JP2016190609A - Inner mirror - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent interference between a mirror and a sun visor in an inner mirror using a pivot structure having high versatility.SOLUTION: An inner mirror 1 includes: a mirror 11; a stay 20 in which a first pivot part 22 having a spherical shape is provided at one end side and a second pivot part 23 having a spherical shape is provided at the other end side; a first spherical bearing 13 integrated with the mirror 11 and with which the first pivot part 22 is rotatably connected; a second spherical bearing 32 attached to a vehicle body of a vehicle and with which the second pivot part 23 is rotatably connected; and rotation restriction parts 23a, 33 which restrict a rotation direction of the second pivot part 23 relative to the second spherical bearing 32 only to a fore and aft direction of the vehicle.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an inner mirror.

  Conventionally, an inner mirror in which a mirror or the like is rotatably connected to a stay is known. For this connection, a pivot structure in which a spherical pivot portion is connected to a spherical bearing is generally used. The inner mirror includes a one-pivot structure in which a pivot structure is provided only on the mirror side of both ends of the stay, and a two-pivot structure in which a pivot structure is provided at each end of the stay.

  In the 1-pivot structure and the 2-pivot structure, the direction of the mirror can be adjusted by rotating the mirror about the pivot part on the mirror side. In the two-pivot structure, the height of the mirror or the horizontal position of the mirror (in the vehicle width direction) is further increased by rotating the stay in the vehicle front-rear direction or the left-right direction around the base-side pivot portion attached to the vehicle body. Position) can be adjusted. When the one pivot structure is adopted, the height of the mirror cannot be adjusted. Therefore, it is necessary to design the length of the stay according to the configuration of each vehicle type (for example, the angle of the windshield). On the other hand, the two-pivot structure does not require this, and the driver can adjust the height of the mirror according to the height of the viewpoint. Patent Document 1 describes an inner mirror having a two-pivot structure.

Japanese Patent No. 3873790

  By the way, in the conventional inner mirror having the two-pivot structure, the stay can be rotated in the left-right direction around the pivot portion on the base side, so that the lateral position of the mirror can be adjusted. However, if the mirror overlaps the sun visor when the vehicle is viewed from the side, the mirror may enter the movable area of the sun visor and the mirror may interfere with the sun visor.

  An object of the present invention is to prevent a mirror from interfering with a sun visor in an inner mirror using a pivot structure having high versatility.

  1st invention is the inner mirror provided in the room | chamber interior of a vehicle, Comprising: A spherical 1st pivot part was provided in the one end side, and the spherical 2nd pivot part was provided in the other end side A stay, a first spherical bearing integrated with the mirror and rotatably connected to the first pivot portion; and a second spherical bearing attached to the vehicle body of the vehicle and rotatably connected to the second pivot portion. A spherical bearing and a rotation restricting portion that restricts the rotational direction of the second pivot portion relative to the second spherical bearing only in the vehicle front-rear direction.

  In the first invention, the second pivot portion of the stay is connected to the second spherical bearing attached to the vehicle body. When the driver rotates the stay, the second pivot portion rotates with respect to the second spherical bearing. In the first invention, the rotation blocking portion restricts the rotation direction of the second pivot portion relative to the second spherical bearing only in the vehicle front-rear direction. The driver can rotate the stay in the front-rear direction of the vehicle around the second pivot portion, but cannot rotate the stay in the left-right direction. For this reason, the horizontal position of the mirror cannot be adjusted by rotating the second pivot portion.

  The second invention is an inner mirror provided in a vehicle interior, wherein the mirror and a spherical first pivot portion are provided on one end side, and a spherical second pivot portion is provided on the other end side. A stay, a first spherical bearing integrated with the mirror and rotatably connected to the first pivot portion; and a second spherical bearing attached to the vehicle body of the vehicle and rotatably connected to the second pivot portion. Rotation restriction for restricting movement of the first pivot part side of the stay in the left-right direction of the vehicle by restricting rotation of the second pivot part relative to the spherical bearing and the second spherical bearing in the left-right direction of the vehicle Department.

