JP2008002552A - Dynamic damper - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a dynamic damper of shearing type which is mounted externally on a rotary shaft 1 to suppress occurrence of vibration of the rotary shaft 1, and optionally adjusts a resonance frequency being a target per specification of the rotary shaft 1 allowing mounting of the dynamic damper so as to increase its general purpose property. <P>SOLUTION: The dynamic damper is constituted in such a way that both end sides in the axial direction of the dynamic damper 2 are externally fitted into the rotary shaft 1, a tightening member 8 tightened and mounted at the outer periphery on at least one end side in the axial direction is provided, and a distance L from a fitting part on one end side 5b in the axial direction to a fitting part on the other end side 5c in the axial direction is optionally changed. Since a coefficient of vibration in an axial intermediate region 5a which becomes a mass body is changed when changing the distance L, the resonance frequency by the dynamic damper 2 is changed. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a shear type dynamic damper that is externally mounted on a rotating shaft to suppress vibration of the rotating shaft.

  In general, a rotating shaft such as a drive shaft of an automobile may generate bending vibration or torsional vibration due to rotation imbalance or the like. Therefore, a dynamic shaft having a resonance frequency that matches the natural frequency of the rotating shaft. A damper is prepared, and this dynamic damper is externally mounted on the rotating shaft.

  As generally known, these dynamic dampers are called a shear type and a compression type. Since the present invention is directed to a shear type dynamic damper, here, a conventional shear type dynamic damper is used. Will be described.

  The shear type dynamic damper of the conventional example basically has a configuration in which a substantially cylindrical mass member is covered with a rubber-like elastic body, and is externally mounted on the rotating shaft from one end side in the axial direction. Specifically, in a state where the dynamic damper is mounted on the rotating shaft, the fastening member is tightened and attached from the outer diameter side of the dynamic damper in a state where one end side and the other end side of the dynamic damper are in contact with the rotating shaft. The direction intermediate region is configured to face the rotation shaft via a predetermined annular gap (see, for example, Patent Document 1).

  In this case, vibration of the rotating shaft is suppressed by absorbing vibration energy generated as the rotating shaft rotates as vibration energy of the dynamic damper.

By the way, since the outer shape of the dynamic damper is fixed to a predetermined shape, the dynamic damper exhibits a vibration suppressing effect on the natural frequency of the rotation shaft to be mounted one by one at the time of manufacture. Therefore, it is necessary to make a special design so that the resonance frequency is the same.
JP 2001-349379 A

  In the above conventional example, if the specification (for example, weight, length, etc.) of the rotating shaft to be mounted changes, it is necessary to prepare a dynamic damper set to the corresponding resonance frequency, and there are many types of dynamic dampers. It can be said that there is a lot of waste.

  An object of the present invention is to facilitate adjustment of a target resonance frequency and enhance versatility in a shear type dynamic damper that is externally mounted on a rotating shaft and suppresses vibration of the rotating shaft.

  The present invention is a shear-type dynamic damper that is externally mounted on a rotating shaft and suppresses vibrations of the rotating shaft. Both ends in the axial direction are externally fitted to the rotating shaft, and are tightened and attached to at least the outer periphery on one axial end side. And a separation distance from a fitting portion on one end side in the axial direction to a fitting portion on the other end side in the axial direction can be changed.

  In the first place, in the shear type dynamic damper, the axial intermediate region becomes a mass body, and the axial intermediate region vibrates in the radial direction along with the natural vibration of the rotating shaft, that is, the shearing deformation causes the rotation axis. It is designed to absorb and damp vibrations.

  In such a shear type dynamic damper, the resonance action by the axial intermediate region changes depending on the length of the separation distance from the fitting portion on one end side in the axial direction to the fitting portion on the other end side. By setting appropriately, the target resonance frequency can be designed.

  Therefore, in the present invention, since the separation distance can be arbitrarily changed, the dynamic damper is set to a resonance frequency suitable for vibration suppression of the rotation shaft for each specification of the rotation shaft to be mounted. It becomes possible to do.

