JP2014124964A - Vibration reduction mirror - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a back mirror for a motor cycle which prevents mass increase and damages and reduces vibrations.SOLUTION: A mirror 10 includes: a mirror body 13 which reflects images; a mirror housing 12 which holds the mirror body 13; a mirror stay 11 for attaching the mirror housing 12 directly or indirectly to a structure serving as an exciting source; and a joint mechanism 14 having a stay side joint part 31 and a housing side joint part 32 which contact each other and rotatably connecting the mirror housing 12 to the mirror stay 11. The mirror housing 12 is made of a synthetic resin material and at least a portion 41 of the housing side joint part 32, which contacts the stay side joint part 31, is made of a metal material.

Description

  The present invention relates to a mirror with reduced vibration.

  Conventionally, many mirrors have been used in various scenes such as safety confirmation. For example, a rearview mirror is mounted on the front part of a motorcycle so that the driver can visually recognize the rear of the vehicle while facing the front of the vehicle. The rearview mirror includes a mirror stay attached to the vehicle body and a mirror housing that holds the mirror, and the mirror housing is attached to an end of the mirror stay. The rearview mirror may include a joint mechanism for rotatably connecting the mirror housing to the mirror stay so that the mirror angle can be appropriately adjusted according to the physique and riding posture of the driver.

  While the motorcycle is running, the rearview mirror may vibrate using the engine as a main vibration source. When the rearview mirror vibrates, it is difficult for the driver to visually recognize the rear side of the vehicle. Conventionally, rearview mirrors that suppress vibrations have been proposed (see, for example, Patent Documents 1 and 2).

  In Patent Document 1, a weight for suppressing vibration is built in the mirror housing. The vibration suppression weight is supported by a weight support portion protruding from the inner surface of the mirror housing via a weight support having elasticity. Also in Patent Document 2, an anti-vibration weight is built in the mirror housing. The anti-vibration weight is attached to the back surface of the mirror packing via an elastic member. Both the vibration suppression weight and weight support assembly in Patent Document 1 and the vibration isolating weight and elastic member assembly in Patent Document 2 are expected to function as dynamic vibration absorbers.

Japanese Patent No. 2764913 Japanese Utility Model Publication No. 59-106740

  When a mirror is installed on a structure serving as a vibration source such as a motorcycle or the like, the mirror vibrates, and there is a problem that visibility of an image projected on the mirror is lowered.

  In general mechanical structures, the frequency band of the vibration source is limited, and incidental objects such as mirrors and some of the mechanical structures (hereinafter simply referred to as “vibrated bodies”) When the natural frequency exists in the frequency band of the vibration source, excessive vibration may occur due to resonance due to vibration of the vibration source.

  As a method for reducing the vibration of the vibrating body, for example, the natural frequency of the vibrating body may be separated (detuned) from the frequency band of the vibration source. In order to reduce the natural frequency of the vibrating body, it is conceivable to increase the mass of the vibrating body (increase in mass) and to lower the supporting rigidity of the vibrating body (decrease in supporting rigidity). On the other hand, in order to increase the natural frequency of the oscillating body, it is conceivable to reduce the mass of the oscillating body (mass reduction) or increase the supporting rigidity of the oscillating body (increasing support rigidity). . If the natural frequency can be sufficiently detuned from the lower limit frequency or the upper limit frequency of the frequency band of the excitation source by these methods, the vibration of the vibrating body can be reduced.

  For example, in a motorcycle rearview mirror, when vibration is reduced by detuning, the engine idling speed and the maximum speed are determined for the motorcycle, and the lower limit frequency and the upper limit frequency are determined by these engine speeds. . Therefore, in principle, vibration can be reduced if the natural frequency of the rearview mirror can be sufficiently detuned from the lower limit frequency or the upper limit frequency of the engine. However, in an actual rearview mirror, the engine vibration has a frequency distribution, and due to structural design restrictions, resonance may occur due to insufficient detuning, and vibration may not be sufficiently reduced.

  Furthermore, as another method for reducing vibration of the vibrating body, it is conceivable to use a dynamic vibration absorber as described in Patent Documents 1 and 2.

  The dynamic vibration absorber can reduce the vibration of the vibration mode by causing the dynamic vibration absorber to resonate by matching the natural frequency of the specific vibration mode with the natural vibration frequency of the dynamic vibration absorber.

  However, for example, there are various vibration modes in a rearview mirror or the like, and there are various natural frequencies corresponding to the vibration modes. Therefore, in any of the rearview mirrors of Patent Documents 1 and 2, it is difficult to reduce vibration except in a vibration mode in which the dynamic vibration absorber exhibits a vibration reduction effect. In some cases, the vibration generated by the resonance of the dynamic vibration absorber is transmitted to the rearview mirror, thereby aggravating the rearview mirror vibration. Furthermore, the rear-view mirror using a dynamic vibration absorber may drop off undesirably due to the vibration of the rear-view mirror or the fall of the vehicle. The risk that the dynamic vibration absorber rolls in the mirror housing breaks the mirror.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a mirror with reduced vibration even when installed in a structure serving as a vibration source.

