CA1235157A - Vibration damper - Google Patents
Vibration damperInfo
- Publication number
- CA1235157A CA1235157A CA000449386A CA449386A CA1235157A CA 1235157 A CA1235157 A CA 1235157A CA 000449386 A CA000449386 A CA 000449386A CA 449386 A CA449386 A CA 449386A CA 1235157 A CA1235157 A CA 1235157A
- Authority
- CA
- Canada
- Prior art keywords
- passage
- damper
- piston
- damping
- passages
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired
Links
Abstract
Title: "A VIBRATION DAMPER"
ABSTRACT
A vibration damper (10, 60) has a body (12,61) with a cylinder (13, 65) divided into two variable volume chambers (24, 25; 75, 76) by a piston (23, 72) with an externally extending piston rod (22, 70), fluid passages (27, 28; 77, 78) interconnect the chambers (24, 25; 75,76) and each passage has a one-way valve (33, 36; 81, 82) to provide unidirectional flow of the damping fluid through the passages. A control valve (39, 40; 83, 84) is provided for each passage to control the rate of oil flow through the passages and thereby the rate of damping of the piston (23,72) in each direction. Where the piston rod (22) is provided in only one of the chambers (24), relief valves (48, 50) enable flow between the passages (27, 28) and the interior (14) of the body (13) to compensate for the volume in the chamber (24) occupied by the piston rod (22).
ABSTRACT
A vibration damper (10, 60) has a body (12,61) with a cylinder (13, 65) divided into two variable volume chambers (24, 25; 75, 76) by a piston (23, 72) with an externally extending piston rod (22, 70), fluid passages (27, 28; 77, 78) interconnect the chambers (24, 25; 75,76) and each passage has a one-way valve (33, 36; 81, 82) to provide unidirectional flow of the damping fluid through the passages. A control valve (39, 40; 83, 84) is provided for each passage to control the rate of oil flow through the passages and thereby the rate of damping of the piston (23,72) in each direction. Where the piston rod (22) is provided in only one of the chambers (24), relief valves (48, 50) enable flow between the passages (27, 28) and the interior (14) of the body (13) to compensate for the volume in the chamber (24) occupied by the piston rod (22).
Description
~235157 This invention relates to a vibration damper adapted to control the vibration between two members.
The invention is particularly suitable as, but not limited to, a vibration damper for vehicle seats or the like.
The vibrations transmitted to a vehicle opera-ion via his seat are a major contributor to operator fatigue. This is particularly so in long distance trays-port vehicles) farm and earth moving machinery, and power boats.
To combat this problem, such vehicles are now generally fitted with sprung seats, the seats having adjustable dampers to damp the vibrations. While these seats are an improvement, they are not totally satisfac-tory as the dampers cannot be "tuned" or accurately set to suit their particular applications and they generally require an external reservoir for the oil employed as the damping fluid or medium.
It is an object of the present invention to provide a vibration damper which does not require an external oil reservoir.
It is a preferred object to provide a damper where the degree of damping in both directions can be independently controlled.
It is a further preferred object to provide a damper which can be readily adjusted by means of external controls.
It is a still further preferred object to pro-vise a damper which can be easily assembled and main-twined.
According to the invention there is provided a vibration damper including a damper body formed of a first and second similar parts clamped together in a face to face relationship to define a bore of which opposite end halves are defined by the two parts; a closed Solon-don formed in the bore of said damper body by sealing means disposed axially within the bore at opposed ends B
~23~57 of the bore within said first and second parts; a piston rod passing axially through said sealing means and said closed cylinder; a piston means, supported on said pus-ton rod and movable therewith in said cylinder, said piston means being sealingly engaged against the wall of said closed cylinder to divide said closed cylinder into two variable volume chambers; a damping fluid filling said chambers; passageways defined in said body parts to form a pair of fluid passages interconnecting the two chambers and respective one way valve means within each of said pair of fluid passages to provide unidirectional flow, in opposite directions, of the damping fluid through the passages; and independently controllable valve means in each passage to control the flow of the damping fluid lo through the passages and thereby control the damping of the piston means in each direction, said independently controllable valve means each comprising a metering plug within its respective passage on a rotatable shaft which passes through the damper body transversely of its rest pective passage.