  In short, the versatility is enhanced by making it possible to appropriately change the characteristic to exhibit the optimum vibration suppression effect for each rotating shaft to be mounted, although it is a single dynamic damper.

  As a result, it is sufficient to prepare a single dynamic damper regardless of the specifications of the rotating shaft to be mounted.In other words, a large number of types of dynamic dampers specially designed for each rotating shaft specification as in the conventional example. Since there is no need to prepare, it is advantageous in reducing manufacturing costs and storage management costs, such as simplification of the production mold and production line of the dynamic damper.

  In addition, the present invention is a shear type dynamic damper that is externally mounted on a rotating shaft and suppresses vibration of the rotating shaft, and has a two-piece structure in which a first cylinder and a second cylinder are combined, and the first The cylindrical body has a small inner diameter so that one end side in the axial direction is press-fitted and fitted to the rotary shaft, and a region from the intermediate region in the axial direction to the other end in the axial direction is relative to the outer peripheral surface of the rotary shaft. It has a large inner diameter so as to face each other via an annular gap, and the second cylindrical body is inserted into the annular gap from the other axial end side, and the axial insertion length is a mounting target. It is characterized by being arbitrarily changed for each rotation axis.

  According to this configuration, the axial insertion length of the second cylinder with respect to the first cylinder, that is, the overlapping length is changed by changing the length of the first cylinder from the axially one end fitting portion of the first cylinder to the overlapping portion. The separation distance is changed. Thereby, since the resonance frequency of the dynamic damper is adjusted, it is possible to ensure a resonance frequency suitable for the natural frequency of the rotating shaft to be mounted.

  As described above, since the resonance frequency of the dynamic damper can be adjusted by a simple operation by simply changing the axial relative position between the first cylinder and the second cylinder, the operation can be performed easily and quickly. It becomes like this.

  Furthermore, the present invention is a shear type dynamic damper that is externally mounted on a rotating shaft and suppresses vibration of the rotating shaft, and has a one-piece structure composed of a single cylinder, and one end side in the axial direction thereof is connected to the rotating shaft. It is press-fitted and externally fitted, and is covered so that the axial intermediate region faces the rotating shaft through a predetermined annular gap, and the other axial end is covered so as to face the rotating shaft through a minute gap. It has a fastening member that is fastened and attached to an arbitrary position in the axial direction on the outer peripheral surface on the end side and presses the mounting region against the outer peripheral surface of the rotary shaft, and the fastening member is provided for each rotational shaft to be attached. The mounting position with respect to the outer peripheral surface on the other end side in the direction is changed in the axial direction.

  According to this configuration, the distance from the fitting portion on one axial end side of the dynamic damper to the fastening member mounting position on the other axial end side is determined by the axial mounting position of the fastening member on the other axial end side of the dynamic damper. The distance will be changed. Thereby, since the resonance frequency of the dynamic damper is adjusted, it is possible to ensure a resonance frequency suitable for the natural frequency of the rotating shaft to be mounted.

  Thus, the resonance frequency of the dynamic damper can be adjusted with a simple operation of simply changing the mounting position of the fastening member in the axial direction.

  According to the present invention, it is possible to easily adjust the target resonance frequency according to the natural frequency for each rotating shaft to be mounted, and it can be used in common for many rotating shafts having different specifications. Versatility can be improved.

  Hereinafter, an embodiment of the present invention will be described with reference to FIGS. First, FIG. 1 to FIG. 5 show an embodiment of the present invention.

  In this embodiment, a drive shaft 1 for transmitting power from, for example, a vehicle differential (not shown) to a wheel (not shown) is taken as an example of a rotating shaft to which the dynamic damper 2 is attached.

  As shown in FIG. 1, the drive shaft 1 has an inboard joint 3 on one end side and an outboard joint 4 on the other end side.