  A vibration reduction mirror according to the present invention includes a mirror main body that captures an image, a mirror housing that holds the mirror main body, and a mirror stay that directly or indirectly attaches the mirror housing to a structure serving as a vibration source. A stay side joint portion and a housing side joint portion that contact each other, and a joint mechanism that rotatably connects the mirror housing to the mirror stay, wherein the mirror housing is a synthetic resin material, Of the housing-side joint portion, at least a portion that contacts the stay-side joint portion is a metal material.

  According to the said structure, since the housing side joint part is metal, the contact rigidity of a joint mechanism becomes high, and the natural frequency can be kept high in the vibration mode where the support rigidity of a joint mechanism is dominant. For this reason, it becomes easy to detune this natural frequency from the upper limit frequency of the vibration source, and the vibration of the mirror can be reduced. Even when the detuning is insufficient and resonance is unavoidable, generally, the vibration tends to decrease as the support rigidity increases, so that the vibration reduction effect of the vibration mode can be obtained.

  In the above configuration, at least a portion of the housing side joint portion that contacts the stay side joint portion is made of a metal material, and the mirror housing is made of a synthetic resin material. Therefore, compared to the case where the entire mirror housing is made of a metal material. Thus, a significant weight reduction can be realized without impairing the support rigidity. Further, since the mirror housing is made of a synthetic resin material, an increase in support rigidity can be realized while minimizing an increase in mass compared to a case where the entire mirror housing is made of a resin material. Furthermore, even in a vibration mode in which the support rigidity of the mirror stay is dominant, it is possible to suppress a decrease in the natural frequency accompanying an increase in the mass of the tip, and to reduce the risk of new resonance.

  In addition, according to the above configuration, the vibration reduction effect can be obtained without using a dynamic vibration absorber, so there is a risk of deterioration of vibration caused by the dynamic vibration absorber, loss of function due to dropping of the dynamic vibration absorber, and mirror damage. Nothing.

  As is clear from the above description, according to the present invention, it is possible to provide a mirror with reduced vibration even when installed in a structure serving as a vibration source.

It is a figure which shows the rear-view mirror which concerns on 1st Embodiment seeing later. It is a bottom view of the mirror housing shown in the direction of arrow II in FIG. FIG. 3 is a cross-sectional view of the rearview mirror cut along the line III-III in FIG. 1. It is a perspective view which shows the front-end | tip component shown in FIG. It is explanatory drawing which shows the example of the vibration mode of a rearview mirror. It is a graph which shows the example of the vibration response of a rearview mirror. It is sectional drawing of the rear-view mirror which concerns on 2nd Embodiment. It is a perspective view which shows the front-end | tip component shown in FIG. It is sectional drawing of the rearview mirror which concerns on 3rd Embodiment. It is sectional drawing of the rear-view mirror which concerns on 4th Embodiment. It is sectional drawing of the rear-view mirror which concerns on 5th Embodiment.

  Hereinafter, embodiments will be described with reference to the drawings. The same or corresponding elements are denoted by the same reference numerals throughout all the drawings, and detailed description thereof is omitted. In each embodiment, a case where a mirror is applied to a motorcycle will be described as an example, but the present invention can be applied to a structure requiring vibration reduction. That is, the mirror is directly or indirectly attached to the structure serving as the vibration source.

  In addition, the concept of direction in the following description is based on the direction viewed from the driver riding on the motorcycle.

(Construction)
FIG. 1 is a diagram showing the rearview mirror 10 according to the first embodiment as seen from the rear. The rearview mirror 10 is attached to the front part of the vehicle body 1 of the motorcycle and is disposed in front of a seat (not shown) on which the driver rides. As a result, the driver can visually recognize the rear of the vehicle while facing the front of the vehicle.

  The vehicle body 1 may be a frame of a motorcycle or another member fixed to the frame. The other member may be an attachment member such as a stay or a bracket fixed to the front end portion of the frame, or a windshield, a headlamp unit, or a cowling member fixed to the frame or the attachment member. The vehicle body 1 supports an engine (not shown) that generates traveling power, and the engine is one of structures that serve as a vibration source for the motorcycle rearview mirror 10.

  The rearview mirror 10 includes a mirror stay 11 attached to the vehicle body 1, a mirror housing 12 that holds a mirror body 13 that captures an image, and a joint mechanism 14 that rotatably connects the mirror housing 12 to the mirror stay 11. Prepare.

  The mirror stay 11 extends from the vehicle body 1 to the outer side in the vehicle width direction and / or the upper side (both sides in the present embodiment). The mirror stay 11 includes a stay arm portion 21 that extends in an arm shape, and a vehicle body attachment portion 22 that is provided at a base end portion of the stay arm portion 21. The vehicle body attachment portion 22 is installed on the vehicle body 1. Although FIG. 1 illustrates the case where the vehicle body attachment portion 22 is in direct contact with the vehicle body 1, an inclusion may exist between the vehicle body attachment portion 22 and the vehicle body 1, and in this case The inclusion is preferably a material that exhibits a function of absorbing vibration, such as an elastic sheet. A bolt 23 projects downward from the vehicle body mounting portion 22. The bolt 23 is screwed into a screw hole 1 a formed in the vehicle body 1, whereby the mirror stay 11 (and thus the entire rearview mirror 10) can be firmly attached to the vehicle body 1.

