KR0174138B1 - Dynamic damper - Google Patents

Abstract

The dynamic damper of the present application effectively prevents the direct interference between the mass member and the peripheral device, effectively utilizing the space of the facility and effectively expanding the adjustment range. The dynamic damper comprises a cylindrical mass member arranged in the same axial direction around a metal sleeve and a metal sleeve having a gap determined for a predetermined distance therebetween, an elastic rubber body provided between the metal sleeve and the cylindrical mass member, And a holding means adapted to hold the part and to be fixed to the vibration system. The cylindrical mass member has a stopper which axially projects from both axial ends thereof to cover the holding means so as to be spaced apart from the respective end edge portions of the metal sleeve, each of which is suitable for holding the metal sleeve, Thereby limiting the displacement of the mass member relative to the means.

Description

Dynamic damper

1 is a longitudinal section of an embodiment of a dynamic damper according to the invention;

FIG. 2 is a left elevational view of an embodiment of the present invention. FIG.

3 is a right side elevational view of an embodiment of the present invention.

DESCRIPTION OF THE REFERENCE NUMERALS

1: metal sleeve 2: cylindrical mass member

3: Elastic rubber body 4: Holding means

5: vibration system 23, 24: stopper

BACKGROUND OF THE INVENTION [

[TECHNICAL FIELD]

The present invention relates to a dynamic damper suitable for being installed in a vibration system of an automobile such as a differential gear, an engine mounting bracket, or a motor housing in order to suppress unnecessary vibration generated by vibration of an engine.

[Correlation Technology]

In a drive line, an exhaust system or the like of a motor vehicle connected to the engine, resonance occurs due to vibration of the engine. In general, a dynamic damper is installed to suppress the resonance. As an example of the dynamic damper, there is one disclosed in Japanese Patent Application Laid-Open No. 3-33895. The dynamic damper includes a metal sleeve, a cylindrical mass member disposed coaxially around the metal sleeve with a predetermined spaced-apart space therebetween, a resilient rubber member disposed between the metal sleeve and the cylindrical mass member, And holding means adapted to hold the shaft end of the main sleeve and to be fixed to the vibration system of the motor vehicle. With this structure, when the cylindrical mass member of the conventional dynamic damper is separated from the elastic rubber member with this structure, the falling of the mass member is prevented because the cylindrical mass member is disposed coaxially around the metal sleeve. Therefore, the dynamic damper has a valid fail safe function.

However, if the elastic rubber body is broken and the cylindrical mass body is displaced from the elastic rubber body, the cylindrical mass body freely moves with a distance to the thickness of the elastic rubber body. Therefore, in locations where other devices are installed close to the drive line or the like, they must be installed out of the range of motion of the cylindrical mass member, and conversely, at places where there is some interference around the dynamic damper, The elastic rubber member must be made shorter than the moving distance of the cylindrical mass member to prevent interference.

The conventional dynamic damper having the above structure is switched to a resonance frequency suppressed by determining both the spring constant of the cylindrical mass member and the elastic rubber body.

For example, the spring constant of the resilient rubber body must be reduced where the suppressed resonance frequency is low. For this purpose, the thickness of the elastic rubber body is increased or its axial length is reduced. If the axial length of the elastic rubber body is reduced, the torsional rigidity is lowered, and the mass member generates pitching motions and the displacement of the mass member is enlarged. Therefore, this fact makes it possible to make the axial length of the elastic rubber body as large as possible. In such an atmosphere, it is advantageous to adopt an arrangement in which the thickness of the elastic rubber body can be arbitrarily selected.

[Summary of the Invention]

SUMMARY OF THE INVENTION It is an object of the present invention to provide a dynamic damper that effectively prevents direct interference between a mass member and a peripheral device while effectively utilizing an installation space and effectively extends a tuning range there.

A dynamic damper of the present invention comprises a metal sleeve, a cylindrical mass member having a predetermined spaced space therebetween and coaxially arranged around the metal sleeve, an elastic rubber body provided between the metal sleeve and the cylindrical mass member, And a holding means adapted to hold the part and to be fixed to the vibration system. The cylindrical mass member has a stopper for restricting displacement expansion of the cylindrical mass member relative to the retaining means exceeding the predetermined displacement. Each of the stoppers protrudes axially from each of the shaft ends of the cylindrical mass member and covers the retaining means so as to be spaced from the respective end edge portions suitable for holding the metal sleeve to a predetermined spaced space.

In a preferred embodiment, the distance between the stopper and the facing portion is made shorter than the thickness of the elastic rubber body.

In the present invention, where the elastic rubber body is broken and the cylindrical mass member leaves the elastic rubber body, the stopper of the mass member abuts the end edge portion of the holding means suitable for holding the metal sleeve, and exceeds the predetermined displacement The expansion of the large relative displacement of the cylindrical mass member is prevented, thereby preventing direct interference between the cylindrical mass member and the peripheral device. This fact validates the facility space for the dynamic damper and adjacent devices.