  Although not shown, the inboard joint 3 of the drive shaft 1 is connected to, for example, a differential (not shown) disposed at the center in the vehicle width direction of the vehicle, and the outboard joint 4 of the drive shaft 1 is For example, it is connected to a hub unit for wheel mounting.

  The inboard joint 3 is, for example, a known tripod type constant velocity joint, and the outboard joint 4 is, for example, a known barfield type constant velocity joint.

  As shown in FIG. 1, the dynamic damper 2 is mounted in a region between the inboard joint 3 and the outboard joint 4 in the drive shaft 1, thereby absorbing vibration energy of the drive shaft 1 by resonance and driving. The vibration of the shaft 1 is suppressed.

  Specifically, the dynamic damper 2 has a two-piece structure in which the first cylinder 5 and the second cylinder 6 are combined.

  The first cylindrical body 5 has an outer diameter dimension of the axial intermediate region 5a larger than outer diameter dimensions of the axial one end side 5b and the other end side 5c. A shaped mass member 7 is embedded. In addition, the mass member 7 may not be cylindrical, and may be one in which a plurality of mass members are embedded in the circumference.

  One axial side 5b of the first cylinder 5 has a small inner diameter so as to be press-fitted and fitted to the drive shaft 1, and a region from the axial intermediate region 5a to the other axial end 5c is driven. The inner diameter of the shaft 1 is large so as to face the outer peripheral surface of the shaft 1 via the annular gap 9.

  The second cylinder 6 is inserted into the annular gap 9 between the first cylinder 5 and the drive shaft 1 from the other end side in the axial direction, and the axial insertion length W is the mounting target. The drive shaft 1 is arbitrarily changed for each specification.

  A fastening member 8 is fastened and attached to the outer peripheral surface of the first cylindrical body 5 on the one axial end side 5b and the outer peripheral surface of the second cylindrical body 6 on the other axial end side.

  In addition, the 1st cylinder 5 and the 2nd cylinder 6 are formed, for example with the rubber material which has a suitable softness | flexibility, or the synthetic resin material which has a suitable softness | flexibility, etc. The mass member 6 is embedded in the axial intermediate region 5a by vulcanization molding.

  The mass member 7 is made of a metal material such as aluminum, iron and various alloys, or an appropriate resin, and is formed in a cylindrical shape. The mass member 7 is appropriately managed to have a mass that ensures a target resonance frequency for exerting an appropriate vibration suppressing action in consideration of the natural frequency according to the specifications of the drive shaft 1 to be mounted. .

  Further, the fastening member 8 is, for example, a band-like band that expands and contracts in the radial direction, and is generally formed of a known elastic material or has an assembly structure that can expand and contract.

  In the case of such a fastening member 8, the fastening member 8 is directed radially outward on the outer peripheral surface on the one axial end side 5 b of the first cylinder 5 and the outer peripheral surface on the other axial end side of the second cylindrical body 6. By being fitted from the outer diameter side in an elastically expanded state and compressed by the elastic restoring force of the fastening member 8, the one axial end 5 b of the first cylinder 5 and the other axial end of the second cylinder 6 are compressed. The side is tightened and attached to the drive shaft 1. In addition to this, the fastening member 8 may be separated at, for example, one place around the circumference, and the separated ends may be fastened with screws or the like.

  The dynamic damper 2 having such a configuration is a so-called shear type. In short, in this shear type dynamic damper 2, the axial intermediate region 5 a of the first cylinder 5 that is externally mounted on the drive shaft 1 becomes a mass body, and the axial intermediate region 5 a becomes radial along with the natural vibration of the drive shaft 1. The vibration of the drive shaft 1 is absorbed and damped by the action of vibration and resonance, that is, the action of shear deformation.

  In the state where the dynamic damper 2 is mounted on the drive shaft 1, the separation distance L from the fitting portion on the axial one end side 5 b of the first cylinder 5 to the overlapping portion of the second cylinder 6 with respect to the first cylinder 5. Since the resonance effect of the axial intermediate region 5a varies depending on the length of the distance, the target resonance frequency can be designed by appropriately setting the separation distance L.

