastic member 57, respectively.

As shown in FIGS. 6 to 10, the first rotating shaft 44R of the rotary reflecting mirror 40 has a root portion 45R, an extension portion 46R and a projection portion 47R. The root portion 45R, the extension portion 46R and the projection portion 47R are integrally formed.

The root portion 45R extends axially outward from the holding base 49 in the rotary reflecting mirror 40, thereby constituting the root of the overhang of the first rotating shaft 44R. The root portion 45R is formed in a regular cylindrical shape aligned with the rotation center line A1 of the first rotating shaft 44R.

The extending portion 46R extends axially outward from the root portion 45R of the rotary reflecting mirror 40, thereby constituting the tip portion of the first rotating shaft 44R. The extending portion 46R is formed in a partial cylindrical shape aligned with the center line A1 of the first rotating shaft 44R in a cross section perpendicular to the rotation center line A1 (hereinafter simply referred to as a cross section). ing. In this cross section, the extending portion 46R has a partial circular shape coaxial with the root portion 45R and having the same diameter. The extending portion 46R is given an angle larger than the rotation angle range allowed for the rotary reflecting mirror 40 and less than 180° as the central angle ψ1 of the partial circular shape in the cross section. As described above, the partial cylindrical shape of the extension portion 46R is a shape in which the upper portion of the regular cylindrical root portion 45R, which has a central angle ψ1 smaller than that of a semicircle, is extended coaxially and with the same diameter. , it can be said.

The extending portion 46R forms a hollow portion 46Rd in cooperation with the root portion 45R on the side of the first bearing portion 61R in the radial direction where the lower portion of the right cylindrical root portion 45R is not extended. . In the rotary reflecting mirror 40, the protruding portion 47R is provided in the recessed portion 46Rd by protruding from the extending portion 46R toward the first bearing portion 61R in the radial direction. The protruding portion 47R is formed in a partially spherical shape centered in cross section with respect to the rotation center line A1 of the first rotating shaft 44R. The projecting portion 47R presents a partial circular shape with a smaller diameter than the coaxial root portion 45R and extension portion 46R in a cross section passing through the center point of the partial spherical shape. The projecting portion 47R is given an angle of 180° or more, excluding the extending portion 46R, as the central angle ω1 of the partial circular shape in the cross section.

In such a projecting portion 47R, a spherical surface portion 47Rs having a partially spherical shape is formed by a downwardly convex curved surface. On the other hand, the extending portion 46R, which has a diameter larger than that of the protruding portion 47R, forms a cylindrical surface portion 46Rl having a partially cylindrical surface shape with an upwardly convex curved surface. That is, the extending portion 46R is provided with a cylindrical surface portion 46Rl having a larger diameter than the spherical surface portion 47Rs of the projecting portion 47R.

As shown in FIG. 9, the first clamping portion 62R of the support unit 60 has a first fitting portion 62Rm. A pair of first fitting portions 62Rm in the first clamping portion 62R are formed so as to be elastically deformable on both sides sandwiching the first elastic member 51R of the urging unit 50 in the front and rear directions. Each first fitting portion 62Rm is assembled to the first bearing portion 61R side in the radial direction of the first rotating shaft 44R by snap fitting to the housing 10 . In this assembly radial direction, the first elastic member 51R is sandwiched between the extending portion 46R of the first rotating shaft 44R on the side opposite to the protruding portion 47R and the first sandwiching portion 62R, so that the first elastic member 51R is compressed. is elastically deformed. The elastically deformed first elastic member 51R urges the cylindrical surface portion 46Rl of the extending portion 46R from the side opposite to the projecting portion 47R in the radial direction with a restoring force along the line of action LR in the radial direction.

The first holding portion 62R further has a first locking portion 62Rl. The first locking portion 62Rl protrudes into the inner peripheral side of the first elastic member 51R, which is a compression coil spring of the biasing unit 50, along the radial direction of the first rotating shaft 44R. A clearance 62Rc is provided between the tip surface of the first locking portion 62Rl and the cylindrical surface portion 46Rl of the extension portion 46R of the first rotating shaft 44R. The first locking portion 62Rl can lock the extending portion 46R that has moved by the clearance 62Rc toward the side opposite to the first bearing portion 61R in the radial direction.

