JP2018167625A - Dead angle auxiliary device - Google Patents

Abstract

To enhance the durability of a pair of mirrors of a dead angle auxiliary device.SOLUTION: A dead angle auxiliary device 20 includes: a semitransparent mirror 21; a mirror 22 which faces a reflection surface 21a of the semitransparent mirror 21 with an interval; and a case 23 which stores the pair of mirrors 21, 22. An edge 21g of the semitransparent mirror 21 is held by the case 23 with a cushioning material 50 over the whole circumference. An edge 22d of the mirror 22 is held by the case 23 with a cushioning material 60 over the whole circumference.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a blind spot assisting device that projects an image in a blind spot area that is blocked by an obstacle and cannot be seen by a viewer.

  For example, a driver (viewer) riding in a vehicle cannot see the scenery outside the left and right front pillars of the vehicle body because they are blocked by these front pillars. That is, the left and right front pillars are a kind of obstacle. On the other hand, Patent Document 1 discloses a blind spot assisting device that projects an image in a so-called blind spot area that is blocked by an obstacle and cannot be seen by a viewer.

  The blind spot assisting device known from Patent Document 1 has a basic configuration of a combination of a plate-like (planar) semi-transmissive mirror and a plate-like mirror arranged in parallel to each other. The semi-transmissive mirror is positioned closer to the viewer than the mirror, and receives light representing the image of the object, reflects a part thereof, and transmits the rest. The mirror faces the reflective surface of the semi-transmissive mirror with a gap, and reflects incident light toward the semi-transmissive mirror. The pair of mirrors are housed in a case.

  This case is a two-part case composed of a first case half and a second case half. The open end of the first case half and the open end of the second case half face each other. One case is formed by combining the open ends. The second case half can be fitted into the first case half. The pair of mirrors is fixed in the case by being sandwiched between the first case half and the second case half.

  Such a blind spot assisting device may be subjected to vibration and impact. For example, when the blind spot assisting device is mounted on a vehicle, traveling vibrations accompanying traveling of the vehicle and large vibrations and impacts when the vehicle gets over a step are transmitted to the pair of mirrors in the case. In order to increase the durability of the pair of mirrors, it is necessary to take measures against vibration and shock. In particular, since the blind spot assisting device is required to obtain an image having no distortion, it is preferable to use a substrate having high surface accuracy for the pair of mirrors. Therefore, an inorganic glass such as a float plate glass is preferable for the material of the base material. In order to increase the durability of inorganic glass, it is required to take sufficient measures against vibration and impact.

JP, 2006-101814, A

  This invention makes it a subject to provide the technique which can improve durability of a pair of mirror of a blind spot auxiliary | assistance apparatus.

  According to the first aspect of the present invention, there is provided a blind spot assisting device that projects an image of an object in a blind spot area that is obstructed by an obstacle and cannot be seen by a viewer, and is positioned on the viewer side and emits light representing the image. A plate-shaped semi-transmissive mirror that reflects part of the incident light and transmits the remaining light, and faces the reflective surface of the semi-transmissive mirror with a gap, and reflects the reflected light toward the semi-transmissive mirror. And a semi-transparent mirror and a case for housing the mirror. The edge of the semi-transmission mirror and the edge of the mirror are respectively held in the case by a cushioning material over the entire circumference.

  As described in claim 2, preferably, the cushioning material is made of an elastic material.

  As described in claim 3, preferably, a spacer is provided between the semi-transparent mirror and the mirror so as to maintain a constant distance between the two. The buffer material also serves as an elastic member that generates a force for bringing the semi-transmissive mirror and the mirror into close contact with each other via the spacer.

  In the invention which concerns on Claim 1, the edge of a semi-transmission mirror and the edge of a mirror are respectively hold | maintained at the case with the buffer material over the perimeter. For this reason, when a vibration or impact is applied to each mirror from the outside, the vibration or impact can be absorbed and reduced by the buffer material. As a result, the durability of the pair of mirrors can be increased. For example, when the blind spot assisting device is mounted on a vehicle, traveling vibrations accompanying traveling of the vehicle and large vibrations and impacts when the vehicle gets over a step are transmitted to the pair of mirrors in the case. On the other hand, vibrations and impacts applied to each mirror can be absorbed and reduced by the buffer material. Even when the pair of mirrors is made of inorganic glass, the durability of the inorganic glass can be easily increased.

  In the invention which concerns on Claim 2, compared with the case where a buffer material is comprised with other members, such as a spring, a structure can be simplified.

  In the invention which concerns on Claim 3, the buffer material which hold | maintains the edge of a semi-transmission mirror and the edge of a mirror over each perimeter produces | generates the force for closely_contact | adhering a semi-transmission mirror and a mirror via a spacer Also serves as an elastic member. For this reason, it is not necessary to provide a separate elastic member. The number of parts can be reduced. When the pair of mirrors and the spacer are assembled to the case, there is a dimensional tolerance in the thickness direction of the pair of mirrors. This cushioning material has such elasticity that it can prevent backlash between members due to dimensional errors during assembly. For this reason, rattling can be easily prevented by the cushioning material also serving as the elastic member.