  In the second invention, the rotation preventing portion restricts the rotation of the second pivot portion relative to the second spherical bearing in the left-right direction of the vehicle, so that the first pivot portion side of the stay moves in the left-right direction of the vehicle. To regulate. Due to the restriction of the rotation of the second pivot part, the driver cannot adjust the lateral position of the mirror.

  In each of the first invention and the second invention, the lateral position of the mirror cannot be adjusted. Therefore, even when the mirror overlaps the sun visor when the vehicle is viewed from the side, the mirror does not interfere with the sun visor. In the inner mirror using the pivot structure having high versatility, the mirror can be prevented from interfering with the sun visor.

Schematic structural diagram showing a cross section of the inner mirror according to the embodiment cut in the vertical direction Schematic structural diagram showing the AA cross section of FIG. 1 in the inner mirror according to the embodiment FIG. 1B is a view of the inner mirror according to the embodiment in FIG. The arrow view of the inner mirror which concerns on the modification 1 of the same direction as FIG. Schematic structural diagram showing a cross section of the inner mirror according to Modification 2 cut at the same position as AA in FIG. The perspective view of the 2nd mirror surface bearing of the inner mirror which concerns on the modification 2.

  Hereinafter, embodiments will be described in detail with reference to FIGS.

[Overview]
The present embodiment is an inner mirror (back mirror) having a two-pivot structure provided in a vehicle interior. In the inner mirror, in order to prohibit adjustment of the horizontal position of the mirror, the rotation direction of the pivot portion on the windshield side of the stay is restricted to only the front-rear direction of the vehicle front-rear direction and left-right direction.

[Inner mirror structure]
As shown in FIG. 1, the inner mirror 1 includes an inner mirror main body 10, a stay 20, and a base 30. In the inner mirror 1, the base 30 is attached to the inner surface of the upper part of the windshield 40 of the vehicle. The inner mirror body 10 is supported on the base 30 via the stay 20. The inner mirror 1 is disposed between the sun visor 43 in the driver seat and the sun visor 43 in the front passenger seat when viewed from the front of the vehicle. On the inner surface of the windshield 40, a camera 41 for photographing the front of the vehicle is attached slightly below the base 30. The base 30 and the camera 41 are covered with a cover 42.

  The inner mirror main body 10 includes a mirror 11, a mirror casing 12, and a first spherical bearing 13. The mirror 11 is attached to the mirror casing 12 so that the mirror surface faces the rear of the vehicle. The mirror casing 12 has a through hole 12a formed in the front surface portion. The stay 20 is inserted through the through hole 12a.

  The first spherical bearing 13 is attached to the inner surface of the mirror casing 12. The first spherical bearing 13 is integrated with the mirror 11 via the mirror casing 12. The first spherical bearing 13 is, for example, a resin member. The first spherical bearing 13 is rotatably connected to a first pivot portion 22 described later that is press-fitted through the through hole 12a.

  As shown in FIG. 1, the stay 20 includes a rod-like stay main body 21, a spherical first pivot portion 22 provided on one end side of the stay main body 21, and a spherical shape provided on the other end side of the stay main body 21. The second pivot portion 23 is provided. The stay main body 21 has a bar shape bent in a side view. A cylindrical first protrusion 22 a is formed on the outer peripheral surface of the first pivot portion 22. The first protrusion 22 a protrudes from the back side of the connection portion of the stay body 21 on the outer peripheral surface of the first pivot portion 22. The second pivot portion 23 is formed with a cylindrical second protrusion 23a. The second protrusion 23 a protrudes from the back side of the connection portion of the stay body 21 on the outer peripheral surface of the second pivot portion 23.

  As shown in FIG. 1, the base 30 includes a casing 31 and a second spherical bearing 32. The casing 31 is attached to the windshield 40. The casing 31 is open on the windshield 40 side. A through hole 31 a is formed in the casing 31 on the side opposite to the windshield 40. The stay 20 is inserted through the through hole 31a. In addition, although the base 30 is attached to the windshield 40, you may be attached to the ceiling of the compartment.

