JP5771949B2 - Isolation damper pulley - Google Patents

Description

  The present invention relates to an isolation damper pulley including a torsion rubber elastic body and a rotation fluctuation absorbing rubber elastic body.

  Conventionally, as an isolation damper pulley, for example, there is one described in Japanese Utility Model Publication No. 6-56553 (Patent Document 1). The isolation damper pulley can absorb torsional vibration transmitted to the hub by the action of the torsion rubber elastic body and the inertia mass connected to the rubber elastic body. Furthermore, when the rotational fluctuation is transmitted to the hub, the rotational fluctuation absorbing rubber elastic body can absorb the rotational fluctuation and prevent it from being transmitted to the pulley body. If an excessive torque is generated in the pulley main body due to a malfunction of a device connected to the pulley main body, the rotation fluctuation absorbing rubber elastic body may be twisted and damaged. Therefore, in Patent Document 1, a circular arc-shaped long hole is provided in the pulley body, and a stopper pin is provided in the inertial mass at a position facing the long hole. When an excessive torque is generated, the stopper pin is stopped at the end of the long hole to prevent the rubber elastic body from being damaged.

Japanese Utility Model Publication No. 6-56553

  Although it is said that the rubber elastic body can be prevented from being damaged by the stopper pin and the long hole, even if the rubber elastic body is damaged, it needs to be safe. And in the isolation damper pulley of patent document 1, when a rubber elastic body is damaged, there exists a possibility that a pulley main body may fall from a hub.

  The present invention has been made in view of such circumstances, and provides an isolation damper pulley having a fail-safe function capable of preventing the pulley body from falling off the hub even if the rubber elastic body is damaged. For the purpose.

(1) An isolation damper pulley according to the present invention comprises a hub connected to a crankshaft of an internal combustion engine, an inertia mass provided at a distance from the hub, and the hub and the inertia mass. A torsional rubber elastic body that is connected to each other and absorbs torsional vibration transmitted to the hub, and a pulley body that is provided at a distance from the hub and that is relatively rotatable with respect to the inertia mass. A rubber elastic body for absorbing rotational fluctuation that elastically connects the hub and the pulley body and absorbs rotational fluctuation transmitted to the hub. One of the hub or the inertia mass and the pulley main body has a pin protruding in the rotation axis direction. The other of the hub or the inertia mass and the pulley main body is provided with a rotation allowance groove that accommodates the pin and allows relative rotation within a predetermined phase range with respect to the pin, and is provided at both ends of the rotation allowance groove. A locking groove, and the locking groove regulates relative rotation between the pin and the locking groove when the pin relatively rotates beyond the predetermined phase range, and the pin is The pin is prevented from coming off from the locking groove in the axial direction of the pin.

(Claim 2) In the isolation damper pulley of the present invention, the locking groove is provided at both ends of the rotation permissible groove, and the pin and the locking groove A friction locking groove may be provided that restricts relative rotation of the pin and restricts the pin from coming out of the locking groove in the axial direction of the pin.

  (Claim 3) In the isolation damper pulley of the present invention, a cross-sectional shape of an outer peripheral surface of the pin is formed in a circular shape, and a groove width of the friction locking groove increases toward the end portion. You may make it form in a V shape so that it may become small gradually with respect to the outer diameter.

(Claim 4) In the isolation damper pulley of the present invention, a constricted recess is formed at the base end of the pin, and the locking groove is provided at both ends of the rotation allowance groove, The pin may be provided with a pull-out restricting protrusion that engages with the constricted concave portion in the axial direction of the pin and restricts the pin from coming out of the locking groove in the axial direction of the pin.

(Claim 5) In the isolation damper pulley of the present invention, the locking groove is formed on the rotation permission groove side of the friction locking groove, and the rotation permission groove to the friction locking groove. You may make it provide the return control protrusion which accept | permits and restrict | limits the return movement from the said friction locking groove to the said rotation permission groove.

(Claim 6) Further, in the isolation damper pulley of the present invention, a constricted recess is formed at a base end portion of the pin, and the locking groove is provided at both ends of the rotation allowance groove. A slip-out restricting projection that engages in the axial direction of the pin with respect to the constricted recess of the pin and restricts the pin from coming out of the locking groove in the axial direction of the pin; A return restricting protrusion formed at a circumferential boundary with the groove, allowing entry from the rotation allowance groove to the drop restricting protrusion side, and restricting return movement from the drop restricting protrusion side to the rotation allowance groove; You may make it provide.