It is a schematic diagram near the driver's seat of a vehicle equipped with a blind spot assisting device according to the present invention. It is explanatory drawing explaining the principle of the blind spot auxiliary | assistance apparatus shown by FIG. It is the perspective view which decomposed | disassembled the pair of mirror of the blind spot auxiliary | assistance apparatus shown by FIG. 2, and the case which accommodates this pair of mirror. FIG. 4 is a perspective view of a configuration in which a pair of mirrors, a pair of cushioning materials, and a plurality of spacers shown in FIG. 3 are combined. FIG. 4 is a cross-sectional view of a portion deviated from the position of a spacer in the configuration in which the pair of mirrors, the pair of buffer materials, and the case illustrated in FIG. FIG. 4 is a cross-sectional view of a portion where a spacer is located in a configuration in which a pair of mirrors, a pair of cushioning materials, and a case shown in FIG. It is the perspective view which decomposed | disassembled the structure which combined a pair of mirror shown by FIG. 4, a pair of shock absorbing material, and one spacer. FIG. 8 is a perspective view of a configuration in which a pair of mirrors, a pair of cushioning materials, and one spacer are combined in a cross section taken along line 8-8 in FIG. 7.

  Embodiments of the present invention will be described below with reference to the accompanying drawings. In this embodiment, an example in which an image of a blind spot area that is blocked by the front pillar of the vehicle is projected by a blind spot assisting device will be described. However, the blind spot assisting device is not limited to the configuration adopted for the front pillar of the vehicle.

  A blind spot assisting apparatus according to an embodiment will be described with reference to the drawings.

  As shown in FIG. 1, a vehicle 10 such as an automobile includes a left and right front pillars 11 and 11 at a front portion of a vehicle body, a windshield 12 provided between the left and right front pillars 11 and 11, and left and right front pillars. Left and right side glasses 13 and 13 provided at the rear ends of the pillars 11 and 11 are provided.

  The windshield 12 is composed of a plate-like transparent base made of glass or resin. A strip-shaped shielding layer 14 that blocks light transmission is provided on the entire periphery of the windshield 12. The shielding layer 14 is made of, for example, a well-known black ceramic layer that is formed in a strip shape having a predetermined width by printing on the entire rear surface of the windshield 12. This black ceramic layer is formed integrally with the windshield 12 by applying a black ceramic paste containing a black pigment to the back surface of the windshield 12, and is commonly referred to as a black ceramic portion.

  A steering wheel 16 and a seat (not shown) are arranged in the front part of the passenger compartment 15 located behind the windshield 12. Hereinafter, as an example of the vehicle 10, a right-hand drive vehicle is illustrated, but the present invention is not limited thereto.

  Referring also to FIG. 2, the viewer Mn (mainly the driver) in the passenger compartment 15 directly views the scenery outside the vehicle through the windshield 12 (excluding the portion of the shielding layer 14) and the left and right side glasses 13, 13. Can be visually recognized. However, in the area of the vehicle 10 where the left and right front pillars 11 and 11 and the shielding layers 14 and 14 are arranged, the visual field of the viewer Mn is blocked and the external scenery cannot be directly seen. . That is, a blind spot area Ad is generated. The left and right front pillars 11 and 11 and the shielding layers 14 and 14 correspond to obstacles.

  In contrast, as shown in FIGS. 1 and 2, the vehicle 10 of the present invention includes a blind spot assisting device 20. This blind spot assisting device 20 displays an image of the object Oj in the blind spot area Ad that is blocked by the obstacle 11 (front pillar 11) and cannot be seen by the viewer Mn. Here, the object Oj includes organisms such as humans, animals, and plants.

  The blind spot assisting device 20 is disposed on the front pillar 11 on the right side (driver side) when viewed from the viewer Mn side, and projects an image of the object Oj in the blind spot area Ad blocked by the front pillar 11 and the shielding layer 14. is there. The blind spot assisting device 20 is arranged to face the front pillar 11 and the shielding layer 14 when viewed from the viewer Mn. Hereinafter, the blind spot assisting device 20 will be described in detail.

  The blind spot assisting device 20 includes a semi-transmissive mirror 21 and a mirror 22. Hereinafter, both the semi-transmissive mirror 21 and the mirror 22 are collectively referred to as “a pair of mirrors 21 and 22” as appropriate.

  The semi-transmissive mirror 21 is a so-called magic mirror that is located on the viewer Mn side, receives light La representing an image of the object Oj, reflects part of it, and transmits the rest. For example, the semi-transmissive mirror 21 is formed as follows. In the first example, a semi-transmissive reflective layer having a desired reflectance is formed by depositing a metal such as aluminum on the surface of a substrate made of an inorganic glass plate. In the second example, the surface of the base material is coated with a dielectric multilayer film to form a transflective layer having a desired reflectance.

  The mirror 22 faces the reflective surface 21 a of the semi-transmissive mirror 21 with a gap, and reflects the reflected light toward the semi-transmissive mirror 21. This mirror 22 is formed by depositing a metal such as aluminum on the surface of a substrate made of an inorganic glass plate, for example, to form a reflective layer.

  The semi-transmissive mirror 21 and the mirror 22 are formed in a plate shape such as a flat plate shape. As described above, the pair of mirrors 21 and 22 are positioned so that the reflecting surfaces 21a and 22a face each other. As shown in FIG. 2, when the vehicle 10 is viewed from above, one end surface 21 b of the semi-transmissive mirror 21 and one end surface 22 b of the mirror 22 are close to the glass surface of the windshield 12. The end 21c on the side opposite to the one end face 21b in the semi-transmissive mirror 21 is referred to as “the other end face 21c”.