  The second spherical bearing 32 is attached to the windshield 40. The second spherical bearing 32 is attached to the vehicle body via the windshield 40. The second spherical bearing 32 is a resin member, for example. A second pivot portion 23 press-fitted through the through hole 31a is rotatably connected to the second spherical bearing 32. Note that the second spherical bearing 32 may be attached to the casing 31. Further, the base 30 and the second spherical bearing 32 may be attached to the windshield 40 via a member such as a base plate.

[Structure for adjusting the orientation or position of the mirror]
The first spherical bearing 13 has a bearing surface 13a that slidably holds the first pivot portion 22. The inlet to the bearing surface 13 a when the first pivot portion 22 is press-fitted is located immediately inside the through hole 12 a in the mirror casing 12. The bearing surface 13 a is configured by a spherical surface having approximately the same size as the first pivot portion 22.

  Further, the first spherical bearing 13 is formed with a through hole 13b extending from the bearing surface 13a to the mirror 11 side. The first protrusion 22a of the first pivot portion 22 is inserted into the through hole 13b. Although illustration is omitted, the through-hole 13b has a circular shape, for example, and the length in the vertical direction of the vehicle and the length in the vehicle width direction are larger than the diameter of the first protrusion 22a. Therefore, the driver rotates the inner mirror body 10 in the front-rear direction or the left-right direction around the first pivot portion 22 until the hole surface of the through hole 13b contacts the first protrusion 22a. The direction of the mirror 11 can be adjusted. When the inner mirror body 10 is rotated, the hole surface of the through hole 13b contacts the first protrusion 22a before the edge of the through hole 12a contacts the stay 20.

  Next, the second spherical bearing 32 will be described. The second spherical bearing 32 has a bearing surface 32a that holds the second pivot portion 23 slidably. The inlet to the bearing surface 32 a when the second pivot portion 23 is press-fitted is located immediately inside the through hole 31 a in the casing 31. The bearing surface 32 a is configured by a spherical surface having approximately the same size as the second pivot portion 23.

  The second spherical bearing 32 is formed with a through-hole (slit) extending from the bearing surface 32a to the windshield 40 side. As shown in FIGS. 1 and 2, the through hole and the windshield 40 form a base groove 33 that opens on the bearing surface 32a side. The second protrusion 23 a of the second pivot portion 23 is inserted into the base groove 33.

  As shown in FIG. 1, the base groove 33 extends obliquely upward from the front side to the rear side of the vehicle. As shown in FIG. 3, the base groove 33 has a substantially rectangular shape in a front view of the windshield 40. In the base groove 33 shown in FIG. 3, the height is larger than the width. The width of the base groove 33 (that is, the length in the vehicle width direction) is slightly larger (substantially the same) than the diameter of the second protrusion 23a. The second protrusion 23 a is movable in the longitudinal direction of the base groove 33 (in the direction of the arrow shown in FIG. 3). The second protrusion 23 a is formed on the second spherical bearing 32 until it contacts the wall surface 33 a extending in the short direction in the base groove 33. On the other hand, the second pivot portion 23 can be rotated in the front-rear direction. The driver can rotate the stay 20 in the front-rear direction in order to adjust the height of the inner mirror body 10. When the second pivot portion 23 is rotated in the front-rear direction, the second protrusion 23 contacts the wall surface 33a before the stay 20 contacts the edge of the through hole 31a.

  Further, the movement of the second protrusion 23 a in the width direction of the base groove 33 is restricted by the wall surface 33 b extending in the longitudinal direction in the base groove 33. The second protrusion 23 a cannot move in the width direction of the base groove 33, and the second pivot portion 23 cannot be rotated in the left-right direction with respect to the second spherical bearing 32. Even if the driver tries to rotate the stay 20 in the left-right direction, the stay 20 cannot be rotated, and the lateral position of the inner mirror body 10 cannot be adjusted. The base groove 33, together with the second protrusion 23 a, is a rotation restricting portion that restricts the rotational direction of the second pivot portion 23 relative to the second spherical bearing 32 only in the vehicle front-rear direction (second relative to the second spherical bearing 32. By restricting the rotation of the pivot portion 23 in the left-right direction of the vehicle, a rotation restricting portion that restricts the movement of the first pivot portion 22 side of the stay 20 in the left-right direction of the vehicle is configured.