(Claim 1) According to the present invention, when an excessive torque is generated in the elastic member for absorbing rotational fluctuation, the locking groove restricts the relative rotation between the pin and the locking groove and the pin is locked. It is restricted from coming out of the groove in the axial direction of the pin. As a result, even if excessive torque is generated in the rotation fluctuation absorbing rubber elastic body and the rotation fluctuation absorbing rubber elastic body is damaged, it is possible to prevent the pulley body from falling off the hub.

  By the way, in order to absorb rotational fluctuation, it is required to lower the resonance frequency of the rubber elastic body for absorbing rotational fluctuation. That is, in order to lower the resonance frequency band of the rubber elastic body for absorbing rotational fluctuation, the rubber elastic body is softened, and the strength of the rubber elastic body is reduced. However, as described above, according to the present invention, there is no need to increase the strength of the elastic rubber body for absorbing rotational fluctuation for the purpose of preventing the pulley body from falling off the hub. Therefore, the rubber elastic body for absorbing rotational fluctuation can be adjusted to a resonance frequency that can reliably exhibit the rotational fluctuation absorbing function.

(Claim 2) According to the present invention, the pin can be locked with an easy shape because the locking groove is constituted by friction locking.
(Claim 3) According to the present invention, it is possible to securely lock the friction.

(Claim 4) According to the present invention, it is possible to physically prevent the pin from being pulled out by the constricted concave portion and the pull-out restricting projection.
(Claim 5) According to the present invention, after the pin is returned to the friction locking groove by the relative rotation of the hub and the pulley body, the pin is moved from the friction locking groove to the rotation allowing groove. Is restricted from moving to. Therefore, the state in which the pin is locked in the friction locking groove can be maintained.

(Claim 6) According to the present invention, it is possible to physically prevent the pin from being pulled out by the constricted concave portion and the pull-out restricting projection. Further, after moving to the locking groove beyond the pin return restricting protrusion by the relative rotation between the hub and the pulley body, the pins it is restricted to move from the locking groove towards the rotation allowing groove. Therefore, the state in which the pin is locked in the locking groove can be maintained.

It is an axial sectional view of the isolation damper pulley in the first embodiment. However, only one side from the central axis is illustrated. It is the partial figure seen from the right side (axial direction) of FIG. It is an axial sectional view of the isolation damper pulley in the second embodiment, and is an AA sectional view of FIG. It is an axial sectional view of the isolation damper pulley in the second embodiment, and is a BB sectional view of FIG. It is the partial figure seen from the right side (axial direction) of FIG. It is the partial figure seen from the axial direction of the isolation damper pulley in 3rd embodiment.

  Hereinafter, an embodiment in which an isolation damper pulley of the present invention is embodied will be described with reference to the drawings.

<First embodiment>
(Overall structure description of isolation damper pulley)
The overall structure of the isolation damper pulley of the first embodiment will be described with reference to FIG. The isolation damper pulley 1 is connected to, for example, a crankshaft (rotary shaft) of an internal combustion engine of an automobile, and is used with a poly V belt suspended on the outer periphery. Then, the rotational driving force of the crankshaft by the internal combustion engine is transmitted to various accessories mounted on the automobile via a poly V belt, for example, an alternator, a water pump, a cooler compressor, etc. Driving kind.

  The isolation damper pulley 1 has a function of absorbing torsional vibrations transmitted to the hub 10 and a function of absorbing rotational fluctuations transmitted to the hub 10. As shown in FIG. 1, the isolation damper pulley 1 includes a hub 10, an inertia mass 20, a torsional rubber elastic body 30, a pulley body 40, a rotation fluctuation absorbing rubber elastic body 50, and a bearing 60. The stopper pin 70 is provided.

  The hub 10 is formed in a metal ring shape, and is disposed at the central shaft portion of the isolation damper pulley 1. The hub 10 includes a cylindrical hub inner cylinder portion 11, a cylindrical hub outer cylinder portion 12 concentrically disposed on the outer peripheral side of the hub inner cylinder portion 11, and one end of the hub inner cylinder portion 11 (see FIG. 1). A disc-shaped hub connecting portion 13 that connects the left end) and one end of the hub outer cylinder portion 12 (the left end in FIG. 1) is integrally formed. That is, the hub 10 is formed in a shape having a circular groove that opens on one axial side (the right side in FIG. 1). An annular protrusion 12 a that protrudes radially outward is formed at the axially central portion of the outer peripheral surface of the hub outer cylinder portion 12. The crankshaft of the internal combustion engine is connected to the inner peripheral side of the hub inner cylinder portion 11 by being fixed by fitting. That is, the hub 10 rotates integrally with the crankshaft.