  The stay arm portion 21 extends upward from the vehicle body 1 and then bends, and further extends outward in the vehicle width direction. In the present embodiment, the stay arm portion 21 is integrally formed with a portion that extends upward, a bent portion, and a portion that extends outward in the vehicle width direction, and is formed of a bent tube material. The pipe material forming the stay arm portion 21 is made of metal such as steel and has a circular cross section. The stay arm portion 21 is bent at an obtuse angle, and the portion extending outward in the vehicle width direction also extends upward. The central axis of the stay arm portion 21 is a portion extending upward from the vehicle body mounting portion 22, and is parallel or coincident with the central axis of the bolt 23. However, the material, shape, and structure of the stay arm portion 21 are merely examples, and can be changed as appropriate.

  FIG. 2 is a bottom view of the mirror housing 12 as seen in the direction of arrow II in FIG. As shown in FIGS. 1 and 2, the mirror housing 12 has a mirror holding portion 26 that holds the mirror main body 13. The mirror holding portion 26 is formed in a bowl shape having an opening 27, and the mirror main body 13 is attached to the mirror holding portion 26 so as to seal the opening 27. In this embodiment, since the rearview mirror 10 includes the rotatable joint mechanism 14, the posture of the mirror body 13 with respect to the mirror housing 12 is fixed. The mirror holding part 26 does not incorporate a mechanism for swinging the mirror main body 13, and the mass of the mirror housing 12 is reduced. Moreover, in this embodiment, the mirror holding | maintenance part 26 does not incorporate a dynamic vibration absorber, and the mass of the mirror housing 12 (as a result, the whole rear-view mirror 10) becomes small.

  As shown in FIG. 1, the joint mechanism 14 rotatably connects the mirror housing 12 to the end of the mirror stay 11. The joint mechanism 14 includes a stay side joint portion 31 provided at an end portion of the mirror stay 11 (in this embodiment, as an example, a tip portion of the stay arm portion 21), and a housing side joint portion provided in the mirror housing 12. The housing side joint part 32 is in contact with the stay side joint part 31 so as to be rotatable. In the present embodiment, the stay side joint portion 31 and the housing side joint portion 32 have a concave spherical surface 38 and a convex spherical surface 42, respectively, and these two spherical surfaces 38 and 42 constitute a spherical pair, and the convex spherical surface 42 is formed. The concave spherical surface 38 abuts on the concave spherical surface 38 (more specifically, so as to be able to perform spherical motion in a spherical pair).

  3 is a cross-sectional view of the rearview mirror 10 cut along the line III-III in FIG. As shown in FIG. 3, the stay side joint part 31 is formed in a cylindrical shape. The stay side joint portion 31 has a through hole 33 extending in the axial direction, and has openings 34 and 35 associated therewith on the proximal end side and the distal end side in the axial direction. The cross section of the base end side opening 34 may have any shape as long as it matches the cross section of the stay arm portion 21. The front end side opening 35 has a circular cross section so that a spherical pair can be formed together with the housing side joint portion 32.

  From the distal end portion of the stay arm portion 21, a cylindrical rod 36 projects further toward the distal end side. The proximal end portion of the rod 36 has an outer diameter smaller than that of the stay arm portion 21, and an annular end surface is formed at the distal end of the stay arm portion 21 when viewed in the axial direction. The rod 36 is inserted through the through hole 33 of the stay side joint portion 31. The base end portion of the stay side joint portion 31 is supported by the annular end surface of the stay arm portion 21. Thereby, the stay side joint part 31 is fixed to the stay arm part 21.

  The distal end portion of the stay side joint portion 31 has an annular end surface surrounding the circular distal end side opening 35, and this end surface is closer to the stay arm portion 21 side from the radially outer peripheral side toward the inner peripheral side. And a concave spherical surface 38 is formed. The stay side joint portion 31 is increased in diameter from the proximal end side in the axial direction toward the distal end side. Therefore, the radius of the concave spherical surface 38 can be increased.

  The housing side joint portion 32 protrudes from the mirror holding portion 26 in a cylindrical shape. The mirror housing 12 is connected to the mirror stay 11 when the housing side joint portion 32 is assembled to the stay side joint portion 31. At this time, the projecting end 41 of the housing side joint portion 32 (the end opposite to the mirror holding portion 26) is pushed into the distal end opening 35 of the stay side joint portion 31, and the distal end portion of the stay side joint portion 31. Abut. The protruding end portion 41 is formed in a substantially hemispherical shape, and the outer surface of the protruding end portion 41 forms a convex spherical surface 42. The radius of curvature of the convex spherical surface 42 is substantially equal to the radius of curvature of the concave spherical surface 38 of the stay side joint portion 31. Therefore, when the protruding end 41 is pushed into the tip opening 35, the two spherical surfaces 38 and 42 are in surface contact, and the center of the convex spherical surface 42 is arranged at the same position as the center of the concave spherical surface 38 (FIG. The two centers are indicated by a single symbol O for convenience).