  The transflective mirror 21 is displaced with respect to the mirror 22 along the reflection surface 22 a of the mirror 22. That is, when the transflective mirror 21 is viewed from the direction perpendicular to the plane Fa (direction Fa toward the plate surface of the semitransparent mirror 21; direction Fa perpendicular to the plate surface), the one end surface 21b of the semitransparent mirror 21 is reflected by the mirror 22. The position is shifted from the surface 22 a toward the glass surface of the windshield 12. In other words, the semi-transmissive mirror 21 and the mirror 22 are positioned in a stepped manner in the horizontal direction. Hereinafter, a portion 21d of the semi-transmissive mirror 21 that faces the reflecting surface 22a of the mirror 22 is referred to as an “opposing portion 21d”, and a portion 21e that does not face the reflecting surface 22a of the mirror 22, that is, the semi-transmissive mirror 21. The portion on the one end face 21b side is referred to as “non-opposing portion 21e”.

  The reflecting surface 21a of the semi-transmissive mirror 21 is not parallel to the reflecting surface 22a of the mirror 22, but is inclined by a predetermined inclination angle θ. The inclination direction of the reflection surface 21a of the semi-transmission mirror 21 is a direction in which the interval between the reflection surfaces 21a and 22a increases as it goes from the one end surface 21b of the semi-transmission mirror 21 to the other end surface 21c. In other words, the tilt direction is a direction in which the semi-transmissive mirror 21 opens toward the viewer Mn with respect to the mirror 22. Note that the reflective surface 21 a of the semi-transmissive mirror 21 may be parallel to the reflective surface 22 a of the mirror 22.

  Here, in the semi-transmissive mirror 21, the surface 21f opposite to the reflective surface 21a is referred to as a “transmissive surface 21f”. In the mirror 22, the surface 22c opposite to the reflecting surface 22a is referred to as a “back surface 22c”.

  Next, the principle of the blind spot assisting device 20 will be described with reference to FIG. FIG. 2 shows a state in which the viewer Mn is seated in the driver's seat, and the viewpoint Pi shows the viewpoint (eye point) of the viewer Mn.

  In the front field of view of the viewer Mn (viewpoint Pi), there is a blind spot area Ad that is blocked by the front pillar 11 (not shown in FIG. 2, but also including the shielding layer 14 in FIG. 1). Therefore, the object Oj existing in the blind spot area Ad cannot be directly viewed from the viewpoint Pi.

  On the other hand, the light La (light La representing the image) directed from the object Oj to the pair of mirrors 21 and 22 is incident on the non-facing portion 21e in the reflecting surface 21a of the semi-transmissive mirror 21. For this reason, the light La from the object Oj is repeatedly reflected between the pair of mirrors 21 and 22, and a part of the light is emitted from the pair of mirrors 21 and 22 (that is, a part of the light La is half). The light passes through the transmission mirror 21). A part of the light La emitted from the pair of mirrors 21 and 22 reaches the viewpoint Pi. Therefore, the image of the object Oj reflected on the mirror 22 can be seen through the semi-transmissive mirror 21 continuously with the scenery that can be seen directly from the viewpoint Pi.

  Of the blind spot area Ad, a small area on the back side of the front pillar 11 (portion represented by hatching in FIG. 2) cannot allow light from this area to enter the pair of mirrors 21 and 22 and the object Oj. This is a so-called invisible region where an image cannot be projected by the pair of mirrors 21 and 22.

  Incidentally, as described above, the reflective surface 21 a of the semi-transmissive mirror 21 is inclined with respect to the reflective surface 22 a of the mirror 22. The tilt direction is a direction in which the semi-transmissive mirror 21 opens toward the viewer Mn with respect to the mirror 22. That is, the interval between the reflecting surfaces 21a and 22a gradually increases in the traveling direction of the light La that travels while repeating reflection between the reflecting surfaces 21a and 22a.

  The incident angle at which the light La representing the image is incident on the non-facing portion 21e in the reflecting surface 21a of the semi-transmissive mirror 21 is referred to as “first incident angle”. The emission angle at which the light La representing the image is emitted from the pair of mirrors 21 and 22 toward the viewpoint Pi after being repeatedly reflected between the reflection surfaces 21a and 22a is referred to as a “last emission angle”. The final exit angle is greater than the initial incident angle. For this reason, by arbitrarily setting an arbitrary inclination angle θ in advance, the light La (light ray La) incident on the reflecting surface 21a of the semi-transmissive mirror 21 from the object Oj at the first incident angle is represented by the viewpoint Pi and the object. It intersects with a straight line Lp connecting Oj. Therefore, when the viewer Mn visually recognizes the image of the object Oj, there is no deviation between the image reflected on the mirror 22 and the front scenery that is directly visually recognized.