  Strictly speaking, the separation distance L is the inner end edge of the overlapping portion of the second cylindrical body 6 with respect to the first cylindrical body 5 from the inner end edge of the fitting portion on the axial one end side 5b of the first cylindrical body 5. It is the separation distance up to.

  Next, operations and procedures for adjusting the separation distance L of the dynamic damper 2 described above will be described.

  That is, by changing the axial insertion length W of the second cylinder 6 with respect to the first cylinder 5, that is, the overlapping length, the overlapping is performed from the fitting portion on the axial one end side 5 b of the first cylinder 5. The separation distance L to the part is changed in length. Thereby, since the resonance frequency of the dynamic damper 2 is adjusted, it becomes possible to ensure a resonance frequency suitable for the natural frequency of the drive shaft 1 to be mounted.

  Incidentally, FIG. 4 shows a state in which the axial insertion length W is increased and the separation distance L is shortened, and in FIG. 5, the axial insertion length W is shortened and the separation distance is reduced. The state which lengthened L is shown.

  By the way, in this embodiment, the annular rib 5d that protrudes radially inwardly on the inner peripheral surface of the region from the axial intermediate region 5a to the axial other end side 5c of the first cylindrical body 5 is depressed radially outward. A plurality of circumferential grooves 5e are provided adjacent to each other in the axial direction, and the circumferential groove 6a and the annular rib 6b are fitted to the annular rib 5d and the circumferential groove 5e also on the outer peripheral surface of the second cylindrical body 6. Are provided side by side in the axial direction.

  Then, the annular rib 5d and the circumferential groove 5e of the first cylindrical body 5 are respectively fitted to the circumferential groove 6a and the annular rib 6b at appropriate positions in the second cylindrical body 6, so that the axial insertion length W and The separation distance L is adjusted. Note that the degree of adjustment of the resonance frequency of the dynamic damper 2 can be changed by changing the installation interval and the axial occupation width of the annular ribs 5d and 6b and the circumferential grooves 5e and 6a.

  In this way, if the adjustment of the axial overlapping range of the second cylinder 6 with respect to the first cylinder 5 is performed by fitting the irregularities (the annular ribs 5d, 6b and the circumferential grooves 5e, 6a), the first Since it is possible to prevent the first cylinder 5 and the second cylinder 6 from being displaced in the axial direction in the process until the fastening member 8 is attached to the cylinder 5 and the second cylinder 6, the resonance frequency The adjustment work can be easily and accurately performed, so that it is excellent in practicality.

  As described above, in the embodiment to which the present invention is applied, the resonance frequency of the dynamic damper 2 can be set with a simple operation by simply changing the axial overlapping region of the second cylinder 6 relative to the first cylinder 5. The versatility of the dynamic damper 2 can be enhanced, for example, it can be adjusted arbitrarily.

  Therefore, since it is sufficient to prepare a single dynamic damper 2 regardless of the specification of the drive shaft 1 (rotating shaft) to be mounted, in other words, a dedicated design is made for each specification of the drive shaft 1 as in the conventional example. Since it is not necessary to prepare a large number of types of dynamic dampers 2, it is advantageous in reducing manufacturing costs and storage management costs, such as simplification of the manufacturing mold and production line of the dynamic dampers 2.

  Hereinafter, other embodiments of the present invention will be described.

  (1) FIGS. 6 to 9 show other embodiments of the present invention. The dynamic damper 2 of this embodiment has a one-piece structure. The fastening member 8 is attached only to one axial end of the dynamic damper 2, and the fastening mounting position of the fastening member 8 is changed in the axial direction. By making it possible, the resonance frequency of the dynamic damper 2 can be adjusted.

  Specifically, in the dynamic damper 2, the outer diameter dimension of the axial intermediate region 2a is larger than the outer diameter dimensions of the one axial end side 2b and the other axial end 2c. For example, a cylindrical mass member 7 is embedded in the axial intermediate region 2a.