  As described above, in the present embodiment, the distal end portion of the stay side joint portion 31 is a portion that contacts the housing side joint portion 32, and the concave spherical surface 38 is a surface that actually contacts the housing side joint portion 32. Further, the projecting end portion 41 of the housing side joint portion 32 is a portion that comes into contact with the stay side joint portion 31, and the convex spherical surface 42 is a surface that actually comes into contact with the stay side joint portion 31.

  The two spherical surfaces 38 and 42 constitute a spherical pair, and the housing side joint portion 32 having the convex spherical surface 42 moves in a spherical motion around the center O with respect to the stay side joint portion 31 having the concave spherical surface 38. It can be performed. In this way, the mirror housing 12 is pivotally connected to the mirror stay 11. Therefore, the driver changes the posture of the mirror housing 12 with respect to the mirror stay 11 (and thus the vehicle body 1 (see FIG. 1)) according to his / her physique and riding posture so that the rear of the vehicle can be easily seen. The angle can be adjusted.

  The inner diameter of the base end portion of the stay side joint portion 31 is constant during a certain distance from the base end side opening 34 toward the tip end side in the axial direction. The stay side joint portion 31 is closely fitted to the rod 36 at the portion having the constant inner diameter. As a result, the contact area of the stay side joint portion 31 with the rod 36 increases, the stay side joint portion 31 is firmly attached to the rod 36, and the stay side when the mirror housing 12 is rotated. The load acting on the joint portion 31 can be firmly received by the rod 36 and the stay arm portion 21.

  The housing side joint portion 32 has a joint inner space 43 formed therein, and an opening 44 provided in the protruding end portion 41 of the housing side joint portion 32 to open the joint inner space 43.

  The rod 36 reaches the joint inner space 43 from the distal end portion of the stay arm portion 21 through the distal end side opening 35 of the stay side joint portion 31 and the opening 44 of the housing side joint portion 32. A spring retainer 51 is provided in the joint inner space 43 (specifically, the inner space of the protruding end portion 41). The rod 36 passes through the spring retainer 51. A nut 52 is screwed onto the tip of the rod 36, and the lower surface of the nut 52 is opposed to the support surface of the spring retainer 51 in the axial direction. A spring element 53 such as a disc spring or a coil spring is provided between the lower surface and the support surface. The spring element 53 is provided on the outer peripheral side of the rod 36, and both ends thereof are supported by the lower surface and the support surface, respectively. The spring retainer 51 is biased by the elastic force of the spring element 53 and is pressed against the inner surface of the protruding end portion 41.

  The spring retainer 51 is formed in a hemispherical shape, and the outer surface opposite to the support surface of the spring retainer 51 forms a convex spherical surface 54. The inner surface of the protruding end 41 forms a concave spherical surface 46 having substantially the same radius of curvature as the convex spherical surface 54. For this reason, when the spring retainer 51 is biased, the convex spherical surface 54 comes into surface contact with the concave spherical surface 46, and these two spherical surfaces 46, 54 also constitute a spherical pair, and the centers of these two spherical surfaces 46, 54 are also Are arranged at the same position as the center O of the spherical pair (spherical surfaces 38, 42) described above.

  For this reason, when the mirror housing 12 is rotated with respect to the mirror stay 11, the housing side joint portion 32 having the concave spherical surface 46 becomes convex as well as the spherical motion on the spherical pair (spherical surfaces 38, 42) described above. A spherical movement about the center O is performed on the spring retainer 51 having the spherical surface 54. Accordingly, the mirror housing 12 can be rotated with respect to the mirror stay 11 while the rod 36, the spring element 53, and the spring retainer 51 are fixed to the mirror stay 11.

  Regardless of the attitude of the mirror housing 12 with respect to the mirror stay 11, the convex spherical surface 54 of the spring retainer 51 is pressed against the concave spherical surface 46 of the protruding end portion 41 based on the elastic force of the spring element 53, and thereby the protruding end portion 41. The convex spherical surface 42 is pressed against the concave spherical surface 38 of the stay side joint portion 31. For this reason, the mirror housing 12 can maintain the posture with respect to the mirror stay 11 against the weight of the mirror housing 12 and the traveling wind pressure from the front of the vehicle. In other words, the spring element 53 exhibits a sufficiently large elasticity to maintain the posture of the mirror housing 12 against such an external force.

  In the present embodiment, the joint inner space 43 is connected to the inner space 26 a of the mirror holding portion 26. For this reason, the space for arranging the nut 52 and the spring element 53 can be secured sufficiently wide, and the joint mechanism 14 having the above-described action can be easily provided.

(material)
Next, materials and manufacturing methods of the mirror housing 12 and the joint mechanism 14 will be described. The mirror housing 12 is a synthetic resin material. Of the housing-side joint portion 32 provided in the mirror housing 12, at least a portion in contact with the stay-side joint 31 is a metal material. Any metal material may be used. Conversely, at least the mirror holding portion 26 is a synthetic resin material. In using the synthetic resin material, the mirror housing 12 (mirror holding portion 26) is molded.