  Next, the exterior structure of the blind spot assisting device 20 will be described. As shown in FIG. 3, the pair of mirrors 21 and 22 are elongated in the vertical direction along the front pillar 11 (see FIG. 1). The blind spot assisting device 20 includes a case 23 that houses a semi-transmissive mirror 21 and a mirror 22. The case 23 is a divided case composed of a first case half 30 and a second case half 40. The first and second case halves 30 and 40 are divided in the plate surface direction of the pair of mirrors 21 and 22. The first case half 30 is located on the viewer Mn (see FIG. 2) side.

  The first case half 30 is a substantially rectangular box that is vertically elongated in accordance with the pair of mirrors 21 and 22, and the surface facing the second case half 40 is completely open (that is, the first case half 30). 1 opening 31). The first case half 30 is an integrally molded resin product including a peripheral wall 32 that forms the periphery of the first opening 31 and a front wall 33 that covers the front surface of the peripheral wall 32.

  The first half of the first case half 30 (that is, the side opposite to the first opening 31) is a large second opening formed by leaving both ends (upper end and lower end) in the longitudinal direction. 34. The second opening 34 is greatly opened across the peripheral wall 32 and the front wall 33. The light La (see FIG. 2) emitted from the pair of mirrors 21 and 22 to the viewer Mn side can reach the viewer Mn through the second opening 34. The semi-transmissive mirror 21 is located on the second opening 34 side in the first case half 30. The reflecting surface 21 a of the semi-transmissive mirror 21 faces the opposite side with respect to the second opening 34.

  The second opening 34 is provided with a louver 35 extending vertically. The louver 35 is constituted by a plurality of vertical plates arranged at a predetermined pitch in the width direction of the first case half 30. As shown in FIGS. 2 and 3, the louver 35 is located on the viewer Mn side with respect to the semi-transmissive mirror 21, and is placed on the pair of mirrors 21 and 22 at a predetermined entry angle from the viewer Mn side. It functions as a light shielding unit that blocks incident external light.

  The first opening 31 of the first case half 30 is detachably closed by the second case half 40. The second case half 40 has a substantially flat lid shape elongated vertically. Both ends (upper end and lower end) in the longitudinal direction of the second case half 40 have a plurality of fitting pieces 41 and 41 and a plurality of coupling flanges 42. The plurality of fitting pieces 41, 41 extend from both longitudinal ends of the second case half 40 toward the first opening 31 of the first case half 30 and can be fitted into the first opening 31. It is. The plurality of coupling flanges 42 have a plurality of screw insertion holes 42a penetrating each other.

  The first case half 30 has a plurality of coupling protrusions 36 that bulge from the outer surface of the peripheral wall 32. The plurality of coupling protrusions 36 have a plurality of female screws 36a.

  The procedure for assembling the second case half 40 to the first case half 30 is as follows. First, the plurality of fitting pieces 41 and 41 are fitted into the first opening 31. Next, the second case half 40 is overlaid on the first case half 30 to align both. Finally, the plurality of screws 43 inserted from the plurality of screw insertion holes 42a are screwed into the plurality of female screws 36a. Thus, the assembly work of the case 23 is completed.

  As shown in FIGS. 3 to 5, the edge 21 g of the semi-transmissive mirror 21 and the edge 22 d of the mirror 22 are covered with the cushioning materials 50 and 60 over the entire circumference, and the cushioning materials 50 and 60 cover the case 23. Is retained. For this reason, when a vibration or impact is applied to the mirrors 21 and 22 from the outside, the shock absorbers 50 and 60 can absorb and mitigate the vibration and impact. As a result, the durability of the pair of mirrors 21 and 22 can be enhanced. For example, when the blind spot assisting device 20 is mounted on the vehicle 10 (see FIG. 1), traveling vibrations associated with the traveling of the vehicle 10 and large vibrations and impacts when the vehicle 10 crosses a step are caused in the case 23. It is transmitted to the pair of mirrors 21 and 22. On the other hand, vibrations and impacts applied to the mirrors 21 and 22 can be absorbed and reduced by the buffer materials 50 and 60. Even if it is a case where a pair of mirrors 21 and 22 are comprised with inorganic glass, durability of inorganic glass can be improved easily. Particularly, since the corners (corners) of the edges 21g and 22d of the mirrors 21 and 22 are covered with the cushioning materials 50 and 60, the durability of the mirrors 21 and 22 can be further enhanced.

  Each buffer material 50, 60 is made of an elastic material such as rubber or hard sponge. For this reason, a structure can be simplified compared with the case where each buffer material 50 and 60 is comprised by other members, such as a spring.

  Hereinafter, the buffer material 50 that holds the semi-transmissive mirror 21 is appropriately referred to as a “first buffer material 50”. The buffer material 60 that holds the mirror 22 is appropriately referred to as a “second buffer material 60”.

  The first cushioning material 50 is configured by a frame having a substantially rectangular cross section, and a mirror fitting groove 51 is formed over the entire circumference of the inner circumferential surface. In this mirror fitting groove 51, the edge 21g of the semi-transmissive mirror 21 is fitted. The width of the mirror fitting groove 51 is preferably the same as or slightly smaller than the thickness of the semi-transmissive mirror 21. This is because the semi-transmissive mirror 21 can be supported by the first buffer material 50 without rattling.