  The axial one end side 2b has a small inner diameter so as to be press-fitted to the drive shaft 1, and the axial intermediate region 2a faces the outer peripheral surface of the drive shaft 1 with an annular gap 9 therebetween. The inner diameter dimension is set to a large inner diameter dimension so that the other end 2c in the axial direction is opposed to the outer peripheral surface of the drive shaft 1 through a minute gap.

  Here, the other axial end 2c is longer in the axial direction than the one axial end 2b, and bulging portions 2d and 2e bulging radially inward are adjacent to each other on the inner diameter side. Is provided. Two circumferential grooves 2f and 2g continuous in the circumferential direction are provided adjacent to each other in the axial direction in a region corresponding to the two bulging portions 2d and 2e on the outer peripheral surface of the other axial end 2c.

  As shown in FIG. 8, the two bulging portions 2d and 2e are respectively provided with recesses 2h that are recessed outward in the radial direction at several circumferentially spaced intervals. As a result, the bulging portions 2d and 2e are shaped as if convex portions are provided on the circumference of the circumference, but when the inscribed circle diameter of each convex portion is in a natural state, It is set to be slightly larger than the outer diameter so as to be non-contact.

  Here, first, for example, when the fastening member 8 is mounted in an axially expanded circumferential groove 2g on the other axial end 2c side in an elastically expanded state, the elastic restoring force of the fastening member 8, that is, the radially inward force Due to the elastic compression action, as shown in FIG. 7, the bulging portion 2e existing on the inner diameter side of the axially outer circumferential groove 2g is pressed against the outer peripheral surface of the drive shaft 1, so that the separation distance L is long. Become.

  On the other hand, for example, when the fastening member 8 is attached to the axially inner circumferential groove 2d on the other axial end side 2c, the elastic restoring force of the fastening member 8, that is, the radially inward elastic compression action, as shown in FIG. Since the bulging portion 2d existing on the inner diameter side of the circumferential groove 2d on the inner side in the axial direction is pressed against the outer peripheral surface of the drive shaft 1, the separation distance L is shortened.

  Strictly speaking, in this embodiment, the above-mentioned separation distance L is bulged (2d or 2e) on the fastening member 8 mounting side from the inner end edge of the fitting portion on the axial one end side 2b to the axial other end side 2c. ) Is the separation distance to the inner edge.

  Also in this embodiment, it is possible to obtain the same operations and effects as those described in the above embodiment. That is, it is sufficient to prepare a single dynamic damper 2 regardless of the specification of the drive shaft 1 (rotating shaft) to be mounted. In other words, the drive shaft 1 is designed exclusively for each specification as in the conventional example. Since it is not necessary to prepare a large number of types of dynamic dampers 2, it is advantageous in reducing manufacturing costs and storage management costs, such as simplification of the manufacturing mold and production line of the dynamic dampers 2. Moreover, in this embodiment, since the dynamic damper 2 has a one-piece structure, the number of parts can be reduced as compared with the embodiments shown in FIGS. 1 to 5, which is advantageous in reducing the cost.

  In this embodiment, the fastening member 8 is attached only to one axial end (2c), but the fastening member 8 may be attached to both axial ends. In this case, the mounting position of the fastening member 8 can be changed in the axial direction only for one axial end (2c), and the mounting position of the fastening member 8 can be mounted only in the axial fixed position for the remaining one end. Alternatively, both ends in the axial direction may be configured such that the mounting position of the fastening member 8 can be changed in the axial direction as described above.

  (2) FIGS. 10 to 13 show still another embodiment of the present invention. The dynamic damper 2 of this embodiment has a one-piece structure, and the outer diameter of the drive shaft 1 as a rotating shaft is divided into two stages of a small diameter region 1a and a large diameter region 1b, and the axis of the dynamic damper 2 with respect to the drive shaft 1 The resonance frequency of the dynamic damper 2 can be adjusted by changing the mounting position in the direction.