  The protruding end portion 41 is a portion that contacts the stay side joint portion 31. In manufacturing the mirror housing 12 according to the present embodiment, a tip part 61 made of a metal material is prepared. When the synthetic resin portion (for example, the mirror holding portion 26) of the mirror housing 12 is molded, the tip part 61 is inserted. The protruding end portion 41 is a portion exposed to the outside of the tip part 61 and is formed by insert molding.

  FIG. 4 is a perspective view of the tip part 61 shown in FIG. As shown in FIG. 4, the tip part 61 has a cylindrical part 62. In the present embodiment, the cylindrical portion 62 has a circular cross section and is formed in a cylindrical shape. The protruding end portion 41 protrudes from the end portion of the cylindrical portion 62. The protruding end portion 41 has a smaller diameter than the cylindrical portion 62, and the protruding end portion 41 is continuous with the cylindrical portion 62 via an annular stepped wall 63. As described above, the protruding end portion 41 is formed in a hemispherical shape, and the outer surface of the protruding end portion 41 forms a convex spherical surface 42 that forms a spherical pair with the concave spherical surface 38 of the stay side joint portion 31. The inner surface of 41 forms a concave spherical surface 46 constituting a spherical spherical pair with the convex spherical surface 54 of the spring retainer 51.

  Returning to FIG. 3, the housing side joint portion 32 according to the present embodiment has a cylindrical portion 64 that protrudes continuously from the mirror holding portion 26 (also shown in FIG. 2). The cylindrical portion 64 is also molded with a synthetic resin material integrally with the mirror holding portion 26. The cylindrical part 62 of the tip part 61 is embedded in a cylindrical part 64 integral with the mirror holding part 26, and the protruding end part 41 projects from the cylindrical part 64 integral with the mirror holding part 26. In this manner, the housing side joint portion 32 having the protruding end portion 41 made of a metal material is integrally provided on the mirror housing 12 made of a synthetic resin material.

  The resin material forming the cylindrical portion 64 covers the inner surface of the step wall 63 of the tip part 61, and a resin wall is laminated inside the step wall 63. Thereby, the front-end | tip component 61 is favorably hold | maintained with a synthetic resin material, and the integrity with the mirror housing 12 of the protrusion edge part 41 can be improved. On the other hand, the resin material forming the cylindrical portion 64 does not reach the outer surface of the protruding end portion 41, and therefore the convex spherical surface 42 of the protruding end portion 41 is maintained as a metal surface. In the present embodiment, the resin material forming the cylindrical portion 64 does not reach the inner surface of the protruding end portion 41, and therefore the concave spherical surface 46 of the protruding end portion 41 is also maintained as a metal surface.

  The stay side joint portion 31 may be made of any material. It is preferable that at least a portion of the stay side joint portion 31 that contacts the housing side joint portion 32 is made of a metal material. For example, at least the distal end portion of the stay side joint portion 31, more specifically, at least the concave spherical surface 38 of the stay side joint portion 31 is preferably made of a metal material. In the present embodiment, the stay side joint portion 31 is made of a metal material as a whole, and therefore the concave spherical surface 38 of the stay side joint portion 31 is a metal surface. The spring retainer 51 may be made of any material. In this embodiment, it is made of a metal material, and the convex spherical surface 54 of the spring retainer 51 is a metal surface.

(Function)
Like the rear-view mirrors for motorcycles listed here, mirrors with a wide distribution of vibration sources and severe structural design constraints are resonant as described above (see the problem to be solved by the invention). Is difficult to avoid completely. Therefore, as a vibration countermeasure when the detuning is insufficient and resonance avoidance is difficult, the natural frequency of the rearview mirror 10 is decreased to detune from the lower limit frequency of the engine vibration serving as the excitation source, or It is conceivable to increase the natural frequency of the rearview mirror 10 so as to detune from the upper limit frequency of engine vibration.

  First, in order to reduce the natural frequency of the rearview mirror 10, the mass of the rearview mirror 10 may be increased or the support rigidity of the rearview mirror 10 may be reduced. However, generally, even if the mass is increased, the effect of reducing the vibration is limited, and if the support rigidity is lowered, the vibration is increased, so that the separation due to the lowering of the natural frequency of the rearview mirror 10 is caused. Adjustment is not sufficient as a vibration countermeasure.

  On the other hand, in order to increase the natural frequency of the rearview mirror 10, the mass of the rearview mirror 10 may be reduced or the support rigidity of the rearview mirror 10 may be increased. However, even if the mass is reduced, the vibration reduction effect is limited, but if the support rigidity is increased, the vibration reduction effect is expected.

  Therefore, the rearview mirror 10 according to the present embodiment includes a mirror housing 12 made of a synthetic resin material and a joint at least part of which is made of metal in order to increase support rigidity while minimizing an increase in mass. By providing the mechanism 14, vibration can be reduced. The operation will be described below.