As shown in FIGS. 6, 7 and 9 to 12, the first bearing portion 61R of the support unit 60 has a first bearing recessed portion 61Rc. The first bearing recessed portion 61Rc is recessed in the opposite direction to the first elastic member 51R with the first rotating shaft 44R sandwiched above and below in the radial direction. That is, the first bearing recessed portion 61Rc is recessed radially opposite to the spherical surface portion 47Rs of the projecting portion 47R of the first rotating shaft 44R. The first bearing portion 61R has a U-shaped groove in a longitudinal section including the rotation center line A1 (hereinafter simply referred to as a longitudinal section). The opening edge portion 61Ro of the first bearing recess portion 61Rc is recessed into the recess portion 46Rd of the first rotating shaft 44R as shown in FIGS. located on both sides.

As shown in FIGS. 6 and 12 to 14, the first bearing recess 61Rc has a plurality of projections 61Rp projecting inward. Two first bearing recesses 61Rc are provided on both inner side surfaces of the U-shaped groove at substantially the same vertical position. The tip end surface of each projection 61Rp has a partially spherical shape. The first bearing recessed portion 61Rc brings the tip surface of each protrusion 61Rp into contact with the spherical surface portion 47Rs of the projecting portion 47R projecting into the recessed portion 46Rd on the first rotating shaft 44R. The first bearing recessed portion 61Rc provides a thrust bearing and a radial bearing for the spherical surface portion 47Rs in contact with each projection 61Rp from the side opposite to the first elastic member 51R in the radial direction, thereby forming a shaft of the rotatable first rotating shaft 44R. It regulates relative movement in both directions. Due to the relative movement restricting function of the first bearing recessed portion 61Rc, the first bearing portion 61R moves the first rotating shaft 44R at the reference point PB, which is a support point on one side in the axial direction, as shown in FIGS. positioning. Here, the reference point PB of this embodiment is defined as the center point on the rotation center line A1 of the spherical portion 47Rs that is supported by the first bearing portion 61R.

As shown in FIGS. 13 and 14, two projections 61Rp of the first bearing recessed portion 61Rc of the first bearing portion 61R contact the spherical portion 47Rs at contact points PC on both axial sides of the first rotating shaft 44R. , a pair of tangential planes TP in contact with the spherical portion 47Rs is assumed. That is, the first bearing recessed portion 61Rc provides a thrust bearing and a radial bearing to the spherical surface portion 47Rs on each tangential plane TP by two protrusions 61Rp. The angle θ between these tangential planes TP and the action line LR of the restoring force acting from the first elastic member 51R to the cylindrical surface portion 46Rl of the extension portion 46R of the first rotating shaft 44R is 0. is set so as to satisfy the following formula 1 in a larger range than
θ≦arcsin(1/√5) Equation 1

As shown in FIGS. 15 to 17, the second rotating shaft 44L of the rotating reflecting mirror 40 has a pair of extensions 46L and 47L. These extending portions 46L and 47L are formed by integral molding.

The urging-side extending portion 46L extends axially outward from the holding base 49 in the rotary reflecting mirror 40, thereby constituting at least the root of the protrusion of the second rotating shaft 44L. The urging side extending portion 46L is formed in a partial columnar shape that is centered in cross section with respect to the rotation center line A1 of the second rotating shaft 44L. In this cross section, the urging side extension 46L has a partial circular shape. The urging side extending portion 46L is given an angle larger than the rotation angle range allowed for the rotary reflecting mirror 40 and less than 180° as the central angle ψ2 of the partial circular shape in the cross section. From the above, it can be said that the partial columnar shape of the urging side extending portion 46L is a shape in which the upper portion of which the central angle ψ2 is smaller than that of a semicircular shape is extended.

The bearing-side extension portion 47L extends axially outward from the holding base 49 in the rotary reflecting mirror 40, thereby forming a portion from the root to the tip of the extension of the second rotation shaft 44L. An extension base portion 47Lb closer to the holding base 49 than the tip portion 47e of the bearing-side extension portion 47L is formed in a partial columnar shape that is centered in cross section with respect to the rotation center line A1 of the second rotation shaft 44L. It is In the cross section of the extension base portion 47Lb, the bearing side extension portion 47L has a partial circular shape with a smaller diameter than the coaxial biasing side extension portion 46L. The extending base portion 47Lb of the bearing-side extending portion 47L is given an angle of 180° or more, excluding the urging-side extending portion 46L, as the central angle ω2 of the partial circle in the cross section.