The stopper provided on the cylindrical mass member significantly increases the thickness of the elastic rubber body when determining the spring constant. Therefore, the selection range of the thickness of the elastic rubber body is expanded, and the adjustment range is remarkably enlarged.

Here, when a considerable vibration is generated, the stopper restricts a large relative displacement between the metal sleeve and the cylindrical mass member exceeding the predetermined displacement, thereby suppressing the excessive deformation of the elastic rubber body and improving its durability. The distance between the stopper and the holding means is reduced to be shorter than the thickness of the elastic rubber body so that direct interference between the cylindrical mass body and the peripheral device is reliably prevented and the adjustment range is significantly increased and the durability of the elastic rubber body It is greatly improved.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

[Description of the Preferred Embodiment]

Fig. 1 is a longitudinal sectional view of the dynamic damper of the present embodiment, Fig. 2 is a left elevational view of the dynamic damper, and Fig. 3 is a right elevational view.

The dynamic damper of this embodiment has a metal sleeve 1 and a cylindrical mass member 2 disposed coaxially around the metal sleeve 1 and spaced apart from the metal sleeve 1 and a predetermined space, Stoppers 23 and 24, an elastic rubber body 3 sandwiched between the metal sleeve 1 and the cylindrical mass member 2, and holding means (not shown) holding the both axial ends of the metal sleeve 1 and fixed to the vibration system 4).

The metal sleeve 1 is formed of a hollow cylindrical configuration of metal material and having a predetermined dimension. The mass member 2 has a cylindrical portion 21 whose inner diameter is larger than the outer diameter of the metal sleeve 1 by a predetermined amount and whose axial length is slightly smaller than that of the metal sleeve 1, And has a circular main part 22 to be fitted. The cylindrical portion 21 and the main portion 22 are designed to have a predetermined mass as a whole.

The stoppers 23 and 24 are provided at both axial ends of the main part 22 and axially project toward the arcuate upper part. These stoppers 23 and 24 each have an arch-shaped inner surface of about 200 degrees, which covers the corners of the respective brackets 41 and 42 of the holding means 4 with a predetermined spacing space. The distance between the facing parts, which are adjacent to each other at the time of relative displacement of the respective stoppers 23, 24 and the respective brackets 41, 42, that is, their relative displacements, (I.e., the distance between the metal sleeve 1 and the cylindrical portion 21).

The elastic rubber body 3 is composed of a rubber material containing natural rubber as a main component and has a ring shape. The elastic rubber body 3 is hardened at both the outer peripheral portion of the metal sleeve 1 and the cylindrical portion 21 at the center of the shaft. The spring constant of the elastic rubber body 3 is determined to be a predetermined value based on the axial length, the thickness and the rubber strength. By determining the spring constant of the elastic rubber member 3 together with the mass of the mass member 2, the dynamic damper is adjusted to the suppression resonance frequency.

The brackets 41 and 42 of the holding means 4 are generally made of a metal plate having an L shape and are arranged to face each other. The bolt 43 and the nut 44 connect the brackets 41 and 42 to each other. The brackets 41, 42 are provided with paddles 41a, 42a, through which the bores 43 extend, respectively, at the center of the facing portion. These brackets 41 and 42 are provided with nuts 44 on the bolts 43 which are inserted through the bolts 43 of the brackets 41 and the bolts 43 of the brackets 42 in the axial direction of the metal sleeve 1, And is assembled with the metal sleeve 1 sandwiched therebetween. Each of the leg portions of the brackets 41 and 42 has a pair of legs 41b and 42b suitable for insertion of the bolt screw 6 and the like when the dynamic damper is fixed to the vibration system 5. [

As shown in Fig. 1, the dynamic damper of the present embodiment is fixed to a predetermined position of the vibration system 5, such as a differential gear of an automobile, by means of a bolt screw 6 or the like.

In the device thus arranged, when the vibration occurs in the vibration system by the engine vibration, the mass member 2 is resonated through the elastic deformation of the elastic rubber body 3 so that the vibration can be effectively suppressed. When a very large scale vibration occurs in the vibration system, the stoppers 23 and 24 limit a considerably large displacement exceeding the predetermined displacement between the metal sleeve 1 and the mass member 2, so that the elastic rubber body 3 ) And ensures good durability.

When the elastic member 3 is broken and the mass member 2 is displaced from the elastic rubber member 3, the stoppers 23 and 24 of the mass member 2 are adjacent to the brackets 41 and 42, Thereby limiting a considerably large displacement of the mass member 2 exceeding the determined displacement. This results in effective prevention of direct interference between the mass member 2, the vibration system 5 and the peripheral device.