  The first buffer material 50 includes an inner buffer portion 52 held in contact with the reflecting surface 21a (see FIG. 5) of the semi-transmissive mirror 21, an outer buffer portion 53 held in contact with the transmissive surface 21f of the semi-transmissive mirror 21, and It consists of an outer periphery buffering portion 54 that is in contact with and holds the outer peripheral surface of the semi-transmissive mirror 21. The outer buffer portion 53 is overlaid on the first facing surface 37 of the first case half 30. The first facing surface 37 is the inner surface 37 of the front wall 33 and faces the plate surface of the semi-transmissive mirror 21. The outer peripheral buffer portion 54 is fitted into the inner peripheral surface 41 a of the fitting piece 41 of the second case half 40.

  Similar to the first cushioning material 50, the second cushioning material 60 is constituted by a frame having a substantially rectangular cross section, and a mirror fitting groove 61 is formed over the entire circumference of the inner circumferential surface. In this mirror fitting groove 61, the edge 22d of the mirror 22 is fitted. The width of the mirror fitting groove 61 is preferably the same or slightly smaller than the thickness of the mirror 22. This is because the mirror 22 can be supported without backlash by the second buffer material 60.

  The second buffer material 60 is in contact with the inner buffer portion 62 that is held in contact with the reflecting surface 22 a of the mirror 22, the outer buffer portion 63 that is held in contact with the rear surface 22 c of the mirror 22, and the outer peripheral surface of the mirror 22. And an outer periphery buffering portion 64 for holding. The inner buffer part 62 faces the inner buffer part 52 of the first buffer material 50. The outer buffer portion 63 is overlapped with the second facing surface 44 of the second case half 40. The outer peripheral buffer part 64 is fitted into the inner peripheral surface 41 a of the fitting piece 41 of the second case half 40.

  Thus, each buffer material 50 and 60 is an integrally molded product formed in a frame shape. For this reason, compared with the case where each buffer material 50 and 60 is made into a divided product, the number of parts can be reduced. In addition, each buffer material 50 and 60 may be a divided product in consideration of the structure and assembly property. For example, each of the frame-shaped cushioning materials 50 and 60 can be divided into four sides.

  As shown in FIGS. 3 and 6 to 8, the first facing surface 37 of the first case half 30 includes a plurality of mirror support portions 38 and a plurality of first fitting holes 39. The plurality of mirror support portions 38 can be supported by being partially in contact with the semi-transmissive mirror 21. The shape of the plurality of mirror support portions 38 is a spherical shape protruding from the first facing surface 37 toward the plate surface of the semi-transmissive mirror 21. The tip of each mirror support portion 38 is a convex surface having a relatively large curvature radius (for example, 1000 mm). By increasing the curvature radius, stress concentration between the mirrors 21 and 22 and the mirror support portions 38 is suppressed as much as possible. The plurality of first fitting holes 39 are located in the vicinity of the plurality of mirror support portions 38.

  The second facing surface 44 that faces the back surface 22 c of the mirror 22 in the second case half 40 has a plurality of second fitting holes 46.

  As shown in FIG. 3, the number of the plurality of mirror support portions 38 is preferably three. The plurality of first fitting holes 39 and the plurality of second fitting holes 46 are also preferably three each.

  As shown in FIGS. 3 and 6 to 8, a plurality of spacers 70 are provided between the semi-transmissive mirror 21 and the mirror 22 so as to keep a constant distance between the two mirrors 21 and 22. The plurality of spacers 70 include a plurality of first fitting portions 71, a plurality of second fitting portions 72, a plurality of first contact portions 73, and a plurality of second contact portions 74. That is, one spacer 70 has the 1st fitting part 71, the 2nd fitting part 72, the 1st contact part 73, and the 2nd contact part 74 one each.

  The plurality of first fitting portions 71 extend from the plurality of spacers 70 toward the first facing surface 37 along the edge 21 g of the semi-transmissive mirror 21 and can be fitted into the plurality of first fitting holes 39. is there. The plurality of second fitting portions 72 extend from the plurality of spacers 70 toward the second facing surface 44 along the edge 22 d of the mirror 22 and can be fitted into the plurality of second fitting holes 46.

  The plurality of first contact portions 73 are formed on each end surface of the plurality of spacers 70 facing the reflecting surface 21 a of the semi-transmissive mirror 21. The plurality of first contact portions 73 can partially contact the plate surface (reflective surface 21 a) of the semi-transmissive mirror 21. The plurality of second contact portions 74 are formed on each other end surface of the plurality of spacers 70 facing the reflecting surface 22 a of the mirror 22. The plurality of second contact portions 74 can partially contact the plate surface (reflection surface 22a) of the mirror 22.

  The shapes of the plurality of first and second contact portions 73 and 74 are protruding spherical shapes. The tips of the first contact portions 73 and the second contact portions 74 are convex surfaces having a relatively large radius of curvature (for example, 1000 mm). By increasing the curvature radius, it is possible to suppress stress concentration between the mirrors 21 and 22 and the contact portions 73 and 74 as much as possible.

  The positions of the plurality of mirror support portions 38 and the plurality of first and second contact portions 73 and 74 are perpendicular to the surface Fa of the semi-transmissive mirror 21 (direction Fa toward the plate surface of the semi-transmissive mirror 21. On the plate surface). As seen from the vertical direction Fa), they match each other (overlap). More specifically, the positions of the plurality of first contact portions 73 coincide with the positions of the plurality of mirror support portions 38 when viewed from the surface direction Fa of the semi-transmissive mirror 21. The positions of the plurality of second contact portions 74 coincide with the positions of the plurality of first contact portions 73 when viewed from the plane direction Fa of the semi-transmissive mirror 21.