  The inertia mass 20 is formed in a metal ring shape, and is provided concentrically at a distance from the hub outer cylinder portion 12 in the radial direction. The inertia mass 20 includes a cylindrical mass cylinder portion 21 disposed to face the outer side in the radial direction of the hub outer cylinder portion 12, and a flange portion 22 that extends radially outward from one end (the left end in FIG. 1) of the mass cylinder portion. And are integrally formed. A concave groove 21 a that is recessed outward in the radial direction is formed at the axially central portion of the inner peripheral surface of the mass cylinder portion 21. The concave groove 21 a of the mass cylinder portion 21 is disposed at a position facing the annular protrusion 12 a of the hub outer cylinder portion 12.

  The torsional rubber elastic body 30 elastically connects the outer peripheral surface of the hub outer cylindrical portion 12 and the inner peripheral surface of the mass cylindrical portion 21 of the inertia mass 20. When torsional vibration is transmitted to the hub 10 from the crankshaft, the torsional rubber elastic body 30 absorbs the transmitted torsional vibration.

  The pulley body 40 is formed in a metal ring shape, is provided concentrically with a distance from the hub 10, and is provided so as to be relatively rotatable with respect to the inertia mass 20. The pulley main body 40 forms an annular groove that accommodates the hub outer cylinder portion 12, the mass cylinder portion 21 of the inertia mass 20, and a part of the torsional rubber elastic body 30. The pulley body 40 includes a pulley inner cylinder portion 41, a pulley outer cylinder portion 42, and a pulley connection portion 43, and is integrally formed.

  The pulley inner cylinder portion 41 is formed in a cylindrical shape, is provided at a large distance radially outward from the hub inner cylinder portion 11, and is slightly spaced radially inward from the hub outer cylinder portion 12. Provided. The pulley outer cylinder part 42 is formed in a cylindrical shape, is concentrically arranged on the outer peripheral side of the pulley inner cylinder part 41, and is provided at a slight distance outward in the radial direction with respect to the mass cylinder part 21 of the inertia mass 20. It is done. A plurality of V grooves on which a poly V belt (not shown) is suspended are formed on the outer peripheral surface of the pulley outer cylinder portion 42 in the axial direction. The pulley connecting portion 43 is formed in a disc shape, and connects one end of the pulley inner cylinder portion 41 (right end in FIG. 1) and one end of the pulley outer cylinder portion 42 (right end in FIG. 1). The pulley connecting portion 43 is formed with an arc-shaped long hole 43a in a part in the circumferential direction. Details of the long hole 43a will be described later.

  The rubber elastic body 50 for absorbing rotational fluctuation is formed in a cylindrical shape, and elastically connects the outer peripheral surface of the hub inner cylindrical portion 11 and the inner peripheral surface of the pulley inner cylindrical portion 41 of the pulley body 40. When the rotational fluctuation is transmitted from the crankshaft to the hub 10, the rotational fluctuation absorbing rubber elastic body 50 absorbs the transmitted rotational fluctuation. Specifically, the outer peripheral surface of the rotational fluctuation absorbing rubber elastic body 50 is connected to the inner peripheral face of the pulley inner cylinder portion 41 by vulcanization adhesion, and the inner peripheral surface of the rotational fluctuation absorbing rubber elastic body 50 is an auxiliary cylinder. It is connected to the outer peripheral surface of the metal fitting 51 by vulcanization adhesion. And the auxiliary | assistant cylinder metal fitting 51 is fitted by the outer peripheral surface of the hub inner cylinder part 11 by press fit, and the rubber elastic body 50 for rotation fluctuation absorption is connected with the hub inner cylinder part 11. FIG. The radial length of the rotational fluctuation absorbing rubber elastic body 50 is sufficiently longer than the radial length of the torsional rubber elastic body 30. This is because the resonance frequency required for the rotational fluctuation absorbing rubber elastic body 50 is low, and therefore it is necessary to make it sufficiently soft in the rotational direction.