[Effect of the embodiment]
In the present embodiment, since the rotation direction of the second pivot portion 23 is restricted only in the vehicle front-rear direction, the lateral position of the mirror 11 cannot be adjusted. Therefore, even when the mirror 11 (inner mirror main body 10) overlaps with the sun visor 43 when the vehicle is viewed from the side, the mirror 11 does not interfere with the sun visor 43. In the inner mirror 1 using a pivot structure having high versatility, the mirror 11 can be prevented from interfering with the sun visor 43. In addition, since the second pivot portion 23 is used as the rotation mechanism of the stay 20, the height of the mirror 11 can be adjusted smoothly. A wide sun visor 43 can also be installed.

  It should be noted that, when the camera 41 is attached to the inner surface of the windshield 40 beside the base 30 of the inner mirror 1, it does not look good. In this embodiment, the base 30 and the camera 41 are moved up and down as shown in FIG. And is covered with a cover 42. In this case, for example, the cover 42 needs to be hidden by the inner mirror 1 when viewed from the driver in order to conform to the safety standards of the vehicle, and the front 42 does not deteriorate in appearance because the size of the cover 42 increases. A base 30 and a camera 41 are attached above and behind the glass 40. In this case, since the entire inner mirror 1 is disposed on the rear side, in the conventional inner mirror capable of adjusting the horizontal position of the mirror, the mirror may interfere with the sun visor. On the other hand, in this embodiment, the base 30 can be attached to the rear side position of the windshield 40 without interference between the mirror 11 and the sun visor 43. Therefore, it is possible to conform to the above-described security standard and to further improve the appearance of the cover 42.

  In the present embodiment, the rotation restricting portion is configured by the second protrusion 23 a and the base groove 33. Therefore, the rotation restricting portion can be configured by a simple design change that changes the shape of the base groove 33 (through hole) in the second spherical bearing 32.

[Modification 1]
In Modification 1, as shown in FIG. 4A, the second protrusion 23a is formed in a prismatic shape (in FIG. 4A, a regular polygonal columnar shape). The second protrusion 23a is formed in a prismatic shape having an even number of corners (in FIG. 4A, a hexagonal columnar shape). Further, the distance between the opposing side surfaces of the second protrusion 23a is slightly smaller (substantially the same) than the width of the base groove 33 (the distance between the wall surfaces 33b). In the second protrusion 23a, a pair of opposing side surfaces extend substantially parallel to the wall surface 33b. Thereby, in the modification 1, rotation centering on the axis | shaft of the B arrow direction of FIG. 1 can also be prevented.

  Further, as shown in FIG. 4B, the second protrusion 23a may be formed in an elliptic cylinder shape. In this case, for example, the dimension (major axis) of the elliptical long axis of the second protrusion 23a is slightly smaller (substantially the same) than the width of the base groove 33 (the distance between the wall surfaces 33b). Thereby, even if it is the 2nd protrusion 23a formed in the elliptical column shape, the rotation centering on the axis | shaft of the B arrow direction of FIG. 1 can be prevented.

[Modification 2]
Modification 2 differs from the above-described embodiment in the configuration of the rotation restricting portion. Specifically, the structures of the second pivot portion of the stay and the second spherical bearing are different from those of the above-described embodiment. In addition, the cross section which cut | disconnected the inner mirror which concerns on the modification 2 in the up-down direction is the same as the cross section of the inner mirror of embodiment shown in FIG. FIG. 5 shows a cross section of the inner mirror according to Modification 2 cut at the same position as AA in FIG. FIG. 6 is a perspective view of the second mirror bearing with the windshield side facing upward.