  The distance and angle between the semi-transmissive mirror 21 and the mirror 22 are defined by the plurality of first and second contact portions 73 and 74 of the plurality of spacers 70.

  There are three mirror support portions 38 and three spacers 70, respectively. The three spacers 70 are located at the ends of the portions where the semi-transparent mirror 21 and the mirror 22 overlap with each other as much as possible, and at a triangular position.

  The first buffer material 50 includes a passage portion 55, a connecting portion 56, a first notch portion 57, and a second notch portion 58, respectively, in accordance with the plurality of mirror support portions 38 and the plurality of spacers 70.

  The passage portion 55 is a portion that can pass the first fitting portion 71 of the spacer 70 in the direction perpendicular to the surface Fa of the semi-transmissive mirror 21. The passage portion 55 is constituted by a notch or a through hole formed in the outer peripheral buffer portion 54.

  The connecting portion 56 is a connecting portion between the bottom of the mirror fitting groove 51 and the bottom of the passing portion 55 in the first cushioning material 50. The edge 21 g of the semi-transmissive mirror 21 is covered with the connecting portion 56 even if the first buffer material 50 has the passage portion 55. For this reason, when a vibration or impact is applied to the semi-transmissive mirror 21 from the outside, the first shock absorbing material 50 can absorb and mitigate the vibration or impact. As a result, the durability of the semi-transmissive mirror 21 can be enhanced. In addition, the first cushioning material 50 can maintain the frame shape by the connecting portion 56 despite having the passage portion 55, the first cutout portion 57, and the second cutout portion 58.

  The first cutout portion 57 is a portion that allows the mirror support portion 38 of the first case half 30 to pass through in the direction perpendicular to the surface Fa of the semi-transmissive mirror 21 and to contact the transmission surface 21 f of the semi-transmissive mirror 21. It is. The first cutout portion 57 is configured by a cutout or a through hole formed in the outer buffer portion 53.

  The second notch 58 is a portion that allows the first contact portion 73 of the spacer 70 to pass through in the direction perpendicular to the surface Fa of the semi-transmissive mirror 21 and to contact the reflective surface 21 a of the semi-transmissive mirror 21. The second notch 58 is formed by a notch or a through hole formed in the inner buffer portion 52.

  The second cushioning material 60 includes a passage portion 65, a connecting portion 66, and a notch portion 67 in accordance with the plurality of spacers 70.

  The passing portion 65 is a portion that can pass the second fitting portion 72 of the spacer 70 in the direction perpendicular to the surface Fa of the semi-transmissive mirror 21. The passage portion 65 is configured by a notch or a through hole formed in the outer peripheral buffer portion 64.

  The connecting portion 66 is a connecting portion between the bottom of the mirror fitting groove 61 and the bottom of the passing portion 65 in the second cushioning material 60. The edge 22 d of the mirror 22 is covered with the connecting portion 66 even if the second buffer material 60 has the passage portion 65. For this reason, when a vibration or impact is applied to the mirror 22 from the outside, the second shock absorbing material 60 can absorb and mitigate the vibration or impact. As a result, the durability of the mirror 22 can be increased. In addition, the second cushioning material 60 can maintain the frame shape by the connecting portion 66 despite having the passage portion 65 and the notch portion 67.

  The cutout portion 67 is a portion that allows the second contact portion 74 of the spacer 70 to pass through in the direction perpendicular to the surface Fa of the semi-transmissive mirror 21 and to contact the reflective surface 22a of the mirror 22. The notch 67 is formed by a notch or a through hole formed in the inner buffer portion 62.

  The outer buffer part 63 of the second buffer material 60 does not have a notch or a through hole. The outer buffer portion 63 serves as an elastic member that generates a force for bringing the semi-transmissive mirror 21 and the mirror 22 into close contact with each other via the plurality of spacers 70. That is, the second buffer material 60 (buffer material 60) also serves as an elastic member that generates a force for bringing the semi-transmissive mirror 21 and the mirror 22 into close contact with each other via the plurality of spacers 70.

  For this reason, it is not necessary to provide a separate elastic member. The number of parts can be reduced. When the pair of mirrors 21 and 22 and the plurality of spacers 70 are assembled to the case 23, there is a dimensional tolerance in the thickness direction of the pair of mirrors 21 and 22. The second cushioning material 60 has an elasticity that can prevent rattling between members due to dimensional errors during assembly. For this reason, rattling can be easily prevented by the second cushioning material 60 also serving as an elastic member.

  The above description can be summarized with reference to FIGS. 3 and 6 as follows.

  The plurality of spacers 70 interposed between the pair of mirrors 21 and 22 facing each other have a plurality of first contact portions 73 and a plurality of second contact portions 74. The plurality of first and second contact portions 73 and 74 can make partial contact with the plate surfaces of the mirrors 21 and 22. That is, the plate surfaces of the pair of mirrors 21 and 22 are not in contact with the entire plurality of spacers 70.