  Specifically, the dynamic damper 2 has an outer diameter dimension of the axial intermediate region 2a larger than an outer diameter dimension of the one axial end side 2b and the other axial end side 2c, and is within the axial intermediate region 2a. For example, a cylindrical mass member 7 is embedded.

  Then, one end 2b in the axial direction of the dynamic damper 2 has a small inner diameter so as to be press-fitted and fitted to the drive shaft 1. On the other hand, the region from the axial intermediate region 2a to the other axial end 2c of the dynamic damper 2 has a large inner diameter so as to face the outer peripheral surface of the small-diameter region 1a of the drive shaft 1 through the annular gap 9. In addition, the inner diameter dimension is substantially the same as that of the large-diameter region 1b of the drive shaft 1, that is, the inner-diameter dimension fitted into the large-diameter region 1b in a just-fit state or a slight tight-fit state.

  However, the area from the axial middle 2a to the other axial end 2c of the dynamic damper 2 is appropriately set so as to be press-fitted into the inner diameter dimension smaller than the large diameter area 1b of the drive shaft 1, that is, the large diameter area 1b. It is good also as an internal-diameter dimension with a fitting interference allowance.

  Here, the attachment form with respect to the drive shaft 1 of the dynamic damper 2 mentioned above is demonstrated.

  In short, one end 2b in the axial direction of the dynamic damper 2 is press-fitted and fitted into the small-diameter region 1a of the drive shaft 1, while the region from the intermediate intermediate region 2a to the other end 2c in the axial direction is the large-diameter region of the drive shaft 1. The other end 2c in the axial direction is fixed to the large diameter region 1b of the drive shaft 1 by fitting the fastening member 8 only on the outer peripheral surface of the other end 2c in the axial direction.

  At this time, if the axial insertion length W of the dynamic damper 2 with respect to the large-diameter region 1b of the drive shaft 1 is changed, the fitting of the dynamic damper 2 from the fitting portion of the axial one end side 2b to the fitting of the other end 2c in the axial direction is performed. The separation distance L to the joining portion can be changed.

  In this embodiment, strictly speaking, the above-described separation distance L is the separation distance from the inner end edge of the fitting portion on the one axial end side 2b to the inner end edge of the large-diameter region 1b of the drive shaft 1. .

  Incidentally, FIG. 11 shows a state in which the axial insertion length W is shortened and the separation distance L is increased, and FIG. 13 shows the axial insertion length W is increased and the separation distance is increased. The state where L is shortened is shown.

  As described above, when the separation distance L is changed, the resonance frequency of the dynamic damper 2 is adjusted, so that a resonance frequency suitable for the natural frequency of the drive shaft 1 to be mounted can be ensured.

  Even in this case, it is possible to obtain the same operations and effects as those described in the above embodiment. That is, it is sufficient to prepare a single dynamic damper 2 regardless of the specification of the drive shaft 1 (rotating shaft) to be mounted. In other words, the drive shaft 1 is designed exclusively for each specification as in the conventional example. Since it is not necessary to prepare a large number of types of dynamic dampers 2, it is advantageous in reducing manufacturing costs and storage management costs, such as simplification of the manufacturing mold and production line of the dynamic dampers 2. Moreover, in this embodiment, since the dynamic damper 2 has a one-piece structure, the number of parts can be reduced as compared with the embodiments shown in FIGS. 1 to 5, which is advantageous in reducing the cost.

  In short, the dynamic damper 2 of this embodiment has a one-piece structure composed of a single cylinder, and has a small inner diameter so that one end 2b in the axial direction is press-fitted and fitted to the drive shaft 1 (rotating shaft). The region from the axial intermediate region 2a to the other axial end 2c has an inner diameter larger than the inner diameter of the first axial end 2b, and the fastening member 8 is fastened to the outer peripheral surface of the second axial end 2c. The drive shaft 1 (rotating shaft) to be mounted has an outer diameter different from that of the small-diameter region 1a and the large-diameter region 1b, and depends on the natural frequency of the drive shaft 1 (rotating shaft). The axial fitting length W of the region from the axial intermediate region 2a to the other axial end 2c with respect to the large-diameter region 1b is arbitrarily adjusted.