  The bearing 60 is interposed between the inner peripheral surface of the hub outer cylindrical portion 12 and the outer peripheral surface of the pulley inner cylindrical portion 41, and supports the pulley body 40 so as to be rotatable with respect to the hub 10.

  The stopper pin 70 is formed on the mass cylinder portion 21 so as to protrude from the end surface (the right end surface in FIG. 1) on the pulley coupling portion 43 side of the mass cylinder portion 21 of the inertia mass 20 in the rotation axis direction (the right side in FIG. 1). It is fixed to one end face. The stopper pin 70 is formed in a cylindrical shape. The stopper pin 70 is inserted into a long hole 43a formed in the pulley connecting portion 43, and is allowed to rotate relative to the long hole 43a.

(Detailed shape of the long hole formed in the pulley connection part of the pulley body)
An arc-shaped long hole 43 a is formed in the pulley connecting portion 43 of the pulley body 40. The detailed shape of the long hole 43a will be described with reference to FIG. The long hole 43 a includes an arc-shaped rotation allowance groove 81 and friction locking grooves 82 and 83 located at both ends of the arc of the rotation allowance groove 81.

  The rotation allowance groove 81 accommodates the stopper pin 70 and allows relative rotation of the stopper pin 70 within a predetermined phase range θ. Specifically, the rotation allowance groove 81 is formed in an arc shape having the same radial width. Here, the arc radius at the center of the radial width of the rotation-permissible groove 81 is approximately the same as the distance from the rotation center of the isolation damper pulley 1 at the stopper pin 70. Further, the radial width of the rotation allowing groove 81 is set to be larger than the diameter of the stopper pin 70. Further, the arc-shaped phase range of the rotation-permissible groove 81 is matched with the above-described predetermined phase range θ.

  The predetermined phase range θ is a range that is an allowable range of the rotational fluctuation absorbing rubber elastic body 50 when the pulley body 40 rotates relative to the inertia mass 20. That is, if the relative rotation between the pulley body 40 and the inertia mass 20 is used within the predetermined phase range θ, the rotation fluctuation absorbing rubber elastic body 50 falls within the allowable range. Accordingly, in the normal state, the phase range of the relative rotation between the pulley body 40 and the inertia mass 20 is within the predetermined phase range θ.

  Here, in FIGS. 1 and 2, the rotation allowing groove 81 is shown as a hole penetrating in the axial direction with respect to the pulley connecting portion 43, but is not limited to the through hole, and opens to the inertial mass 20 side. It is good also as a recessed part with a bottom. The meaning of the term of the rotation permissible groove 81 is used to include both.

  The friction locking grooves 82 and 83 are located at both ends of the arc of the rotation allowing groove 81. For example, a large torque may be generated in the pulley main body 40 due to an abnormality in the connected auxiliary machine. In such a case, the amount of relative rotation of the pulley body 40 with respect to the inertia mass 20 becomes large. Then, a large torque is applied to the rotational fluctuation absorbing rubber elastic body 50. The friction locking grooves 82 and 83 act to prevent this state.

  The friction locking grooves 82 and 83 come into contact with the stopper pin 70 when a large torque is generated in the pulley body 40 and the stopper pin 70 rotates beyond the predetermined phase range θ. The relative rotation is restricted. The groove widths of the friction locking grooves 82 and 83 are formed in a V shape so as to gradually decrease with respect to the outer diameter of the stopper pin 70 as it goes to the end.

  Therefore, when the pulley main body 40 rotates relatively relative to the inertia mass 20 and the stopper pin 70 comes into contact with the friction locking grooves 82 and 83, the stopper pin 70 is engaged with the stopper pin 70 by friction. The relative rotation is restricted and the stopper pin 70 is prevented from coming off.

  Thus, by forming the friction locking grooves 82 and 83 as described above at both ends of the long hole 43a, when an abnormally large torque is generated in the pulley body 40, the stopper pin 70 and the friction locking groove 82 are provided. , 83 can be locked by friction. Therefore, after being locked, the pulley body 40 is integrated with the inertia mass 20 and is also substantially integrated with the hub 10. As a result, even if an abnormally large torque is generated in the pulley main body 40, the rotation fluctuation absorbing rubber elastic body 50 can be prevented from being damaged without an excessive torque acting.