  In the second modification, as shown in FIG. 5, a pair of side protrusions 23 b that protrude laterally from the spherical surface of the second pivot part 23 are formed on the second pivot part 23 of the stay 20. The pair of side protrusions 23b are formed symmetrically. Each side protrusion 23b is formed in a cylindrical shape. The axial centers of the side protrusions 23 b coincide with each other and pass through the center of the pivot portion 23. The pair of side protrusions 23 b constitute a rotation shaft that extends in the vehicle width direction through the center of the second pivot portion 23.

  The second spherical bearing 32 is formed with a pair of bearing portions 34 serving as bearings for the side projections 23b at positions corresponding to the pair of side projections 23b. Each bearing portion 34 is a substantially circular hole, and is connected to a slit portion 35 extending to the side opposite to the windshield 40 side (lower side in FIG. 6). The shaft centers of the bearing portions 34 coincide with each other and pass through the center of the bearing surface 32a (movable center of the pivot portion 23). The diameter of each bearing part 34 is slightly larger than the diameter of each side protrusion 23b. The width of the slit portion 35 is smaller than the diameter of each side protrusion 23b.

  When the second pivot portion 23 is press-fitted into the second spherical bearing 32, each side projection 23 b extends the slit portion 35, passes through the slit portion 35, and fits into the bearing portion 34. Each side protrusion 23b is rotatably held by a bearing portion 34. In this state, the bearing surface 32a is in contact with the second pivot portion 23 from the left and right. Accordingly, the rotation direction of the second pivot portion 23 is restricted only in the front-rear direction of the vehicle, and the lateral position of the mirror 11 cannot be adjusted, so that the mirror 11 can be prevented from interfering with the sun visor 43. Further, since the second pivot portion 23 is used, the height of the mirror 11 can be adjusted smoothly.

  Further, in a state in which each side protrusion 23 b is fitted in the bearing portion 34, the slit portion 35 prevents each side protrusion 23 b from being detached from each bearing portion 34. In the second modification, in order to prevent the side protrusions 23b from coming off from the bearings 34, the slits 35 in the second spherical bearing 32 are prevented by an annular elastic member 36 (for example, a rubber ring). The position of is tightened. By this tightening, the bearing surface 32 a is pressed against the pivot portion 23. This pressing force acts as a pivot torque on the driver that rotates the stay 20. When the pivot torque is insufficient due to the slit portion 35, the pivot torque can be improved by the elastic member 36.

  The present invention is applicable to an inner mirror or the like.

DESCRIPTION OF SYMBOLS 1 Inner mirror 10 Inner mirror main body 11 Mirror 12 Mirror casing 13 1st spherical bearing 20 Stay 21 Stay main body 22 1st pivot part 23 2nd pivot part 23a 2nd protrusion 30 Base 31 Casing 32 2nd spherical bearing 33 Base groove

Claims (2)

An inner mirror provided in a vehicle interior,
Mirror,
A stay provided with a spherical first pivot portion on one end side and a spherical second pivot portion on the other end side;
A first spherical bearing integrated with the mirror and rotatably connected to the first pivot portion;
A second spherical bearing attached to the vehicle body of the vehicle and having the second pivot portion rotatably connected thereto;
An inner mirror, comprising: a rotation restricting portion that restricts a rotation direction of the second pivot portion relative to the second spherical bearing only in a front-rear direction of the vehicle. An inner mirror provided in a vehicle interior,
Mirror,
A stay provided with a spherical first pivot portion on one end side and a spherical second pivot portion on the other end side;
A first spherical bearing integrated with the mirror and rotatably connected to the first pivot portion;
A second spherical bearing attached to the vehicle body of the vehicle and having the second pivot portion rotatably connected thereto;
By restricting the rotation of the second pivot portion with respect to the second spherical bearing in the left-right direction of the vehicle, the movement of the first pivot portion side of the stay in the left-right direction of the vehicle is restricted. An inner mirror having a rotation restricting portion.

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