  In this embodiment, the fastening member 8 is mounted only on the other axial end side 2c. However, the fastening member 8 may be mounted on the axial one end side 2b.

  (3) In the above-described embodiment, an example is given in which the rotating shaft to which the dynamic damper 2 is mounted is the drive shaft 1 of the automobile. However, the present invention is not limited to this example. Rotation shafts used for various machine tools and devices can be mounted.

1 is a longitudinal sectional view showing a state in which a dynamic damper according to an embodiment of the present invention is mounted on a drive shaft. It is a perspective view of the dynamic damper of FIG. It is an arrow view of the (3)-(3) line cross section of FIG. FIG. 4 is a cross sectional view taken along line (4)-(4) of FIG. 3 and shows a state in which the axial insertion length of the second cylinder relative to the first cylinder is increased to shorten the separation distance. In the dynamic damper shown in FIG. 4, the axial insertion length of the second cylinder relative to the first cylinder is shortened to increase the separation distance. It is a figure corresponding to Drawing 2 in other embodiments of a dynamic damper concerning the present invention. FIG. 7 is a cross-sectional view of the dynamic damper of FIG. 6 showing a state in which the separation distance is increased. FIG. 8 is a cross-sectional view taken along line (8)-(8) in FIG. 7. FIG. 7 is a cross-sectional view of the dynamic damper of FIG. 6 showing a state in which the separation distance is shortened. FIG. 6 is a view corresponding to FIG. 2 in still another embodiment of the dynamic damper according to the present invention. It is sectional drawing of the dynamic damper of FIG. 10, and has shown the state which made the separation distance long. It is an arrow view of the (12)-(12) line cross section of FIG. It is sectional drawing of the dynamic damper of FIG. 10, and has shown the state which shortened the separation distance.

Explanation of symbols

1 Drive shaft (rotating shaft)
2 Dynamic damper
5 1st cylinder
5a Axial intermediate region
5b One axial end
5c Axial other end
6 Second cylinder
7 Mass members
8 Fastening member
9 annular gap
L Separation distance
W Insertion length in the axial direction

Claims (3)

It is a shear type dynamic damper that is sheathed on the rotating shaft and suppresses vibration of the rotating shaft,
Both ends in the axial direction are externally fitted to the rotary shaft, and has a fastening member that is fastened to the outer periphery on at least one axial end side,
And the dynamic damper characterized by being able to change the separation distance from the fitting part of an axial direction one end side to the fitting part of an axial direction other end side. It is a shear type dynamic damper that is sheathed on the rotating shaft and suppresses vibration of the rotating shaft,
A two-piece structure combining the first cylinder and the second cylinder,
The first cylindrical body has a small inner diameter so that one axially intermediate end is press-fitted and fitted to the rotating shaft, and a region from the axially intermediate region to the other axial end is the rotational shaft. It has a large inner diameter so as to face the outer peripheral surface through an annular gap,
The second cylinder is inserted into the annular gap from the other axial end side, and the axial insertion length is arbitrarily changed for each rotation shaft to be mounted. Dynamic damper. It is a shear type dynamic damper that is sheathed on the rotating shaft and suppresses vibration of the rotating shaft,
It is a one-piece structure consisting of a single cylinder,
One end in the axial direction is press-fitted and fitted to the rotating shaft, and the outer intermediate region is opposed to the rotating shaft through a predetermined annular gap, and the other end in the axial direction is opposed to the rotating shaft through a minute gap. To be packaged and
A fastening member that is fastened and attached to an arbitrary position in the axial direction on the outer peripheral surface on the other end side in the axial direction and presses the mounting region against the outer peripheral surface of the rotary shaft;
The dynamic damper, wherein the fastening member is changed in the axial direction with respect to the outer peripheral surface on the other end side in the axial direction for each rotation shaft to be mounted.

Images