In the extension base portion 47Lb of the bearing-side extension portion 47L, a bearing-side cylindrical surface portion 47Ls having a partially cylindrical surface shape is formed by a downwardly convex curved surface. On the other hand, in the urging side extension portion 46L, which has a larger diameter than the extension base portion 47Lb of the bearing side extension portion 47L, an urging side cylindrical surface portion 46Ll having a partially cylindrical surface shape is formed by an upwardly convex curved surface. there is That is, the biasing-side extending portion 46L is provided with a biasing-side cylindrical surface portion 46Ll having a larger diameter than the bearing-side cylindrical surface portion 47Ls. Further, the diameter of the spherical surface portion 47Rs of the first rotating shaft 44R is formed to be larger than that of the bearing-side cylindrical surface portion 47Ls of the second rotating shaft 44L.

As shown in FIG. 16, the second clamping portion 62L of the support unit 60 has a second fitting portion 62Lm. A pair of second fitting portions 62Lm in the second clamping portion 62L are formed to be elastically deformable on both sides sandwiching the second elastic member 51L of the biasing unit 50 in the front and rear directions. Each second fitting portion 62Lm is assembled to the second bearing portion 61L side in the radial direction of the second rotating shaft 44L by snap fitting to the housing 10 . In this assembly radial direction, the second elastic member 51L is sandwiched between the second holding portion 62L and the biasing side extending portion 46L on the side opposite to the bearing side extending portion 47L of the second rotating shaft 44L. As a result, it is elastically deformed into a compressed state. The elastically deformed second elastic member 51L attaches the cylindrical surface portion 46Ll of the urging side extension portion 46L from the side opposite to the bearing side extension portion 47L in the radial direction by the restoring force along the line of action LL in the radial direction. I am gaining momentum.

The second holding portion 62L further has a second locking portion 62Ll. The second locking portion 62Ll protrudes into the inner peripheral side of the second elastic member 51L, which is a compression coil spring of the biasing unit 50, along the radial direction of the second rotating shaft 44L. A clearance 62Lc is provided between the tip surface of the second locking portion 62Ll and the biasing side cylindrical surface portion 46Ll of the biasing side extension portion 46L of the second rotating shaft 44L. The second locking portion 62Ll can lock the urging side extending portion 46L that has moved by the clearance 62Lc toward the side opposite to the second bearing portion 61L in the radial direction.

As shown in FIGS. 15 to 19, the second bearing portion 61L of the support unit 60 has a second bearing concave portion 61Lc. The second bearing recessed portion 61Lc is recessed in the opposite direction to the second elastic member 51L with the second rotating shaft 44L sandwiched above and below in the radial direction. That is, the second bearing recessed portion 61Lc is recessed radially opposite to the bearing-side cylindrical surface portion 47Ls of the bearing-side extending portion 47L of the second rotating shaft 44L. The second bearing portion 61L has a V-shaped groove in a longitudinal section.

Both inner side surfaces of the V-shaped groove of the second bearing recessed portion 61Lc are in contact with the cylindrical surface portion 47Ls of the bearing-side extending portion 47L of the second rotating shaft 44L. The second bearing concave portion 61Lc radially bears the bearing-side cylindrical surface portion 47Ls in contact with each inner surface from the side opposite to the second elastic member 51L in the radial direction without a thrust bearing, thereby forming a rotatable second rotating shaft 44L. , relative movement to both sides in the axial direction is allowed. Due to the relative movement permitting function of the second bearing recessed portion 61Lc, the second bearing portion 61L absorbs the dimensional error in the axial direction of the rotary reflecting mirror 40 positioned at the reference point PB as shown in FIGS. .

As shown in FIGS. 6 to 8, in the rotary reflecting mirror 40, the holding base 49 forms an accommodating portion 49c on the right side of the reflecting surface 41a, which is axially outward. The accommodating portion 49c has a rectangular groove shape recessed toward the reflecting surface 41a. A first rotating shaft 44R protrudes through the inside of the accommodating portion 49c. A third elastic member 57, which is a torsion coil spring of the urging unit 50, is coaxially arranged on the outer peripheral side of the root portion 45R penetrating through the housing portion 49c in the first rotating shaft 44R. With such arrangement, the one end portion 57a side of the third elastic member 57 is accommodated in the accommodation portion 49c.