  Even if an excessive torque is generated in the rotation fluctuation absorbing rubber elastic body 50, at that time, the friction locking grooves 82 and 83 restrict the relative rotation with the stopper pin 70 and the stopper pin 70 is prevented from coming off. doing. As a result, even if excessive torque is generated in the rotational fluctuation absorbing rubber elastic body 50 and the rotational fluctuation absorbing rubber elastic body 50 is damaged, it is possible to prevent the pulley body 40 from falling off the hub 10.

  Further, in order to absorb rotational fluctuation, it is required to lower the resonance frequency of the rubber elastic body 50 for absorbing rotational fluctuation. That is, in order to reduce the resonance frequency band of the rotational fluctuation absorbing rubber elastic body 50, the rotational elastic band is softened in the rotational direction, leading to a decrease in strength of the rotational fluctuation absorbing rubber elastic body 50. However, as described above, for the purpose of preventing the pulley body 40 from falling off the hub 10, it is not necessary to increase the strength of the rubber elastic body 50 for absorbing rotational fluctuation. Therefore, the rubber elastic body 50 for absorbing rotational fluctuation can be adjusted to a resonance frequency that can reliably exhibit the rotational fluctuation absorbing function.

<Second embodiment>
The long hole 143a and the stopper pin 170 according to the second embodiment will be described with reference to FIGS. In addition, in 2nd embodiment, since structures other than the long hole 143a and the stopper pin 170 are the same as 1st embodiment, the same code | symbol is attached | subjected and description is abbreviate | omitted.

  As shown in FIG. 3, the stopper pin 170 protrudes in the rotational axis direction (right side in FIG. 1) from the end surface (right end surface in FIG. 1) on the pulley coupling portion 43 side of the mass cylinder portion 21 of the inertia mass 20. Further, it is fixed to one end face of the mass cylinder portion 21. The stopper pin 170 is formed in a substantially cylindrical shape as a whole, and a constricted concave portion 171 is formed at the base end portion. The stopper pin 170 is inserted into a long hole 143a formed in the pulley connecting portion 43, and is allowed to rotate relative to the long hole 143a.

  The long hole 143a includes an arc-shaped rotation allowance groove 81 (the same shape as the rotation allowance groove 81 of the first embodiment) and locking grooves 110 and 120 positioned at both ends of the arc of the rotation allowance groove 81. The locking grooves 110 and 120 have the effect of preventing an excessive torque from being applied to the rotational fluctuation absorbing rubber elastic body 50, similarly to the friction locking grooves 82 and 83 of the first embodiment.

  The locking grooves 110 and 120 include locking groove main body portions 111 and 121, removal restriction projections 112 and 122, and return restriction projections 113 and 123. The locking groove main body portions 111 and 121 have the same shape as the friction locking grooves 82 and 83 of the first embodiment. That is, the groove widths of the locking groove main body portions 111 and 121 are formed in a V shape so as to gradually decrease with respect to the cylindrical outer diameter of the stopper pin 170 toward the end portion.

  The slip-out restricting projections 112 and 122 are formed so as to protrude from the inertia mass 20 side to the groove inside of the locking groove main body portions 111 and 121. In the present embodiment, the slip-out restricting projections 112 and 122 are provided on the radially outer side (upper side in FIG. 3) of the locking groove main body portions 111 and 121. Further, the slip-out restricting protrusions 112 and 122 are provided over the entire circumferential direction of the locking groove main body portions 111 and 121. The axial width of the slip-out restricting projections 112 and 122 is formed to be narrower than the concave width of the constricted concave portion 171 of the stopper pin 170, and the constricted concave portion 171 is formed in a state where the stopper pin 170 is positioned in the locking grooves 110 and 120. It is formed in the position to engage. That is, when a large torque is generated in the pulley body 40 and the stopper pin 170 rotates beyond the predetermined phase range θ, the constricted concave portion 171 of the stopper pin 170 is engaged with the removal restricting projections 112 and 122. The stopper pin 170 is restricted from coming off from the locking grooves 110 and 120 in the protruding direction (axial direction) of the stopper pin 170.

  The return restricting projections 113 and 123 are formed on the rotation allowing groove 81 side of the locking groove main body portions 111 and 121 so as to protrude from the locking groove main body portions 111 and 121 to the inside of the groove. In the present embodiment, the return regulating protrusions 113 and 123 are provided on both the radially outer side and the radially inner side of the locking groove main body portions 111 and 121. The opening widths of the return restricting protrusions 113 and 123 are slightly smaller than the cylindrical outer diameter of the stopper pin 170.

  That is, when the stopper pin 170 reaches the return restricting projections 113 and 123 from the rotation allowance groove 81 at a somewhat large speed, the stopper pin 170 or the return restricting projections 113 and 123 are slightly elastically deformed, whereby the locking groove main body portion 111. , 121 is allowed to enter. On the other hand, after the stopper pin 170 has entered the locking groove body portions 111 and 121, the relative rotational speed of the stopper pin 170 with respect to the locking groove body portions 111 and 121 is relatively small. Therefore, even if it tries to return to the rotation permission groove 81 side from the locking groove main body portions 111 and 121, the stopper pin 170 and the return restricting projections 113 and 123 are not elastically deformed and restrict the return movement.

  According to the present embodiment, the stopper pin 170 can be locked by friction by the locking groove main body portions 111 and 121, similarly to the friction locking grooves 82 and 83 of the first embodiment. Furthermore, according to the present embodiment, when the stopper pin 170 has entered the locking groove main body portions 111 and 121, the constricted concave portion 171 of the stopper pin 170 is engaged in the axial direction with respect to the removal restricting projections 112 and 122. Match. Accordingly, the axial disengagement of the stopper pin 170 with respect to the locking grooves 110 and 120 is restricted by physical engagement in addition to the frictional force.

  Further, even when a force to return to the rotation allowance groove 81 side acts on the stopper pin 170 in a state in which the stopper pin 170 has entered the locking groove main body portions 111 and 121, the stopper pin 170 is not moved back. 123 restricts the return movement from the locking groove main body 111, 121 side to the rotation allowing groove 81 side. Accordingly, the stopper pin 170 is maintained in a state of being frictionally locked to the locking groove main body portions 111 and 121.

  In this way, by forming the locking groove main body portions 111 and 121, the drop restricting projections 112 and 122, and the return restricting projections 113 and 123 as described above at both ends of the long hole 143a, an abnormally large torque is applied to the pulley main body 40. When this occurs, the stopper pin 170 and the locking grooves 110 and 120 are locked. Therefore, after being locked, the pulley body 40 is integrated with the inertia mass 20 and is also substantially integrated with the hub 10. As a result, even if an abnormally large torque is generated in the pulley main body 40, the rotation fluctuation absorbing rubber elastic body 50 can be prevented from being damaged without an excessive torque acting.

  Even if an excessive torque is generated in the rotational fluctuation absorbing rubber elastic body 50, at that time, the locking grooves 110 and 120 restrict the relative rotation with the stopper pin 170 and the stopper pin 170 is prevented from coming off. ing. As a result, even if excessive torque is generated in the rotational fluctuation absorbing rubber elastic body 50 and the rotational fluctuation absorbing rubber elastic body 50 is damaged, it is possible to prevent the pulley body 40 from falling off the hub 10.

<Third embodiment>
The long hole 243a of 3rd embodiment is demonstrated with reference to FIG. The long hole 243a of the present embodiment includes locking groove main body portions 211 and 221, removal restriction projections 112 and 122, and return restriction projections 113 and 123. Here, the locking groove main body portions 211 and 221 of the long hole 243a of the present embodiment are different from the locking groove main body portions 111 and 121 of the long hole 143a of the second embodiment. Further, the drop-out restricting projections 112 and 122 and the return restricting projections 113 and 123 of the present embodiment are the same as those in the second embodiment.

  The locking groove main body portions 211 and 221 are not V-shaped with a gradually decreasing groove width, but have a slight phase range with the same width as the rotation allowing groove 81, and the end portions of the locking groove main body portions 211 and 221 are , And formed in an arc shape having the width as a diameter. That is, the locking groove main body portions 211 and 221 are not locked to the stopper pin 170 by friction as in the second embodiment.

  In such a configuration, when the stopper pin 170 enters the locking groove main body portions 211 and 221, the stopper pin 170 restricts the removal from the locking groove main body portions 211 and 221 by the removal restricting projections 112 and 122. Furthermore, the return restricting protrusions 113 and 123 restrict the stopper pin 170 from returning to the rotation allowing groove 81 side. Therefore, after the stopper pin 170 enters the locking groove main body portions 211 and 221, the stopper pin 170 continues to be positioned on the locking groove main body portions 211 and 221. Thereby, there exists an effect substantially the same as 2nd embodiment.