  First, vibration characteristics when the joint mechanism 14 of the rearview mirror 10 is made of a synthetic resin material (hereinafter simply referred to as “conventional structure”) will be described. The conventional structure is assumed to have the same shape and the same dimensions as the present embodiment, and for convenience of description, the same reference numerals are given to elements having the same shape as the present embodiment in the following description of the conventional structure. Here, for convenience, the case where the rearview mirror 10 is about L1 = 160 mm, L2 = 140 mm, L3 = 170 mm, and Φ1 = 10 mm will be described as an example (see FIG. 1 for L1, L2, L3, and Φ1). ). L1 is a distance in the Y direction to be described later from the vehicle body attachment portion 22 to the center of the mirror body 13, L2 is a distance in the vertical direction from the vehicle body attachment portion 22 to the center of the mirror body 13, and L3 is The dimension of the entire mirror housing 12 in the Y direction will be described later, and Φ1 is the diameter (thickness) of the stay arm portion 21.

  FIG. 5 is a diagram illustrating an example of the vibration mode of the rearview mirror 10. Here, three main vibration modes of the rearview mirror 10 will be described. The vibration mode shown in FIG. 5A is called “mode 1”, the vibration mode shown in FIG. 5B is called “mode 2”, and the vibration mode shown in FIG. 5C is called “mode 3”. XY described in FIGS. 5B and 5C indicates the rotation axis of the mirror housing 12. The horizontal axis Y is directed in the longitudinal direction of the flat mirror body 13 and the mirror housing 12, and the vertical axis X is a direction perpendicular to the horizontal axis Y and perpendicular to the normal direction of the mirror body 13. It is.

  As shown in FIG. 5A, in the mode 1, the mirror housing 12 substantially translates due to the bending of the stay arm portion 21 of the mirror stay 11. Mode 1 is a vibration mode in which the support rigidity of the mirror stay 11 is dominant because it occurs due to the bending of the stay arm portion 21.

  On the other hand, as shown in FIG. 5B, in mode 2, a rotational motion around the vertical axis X of the mirror body 13 occurs. Further, as shown in FIG. 5C, in mode 3, a rotational motion around the horizontal axis Y of the mirror body 13 occurs. Modes 2 and 3 are vibration modes in which the support rigidity of the joint mechanism 14 is dominant in light of the fact that the mirror housing 12 is rotatably connected to the mirror stay 11 in the joint mechanism 14.

  FIG. 6 is a graph showing an example of vibration response of the rearview mirror 10. The horizontal axis indicates the frequency, and the vertical axis indicates the amplitude. The dotted lines in the figure represent the frequency and amplitude of the rearview mirror according to the conventional structure. ω1 is the natural frequency of mode 1, ω2 ′ is the natural frequency of mode 2, and ω3 ′ is the natural frequency of mode 3. In addition, the continuous line in a figure shows the example of the vibration response of the rear-view mirror 10 which concerns on this Embodiment (after-mentioned).

  In the conventional structure, the natural frequencies ω1, ω2 ′, and ω3 ′ of modes 1 to 3 are in the normal engine speed range (frequency range) while the motorcycle is running.

  When it vibrates in mode 1, the mirror housing 12 moves in a translational manner, so that an image reflected on the mirror main body 13 is hardly shaken and the visibility is hardly deteriorated. On the other hand, when it vibrates in mode 2 or mode 3, rotational movement occurs in the mirror housing 12, and the image reflected on the mirror main body 13 is greatly blurred, so the visibility is likely to deteriorate. As described above, in the conventional structure, the vibrations of modes 2 and 3 appear during traveling of the motorcycle, and the visibility may be deteriorated in a wide rotation speed range.

  Next, the vibration characteristics of the rearview mirror 10 according to the present embodiment will be described. In this vibration characteristic, each dimension of the rearview mirror 10 is the same as that of the conventional structure described above.

  In the rearview mirror 10 according to the present embodiment, the support rigidity can be increased by using the metal joint mechanism 14. If the support rigidity can be increased sufficiently, the appearance of modes 2 and 3 among the vibration modes shown in FIG. 5 can be suppressed, which can contribute to lower vibration.

  Further, the vibration response of the rearview mirror 10 according to the present embodiment is obtained by increasing the support rigidity while minimizing the increase in mass, as shown by the solid line in FIG. Can be increased from ω2 ′ and ω3 ′ of the conventional structure to ω2 and ω3, respectively. If these natural frequencies can be sufficiently detuned from the upper limit frequency of the vibration source, mirror vibration can be reduced. Even if the detuning is insufficient and resonance is unavoidable, the vibration tends to decrease as the support rigidity increases. Therefore, the vibration reduction effect of modes 2 and 3 can be expected.

  Furthermore, in the rearview mirror 10 according to the present invention, an increase in the mass of the tip of the mirror 10 can be minimized, so that the natural vibration of the vibration mode in which the support rigidity of the mirror stay 11 is dominant as in the mode 1. The effect on the number is small. Therefore, it is possible to realize a countermeasure for a vibration mode in which the support rigidity of the joint mechanism 14 is dominant as in modes 2 and 3 while reducing the risk of new resonance.

  In this embodiment, vibration reduction is realized without using a dynamic vibration absorber. Therefore, it is possible to reduce the vibration without accompanying the deterioration of the vibration caused by the dynamic vibration absorber and the risk of functional loss and mirror damage due to the drop of the dynamic vibration absorber.