One end portion 57a of the third elastic member 57 is linked to the holding base 49 of the rotary reflecting mirror 40 inside the housing portion 49c and on the outer peripheral side of the root portion 45R. 5 and 8, the third elastic member 57 and the accommodating portion 49c are connected to each other on the outer peripheral side of the first rotating shaft 44R including the rotation center line A1. is formed on the outside in the axial direction of the The other end portion 57b of the third elastic member 57 is held by the housing 10 outside the accommodating portion 49c. Under these linkages and holdings, the third elastic member 57 elastically deforms in a twisted state according to the driving force of the actuator 70 received through the drive transmission shaft 48 and the holding base 49, thereby rotating the rotary reflecting mirror 40 in the rotational direction. energize.

As shown in FIGS. 6 and 8, the connecting arm 73 of the actuator 70 that transmits the rotational driving force to the rotating reflecting mirror 40 is linked to the drive transmission shaft 48 of the rotating reflecting mirror 40 as described above. 5 and 8, the connecting arm 73 and the drive transmission shaft 48 are connected to each other on the outer peripheral side of the coaxial shaft 48 including the eccentric line A2. forming. In particular, the second connecting point P2 of the present embodiment is formed outside the first connecting point P1 and inside the reference point PB in the axial direction of the rotary reflecting mirror 40 . In other words, the reference point PB formed by positioning the first rotating shaft 44R by the first bearing portion 61R is set outside the first and second connecting points P1 and P2 in the axial direction. . Furthermore, the separation distance ΔP between the first connecting point P1 and the second connecting point P2 in the radial direction of the rotary reflecting mirror 40 is smaller than the width WM of the holding frame 43 that matches the width of the rotary reflecting mirror 40 as a whole. is set.

With these settings, even if the reflecting surface 41a is projected onto the first connecting point P1 and the second connecting point P2 in the axial direction of the rotary reflecting mirror 40, the first connecting point P1 and the second connecting point P2 are connected to each other. Located in the middle of nowhere. At the first connecting point P1 and the second connecting point P2 of this embodiment, each of the third elastic member 57 and the actuator 70 is in contact with the rotary reflecting mirror 40 according to the rotational position of the mirror 40. A relative positional relationship in which the reflecting surfaces 41a deviate from each other is satisfied at any point of the portion.

Here, particularly in the present embodiment, the positions of the connecting points P1 and P2 are set so that the virtual straight line LV connecting the first connecting point P1 and the second connecting point P2 deviates from the reflecting surface 41a. there is This imaginary straight line LV is defined only between the first series of connecting points P1 and the second connecting point P2, and is assumed to be a straight line that is not extended to opposite sides of the connecting points P1 and P2. However, the first connecting point P1 and the second connecting point P2 when defining the virtual straight line LV are defined as , for example, may be defined at a location where the distance between them is the shortest.

(Effect)
The effects of this embodiment described above will be described below.

In the first rotating shaft 44R of the present embodiment, a projection 47R extends from the extension 46R into a recess 46Rd formed by the extension 46R extending in the axial direction on the radial side of the first bearing 61R. It protrudes in a partial spherical shape. Therefore, in the first bearing portion 61R that thrust-bearing the projecting portion 47R from the side opposite to the first elastic member 51R in the radial direction, the opening edge portion 61Ro of the first bearing recess portion 61Rc is allowed to escape into the recess portion 46Rd. are positioned on both sides in the axial direction of the projecting portion 47R. According to this, in the first rotating shaft 44R which is biased axially outside of the reflecting surface 41a by the restoring force of the first elastic member 51R along which the line of action LR extends in the radial direction, the protruding portion formed with a diameter as small as possible 47R is thrust-beared from both sides in the axial direction, so that relative movement to both sides in the axial direction can be restricted. Therefore, it is possible to reduce the size of the bearing portion and suppress display distortion due to stress deformation of the reflecting surface 41a caused by the biasing force from the first elastic member 51R.