  It is easier to manage the dimensional tolerances of the tips of the first and second contact portions 73 and 74 than to manage the dimensional tolerances of the first and second case halves 30 and 40. . Therefore, the distance between the pair of mirrors 21 and 22 and the predetermined angle can be easily defined by the plurality of first and second contact portions 73 and 74. Without being affected by the case 23, the distance between the pair of mirrors 21 and 22 and a predetermined angle can be accurately ensured. As a result, an image in the blind spot region can be projected on the pair of mirrors 21 and 22 without distortion. The so-called visibility in which the viewer Mn clearly sees the image in the blind spot area Ad shown in FIG. 2 can be improved.

  Further, the first facing surface 37 that faces the plate surface of the semi-transmissive mirror 21 in the first case half 30 has a plurality of mirror support portions 38. The plurality of mirror support portions 38 can partially contact the semi-transmissive mirror 21. The semi-transmissive mirror 21 can be supported by the plurality of mirror support portions 38 and the plurality of first contact portions 73. In addition, an outer buffer portion 63 of the second buffer material 60 is provided on the second facing surface 44 that faces the plate surface of the mirror 22 in the second case half 40. The mirror 22 can be supported by the outer buffer portion 63 and the plurality of second contact portions 74. As described above, the pair of mirrors 21 and 22 can be arranged at an accurate position in the case 23, and the flatness of the pair of mirrors 21 and 22 can be increased and supported.

  Furthermore, the plurality of first fitting holes 39 of the first case half 30 are located in the vicinity of the plurality of mirror support portions 38. The fitting portions 71 and 72 of the plurality of spacers 70 can be fitted into the plurality of first and second fitting holes 39 and 46 provided in the case 23. Only with such a fitting structure, the plurality of first and second contact portions 73 and 74 can be accurately and easily positioned with respect to the plurality of mirror support portions 38. Moreover, each first fitting portion 71 extends in the mirror thickness direction along the edge 21 g of the semi-transmissive mirror 21 via the plurality of connecting portions 56 of the first cushioning material 50. Each second fitting portion 72 extends in the mirror thickness direction along the edge 22d of the mirror 22 via the plurality of connecting portions 66 of the second cushioning material 60. Therefore, the pair of mirrors 21 and 22 can be easily positioned with respect to the case 23 in the direction Fb (see FIG. 6) along the plate surfaces of the pair of mirrors 21 and 22. In addition, the angle θ (see FIG. 2) between the pair of mirrors 21 and 22 can be ensured with higher accuracy.

  Further, the positions of the plurality of first contact portions 73 coincide with the positions of the plurality of mirror support portions 38 when viewed from the surface direction Fa of the semi-transmissive mirror 21. The positions of the plurality of first contact portions 73 and the positions of the plurality of second contact portions 74 are in agreement (overlapping) with each other when viewed from the plane direction Fa of the semi-transmissive mirror 21. As a result, the positions of the plurality of mirror support portions 38 and the plurality of first and second contact portions 73 and 74 coincide with each other when viewed from the plane direction Fa of the semi-transmissive mirror 21. For example, each one of the mirror support portions 38 and the first and second contact portions 73 and 74 are arranged in a straight line (overlapping) in the direction perpendicular to the surface Fa of the semi-transmissive mirror 21. For this reason, the mirrors 21 and 22 are supported by the mirror support portion 38 and the contact portions 73 and 74 that are in positions that coincide with each other as viewed from the direction perpendicular to the plane Fa of the semi-transmissive mirror 21. The

  For example, consider a case where a force is applied from the plurality of mirror support portions 38 of the first case half 30 to the plate surface of the semi-transmissive mirror 21. This force passes through each mirror support portion 38, each contact portion 73, 74, and the outer buffer portion 63 that are in a position coincident with each other when viewed from the plane direction Fa of the semi-transmissive mirror 21, and passes through the second case half 40. It is transmitted as it is. For this reason, excessive concentration of bending force does not occur in the pair of mirrors 21 and 22. Therefore, distortion generated in the pair of mirrors 21 and 22 due to the applied force can be further prevented.

  Furthermore, the number of the plurality of mirror support portions 38 and the number of the first and second contact portions 73 and 74 are three each. When the mirror support part 38 and the contact parts 73 and 74 are “two” respectively, it is not easy to ensure the flatness of the pair of mirrors 21 and 22. In addition, when there are “four” mirror support portions 38 and the respective contact portions 73 and 74, there are four support points. It is not easy to manage each dimensional tolerance so that the pair of mirrors 21 and 22 is uniformly supported by four support points while ensuring the flatness of the pair of mirrors 21 and 22. On the other hand, in the present embodiment, the number of the mirror support portions 38 and the contact portions 73 and 74 is “three”. With the three support points, the pair of mirrors 21 and 22 can be supported relatively easily and uniformly and stably.

  Furthermore, the shape of the plurality of mirror support portions 38 is a protruding spherical shape. For this reason, the plurality of mirror support portions 38 can be brought into point contact with the plate surface of the semi-transmissive mirror 21. The tips of the plurality of mirror support portions 38 are easily set to dimensions as designed. Moreover, the shape of the plurality of first and second contact portions 73 and 74 is a protruding spherical shape. Therefore, the plurality of first and second contact portions 73 and 74 can be brought into point contact with the plate surfaces of the pair of mirrors 21 and 22. The tips of the plurality of first and second contact portions 73 and 74 are easily set to dimensions as designed.