The body may be mounted on a fixed frame or support and the piston rod connected to a movable member, or vice versa, or the body and piston rod may be connected to a pair of relatively movable members.
Further features of the invention will be apparent from the following description with reference to the accompanying drawings, in which:
FIG. 1 is a front view of a vibration of the damper, parts being broken away for clarity;
FIG. 2 is a sectional plan view taken on line
The invention is particularly suitable as, but not limited to, a vibration damper for vehicle seats or the like.
The vibrations transmitted to a vehicle opera-ion via his seat are a major contributor to operator fatigue. This is particularly so in long distance trays-port vehicles) farm and earth moving machinery, and power boats.
To combat this problem, such vehicles are now generally fitted with sprung seats, the seats having adjustable dampers to damp the vibrations. While these seats are an improvement, they are not totally satisfac-tory as the dampers cannot be "tuned" or accurately set to suit their particular applications and they generally require an external reservoir for the oil employed as the damping fluid or medium.
It is an object of the present invention to provide a vibration damper which does not require an external oil reservoir.
It is a preferred object to provide a damper where the degree of damping in both directions can be independently controlled.
It is a further preferred object to provide a damper which can be readily adjusted by means of external controls.
It is a still further preferred object to pro-vise a damper which can be easily assembled and main-twined.
According to the invention there is provided a vibration damper including a damper body formed of a first and second similar parts clamped together in a face to face relationship to define a bore of which opposite end halves are defined by the two parts; a closed Solon-don formed in the bore of said damper body by sealing means disposed axially within the bore at opposed ends B
~23~57 of the bore within said first and second parts; a piston rod passing axially through said sealing means and said closed cylinder; a piston means, supported on said pus-ton rod and movable therewith in said cylinder, said piston means being sealingly engaged against the wall of said closed cylinder to divide said closed cylinder into two variable volume chambers; a damping fluid filling said chambers; passageways defined in said body parts to form a pair of fluid passages interconnecting the two chambers and respective one way valve means within each of said pair of fluid passages to provide unidirectional flow, in opposite directions, of the damping fluid through the passages; and independently controllable valve means in each passage to control the flow of the damping fluid lo through the passages and thereby control the damping of the piston means in each direction, said independently controllable valve means each comprising a metering plug within its respective passage on a rotatable shaft which passes through the damper body transversely of its rest pective passage.
The body may be mounted on a fixed frame or support and the piston rod connected to a movable member, or vice versa, or the body and piston rod may be connected to a pair of relatively movable members.
Further features of the invention will be apparent from the following description with reference to the accompanying drawings, in which:
FIG. 1 is a front view of a vibration of the damper, parts being broken away for clarity;
FIG. 2 is a sectional plan view taken on line
2-2 in FIG. l;
FIG. 3 is a sectional side view of an embody-mint of vibration damper in accordance with the invention;
and FIG. 4 is a sectional end view of one of the control valves taken on line 4-4 in FIG. 3.
.
By 123~S7 Referring to FIGS. 1 and 2, the damper has a rectangular base plate lo provided with mounting holes 11 adjacent each corner. A circular outer cylinder 12, forming the damper body, is mounted on the base plate lo and welded thereto to close its lower end. A circular inner cylinder 13, of reduced diameter, is similarly mounted on the base plate lo and the annular space 14 formed between the two cylinders forms a reservoir for the oil used as the damping fluid.
lo The upper end of the annular space is closed by an annular plate 15 sealable secured to the upper ...
B
, ~L23~1S7 ends of the two cylinders 12, 13. A cover plate 16, has a central bush 17 and an annular flange 18, is secured to the annular plate 15 by studs 19. A central bore 20 is provided in the bush 17, and fitted with a pair of neoprene seals 21 to sealable engage the piston rod 22 of a piston 23 slid ably movable in the inner cylinder 13, dividing the latter into upper and lower variable volume chambers 24, 25 respectively.