  In this embodiment, when manufacturing the protrusion end part 41 with a metal material, the protrusion end part 41 is insert-molded. For this reason, the joint force of the part manufactured with the metal material and the part manufactured with the synthetic resin material can be improved, and the highly reliable joint mechanism 14 can be provided.

  In the present embodiment, a portion of the stay side joint portion 31 that contacts the housing side joint portion 32 (that is, a tip portion of the stay side joint portion 31) is made of a metal material. Thereby, the concave spherical surface 38 of the stay side joint part 31 which comprises a spherical pair with the convex spherical surface 42 becomes a metal surface. Since the metal surfaces come into contact with each other in the spherical pair, the contact rigidity is further increased, and the natural frequencies of modes 2 and 3 are easily detuned.

  Even if the tip of the stay side joint 31 is made of a synthetic resin material, if a metal retainer is interposed between the tip of the stay side joint 31 and the protruding end 41, Metal surfaces can be brought into contact with each other in a spherical pair formed by the convex spherical surface 42. If the tip of the stay side joint portion 31 is made of metal as in the present embodiment, the retainer can be omitted, so that an increase in the number of parts and an increase in cumulative assembly error in the joint mechanism 14 can be suppressed. it can. Along with this, it is possible to set a small dimensional tolerance in the spherical pair, and it is possible to provide the joint mechanism 14 with a small play.

  In the present embodiment, the convex spherical surface 42 is pressed against the concave spherical surface 38 by the elastic force of the spring element 53. For this reason, even if the convex spherical surface 42 and the concave spherical surface 38 have irregularities when viewed microscopically, the irregularities are smoothed by this pressing. Thereby, the contact area of the convex spherical surface 42 and the concave spherical surface 38 is increased, and the contact rigidity is increased in the spherical pair constituted by the spherical surfaces 42 and 38. Therefore, it becomes easy to detune the natural frequencies of modes 2 and 3. In addition, when the two spherical surfaces are metal surfaces, settling due to the elastic force of the spring element 53 is less likely to occur on the spherical surface than when at least one of the spherical surfaces is a resin surface. For this reason, it is possible to obtain the effect of maintaining the mirror posture and reducing the mirror vibration while extending the life of the joint mechanism 14.

  The concave spherical surface 46 of the protruding end 41 is also a metal surface. For this reason, the contact rigidity is increased even in the spherical pair formed by the concave spherical surface 46, and the natural frequencies of the modes 2 and 3 are easily detuned. Further, the convex spherical surface 54 of the spring retainer 51 that forms the spherical pair with the concave spherical surface 46 is also a metal surface, and the contact rigidity at the spherical pair is further increased.

(Other embodiments)
FIG. 7 is a cross-sectional view of the rearview mirror 210 according to the second embodiment. FIG. 8 is a perspective view of the tip part 261 shown in FIG. In the second embodiment, a tip component 261 is different from the tip component 61 (see FIG. 4) of the first embodiment. Hereinafter, the rearview mirror 210 according to the second embodiment will be described focusing on differences from the above embodiment.

  As shown in FIG. 8, the tip part 261 has a cylindrical part 262, a protruding end 241 and a stepped wall 263, which are the cylindrical part 62, the protruding end 41 and the stepped wall 63 of the first embodiment (FIG. 5). Reference) formed in the same manner as each. The cylindrical portion 262 is provided with a plurality of through holes 265.

  This tip part 261 is also made of a metal material, and the outer surface and the inner surface of the projecting end 241 have a convex spherical surface 242 that rotatably contacts the stay side joint portion 31 (see FIG. 7), and a spring retainer (FIG. 7). And a concave spherical surface 246 that is pivotably abutted to each other (not shown in FIG. 8). Therefore, as in the first embodiment, the contact rigidity is increased at the two spherical pairs formed by the spherical surfaces 242 and 246, and the vibration of the rearview mirror 210 can be reduced.

  As shown in FIG. 7, in manufacturing the housing side joint portion 232, the tip part 261 is inserted into the mirror housing 212 when the mirror housing 212 is molded with a synthetic resin material. The tube portion 262 is embedded in a tube portion 264 made of synthetic resin that is integral with the mirror holding portion 226, and the protruding end portion 241 protrudes from the tube portion 264 and is exposed.

  In the present embodiment, a through hole 265 is provided in a cylindrical portion 262 that is a portion embedded in the mirror housing 212 of the tip part 261. For this reason, when molded with a synthetic resin material, the synthetic resin material flows into the through hole 265 and hardens. Then, the resin material on the inner peripheral side of the cylindrical portion 262 and the resin material on the outer peripheral side are continued through the resin material in the through hole 265. Therefore, the coupling force of the tip part 261 to the mirror housing 212 is improved.