  Furthermore, the outer buffer part 63 is made of an elastic material. When the pair of mirrors 21 and 22 and the spacer 70 are assembled to the case 23, there is a dimensional tolerance in the thickness direction of the pair of mirrors 21 and 22. The outer buffer part 63 has elasticity that can prevent rattling between members due to dimensional errors during assembly. For this reason, rattling can be easily prevented by the outer buffer part 63.

  Further, each mirror support portion 38 that supports the semi-transmissive mirror 21 is not constituted by an elastic member. Only the outer cushioning portion 63 of the second cushioning material 60 that supports the mirror 22 is constituted by an elastic member. That is, the elastic member is located only on the back surface of the mirror 22 (the surface opposite to the reflecting surface 22a). For this reason, the elastic member cannot be seen from the viewer Mn side (see FIG. 2). The appearance of the blind spot assisting device 20 can be improved.

  Although the blind spot assisting device 20 according to the present invention has been described as an example provided in the vehicle 10, it can be applied to other vehicles and is not limited to these types. That is, the present invention is not limited to the examples as long as the operations and effects of the present invention are exhibited.

  Although the blind spot assisting device 20 of the present embodiment is disposed on the right front pillar 11 when viewed from the driver's seat side of the vehicle 10, a similar blind spot assisting device 20 is disposed on the left front pillar 11. May be. In addition to the front pillar 11 as an obstacle in the vehicle 10, the blind spot assisting device 20 may be disposed on a center pillar, a rear pillar, or the like, and may display an image of a blind spot area blocked by these.

  Further, the present invention can be widely applied to fields other than the vehicle 10 as the blind spot assisting device 20 that projects the image of the object Oj in the blind spot area Ad blocked by the obstacle. For example, when the blind spot assisting device 20 according to the present invention is used in a house, the blind spot assisting device 20 of the ceiling is attached to the ceiling and only the incident part is exposed to the outdoors from the wall or the like by attaching the large area blind spot assisting device 20 to the ceiling. You can see the sky and guide the sunlight from the ceiling indoors. It is particularly suitable for densely populated houses and houses with circumstances where ordinary windows cannot be attached.

  Also, for example, in a high-rise building such as a tourist facility, a blind spot assisting device 20 having a large area is embedded under the floor of a higher floor, and only the light incident portion is exposed to the outside. It is possible to feel under the feet and emphasize the height of the building. In order to obtain the same effect, conventionally, it was necessary to provide a space under the floor, but the blind spot assisting device 20 of the present invention is suitable because it can be easily arranged in an existing building.

  In addition, as an example used for the wall surface, the blind spot assisting device 20 of the present invention is arranged at the corner of the saddle at an intersection where the fence is standing close to the road and the line of sight is bad, thereby walking the blind spot area Ad. Can quickly recognize the presence of people and vehicles, and contribute to the prevention of accidents at the beginning of encounters.

  In addition, the pair of mirrors 21 and 22 of the present invention may be a plate-like configuration disposed so as to face each other, and may be a curved mirror in addition to the flat plate mirror. For example, the pair of mirrors 21 and 22 can have a curved configuration when the vehicle 10 is viewed from above (see Japanese Patent Application Laid-Open No. 2006-094117). More specifically, the reflecting surface 21a of the semi-transmissive mirror 21 has a concave curved shape. The reflection surface 22 a of the mirror 22 has a curved surface shape that is convex toward the reflection surface 21 a of the semi-transmissive mirror 21.

  The base material of the pair of mirrors 21 and 22 of the present invention is not limited to inorganic glass, and may be a resin sheet, for example.

  The blind spot assisting device 20 of the present invention is suitable for use in the left and right front pillars 11 of the vehicle 10.

10 Vehicle 11 Obstacle (front pillar)
20 Blind Spot Auxiliary Device 21 Semi-Transparent Mirror 21a Reflective Surface 21g Edge of Semi-Transparent Mirror 22 Mirror 22a Reflective Surface 22d Mirror Edge 23 Case 50 First Buffer Material 60 Second Buffer Material 70 Spacer Ad Blind Spot Area Fa Direction La Light representing the image Mn Viewer Oj Object present in the blind spot area

Claims (3)

A blind spot assisting device that displays an image of an object in a blind spot area that is blocked by an obstacle and cannot be seen by a viewer,
A plate-shaped semi-transmissive mirror that is located on the viewer side, is incident on the light representing the image and reflects part of it and transmits the rest;
A plate-like mirror that faces the reflective surface of the semi-transmissive mirror with a gap and reflects the reflected light toward the semi-transmissive mirror;
Including a semi-transparent mirror and a case for storing the mirror,
The blind spot assisting device, wherein an edge of the semi-transmissive mirror and an edge of the mirror are respectively held by the case with a cushioning material over the entire circumference.   The blind spot assisting device according to claim 1, wherein the cushioning material is made of an elastic material. Between the semi-transmissive mirror and the mirror, there is a spacer that keeps the distance between them constant,
The blind spot assisting device according to claim 1 or 2, wherein the cushioning material also serves as an elastic member that generates a force for bringing the semi-transmissive mirror and the mirror into close contact with each other via the spacer. .

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