The extending portion 46R of the first rotating shaft 44R of this embodiment presents a partial circular shape centered on the rotation center line A1 of the first rotating shaft 44R with a central angle ψ1 of less than 180° in cross section. According to this, the recessed portion 46Rd into which the opening edge portion 61Ro of the first bearing recessed portion 61Rc escapes can be formed as large as possible on the first bearing portion 61R side of the extension portion 46R. Therefore, it is possible to increase the amount of escape of the opening edge portion 61Ro into the recessed portion 46Rd, and to promote miniaturization at the bearing portion.

In the first rotating shaft 44R of the present embodiment, the projecting portion 47R presents a partial circular shape with a smaller diameter than the coaxial extending portion 46R in cross section. According to this, it is possible to reduce the diameter of the projecting portion 47R as much as possible and promote miniaturization at the bearing portion.

According to the first rotating shaft 44R of the present embodiment, the extending portion 46R coaxially extending from the root portion 45R constituting the root of the overhang in the rotary reflecting mirror 40 has the same diameter as the root portion 45R in cross section. It has a partial circular shape. According to this, it is possible to improve durability by suppressing stress deformation of the reflecting surface 41a caused by the biasing force from the first elastic member 51R and damage to the first rotating shaft 44R due to the biasing force. Become.

Furthermore, in the first rotating shaft 44R of the present embodiment, the protruding portion 47R has a partial circular cross section with a smaller diameter than the coaxial root portion 45R. According to this, it is possible to reduce the diameter of the projecting portion 47R as much as possible and promote miniaturization at the bearing portion.

In the first rotating shaft 44R of the present embodiment, the extending portion 46R is integrally formed with the protruding portion 47R and the root portion 45R, thereby increasing the rigidity. Therefore, it is possible to suppress stress deformation of the reflecting surface 41a caused by the biasing force from the first elastic member 51R and damage to the first rotating shaft 44R due to the biasing force, thereby improving durability.

According to this embodiment, a torsion coil spring, which is a type of torsion spring, is arranged on the outer peripheral side of the root portion 45R as the third elastic member 57 that biases the rotary reflecting mirror 40 in the rotational direction. According to this, it is possible to effectively utilize the space on the outer peripheral side of the root portion 45R and suppress the rattling of the rotating reflecting mirror 40 in the rotating direction. Therefore, it is possible to reduce the size of the configuration for suppressing rattling of the rotary reflecting mirror 40 and to suppress display distortion due to such rattling.

The first holding portion 62R of the present embodiment is assembled on the first bearing portion 61R side in the radial direction where the first elastic member 51R is held between it and the extension portion 46R of the first rotating shaft 44R. According to this, a desired restoring force can be applied to the extending portion 46R in the radial direction in which the first holding portion 62R is assembled and the first elastic member 51R is held. Therefore, it is possible to suppress the display distortion caused by the backlash of the bearing caused by the variation in the restoring force at the manufacturing stage.

The first holding portion 62R of the present embodiment locks the extending portion 46R of the first rotating shaft 44R directed toward the first elastic member 51R side in the radial direction by the first locking portion 62Rl. According to this, it is possible to avoid a situation in which the first rotating shaft 44R presses the first elastic member 51R beyond the elastic limit due to the impact of the vehicle 1 . Therefore, it is possible to suppress stress deformation of the reflecting surface 41a caused by the biasing force from the first elastic member 51R and damage of the first elastic member 51R itself, thereby improving durability.

(Other embodiments)
Although one embodiment has been described above, the present disclosure is not to be construed as being limited to that embodiment, and can be applied to various embodiments within the scope of the present disclosure.

In the modified first rotating shaft 44R, the extending portion 46R and the protruding portion 47R may be formed to have the same diameter. In this case, in the cross section passing through the central points of the projecting portion 47R and the spherical surface portion 47Rs, the cylindrical surface portion 46Rl and the spherical surface portion 47Rs having the same diameter are continuous in the rotation direction, so that the first rotating shaft 44R exhibits a perfect circle shape. In the first rotating shaft 44R of the modified example, the central angle ψ1 of the extending portion 46R in the cross section may be 180° or more. In the first rotating shaft 44R of the modified example, at least two elements out of the root portion 45R, the extension portion 46R, and the projection portion 47R may be formed separately and then joined together.