  FIG. 9 is a cross-sectional view of the rearview mirror 310 according to the third embodiment. As shown in FIG. 9, the tip part 361 is not necessarily inserted into the mirror housing 312. In the housing side joint portion 332 of the joint mechanism 314 according to the present embodiment, the outer peripheral surface of the cylindrical portion 362 of the tip part 361 is an inner portion of the synthetic resin cylindrical portion 364 provided integrally with the mirror holding portion 326 of the mirror housing 312. The peripheral surface is bonded using an adhesive. Also in this embodiment, the protruding end portion 341 of the tip part 361 protrudes from the cylindrical portion 364. The projecting end 341 that is in contact with the stay side joint (not shown in FIG. 9) is made of a metal material, and the convex spherical surface 342 on the outer surface and the concave spherical surface 346 on the inner surface are used as the metal surface. The vibration of the rearview mirror 310 can be reduced as in the first embodiment.

  FIG. 10 is a cross-sectional view of the rearview mirror 410 according to the fourth embodiment. As shown in FIG. 10, in the housing side joint part 432 of the joint mechanism 414 according to the present embodiment, the cylindrical part 462 of the tip part 461 is made of a synthetic resin provided integrally with the mirror holding part 426 of the mirror housing 412. It is fitted in the tube portion 463 and fixed to the tube portion 464 using a fixture 469 such as a rivet or a bolt. Also in this embodiment, the vibration of the rearview mirror 410 can be reduced by manufacturing the protruding end portion 441 from a metal material and using the convex spherical surface 442 on the outer surface and the concave spherical surface 446 on the inner surface as the metal surface.

  FIG. 11 is a cross-sectional view of a rearview mirror 510 according to the fifth embodiment. As shown in FIG. 11, the tip part itself can be omitted. In the present embodiment, the portion 541 corresponding to the protruding end portion in the above embodiment is also provided integrally with the mirror holding portion 526 and the cylindrical portion 564 of the mirror housing 512 and is made of a synthetic resin material. The outer surface of the projecting end portion 541 made of this synthetic resin material is covered with a metal coating 549. For the formation of the metal film 549, any treatment such as plating, sputtering, or the like may be used. As a result, the convex spherical surface 542 that actually contacts the stay side joint portion (not shown in FIG. 11) of the housing side joint portion 532 is manufactured from the metal material, and the convex spherical surface 542 becomes the metal surface. Become. Therefore, also in the present embodiment, it is possible to obtain the vibration reduction effect accompanying the improvement of the support rigidity in the same manner as the first embodiment. Moreover, the housing side joint part 532 can be reduced in weight by the structure which manufactures the protrusion edge part 541 with a synthetic resin material, and coat | covers the outer surface with the metal film 549.

  Although the embodiment has been described so far, the above configuration can be appropriately changed within the scope of the present invention. For example, the stay side joint portion and the spring retainer are not necessarily made of a metal material. Moreover, when both the outer surface and inner surface of a protrusion end part comprise separate spherical surface pairs like the said embodiment, at least one should just be a metal surface among the outer surface and inner surface of a protrusion end part. That is, the metal coating in the fifth embodiment may be provided on both the outer surface and the inner surface of the protruding end portion, or may be provided only on the inner surface of the protruding end portion.

  In addition, in each embodiment, although the case where it applied to the rear-view mirror of a motorcycle was demonstrated, it is not restricted to this. For example, the present invention can be applied not only to traveling vehicles such as automobiles, construction machines, and railcars such as pneumatic vehicles, but also to mirrors installed on structures that can serve as vibration sources such as machine tools, production machines, and facilities.

  The present invention is useful for various types of mirrors that are required to improve the visibility of images projected with reduced vibration.

1 Car body 10, 210, 310, 410, 510 Rearview mirror 11 Mirror stay 12, 212, 312, 412, 512 Mirror housing 13 Mirror body 14, 214, 314, 414, 514 Joint mechanism 26, 226, 326, 426, 526 Mirror holding part 31 Stay side joint part 32, 232, 332, 432, 532 Housing side joint part 38 (spherical spherical surfaces 41, 241, 341, 441, 541 (stay side joint part)) Projecting end parts 42, 242, 342, 442 , 542 Convex spherical surfaces 46, 246, 346, 446 (housing side joint portion) Concave spherical surfaces 54 (of the housing side joint portion) Convex spherical surfaces 61, 261, 361, 461 Tip parts 62, 262 362, 462 Tube 64, 264 , 364, 464 Tube part 549 Metal coating

Claims (5)

A mirror body that captures the image,
A mirror housing for holding the mirror body;
A mirror stay for directly or indirectly attaching the mirror housing to a structure serving as a vibration source;
A joint mechanism having a stay side joint portion and a housing side joint portion that contact each other, and rotatably connecting the mirror housing to the mirror stay;
The mirror housing is a synthetic resin material,
The vibration reduction mirror in which at least a portion of the housing side joint portion that comes into contact with the stay side joint portion is a metal material.   The vibration reduction mirror according to claim 1, wherein the housing side joint portion is insert-molded in the mirror housing.   The vibration reduction mirror according to claim 2, wherein the housing side joint portion has a through hole in a portion embedded in the mirror housing.   2. The vibration reduction mirror according to claim 1, wherein the housing side joint portion is formed of a synthetic resin material integrally with the mirror housing, and a portion that contacts the stay side joint portion is covered with the metal material.   The vibration reduction mirror according to any one of claims 1 to 4, wherein at least a portion of the stay side joint portion that comes into contact with the housing side joint portion is a metal material.

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