A pair of neoprene piston rings 26 seal the piston 23 to the inner wall of the inner cylinder.
A pair of fluid passages 27, 28 are provided adjacent the inner cylinder 13, being formed by square section tubes closed by the base plate 10 and annular plate 15. Fluid conduits 29, 30 connect the lower chamber 25 to the passages 27, 28 respectively, while conduits 31, 32 connect the upper chamber 24 to the passages.
A one-way valve 33, having a spring loaded ball 34 and valve seat 35, allows the oil to pass from 20 the lower chamber 25, through fluid passage 27, to the upper chamber 24 when the piston 23 moves down the inner cylinder. A similar valve 36, with ball 37 and valve seat 38, allows the oil to flow from the upper chamber 24 to the lower chamber 25 via passage 28, the valves 25 33, 36 preventing flow of the oil in the opposite direct-ion.
The flow of oil through the passages 27, 28 and thereby the damping applied to a body connected to the piston rod 22, is controlled by respective control 30 valves 39, 40.
Referring to the control valve 39, a rectangular hole is formed in the outer side wall of the passage 27 to slid ably (and sealable) receive a valve block 41 which is movable transversely across the passage 27 to 35 vary the effective cross-sectional area of the passage.
235~S7 The block 41 has a central bore which screw thread-ably receives a threaded spindle 42. A seal block 43, with neoprene seals 44, is formed integrally with the spindle 42 and is sealable mounted in the seal housing 45 formed in the outer cylinder 12. The outer end of the spindle is of square cross section and engaged in a complementary hole formed in a control nut 46. By rotating the nut 46, the block 41 moves along the spindle 42 to open and close the passage.
Control valve 40 is similar to the control valve 39, with a valve block 47 selectively varying the effective area of the passage 28.
A bypass valve 48 is connected to the passage 27 via a hole 49 to enable oil under pressure to be bled to the reservoir 14, while an intake valve 50, connected to the passage 28 via a hole 51, allows the oil from the reservoir to enter the passage.
The operation of the damper will now be described.
The base plate 10 is secured to a frame e.g.
a vehicle chassis and the piston rod 22 to a vehicle seat (not shown).
It will be assumed that the piston 23 is in the position shown in FIG. 1. When the piston 23 is forced downwardly (i.e. on its downstroke), the volume of the lower chamber 25 is reduced, oil flows out of conduit 29 into the passage 27 (the flow into passage 28 being prevented by the onepway valve 36). The bypass valve 48 remains closed and the oil flows through the restriction in the passage formed by the valve block 41, through the one-way valve 33 and conduit 31 to the upper chamber 24.
The piston rod 22 effectively reduces the volume of the upper chamber 24 and so the decrease in the volume of the lower chamber 25 is not matched by ~2~;15 the increase in volume of the upper chamber 24.
The pressure of the oil in the passage 27 increases, it unseats the bypass valve 48 and oil flows through the hole I to the reservoir 14.
On the upstroke of the piston, valves 33 and 48 are closed but one-way valve 36 is opened to allow oil to flow from the upper chamber 24 to the lower chamber 25 via the passage 28, the rate of flow (or degree of clamping) being controlled by the restriction in the passage formed by the valve block 47.
As the increase in the volume of the lower chamber 25 it greater than the decrease of the upper chamber 24, the intake valve 49 opens to allow fluid to enter the passage 28 from the reservoir 14.
As the flow of oil between the chambers follows different paths on the up - and down strokes, the adjustment of the control valves 39, 40 allows the damping on each stroke to be independently controlled, and the degree of damping on each stroke can be from 0% - 100%. The bypass valve 48 and intake valve 49 allows the oil to flow between the reservoir and the inner cylinder, maintaining both chambers full of oil.