As described above, with the dynamic damper of the present invention having the stoppers 23 and 24 at both axial ends of the mass member 2 for restricting the displacement with respect to the brackets 41 and 42 exceeding the predetermined displacement, When the elastic rubber body 3 is broken and the mass member 2 turns off the elastic rubber body 3, the direct interference between the mass member 2, the vibration system 5 and the peripheral device can be effectively prevented . This makes it possible to densely mount the dynamic damper in the vibration system 5 and make it possible to densely install the peripheral device in the dynamic damper of this embodiment. Therefore, the installation space can be utilized effectively.

With the dynamic damper of the present embodiment, the mass of the mass member 2 can be increased by the respective stoppers 23 and 24, which can increase the thickness of the elastic rubber body 3 by the spring constant of the elastic rubber body 3 So that it can be increased a lot. This further widens the selectable range of the thickness of the elastic rubber body 3, so that the tuning range can be satisfactorily enlarged.

A considerably large displacement between the metal sleeve 1 and the mass member 2 which is larger than the predetermined displacement is restrained by the stoppers 23 and 24 when a large vibration occurs so that the excessive deformation of the elastic rubber body 3 is suppressed And therefore durability is improved.

Further, in the dynamic damper of the present embodiment, the distance between the stoppers 23, 24 and the facing portions of the brackets 41, 42 is determined to be smaller than the thickness of the elastic rubber member 3. In the arrangement thus arranged, direct interference between the mass member 2 and the peripheral device can be more reliably prevented, the adjustment range is further expanded, and the durability of the elastic rubber body 3 is further improved.

In this embodiment, the stoppers 23 and 24 are formed in an arch shape, respectively. Alternatively, they may have different shapes depending on the required mass of the mass member. For example, a plurality of protruding features may be provided, each protruding axially so as to move from the end edge of the retaining means to a predetermined spaced-apart space.

In the embodiment of the present invention, the retaining means 4 is constituted by assembling the brackets 41, 42 and the bolts 43 and the nuts 44. It is possible to provide various modifications of the retaining means 4 and they each have a facing portion suitable for abutting the stoppers 23, 24 of the mass member 2. The hollow cylindrical metal sleeve 1 may be replaced by a solid columnar metal sleeve.

As described above, in the present invention, since the mass member has a stopper for restricting displacement with respect to the holding means, each stopper protrudes axially from each axial end of the mass member and covers the holding means, It is possible to move from each of the end edge portions suitable for holding to the predetermined spaced space, to prevent direct interference between the mass member and the peripheral device, and effectively use the installation space. This can increase the thickness of the elastic rubber body in determining the spring constant. Therefore, the thickness of the elastic rubber body can be more freely selected, so that the adjustment range can be satisfactorily enlarged. Moreover, when a large vibration occurs, the relative displacement between the metal sleeve and the mass member, which exceeds the predetermined displacement, is limited by the stopper. This makes it possible to suppress excessive deformation of the elastic rubber body, thereby improving durability.

By making the distance between the facing portion of the stop member and the holding means smaller than the thickness of the elastic rubber body, the direct interference between the mass member and the peripheral device can be more reliably prevented and the adjustment range is further expanded, Can be further improved.

While the present invention has been described with reference to what is presently considered to be the most novel and preferred embodiments of the invention, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. will be.

Claims (6)

The dynamic damper includes: a metal sleeve; a cylindrical mass member having a predetermined spaced space therebetween and coaxially disposed about the metal sleeve; an elastic rubber body disposed between the metal sleeve and the cylindrical mass member; Wherein the cylindrical mass member includes a stopper that limits displacement relative to the retaining means that exceeds the predetermined displacement, and each stopper is disposed on both axes of the cylindrical mass member, And axially projecting from each of the ends and covering the retaining means so as to be spaced from the respective end edge portions thereof suitable for retaining the metal sleeve to a predetermined space. The dynamic damper of claim 1, wherein each of the stoppers is an arcuate shape. 2. The apparatus of claim 1, wherein each of the stoppers includes a plurality of protrusions projecting axially from both axial ends of the cylindrical mass member such that each of the stoppers is spaced from a predetermined spacing action from an end edge portion of the retaining means Wherein the damper comprises: 2. The dynamic damper according to claim 1, wherein the distance between the facing parts of the holding means and the stopper is smaller than the thickness of the elastic rubber body. The dynamic damper according to claim 4, wherein each of the stoppers has an arch shape. 5. The apparatus of claim 4, wherein each stopper comprises a plurality of protrusions projecting axially from both axial ends of the cylindrical mass member such that each of the stoppers is spaced from a predetermined spacing action from an end edge portion of the retaining means Wherein the damper comprises: