JP6448353B2 - Active vibration isolator - Google Patents

Description

  The present invention relates to an active vibration isolator, and more particularly to an active vibration isolator capable of increasing a generated force.

  A rubber-like anti-vibration base that connects the first fixture and the cylindrical second fixture, a liquid chamber in which the anti-vibration base forms at least a part of the chamber wall, and another chamber wall of the liquid chamber A vibration body (piston member) provided at a position facing the vibration isolation base, and an actuator disposed on the opposite side of the liquid chamber with the vibration body interposed therebetween and vibrating the vibration body in the axial direction by a drive shaft There is known an active vibration isolator including the above (Patent Document 1). In the technology disclosed in Patent Document 1, vibration can be attenuated by vibrating the vibrating body (piston member) in the axial direction to change the volume of the liquid chamber and controlling the liquid pressure in the liquid chamber.

JP 2012-107734 A

  However, in the conventional technology described above, there is a demand for an increase in generated force by vibrating the vibrating body (piston member) in the axial direction.

  The present invention has been made to meet the above-described demand, and an object thereof is to provide an active vibration isolator capable of increasing the generated force.

Means for Solving the Problems and Effects of the Invention

  In order to achieve this object, according to the active vibration isolator according to claim 1, the first fixture and the cylindrical second fixture are connected by a vibration isolating base composed of a rubber-like elastic body, A diaphragm is disposed at a position facing the vibration isolation base in the axial direction of the second fixture. The diaphragm is composed of a rubber-like elastic body and forms a liquid chamber at least with the vibration-proofing substrate. The vibration chamber disposed in the liquid chamber divides the liquid chamber into a first liquid chamber on the vibration-proof base side and a second liquid chamber on the diaphragm side in the axial direction of the second fixture. The vibrator is vibrated in the axial direction by the drive shaft by an actuator disposed on the opposite side of the first liquid chamber with the vibrator in the axial direction of the second fixture. The entire vibration body is displaced in the axial direction by vibration by the actuator and changes the axial length of the first liquid chamber and the second liquid chamber, so that the pressure receiving area of the vibration body can be increased. Therefore, there is an effect that the generated force can be increased without increasing the axial displacement amount of the vibrating body.

Ring-shaped orifice forming member, and a first liquid chamber and the first liquid chamber to form an orifice that communicates the first opening to form an orifice through each with the first liquid chamber and the second liquid chamber and the second Two openings are provided. Since the orifice forming member is disposed on the diaphragm side of the vibrating body in the axial direction of the second fixture, the pressure receiving area of the vibrating body can be increased without being restricted by the orifice forming member. Orifice forming member, since the vertical wall around the first opening toward the first liquid chamber side pressure isolator is disposed is projected, by the vertical wall can be secured damping effect due to liquid flow orifice effect There is.

According to the active vibration isolator according to claim 2, the vibration exciter is engaged with the side surface of the vertical wall to restrict displacement in the circumferential direction of the vibration exciter, while the shaft of the vibration exciter Since the displacement in the direction is allowed, it is possible to prevent the vibrating body from being displaced in the circumferential direction and closing the first opening. Therefore, in addition to the effect of claim 1 , there is an effect that the generated force can be increased while suppressing the damping effect by the orifice from being impaired by the vibrating body.

According to the active vibration isolator according to claim 3 , the orifice forming member includes the first stopper portion that restricts the axial displacement of the vibrating body and maintains the engagement between the vertical wall and the engaging portion. Yes. Since the vibrator is provided with a stoppered portion that overlaps with the first stopper portion in the axial projection, in addition to the effect of claim 2 , the axial direction of the drive shaft is caused by the interference between the first stopper portion and the stoppered portion. The displacement of the vibrating body can be restricted and the displacement of the vibrating body in the axial direction can prevent the vibrating body from getting over the vertical wall and hindering the liquid flow of the orifice.

According to the active vibration isolator of claim 4 , the vibration isolating base includes the second stopper portion that restricts the axial displacement of the vibrating body and maintains the engagement between the vertical wall and the engaging portion. Yes. Since the vibration exciter includes a stoppered portion that overlaps with the second stopper portion in the axial projection, in addition to the effects of the second or third aspect , the interference of the second stopper portion and the stoppered portion causes the drive shaft to move. The displacement in the axial direction can be limited, and the displacement of the vibrating body in the axial direction can prevent the vibrating body from getting over the vertical wall and hindering the fluid flow of the orifice.

It is an axial sectional view of the active vibration isolator in the first embodiment of the present invention. It is sectional drawing of the active vibration isolator in the II-II line of FIG. It is a top view of an orifice formation member. It is a front view of an orifice formation member. It is sectional drawing of the orifice formation member in the VV line | wire of FIG. It is an exploded view of an orifice formation member and a vibrating body. It is an axial sectional view of the active vibration isolator in the second embodiment. It is an axial sectional view of an active vibration isolator in a third embodiment. It is an axial sectional view of an active vibration isolator in a fourth embodiment. It is axial direction sectional drawing of the active vibration isolator in 5th Embodiment.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. First, the structure of the active vibration isolator 10 will be described with reference to FIG. FIG. 1 is an axial cross-sectional view of an active vibration isolator 10 according to the first embodiment of the present invention, and FIG. 2 is a cross-sectional view of the active vibration isolator 10 taken along line II-II in FIG. FIG. 1 shows a state before the engine is supported (that is, a state before the weight of the engine is loaded) (the same applies to FIGS. 7 to 10).

  As shown in FIG. 1, the active vibration isolator 10 supports and fixes an automobile engine (vibrating body, not shown), and prevents the engine vibration from being transmitted to a vehicle body frame (not shown). A first fixture 11 attached to the engine side, a cylindrical second fixture 12 attached to the vehicle body frame side below the engine, and a vibration-isolating base configured by connecting these and a rubber-like elastic body 15 and the second fixture 12 to form a liquid chamber 19 between the vibration isolator base 15 and a diaphragm 17 made of a rubber-like elastic body, and a vibration body disposed in the liquid chamber 19 40 and an actuator 50 for oscillating and displacing the vibrating body 40 in the axial direction by the drive shaft 52.

  The first fixture 11 is a member formed in a substantially cylindrical shape from a metal material such as an aluminum alloy, and has a bolt projecting upward from its upper end surface. The first fixture 11 is attached to the engine side via this bolt. The second fixture 12 includes a cylindrical fitting 13 in which the vibration-proof base 15 is vulcanized and a bottom fitting 14 fixed to the lower portion of the cylindrical fitting 13 by caulking. The cylindrical metal fitting 13 is formed in a cylindrical shape having an opening extending upward, and the bottom metal fitting 14 is formed in a cup shape having a bottom portion, respectively, from a steel material or the like. A bolt projects downward from the bottom of the bottom metal fitting 14. The second fixture 12 is attached to the vehicle body via the bolt.

  The anti-vibration base 15 is a member formed in a truncated cone shape from a rubber-like elastic body, and is vulcanized and bonded between the lower surface side of the first fixture 11 and the upper end opening of the cylindrical fitting 13. A rubber film 16 covering the inner peripheral surface of the cylindrical metal fitting 13 is connected to the lower end portion of the vibration isolating base 15. The rubber film 16 is formed with a step 16 a having a reduced film thickness at a position away from the vibration isolating substrate 15 by a predetermined distance.

  The diaphragm 17 is formed as a rubber film bent in a bellows shape from a rubber-like elastic body. The outer periphery of the diaphragm 17 is vulcanized and bonded to an annular mounting plate 18 as viewed from above. The circumference is vulcanized. The mounting plate 18 is formed in a cylindrical shape whose inner peripheral side is bent in the axial direction. The diaphragm 17 is attached to the second fixture 12 by the outer peripheral side of the mounting plate 18 being nipped and fixed together with the bottom metal fitting 14 by the cylindrical metal fitting 13. As a result, a liquid chamber 19 is formed between the upper surface side of the diaphragm 17 and the lower surface side of the vibration isolation base 15. The liquid chamber 19 is filled with an antifreeze liquid (not shown) such as ethylene glycol.

  The orifice forming member 30 is a member made of an annular rigid body that is disposed inside the rubber film 16 that covers the inner peripheral surface of the cylindrical fitting 13. The vibration exciter 40 is a disk-shaped member that is disposed in the liquid chamber 19 together with the orifice forming member 30. In this embodiment, the vibration exciter 40 is disposed closer to the vibration isolating substrate 15 than the orifice forming member 30.

  As shown in FIG. 2, the vibrating body 40 has a substantially circular outer shape, and is formed in such a size that the outer periphery contacts the inner peripheral surface of the rubber film 16. Therefore, by arranging the vibrating body 40 in the liquid chamber 19, the liquid chamber 19 is partitioned into a first liquid chamber 20 on the vibration isolation base 15 side and a second liquid chamber 21 on the diaphragm 17 side. The orifice forming member 30 (see FIG. 1) forms an orifice 22 that communicates the first liquid chamber 20 and the second liquid chamber 21 partitioned by the vibrating body 40.

  The orifice forming member 30 and the vibrating body 40 will be described with reference to FIGS. FIG. 3 is a plan view of the orifice forming member 30, and FIG. 4 is a front view of the orifice forming member 30. FIG. 5 is a cross-sectional view of the orifice forming member 30 taken along the line V-V in FIG. 4, and FIG. 6 is an exploded view of the orifice forming member 30 and the vibrating body 40.

  As shown in FIGS. 3 to 6, the orifice forming member 30 is provided with an annular wall portion 31 that is disposed orthogonal to the axis O, and is connected to the inner periphery of the wall portion 31 and also in the direction of the axis O. A cylindrical body portion 34 extending in the (axial direction) and a wall portion 35 projecting radially outward from the lower end portion of the body portion 34 in a flange shape are provided. In the orifice forming member 30, a first opening 32 and a second opening 36 are formed in a recess in the walls 31 and 35, respectively. A partition wall 37 that connects the wall portions 31 and 35 and the body portion 34 and separates the first opening portion 32 and the second opening portion 36 is provided on the outer periphery of the body portion 34.

  In the orifice forming member 30, a vertical wall 33 projects from a wall portion 31 around the first opening portion 32 toward the opposite side of the body portion 34. The vertical wall 33 is a portion having a wall surface parallel to the axis O, and is located on both sides in the circumferential direction and radially inward of the first opening 32 and the partition wall 37 (see FIGS. 3 and 4), excluding the outer peripheral portion. Surrounding the first opening 32. The vertical wall 33 is positioned on a virtual cylinder (curved surface) in which both end surfaces 33a on the radially outer side pass through the outer peripheral surface of the wall portion 31 and the outer peripheral surface of the wall portion 35 (see FIGS. 3 and 6). . Therefore, the end surface 33 a of the vertical wall 33 of the orifice forming member 30 and the outer peripheral surfaces of the wall portions 31 and 35 can be brought into close contact with the rubber film 16 that covers the inner peripheral surface of the cylindrical metal fitting 13.

  The orifice forming member 30 includes a first stopper portion 38 that is connected to the inner periphery of the wall portion 31. The first stopper portion 38 protrudes in a bowl shape from the wall portion 31 toward the radially inner side of the body portion 34, and has a hole portion 39 whose outer shape in the axial direction (perpendicular to the plane of FIG. 3) is circular. doing.

  As for the vibration body 40, the engaging part 42 (refer FIG.2 and FIG.6) is recessedly provided in the substantially circular outer edge 41. As shown in FIG. The engaging portion 42 matches the shape of the side surface of the vertical wall 33, has an axially contoured outline, and engages with the vertical wall 33 provided on the orifice forming member 30. Accordingly, the vibrating body 40 can move in the axial direction along the vertical wall 33 by engaging the engaging portion 42 with the vertical wall 33, while the vertical wall 33 restricts rotation in the circumferential direction. In addition, as for the vibrating body 40, the outer edge 41 contacts the rubber film 16 over the circumferential direction, and the engaging part 42 contacts the side surface of the vertical wall 33 over the full length.

  Returning to FIG. The vibrating body 40 is coupled to the drive shaft 52 of the actuator 50 via the reinforcing member 43. The reinforcing member 43 is a member formed in a columnar shape, and is inserted into the hole 39 (see FIGS. 3, 5, and 6) of the orifice forming member 30, and has a diameter from an axial end located on the diaphragm 17 side. A hook-shaped stoppered portion 44 that protrudes outward in the direction is provided. In the reinforcing member 43, the shaft-like member 54 (drive shaft 52) of the actuator 50 is screwed into the center of one axial end surface, and the center of the vibrating body 40 is fixed to the center of another axial end surface by a screw 45. Is done.

  The stopper portion 44 has a size in which at least a portion thereof overlaps with the first stopper portion 38 in the axial projection in a state where the orifice forming member 30, the vibrating body 40, and the reinforcing member 43 are disposed inside the cylindrical fitting 13. Is set. The stopper portion 44 has an outer diameter set smaller than the inner diameter of the body portion 34 of the orifice forming member 30, and the first stopper portion 38 has an inner diameter set larger than the outer diameter of the reinforcing member 43. Thereby, the vibrating body 40 and the reinforcing member 43 can move in the axial direction until the first stopper portion 38 and the stopper portion 44 interfere with each other, and the first stopper portion 38 and the stopper portion 44 are moved. When the interference occurs, the movement in the axial direction is restricted.

  The vertical wall 33 provided on the orifice forming member 30 (see FIG. 6) allows the vibrating body 40 and the reinforcing member 43 to move in the axial direction without the first stopper portion 38 and the stopper portion 44 interfering with each other. In the meantime, the length L in the axial direction (see FIG. 4) so that the vertical wall 33 and the engaging portion 42 are engaged (the vibrating body 40 moves within the range of the length in the axial direction of the vertical wall 33) Is set. Therefore, while the vibrating body 40 can move in the axial direction along the vertical wall 33, circumferential rotation is restricted by the vertical wall 33. Therefore, while the vibrating body 40 can move in the axial direction along the vertical wall 33, the vibrating body 40 can be prevented from rotating around the axis O and overlapping the first opening 32 in the axial direction.

  As a result, the outer periphery of the wall portions 31 and 35 of the orifice forming member 30 and the end surface 33a of the vertical wall 33 are brought into close contact with the rubber film 16 (see FIG. 1). In addition, an orifice 22 communicating with the first liquid chamber 20 via the first opening 32 and communicating with the second liquid chamber 21 via the second opening 36 is formed. Since the first opening 32 and the second liquid chamber 21 are separated by the vertical wall 33 and the vibrating body 40, it is possible to prevent the first opening 32 from being short-circuited to the second liquid chamber 21. Since the partition wall 37 exists between the first opening 32 and the second opening 36, the orifice 22 flows about one round from the first opening 32 to the second opening 36 on the outer periphery of the orifice forming member 30. Has a road length.

  Next, the actuator 50 that vibrates the vibrating body 40 and the reinforcing member 43 in the axial direction will be described. The actuator 50 is an iron magnet movable type electromagnet type linear actuator, and is housed and held in a housing space formed by the bottom metal fitting 14 while being sealed from the outside. The actuator 50 includes a stator 51 fixed to the second fixture 12, and a mover 53 that is supported so as to reciprocate with respect to the stator 51 and is connected to the vibrating body 40. The mover 53 is a shaft-like member disposed in a vertical posture along the axis O of the second fixture 12 (coaxially in the present embodiment), and the tip thereof is attached to the vibrating body 40. Coaxially connected to the attached shaft-like member 54, the movable element 53 and the shaft-like member 54 are united so as to vibrate and displace (reciprocate) the vibrator 40 vertically along the axis O direction.

  The drive shaft 52 includes a mover 53, a shaft-shaped member 54, and a bolt. The mover 53 is formed in a cylindrical shape having a through-hole along the axis O, while the shaft-shaped member 54 has a threaded portion that is open to the proximal end side and has a female thread formed on the inner peripheral surface thereof. The front end of the bolt inserted from the base end side of the mover 53 is screwed into the female screw portion of the shaft-like member 54, whereby the mover 53 and the shaft-like member 54 are integrally connected, and the drive shaft 52 is configured. Is done.

  The mover 53 is fixedly provided with a magnetic material portion 55 as a mover core formed by laminating a large number of metal plates made of a magnetic metal such as an electromagnetic steel plate on the outer peripheral surface. A plurality of magnetic material portions 55 (two in the present embodiment) are provided with a predetermined interval in the direction of the axis O. The mover 53 is capable of reciprocating in the direction of the axis O with respect to the stator 51 via a pair of upper and lower plate springs 56, and the position of the axis O in the direction perpendicular to the axis O. It is supported in a state where the direction position is positioned.

  The stator 51 has an annular shape that coaxially surrounds the outer periphery of the mover 53, and supports the mover 53 so that it can reciprocate in the direction of the axis O in its hollow portion. It is held in a lowered state. The mounting plate 57 is caulked and fixed by the bottom metal fitting 14 together with the cylindrical metal fitting 13 and the attachment plate 18 of the diaphragm 17.

  The stator 51 is arranged in a radial direction from both sides so that a yoke 58 formed by laminating a large number of annular metal plates made of a magnetic metal such as an electromagnetic steel plate and the central portion of the yoke 58 face each other with the magnetic material portion 55 interposed therebetween. A pair of magnetic pole portions 59 projecting inward are provided.

  The tip of the magnetic pole part 59 of the stator 51 facing the magnetic material part 55 (that is, the inner end of the magnetic pole part 59) is adjacent to the movable element 53 along the reciprocating direction (axis O direction). A pair of upper and lower permanent magnets 60 and 61 facing the mover 53 while being arranged in parallel are orthogonal to the reciprocating direction of the mover 53 so that their magnetic poles are NS different from each other. The magnetic poles are arranged in the direction, and the arrangement of the magnetic poles (N pole and S pole) is reversed. In the present embodiment, two pairs of upper and lower permanent magnets 60 and 61 are arranged in parallel in the axis O direction so as to correspond to the magnetic material portion 55.

  A coil 62 is wound around each of the pair of magnetic pole portions 59 of the stator 51 around an axis in a direction perpendicular to the reciprocating direction (axis O direction) of the mover 53, and a pair of permanent magnets. The magnetic flux passing through 60 and 61 can be generated. In the present embodiment, a pair of permanent magnets 60 and 61 are provided at the inner end portions of the pair of magnetic pole portions 59 of the stator 51 facing each other with the magnetic material portion 55 interposed therebetween. The magnetic poles are opposed to each other in a direction orthogonal to the reciprocating direction of the movable element 53, and the magnetic poles are arranged so that the opposing magnetic poles are different from each other so that the opposing magnetic poles are different from each other (left and right in FIG. 1). It is installed.

  When the coil 62 of the actuator 50 is in a demagnetized state, the drive shaft 52 supported so as to be displaceable in the axial center O direction (axial direction) with respect to the stator 51 is supported and stopped by a leaf spring 56. When a positive exciting current is passed through the coil 62 from this state, the direction of the magnetomotive force generated in the coil 62 is the same as the direction of the magnetomotive force of the upper permanent magnet 60, and the magnetomotive force is increased. On the other hand, the direction of the magnetomotive force of the lower permanent magnet 61 and the direction of the magnetomotive force of the coil 62 are opposite to each other, and the magnetomotive force of both is canceled and weakened. As a result, an upward force acts on the magnetic material portion 55, and the mover 53 is raised while the leaf spring 56 is elastically deformed. Since the vibrating body 40 coupled to the mover 53 moves upward, the volume of the first liquid chamber 20 decreases.

  On the other hand, when an exciting current in the reverse direction is supplied to the coil 62, a downward force is applied to the magnetic material portion 55, and the mover 53 is lowered while elastically deforming the leaf spring 56. Since the vibrating body 40 coupled to the mover 53 moves downward, the volume of the first liquid chamber 20 increases. Thus, by alternately switching the direction of the excitation current of the coil 62 in the forward and reverse directions, the volume of the first liquid chamber 20 can be changed by vibrating the drive shaft 52 and the vibrating body 40 up and down.

  A method of manufacturing the active vibration isolator 10 (see FIG. 1) configured as described above will be described. A first molded body in which the first fixture 11 and the cylindrical fitting 13 are connected by a vibration-proof base 15, the diaphragm 17 is vulcanized, and the mounting plate 18 and the shaft-shaped member 54 are vulcanized and bonded. The two molded bodies are each vulcanized and molded with a rubber vulcanization mold. Next, the reinforcing member 43 and the second molded body are submerged in the liquid, and after the shaft-like member 54 is screwed onto the reinforcing member 43, the orifice forming member 30 is placed on the reinforcing member 43. Next, the vibration body 40 is fixed to the reinforcing member 43 with the screw 45 while aligning the position of the vertical wall 33 (see FIG. 2) and the position of the engaging portion 42 to obtain an intermediate assembly.

  Next, the first molded body is also submerged in the liquid, and the intermediate assembly is inserted into the cylindrical fitting 13 from the vibrating body 40 side through the lower opening of the first molded body. At this time, the vibrator 40 is disposed inside the rubber film 16 beyond the step 16a, and the tubular metal fitting 13 is caulked while the orifice forming member 30 is sandwiched between the step 16a and the mounting plate 18 in the axial direction. As a result, the intermediate assembly is fixed to the cylindrical fitting 13.

  Thereafter, in a posture in which the first fixture 11 is in a downward position, this member is taken out of the liquid, and while maintaining this posture, the actuator 50 is overlapped from the lower surface side of the diaphragm 17, and the shaft-like member 54 and the mover 53 are attached. Fasten with bolts. Next, the bottom metal 14 is put on the actuator 50, and the bottom metal 14 is fixed to the lower opening of the cylindrical metal 13 by caulking. Thereby, the manufacture of the active vibration isolator 10 is completed.

  Next, the operation of the active vibration isolator 10 will be described. When a relatively large amplitude low-frequency vibration is input from the first fixture 11 or the second fixture 12, the operation of the actuator 50 is performed by a control device (not shown) that controls the active vibration isolator 10. Stopped. In this state, the liquid flows between the first liquid chamber 20 and the second liquid chamber 21 through the orifice 22. The active vibration isolator 10 can dampen vibration by the liquid flow effect of the orifice 22.

  On the other hand, when a relatively high amplitude amplitude is input from the first fixture 11 or the second fixture 12, a control device (not shown) applies a sine wave AC voltage or a rectangular wave to the coil 62 of the actuator 50. An AC voltage or the like is applied, the movable element 53 (that is, the drive shaft 52) is reciprocated up and down, and the vibration exciter 40 connected to the drive shaft 52 is excited and displaced in an opposite phase to the input vibration. When the vibrating body 40 reciprocates, the liquid pressure in the first liquid chamber 20 can be absorbed and vibration can be reduced.

  According to the active vibration isolator 10, the first liquid chamber 20 on the vibration isolator base 15 side and the second liquid chamber 21 on the diaphragm 17 side in the axial center O direction by the vibration body 40 disposed in the liquid chamber 19. The liquid chamber 19 is partitioned. The vibration body 40 is vibrated in the axial direction by the drive shaft 52 by the actuator 50 disposed on the opposite side of the first liquid chamber 20 with the vibration body 40 interposed therebetween in the direction of the axis O. The vibrating body 40 is a partition (boundary) between the first liquid chamber 20 and the second liquid chamber 21, and the axis of the boundary between the first liquid chamber 20 and the second liquid chamber 21 due to the axial displacement of the vibrating body 40. The position of the direction changes. The vibration body 40 is entirely displaced in the axial direction by vibration by the actuator 50 and changes the axial lengths of the first liquid chamber 20 and the second liquid chamber 21, so that the outer diameter of the vibration body 40 is reduced. The inner diameter of the cylindrical fitting 13 can be increased. Since the pressure receiving area of the vibrating body 40 accommodated in the cylindrical fitting 13 can be increased to the maximum of the accommodating range, the generated force can be increased without increasing the axial displacement amount of the vibrating body 40. .

  Here, when the axial displacement amount of the vibrating body 40 is increased in order to increase the generated force, the axial displacement amount of the actuator 50 must be increased. . However, since the active vibration isolator 10 can increase the generated force without changing the axial displacement amount of the vibrating body 40, there is a possibility that the actuator 50 can be downsized. In particular, since the axial size of the actuator 50 can be reduced, the active vibration isolator 10 can be made compact in the axial direction accordingly.

  Further, since the vibration exciter 40 is disposed closer to the vibration isolating substrate 15 than the orifice forming member 30 in the direction of the axis O, the pressure receiving area of the exciter 40 is cylindrical without being restricted by the orifice forming member 30. It can be enlarged up to the inner range of the metal fitting 13. The orifice forming member 30 includes a first opening 32 and a second opening 36 that communicate with the orifice 22 and open into the first liquid chamber 20 and the second liquid chamber 21, respectively. While the engaging part 42 of the vibrating body 40 engages with the vertical wall 33 provided on the second fixture 12 side to restrict the circumferential displacement of the vibrating body 40, the axial direction of the vibrating body 40 Allow displacement. Therefore, the vibrating body 40 is displaced in the circumferential direction (rotated about the axis O), the first opening 32 and the vibrating body 40 overlap in the axial direction, and the vibrating body 40 causes liquid flow through the orifice 22 to flow. Can prevent obstruction. Therefore, the generated force can be increased by increasing the pressure receiving area of the vibrating body 40, and the damping effect by the orifice 22 can be suppressed from being impaired by the vibrating body 40.

  Since the vertical wall 33 faces the first liquid chamber 20 side and protrudes from the orifice forming member 30, the vertical wall 33 is a component compared to the case where a portion for regulating the displacement in the circumferential direction of the vibrating body 40 is provided separately. The increase in points can be suppressed. Further, the vertical wall 33 protrudes from the wall portion 31 around the first opening 32 of the orifice forming member 30, while the engaging portion 42 is recessed in the outer edge 41 of the vibrating body 40 while avoiding the vertical wall 33. Since it is provided, the pressure receiving area of the vibrating body 40 can be increased by the outer edge 41 of the vibrating body 40 other than the engaging portion 42. Therefore, the generated force can be increased while suppressing the damping effect by the orifice 22 from being impaired by the vibrating body 40.

  The orifice forming member 30 includes a first stopper portion 38 that restricts the axial displacement of the vibrating body 40. The reinforcing member 43 of the vibrating body 40 includes a stoppered portion 44 that overlaps the first stopper portion 38 in the axial projection. As a result, the axial displacement of the drive shaft 52 can be limited by the interference between the first stopper portion 38 and the stopper portion 44. That is, it is possible to prevent the diaphragm 17 and the like from being damaged when the actuator 50 becomes uncontrollable and runaway, and to prevent the actuator 50 from being damaged when a large amplitude vibration is input.

  Further, the amount of displacement in the axial direction (vibration isolation base 15 side) of the vibration exciter 40 determined by the axial distance between the first stopper portion 38 and the stopper portion 44 is a vertical amount provided in the orifice forming member 30. The wall 33 is set smaller than the axial length T (see FIG. 4). Therefore, it can be prevented that the vibrating body 40 is greatly displaced in the axial direction and the engagement between the engaging portion 42 and the vertical wall 33 is released. As a result, since the first opening 32 can be prevented from being short-circuited to the second liquid chamber 21, it is possible to ensure the vibration isolation performance by the orifice 22 that communicates the first liquid chamber 20 and the second liquid chamber 21.

  The displacement of the vibration body 40 toward the vibration isolation base 15 in the direction of the axis O is regulated by the first stopper portion 38, but the displacement of the vibration body 40 toward the diaphragm 17 side is limited by the vibration body 40. It is regulated by the radially outer portion coming into contact with the orifice forming member 30. Therefore, the displacement of the vibrating body 40 on both sides in the axial direction is restricted.

  Next, a second embodiment will be described with reference to FIG. 2nd Embodiment demonstrates the case where the outer diameter of the reinforcement member 143 is small compared with the reinforcement member 43 demonstrated in 1st Embodiment. In addition, about the part same as 1st Embodiment, the same code | symbol is attached | subjected and the following description is abbreviate | omitted. FIG. 7 is a sectional view in the axial direction of the active vibration isolator 110 according to the second embodiment.

  In the active vibration isolator 110, a reinforcing member 143 coupled to the vibrating body 40 is disposed on the radially inner side of the orifice molding member 130. The orifice forming member 130 includes a first stopper portion 138 that is connected to the inner periphery of the wall portion 31 (see FIG. 6). The first stopper portion 138 protrudes in a bowl shape from the wall portion 31 toward the inside in the radial direction.

  The reinforcing member 143 is a member formed in a columnar shape, and is provided with a hook-like stoppered portion 144 that protrudes radially outward from an axial end located on the diaphragm 17 side. The reinforcing member 143 is fixed to the vibrating body 40 with a screw 45. The stopper portion 144 has a size in which at least a portion thereof overlaps the first stopper portion 138 in the axial projection in a state where the orifice forming member 130, the vibrating body 40, and the reinforcing member 143 are disposed inside the cylindrical fitting 13. Is set. Accordingly, the vibrating body 40 and the reinforcing member 143 can move in the axial direction until the first stopper portion 138 and the stopper target portion 144 interfere with each other, and the first stopper portion 138 and the stopper target portion 144 are moved. When the interference occurs, the movement in the axial direction is restricted.

  According to the active vibration isolator 110, by appropriately setting the size and material of the reinforcing member 143, the movable member (vibrator 40, reinforcing member 143, and drive shaft 52) that is movable in the axial direction by the actuator 50 is used. The mass can be set as appropriate. Moreover, the material cost which comprises the reinforcement member 143 can be reduced by making the reinforcement member 143 small and reducing a volume.

  Here, when the coil 62 of the actuator 50 is in a demagnetized state, when the load is input to the first fixture 11 and the vibration isolation base 15 is elastically deformed to increase the internal pressure of the first liquid chamber 20, the vibration exciter 40 is It is pushed (lowered) to the actuator 50 side. A spring constant that is a ratio of a thrust generated in the vibrating body 40 due to an increase in the internal pressure of the first liquid chamber 20 (force pushed out from the first liquid chamber 20) and a displacement amount of the vibrating body 40 generated by the thrust, and a movable The natural frequency of the movable member is determined by the mass of the members (vibrator 40, reinforcing member 143, and drive shaft 52). This spring constant is mainly determined by the leaf spring 56, but can be adjusted by bringing the vibrating body 40 into contact (interference) with the rubber film 16 and the vertical wall 33. Since the mass of the movable member can be adjusted by changing the mass of the reinforcing member 143, the natural frequency can be adjusted relatively easily.

  By setting this natural frequency within the frequency band of vibrations that drive the actuator 40 to exhibit the vibration isolation function, the actuator 50 can give the drive shaft 52 vibration substantially equal to the natural frequency. As a result, even if the output of the actuator 50 is small, strong vibration can be generated in the vibrating body 40 by resonance. Since the actuator 50 with a small output can be employed, the actuator 50 can be reduced in size (especially reduced in height). Further, since the vibrating body 40 can be easily vibrated, the current flowing through the coil 62 can be reduced. Therefore, the power consumption of the actuator 50 can be reduced.

  Next, a third embodiment will be described with reference to FIG. In the first and second embodiments, the interference between the stopper portions 44 and 144 provided on the reinforcing members 43 and 143 and the first stopper portions 38 and 138 provided on the orifice forming members 30 and 130 is prevented. The case where the displacement of the vibrating body 40 toward the vibrating base 15 is described has been described. On the other hand, in the third embodiment, a case will be described in which the displacement of the vibration exciter 40 toward the vibration isolator base 15 is restricted by the interference between the vibration exciter 40 and the vibration isolator base 15. In addition, about the part same as 1st and 2nd embodiment, the same code | symbol is attached | subjected and the following description is abbreviate | omitted. FIG. 8 is a sectional view in the axial direction of the active vibration isolator 210 according to the third embodiment.

  In the active vibration isolator 210, a reinforcing member 243 coupled to the vibrating body 40 is disposed on the radially inner side of the orifice molding member 130. The reinforcing member 243 is a member formed in a columnar shape, and is fixed to the vibrating body 40 with a screw 45.

  In the active vibration isolator 210, the displacement of the vibration body 40 toward the diaphragm 17 in the direction of the axis O is restricted by the vibration body 40 coming into contact with the orifice forming member 130. On the other hand, the displacement of the vibration exciter 40 toward the vibration isolator base 15 is caused by the vibration exciter 40 at the boundary between the vibration isolator base 15 and the rubber film 16 (the portion of the inclined surface where the inner diameter is smaller than the rubber film 16). It is regulated by the contact of the radially outer part.

  Note that the axial position of the boundary portion between the vibration isolating base 15 and the rubber film 16 is set in consideration of the axial length L of the vertical wall 33 (see FIG. 4). The engaging portion 42 (see FIG. 6) is detached from the vertical wall 33 before the boundary portion between the vibration isolating base 15 and the rubber film 16 functions as a stopper due to the displacement of the vibrating body 40 toward the vibration isolating base 15. This is to prevent this.

  Next, a fourth embodiment will be described with reference to FIG. In the third embodiment, the description has been given of the case where the boundary portion between the vibration isolating base 15 and the rubber film 16 is used as a stopper for restricting axial displacement. On the other hand, in the fourth embodiment, a case where the stopper function by the anti-vibration base 315 is strengthened will be described. In addition, about the part same as 1st Embodiment to 3rd Embodiment, the same code | symbol is attached | subjected and the following description is abbreviate | omitted. FIG. 9 is an axial sectional view of an active vibration isolator 310 according to the fourth embodiment.

  In the active vibration isolator 310, a vibration isolating base 315 made of a rubber-like elastic body connects the first fixture 11 and the second fixture 12. The anti-vibration base 315 has a second stopper portion 316 formed at the base of the rubber film 16. The second stopper portion 316 is a flat surface orthogonal to the axis O and is formed in an annular shape when viewed in the direction of the axis O.

  In the active vibration isolator 310, the displacement of the vibration body 40 toward the diaphragm 17 in the direction of the axis O is restricted by the vibration body 40 coming into contact with the orifice forming member 130. On the other hand, the displacement of the vibration exciter 40 toward the vibration isolator base 315 is restricted by the radially outer portion of the vibration exciter 40 coming into contact with the second stopper portion 316. The axial position of the second stopper portion 316 is set in consideration of the axial length L of the vertical wall 33 (see FIG. 4). This is to prevent the engaging portion 42 (see FIG. 6) from being detached from the vertical wall 33 before the second stopper portion 316 functions as a stopper due to the displacement of the vibrating body 40 toward the vibration isolation base 315 side. is there.

  According to the active vibration isolator 310, the second stopper portion 316 (a flat surface orthogonal to the axis O) is formed on the vibration isolator base 315, so that the active surface using the inclined surface of the vibration isolator base 15 as a stopper is used. Compared to the mold vibration isolator 210 (third embodiment), the pressure receiving area (the contact area between the vibration exciter 40 and the vibration isolator base 315) when the stopper functions can be increased. As a result, compared to the active vibration isolator 210 in the third embodiment, the displacement of the vibrating body 40 after the stopper functions can be reduced, for example, when a large amplitude vibration is input. Therefore, the engaging portion 42 (see FIG. 6) can be more easily separated from the vertical wall 33.

  Next, a fifth embodiment will be described with reference to FIG. In the third and fourth embodiments, the case where the first stopper portion 138 is provided in the orifice forming member 130 has been described. On the other hand, in the fifth embodiment, an active vibration isolator 410 in which the orifice forming member 230 in which the first stopper portion 138 is omitted will be described. In addition, about the part same as 1st Embodiment to 3rd Embodiment, the same code | symbol is attached | subjected and the following description is abbreviate | omitted. FIG. 10 is an axial sectional view of an active vibration isolator 410 according to the fifth embodiment.

  In the active vibration isolator 410, a reinforcing member 243 coupled to the vibrating body 40 is disposed on the radially inner side of the orifice molding member 230. The orifice molding member 230 has the same configuration as the orifice forming members 30 and 130 except that the first stopper portions 38 and 138 are omitted.

  In the active vibration isolator 410, the displacement of the vibration body 40 toward the diaphragm 17 in the direction of the axis O is restricted by the vibration body 40 coming into contact with the orifice forming member 230 (wall portion 31). On the other hand, the displacement of the vibration exciter 40 toward the vibration isolator base 15 is caused by the vibration exciter 40 at the boundary between the vibration isolator base 15 and the rubber film 16 (the portion of the inclined surface where the inner diameter is smaller than the rubber film 16). It is regulated by the contact of the radially outer part.

  According to the active vibration isolator 410, the first stopper portion 138 is omitted from the orifice forming member 230. Therefore, when the vibrating body 40 is displaced toward the diaphragm 17, the first stopper portion 138 and the vibrating body are excited. The reaction force generated in the vibrating body 40 due to the liquid interposed between them can be suppressed. Due to the reaction force, it is possible to suppress the occurrence of a phase delay in the excitation (vibration) of the vibrating body 40 or an increase in the amount of current flowing through the coil 62. Therefore, it is possible to secure a vibration isolation effect due to the vibration of the vibrating body 40 and suppress an increase in power consumption.

  The present invention has been described above based on the embodiments. However, the present invention is not limited to the above embodiments, and various improvements and modifications can be made without departing from the spirit of the present invention. It can be easily guessed. For example, the shape and size of the vertical wall 33 and the engaging portion 42 are not limited to this embodiment, and various changes can be made.

  In each of the above-described embodiments, the case where the vibration exciter 40 is disposed on the vibration isolation bases 15 and 315 side of the orifice forming member 30 in the direction of the axis O has been described. Of course, it is possible to arrange the vibrating body 40 closer to the diaphragm 17 than the member 30. Also in this case, since the outer diameter of the vibrating body 40 can be made larger than the inner diameter of the body portion 34 of the orifice forming member 30, the pressure receiving area of the vibrating body 40 can be increased and the generated force can be increased. In this case, in order to separate the first liquid chamber 20 and the second opening 36, the wall 35 is provided with a vertical wall 33 that protrudes toward the second liquid chamber 21 so as to surround the second opening 36.

  In each of the above-described embodiments, the case where the active vibration isolator 10, 110, 210, 310, 410 is used as an engine mount that elastically supports an automobile engine has been described. However, the present invention is not necessarily limited thereto. It is naturally possible to apply the active vibration isolator 10, 110, 210, 310, 410 to a vibration isolator that suppresses vibration of an arbitrary vibrating body such as a body mount or a differential mount.

  Although the description is omitted in the above embodiment, when the stopper functions, the first stopper portion 38, so that the buffer material is interposed between the first stopper portions 38, 138 and the stopper portions 44, 144. Needless to say, it is possible to provide a cushioning material such as rubber on 138 or the stopper portions 44 and 144. Thereby, generation | occurrence | production of unusual noise can be suppressed.

  In each of the above-described embodiments, the diaphragm 17 is disposed below the vibration isolation base 15, so that the active vibration isolation devices 10, 110, 210, and the second liquid chamber 21 are provided below the first liquid chamber 20. Although 310 and 410 have been described, the present invention is not necessarily limited to this, and the vibration isolation base 15 and the diaphragm 17 can be arranged at arbitrary positions. For example, it is naturally possible to dispose a diaphragm above the vibration isolation base 15 and provide the second liquid chamber above the first liquid chamber. In this case, an orifice for connecting the first liquid chamber and the second liquid chamber is formed on the outer periphery of the vibration isolating substrate 15.

  In each of the above embodiments, the case where the actuator 50 is energized with an alternating current (such as a sine wave signal or a rectangular wave signal) to excite the coil 62 and the drive shaft 52 elastically supported by the leaf spring 56 is reciprocated is described. However, it is not necessarily limited to this. In the case of an actuator in which the drive shaft is urged to one side in the direction of the axis O by the coil spring, the coil is excited when the coil is intermittently energized and deenergized by intermittently supplying a direct current to the coil. Thus, the coil spring can be compressed to displace the drive shaft, and the drive shaft can be displaced by the restoring force of the coil spring by demagnetizing the coil. Even in an active vibration isolator employing such an actuator, the same actions and effects as in the present embodiment can be realized.

10, 110, 210, 310, 410 Active vibration isolator 11 First fixture 12 Second fixture 15, 315 Anti-vibration base 17 Diaphragm 19 Liquid chamber 20 First liquid chamber 21 Second liquid chamber 22 Orifice 30, 130 , 230 Orifice forming member 31 Wall (first stopper)
32 1st opening part 33 Vertical wall 36 2nd opening part 38,138 1st stopper part 40 Exciting body (stopped part)
42 Engagement part 44,144 Stopped part 50 Actuator 52 Drive shaft 316 Second stopper part

Claims (4)

A first fixture and a cylindrical second fixture;
An anti-vibration base composed of a rubber-like elastic body connecting the first fixture and the second fixture;
A rubber-like elastic body disposed at a position facing the vibration isolating base in the axial direction of the second fixture, and at least a diaphragm that forms a liquid chamber with the vibration isolating base;
A vibration body that is disposed in the liquid chamber and divides the liquid chamber into a first liquid chamber on the vibration-proof base side and a second liquid chamber on the diaphragm side in the axial direction of the second fixture;
An actuator that is disposed on the opposite side of the first liquid chamber across the vibration body in the axial direction of the second fixture, and that vibrates the vibration body in the axial direction by a drive shaft ;
An annular orifice forming member that is disposed closer to the diaphragm than the vibrating body in the axial direction of the second fixture, and that forms an orifice that communicates the second liquid chamber and the first liquid chamber. ,
The orifice forming member includes a first opening and a second opening that communicate with the first liquid chamber and the second liquid chamber, respectively, to form the orifice;
A vertical wall facing the first liquid chamber side and projecting around the first opening,
The active vibration isolator is characterized in that the vibrator is entirely displaced in the axial direction by vibration by the actuator to change the axial lengths of the first liquid chamber and the second liquid chamber. . The vibrator is provided with an engaging portion that engages with a side surface of the vertical wall to restrict circumferential displacement of the vibrator and allows axial displacement of the vibrator. The active vibration isolator according to claim 1 . The orifice forming member includes a first stopper portion that regulates axial displacement of the vibrating body and maintains the engagement between the vertical wall and the engaging portion,
The active vibration isolator according to claim 2 , wherein the vibrating body includes a stopper portion that overlaps the first stopper portion in the axial projection. The vibration-proof base includes a second stopper portion that restricts the axial displacement of the vibrating body and maintains the engagement between the vertical wall and the engagement portion.
The active vibration isolator according to claim 2 or 3 , wherein the vibration exciter includes a stopper portion that overlaps the second stopper portion in an axial projection.

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