In a modified form of this embodiment (not shown), the valve blocks 41, 47 are rotatable, but non-axially, movable on the spindles and the nuts 46 of the control valves 39, 40 are screwthreadably mount-Ed on the seal housing 45. As the nuts 46 are rotated, they move inwardly or outwardly relative to the outer cylinder, respectively, closing or opening the passages 27, 28.
While circular cylinders 12, 13 have been shown in the drawings, these may be substantially square in plan, if preferred. In addition, the passe-goes 27, 28 may be spaced from inner cylinder 13 and connected thereto by short tubes forming the conduits ., 29-32.
The removable cover plate 16 enables the piston 23 to be withdrawn and the damper serviced.
However, the cover plate 16 and annular plate 15 may 5 be made in one piece and the damper sealed for life, the oil acting as a lubricant.
Turning now to the second embodiment of FIGS.
FIG. 3 is a sectional side view of an embody-mint of vibration damper in accordance with the invention;
and FIG. 4 is a sectional end view of one of the control valves taken on line 4-4 in FIG. 3.
.
By 123~S7 Referring to FIGS. 1 and 2, the damper has a rectangular base plate lo provided with mounting holes 11 adjacent each corner. A circular outer cylinder 12, forming the damper body, is mounted on the base plate lo and welded thereto to close its lower end. A circular inner cylinder 13, of reduced diameter, is similarly mounted on the base plate lo and the annular space 14 formed between the two cylinders forms a reservoir for the oil used as the damping fluid.
lo The upper end of the annular space is closed by an annular plate 15 sealable secured to the upper ...
B
, ~L23~1S7 ends of the two cylinders 12, 13. A cover plate 16, has a central bush 17 and an annular flange 18, is secured to the annular plate 15 by studs 19. A central bore 20 is provided in the bush 17, and fitted with a pair of neoprene seals 21 to sealable engage the piston rod 22 of a piston 23 slid ably movable in the inner cylinder 13, dividing the latter into upper and lower variable volume chambers 24, 25 respectively.
A pair of neoprene piston rings 26 seal the piston 23 to the inner wall of the inner cylinder.
A pair of fluid passages 27, 28 are provided adjacent the inner cylinder 13, being formed by square section tubes closed by the base plate 10 and annular plate 15. Fluid conduits 29, 30 connect the lower chamber 25 to the passages 27, 28 respectively, while conduits 31, 32 connect the upper chamber 24 to the passages.
A one-way valve 33, having a spring loaded ball 34 and valve seat 35, allows the oil to pass from 20 the lower chamber 25, through fluid passage 27, to the upper chamber 24 when the piston 23 moves down the inner cylinder. A similar valve 36, with ball 37 and valve seat 38, allows the oil to flow from the upper chamber 24 to the lower chamber 25 via passage 28, the valves 25 33, 36 preventing flow of the oil in the opposite direct-ion.
The flow of oil through the passages 27, 28 and thereby the damping applied to a body connected to the piston rod 22, is controlled by respective control 30 valves 39, 40.
Referring to the control valve 39, a rectangular hole is formed in the outer side wall of the passage 27 to slid ably (and sealable) receive a valve block 41 which is movable transversely across the passage 27 to 35 vary the effective cross-sectional area of the passage.
235~S7 The block 41 has a central bore which screw thread-ably receives a threaded spindle 42. A seal block 43, with neoprene seals 44, is formed integrally with the spindle 42 and is sealable mounted in the seal housing 45 formed in the outer cylinder 12. The outer end of the spindle is of square cross section and engaged in a complementary hole formed in a control nut 46. By rotating the nut 46, the block 41 moves along the spindle 42 to open and close the passage.
Control valve 40 is similar to the control valve 39, with a valve block 47 selectively varying the effective area of the passage 28.
A bypass valve 48 is connected to the passage 27 via a hole 49 to enable oil under pressure to be bled to the reservoir 14, while an intake valve 50, connected to the passage 28 via a hole 51, allows the oil from the reservoir to enter the passage.
The operation of the damper will now be described.
The base plate 10 is secured to a frame e.g.
a vehicle chassis and the piston rod 22 to a vehicle seat (not shown).