<Others>
In the above embodiment, the stopper pin 70 is fixed to the mass cylinder portion 21 of the inertia mass 20, and the long hole is formed in the pulley connection portion 43 of the pulley body 40. In addition, the stopper pin 70 can be fixed to one end surface of the hub outer cylinder portion 12, and the long hole 43 a can be formed in the pulley connection portion 43 of the pulley body 40. Moreover, the member which fixes the stopper pin 70 and the member which forms the long hole 43a can also be replaced.

1: isolation damper pulley 10: hub, 11: hub inner cylinder part, 12: hub outer cylinder part, 12a: annular projection 13: hub connecting part 20: inertia mass, 21: mass cylinder part, 21a: concave groove, 22 : Flange part 30: Rubber elastic body for torsion 40: Pulley body 41: Pulley inner cylinder part 42: Pulley outer cylinder part 43: Pulley connecting part 43a, 143a, 243a: Long hole 50: Rubber elasticity for absorbing rotational fluctuation Body: 51: Auxiliary tube fitting 60: Bearing, 70: Stopper pin 81: Rotation allowance groove, 82, 83: Friction locking groove 110, 120: Locking groove, 111, 121: Locking groove main body 112, 122: Disengagement restricting protrusion 113, 123: Return restricting protrusion 170: Stopper pin, 171: Constricted recess 211, 221: Locking groove main body θ: Predetermined phase range

Claims (6)

A hub connected to the crankshaft of the internal combustion engine;
An inertial mass provided at a distance from the hub;
A rubber elastic body for torsion that elastically connects the hub and the inertial mass and absorbs torsional vibration transmitted to the hub;
A pulley body provided at a distance from the hub and provided to be rotatable relative to the inertial mass;
A rubber elastic body for rotational fluctuation absorption that elastically connects the hub and the pulley body and absorbs rotational fluctuation transmitted to the hub;
With
One of the hub or the inertia mass and the pulley body has a pin protruding in the rotation axis direction,
The other of the hub or the inertia mass and the pulley main body is provided with a rotation allowance groove that accommodates the pin and allows relative rotation within a predetermined phase range with respect to the pin, and is provided at both ends of the rotation allowance groove. A stop groove,
The locking groove restricts relative rotation between the pin and the locking groove when the pin relatively rotates beyond the predetermined phase range, and the pin is moved from the locking groove to the pin. Isolation damper pulley that restricts it from coming off in the axial direction . In claim 1,
The locking groove is provided at both ends of the rotation allowance groove, and the relative rotation between the pin and the locking groove is restricted by friction locking with the pin, and the pin is the locking groove. An isolation damper pulley comprising a friction locking groove for restricting the pin from coming off in the axial direction . In claim 2,
The cross-sectional shape of the outer peripheral surface of the pin is formed in a circular shape,
An isolation damper pulley formed in a V shape so that the groove width of the friction locking groove gradually decreases with respect to the outer diameter of the pin as it goes to the end. In claim 2 or 3,
A constricted recess is formed at the base end of the pin,
The locking grooves are provided at both ends of the rotation allowance groove, and engage the pin in the axial direction of the pin with respect to the constricted concave portion of the pin, so that the pin extends from the locking groove to the axial direction of the pin. An isolation damper pulley provided with a pull-out restricting protrusion that restricts the pull-out. In any one of Claims 2-4,
The locking groove is formed on the rotation permission groove side of the friction locking groove, allows entry from the rotation permission groove to the friction locking groove, and allows rotation from the friction locking groove. An isolation damper pulley provided with a return restricting protrusion for restricting return movement to the groove. In claim 1,
A constricted recess is formed at the base end of the pin,
The locking groove is
Disengagement provided at both ends of the rotation allowance groove to restrict the pin from coming out of the locking groove in the axial direction of the pin by engaging the constricted recess of the pin in the axial direction of the pin. Restriction protrusions,
Formed at the boundary in the circumferential direction between the slip-out restricting projection and the rotation-allowing groove, allowing entry from the rotation-allowing groove to the slip-out restricting projection side, and returning from the slip-out restricting projection side to the rotation-allowing groove A return restricting protrusion for restricting movement;
Isolation damper pulley with

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