In the first rotating shaft 44R of the modified example, the root portion 45R may not be provided, and the extension portion 46R may extend directly from the holding base 49. FIG. In the first rotating shaft 44R of the modified example, an extending portion 46R may be formed with a diameter larger or smaller than that of the root portion 45R. In the first rotating shaft 44R of the modified example, a protruding portion 47R may be formed with a larger diameter or the same diameter as the root portion 45R. The spherical surface portion 47Rs of the first rotating shaft 44R of the modified example may be formed to have a smaller diameter or the same diameter as the cylindrical surface portion 47Ls of the second rotating shaft 44L.

The first clamping portion 62R of the modified example may be assembled in a direction orthogonal to the radial direction in which the first elastic member 51R is clamped between it and the extending portion 46R of the first rotating shaft 44R. In the first clamping portion 62R of the modified example, the first locking portion 62Rl may not be provided.

As shown in FIGS. 20 and 21, in the first bearing portion 61R of the modified example, two protrusions 61Rp are provided on the inner side surface of one side and one protrusion 61Rp is provided on the inner side of the opposite side of the first bearing recessed portion 61Rc. The spherical portion 47Rs may be both a thrust bearing and a radial bearing. As shown in FIGS. 22 and 23, in the first bearing portion 61R of the modified example, in the conical hole-shaped first bearing recess portion 61Rc, the first rotation shaft A spherical portion 47Rs of 44R may be both a thrust bearing and a radial bearing.

As shown in FIGS. 24 and 25, in the first bearing portion 61R of the modified example, the inner side surfaces 61Rv extending on the pair of tangential planes TP in the first bearing recessed portion 61Rc having a V-shaped vertical cross section support the first rotating shaft. A spherical portion 47Rs of 44R may be both a thrust bearing and a radial bearing. As shown in FIG. 26, in a first bearing portion 61R of a modified example, in a first bearing recess portion 61Rc having a groove-like vertical cross section, an inner side surface 61Ra on one side extending on the tangential plane TP and an inner side surface 61Rb on the cross section Accordingly, the spherical portion 47Rs of the first rotating shaft 44R may be both a thrust bearing and a radial bearing.

In a modification, the angle θ between the tangential plane TP and the line of action LR may be set to an angle larger than the calculated value from the right side of Equation 1 above. In the first rotating shaft 44R of the modified example, both axial end face portions that are thrust-beared by both inner side surfaces of a first bearing recessed portion 61Rc that is recessed in a U-shaped groove shape in the longitudinal section of the first bearing portion 61R, and the first bearing recessed portion A cylindrical surface portion radially bearing by the inner bottom surface of 61Rc may be provided instead of the spherical surface portion 47Rs.

In the second rotating shaft 44L of the modified example, the spherical surface portion that is radially supported without a thrust bearing by both inner side surfaces of the second bearing recessed portion 61Lc that is recessed in a V-shaped groove in the cross section of the second bearing portion 61L becomes a cylindrical surface portion. It may be provided in place of 47Ls. In the second bearing portion 61L of the modified example, the cylindrical surface portion 47Ls of the second rotating shaft 44L is radially supported without a thrust bearing by both the inner side surfaces and the inner bottom surface of the second bearing recessed portion 61Lc having a U-shaped cross section. may be In the second rotating shaft 44L of the modified example, the spherical surface portion which is thrust bearing and radially bearing by both inner side surfaces of the second bearing recess portion 61Lc which is recessed in a V-shaped groove shape in the cross section of the second bearing portion 61L is a cylindrical surface portion 47Ls. may be provided instead of In the second rotating shaft 44L of the modified example, both axial end face portions that are thrust-beared by both inner side surfaces of a second bearing recessed portion 61Lc that is recessed in a U-shaped groove shape in the longitudinal section of the second bearing portion 61L, and the second bearing recessed portion A cylindrical surface portion 47Ls radially bearing by the inner bottom surface of 61Lc may be provided.

In the second rotating shaft 44L of the modified example, the extending portions 46L and 47L may be formed to have the same diameter, thereby jointly forming a regular columnar shape. In an arbitrary cross section in this case, the cylindrical surface portions 46Ll and 47Ls having the same diameter continue in the direction of rotation, so that the second rotating shaft 44L has a perfect circular shape. In the second rotating shaft 44L of the modified example, the center angle ψ2 of the extending portion 46L in the cross section may be 180° or more. In the second rotating shaft 44L of the modification, the extending portions 46L and 47L may be formed separately and then joined together.