It will be assumed that the piston 23 is in the position shown in FIG. 1. When the piston 23 is forced downwardly (i.e. on its downstroke), the volume of the lower chamber 25 is reduced, oil flows out of conduit 29 into the passage 27 (the flow into passage 28 being prevented by the onepway valve 36). The bypass valve 48 remains closed and the oil flows through the restriction in the passage formed by the valve block 41, through the one-way valve 33 and conduit 31 to the upper chamber 24.
The piston rod 22 effectively reduces the volume of the upper chamber 24 and so the decrease in the volume of the lower chamber 25 is not matched by ~2~;15 the increase in volume of the upper chamber 24.
The pressure of the oil in the passage 27 increases, it unseats the bypass valve 48 and oil flows through the hole I to the reservoir 14.
On the upstroke of the piston, valves 33 and 48 are closed but one-way valve 36 is opened to allow oil to flow from the upper chamber 24 to the lower chamber 25 via the passage 28, the rate of flow (or degree of clamping) being controlled by the restriction in the passage formed by the valve block 47.
As the increase in the volume of the lower chamber 25 it greater than the decrease of the upper chamber 24, the intake valve 49 opens to allow fluid to enter the passage 28 from the reservoir 14.
As the flow of oil between the chambers follows different paths on the up - and down strokes, the adjustment of the control valves 39, 40 allows the damping on each stroke to be independently controlled, and the degree of damping on each stroke can be from 0% - 100%. The bypass valve 48 and intake valve 49 allows the oil to flow between the reservoir and the inner cylinder, maintaining both chambers full of oil.
In a modified form of this embodiment (not shown), the valve blocks 41, 47 are rotatable, but non-axially, movable on the spindles and the nuts 46 of the control valves 39, 40 are screwthreadably mount-Ed on the seal housing 45. As the nuts 46 are rotated, they move inwardly or outwardly relative to the outer cylinder, respectively, closing or opening the passages 27, 28.
While circular cylinders 12, 13 have been shown in the drawings, these may be substantially square in plan, if preferred. In addition, the passe-goes 27, 28 may be spaced from inner cylinder 13 and connected thereto by short tubes forming the conduits ., 29-32.
The removable cover plate 16 enables the piston 23 to be withdrawn and the damper serviced.
However, the cover plate 16 and annular plate 15 may 5 be made in one piece and the damper sealed for life, the oil acting as a lubricant.
Turning now to the second embodiment of FIGS.
3 and 4, the damper 60 has damper body 61 formed by two body halves 62, 63 secured together by bolts 64 which pass through the length of the body.
A central cylinder 65 is formed in the body 61 and is closed at each end by a respective stainless steel insert 66. Each insert has a peripheral flange 67 located in a recess at the respective ends of the 15 cylinder.
A bronze bearing or bush 68 is fitted in each insert 66 and aligned co-axial bores 69 are provided through the pairs of inserts 66 and bearings 68.
A piston rod 70 is slid ably journal led in the 20 bronze bearings 68 and extends from each end of the body. A series of neoprene o-rings 71 are provided in the bearings 68 to provide a fluid-tight seal between the rod 70 and the bearings 68.
A piston 72 is provided in the cylinder 65 and 25 has its hub 73 fixed to the piston rod 70. A piston ring 74 around the periphery of the piston seals the piston to the inner wall of the cylinder 65. As shown, the piston 72 divides the cylinder 65 into two variable volume chambers 75, 76.
: 30 A pair of passages 77, 78 in the body 61 interconnect the chambers 75, 76. Referring to passage 77, a ball 79 co-operates with a valve seat 80 to provide a one-way valve 81, the ball 79 being seated on the valve seat 80 when the oil seeks to flow from the chanter 76 to chamber 75 but being unseated lZ35~57 to allow unrestricted flow from chamber 75 to chamber 76. A similar one-way valve 82 is provide Ed in passage 78 to limit the flow of the oil in the direction of chamber 76 to chamber 75.
The flow of oil through the passages, and thereby the damping of a body or member connected to the piston rod 70, is controlled by respective control valves 83, 84. Referring to control valve 83, this has a shaft 85 rotatable journal led in the body 61 and sealed thereto by an o-ring 86. A square head 87 on the outer end of the shaft 85 is adapted to receive an operating handle or lever (not shown).
Referring to FIG. 4, the shaft 85 has a reduced diameter portion, aligned with the passage 15 77, forming an eccentric metering plug 88. By rotate in the shaft 85, the plug 88 selectively opens and closes the adjacent ports 89, 90 of the passage 77 to control the flow of oil through the passage.
In FIG. 4, the plug 88 is shown intermediate its closed and open positions and so the degree of damping would be approximately 50% ( the shaft 83 being rotatable through approximately button its opened and closed positions).
A small clearance 91 is provided to ensure 25 that some flow of oil is always possible through the passage 77 to prevent the travel of the piston 72.
The operation of the damper will now be described.
The body 61 may be mounted e.g. on a seat frame and one end of the piston rod 70 connected to one of the legs of a spring-loaded, scissor-type support frame.
As the piston rod 70 moves the piston 72 to reduce the volume of oil in chamber 75, the flow of oil through passage 78 is prevented by the one-way lZ35157 valve 82 and so the oil can only flow to the chamber 76 via passage 77. The ball 79 of the one-way valve 81 is unseated and the oil flows through the control valve 83 at a rate determined by the position of the plug 88 relative to the ports 89 or 90. When the piston 72 is moved in the opposite direction, the oil is transferred between the chambers 76 and 75 at a rate controlled by the control valve 84.
While the control valves 83, 84 are shown on opposite sides of the body 61, it is preferred that they are provided on the same side with their control handles or levers adjacent each other.
In a modified form of this embodiment (not shown) only one fluid passage may be provided where the intermediate portion of the passage is separated into two parallel branches, each having a one-way valve and control valve to provide controlled unidirectional flow in each branch.
It will be readily apparent to the skilled addressee that various other types of control or metering valves may be employed to control the degree of damping and one example is a needle valve.
The damper can be used in a wide range of applications where the vibration of a body relative to a datum, or between a pair of relatively movable bodies, is required to be damped.
Various changes and modifications may be made to the embodiments described without departing from the scope of the appended claims.
Jo `
A central cylinder 65 is formed in the body 61 and is closed at each end by a respective stainless steel insert 66. Each insert has a peripheral flange 67 located in a recess at the respective ends of the 15 cylinder.
A bronze bearing or bush 68 is fitted in each insert 66 and aligned co-axial bores 69 are provided through the pairs of inserts 66 and bearings 68.
A piston rod 70 is slid ably journal led in the 20 bronze bearings 68 and extends from each end of the body. A series of neoprene o-rings 71 are provided in the bearings 68 to provide a fluid-tight seal between the rod 70 and the bearings 68.
A piston 72 is provided in the cylinder 65 and 25 has its hub 73 fixed to the piston rod 70. A piston ring 74 around the periphery of the piston seals the piston to the inner wall of the cylinder 65. As shown, the piston 72 divides the cylinder 65 into two variable volume chambers 75, 76.
: 30 A pair of passages 77, 78 in the body 61 interconnect the chambers 75, 76. Referring to passage 77, a ball 79 co-operates with a valve seat 80 to provide a one-way valve 81, the ball 79 being seated on the valve seat 80 when the oil seeks to flow from the chanter 76 to chamber 75 but being unseated lZ35~57 to allow unrestricted flow from chamber 75 to chamber 76. A similar one-way valve 82 is provide Ed in passage 78 to limit the flow of the oil in the direction of chamber 76 to chamber 75.
The flow of oil through the passages, and thereby the damping of a body or member connected to the piston rod 70, is controlled by respective control valves 83, 84. Referring to control valve 83, this has a shaft 85 rotatable journal led in the body 61 and sealed thereto by an o-ring 86. A square head 87 on the outer end of the shaft 85 is adapted to receive an operating handle or lever (not shown).