The second holding portion 62L of the modified example may be assembled in a direction orthogonal to the radial direction in which the second elastic member 51L is held between the extending portion 46L of the second rotating shaft 44L. In the second clamping portion 62L of the modified example, the second locking portion 62Ll may not be provided.

The third elastic member 57 of the modified example may be a type of torsion spring, such as a spiral spring. The third elastic member 57 of the modified example may be arranged on the outer peripheral side of the second rotating shaft 44L. In a modification, the third elastic member 57 may not be provided. In a modified example, the accommodating portion 49c that accommodates the third elastic member 57 may not be provided in the rotary reflecting mirror 40. FIG.

In a modified example, a reflecting surface 41a may be provided between the first connecting point P1 and the second connecting point P2. In a modification, the first series connection point P1 may be set axially outside the second connection point P2. In a modification, at least one of the first and second connecting points P1 and P2 may be set axially outside the reference point PB. In the modified example, the separation distance ΔP between the first connecting point P1 and the second connecting point P2 may be set to a dimension equal to or greater than the width WM of the holding frame 43 that matches the width of the rotary reflecting mirror 40 as a whole. good.

Reference Signs List 1 vehicle, 3a projection unit, 40 rotating reflector, 41a reflection surface, 44R first rotation shaft, 45R root portion, 46R extension portion, 46Rd depression portion, 47R projection portion, 51R first elastic member, 57 third elastic member , 61R first bearing portion, 61Rc first bearing recessed portion, 61Ro opening edge portion, 62R first clamping portion, 62Rl first locking portion, 100 HUD, A1 rotation center line, LR line of action, VRI virtual image, ψ1 central angle

Claims (7)

A virtual image display device (100) configured to be mounted on a vehicle (1) and displaying a virtual image (VRI) by projecting display light onto a projection unit (3a),
A rotating reflecting mirror (40) having a rotating shaft (44R) axially outside the reflecting surface (41a), and changing a reflection direction of the display light from the reflecting surface toward the projection unit by rotating the rotating shaft. and,
an elastic member ( 51R ) that urges the rotating shaft with a restoring force along the line of action (LR) in the radial direction;
a bearing portion (61R) for thrust-bearing the rotating shaft from the side opposite to the elastic member in the radial direction and restricting relative movement of the rotating shaft to both sides in the axial direction;
The rotating shaft is
an extending portion (46R) extending in the axial direction and forming a recessed portion (46Rd) on the side of the bearing portion in the radial direction;
a projecting portion (47R) projecting in a partially spherical shape from the extending portion into the recessed portion;
The bearing portion
Bearing recesses (61Rc) that bear the protrusions and that are located on both sides of the protrusions in the axial direction with opening edges (61Ro) recessed into the recesses ,
A virtual image display device in which the extending part presents a partial circular shape centered on the rotation center line (A1) of the rotation shaft with a central angle (ψ1) of less than 180° in cross section. 2. The virtual image display device according to claim 1 , wherein the projecting portion has a partial circular shape with a smaller diameter than the coaxial extending portion in cross section. the rotating shaft further has a root portion (45R) that constitutes the root of the overhang in the rotating reflecting mirror;
the extending portion coaxially extends from the root portion and has a partial circular cross section with the same diameter as the root portion;
3. A virtual image display device according to claim 1 , wherein said projecting portion has a partial circular shape with a smaller diameter than said coaxial root portion in cross section. 4. The virtual image display device according to claim 3 , wherein the extending portion is integrally formed with the projecting portion and the root portion. 5. The virtual image display device according to claim 3 , further comprising a torsion spring (57) disposed on the outer peripheral side of the root portion and biasing the rotating reflecting mirror in the rotational direction. The virtual image display device according to any one of claims 1 to 5 , further comprising a clamping portion (62R) assembled on the bearing portion side in a radial direction in which the elastic member is clamped between the extending portion and the elastic member. . 7. The virtual image display device according to claim 6 , wherein the holding portion has a locking portion (62Rl) that locks the extending portion directed to the side opposite to the bearing portion in the radial direction.

Images