Referring to FIG. 4, the shaft 85 has a reduced diameter portion, aligned with the passage 15 77, forming an eccentric metering plug 88. By rotate in the shaft 85, the plug 88 selectively opens and closes the adjacent ports 89, 90 of the passage 77 to control the flow of oil through the passage.
In FIG. 4, the plug 88 is shown intermediate its closed and open positions and so the degree of damping would be approximately 50% ( the shaft 83 being rotatable through approximately button its opened and closed positions).
A small clearance 91 is provided to ensure 25 that some flow of oil is always possible through the passage 77 to prevent the travel of the piston 72.
The operation of the damper will now be described.
The body 61 may be mounted e.g. on a seat frame and one end of the piston rod 70 connected to one of the legs of a spring-loaded, scissor-type support frame.
As the piston rod 70 moves the piston 72 to reduce the volume of oil in chamber 75, the flow of oil through passage 78 is prevented by the one-way lZ35157 valve 82 and so the oil can only flow to the chamber 76 via passage 77. The ball 79 of the one-way valve 81 is unseated and the oil flows through the control valve 83 at a rate determined by the position of the plug 88 relative to the ports 89 or 90. When the piston 72 is moved in the opposite direction, the oil is transferred between the chambers 76 and 75 at a rate controlled by the control valve 84.
While the control valves 83, 84 are shown on opposite sides of the body 61, it is preferred that they are provided on the same side with their control handles or levers adjacent each other.
In a modified form of this embodiment (not shown) only one fluid passage may be provided where the intermediate portion of the passage is separated into two parallel branches, each having a one-way valve and control valve to provide controlled unidirectional flow in each branch.
It will be readily apparent to the skilled addressee that various other types of control or metering valves may be employed to control the degree of damping and one example is a needle valve.
The damper can be used in a wide range of applications where the vibration of a body relative to a datum, or between a pair of relatively movable bodies, is required to be damped.
Various changes and modifications may be made to the embodiments described without departing from the scope of the appended claims.
Jo `
Claims (5)
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:
1. A vibration damper including:
a damper body formed of first and second similar parts clamped together in a face to face relationship to define a bore of which opposite end halves are defined by the two parts;
a closed cylinder formed in the bore of said damper body by sealing means disposed axially within the bore at opposed ends of the bore within said first and second parts;
a piston rod passing axially through said sealing means and said closed cylinder;
a piston means, supported on said piston rod and movable therewith in said cylinder, said piston means being sealingly engaged against the wall of said closed cylin-der to divide said closed cylinder into two variable volume chambers;
a damp?ing fluid filling said chambers;
passageways defined in said body parts to form a pair of fluid passages interconnecting the two chambers and res-pective one way valve means within each of said pair of fluid passages to provide unidirectional flow, in oppo-site directions, of the damping fluid through the pas-sages; and independently controllable valve means in each passage to control the flow of the damping fluid through the passages and thereby control the damping of the piston means in each direction, said independently controllable valve means each comprising a metering plug within its respec-tive passage on a rotatable shaft which passes through the damper body transversely of its respective passage.
a damper body formed of first and second similar parts clamped together in a face to face relationship to define a bore of which opposite end halves are defined by the two parts;
a closed cylinder formed in the bore of said damper body by sealing means disposed axially within the bore at opposed ends of the bore within said first and second parts;
a piston rod passing axially through said sealing means and said closed cylinder;
a piston means, supported on said piston rod and movable therewith in said cylinder, said piston means being sealingly engaged against the wall of said closed cylin-der to divide said closed cylinder into two variable volume chambers;
a damp?ing fluid filling said chambers;
passageways defined in said body parts to form a pair of fluid passages interconnecting the two chambers and res-pective one way valve means within each of said pair of fluid passages to provide unidirectional flow, in oppo-site directions, of the damping fluid through the pas-sages; and independently controllable valve means in each passage to control the flow of the damping fluid through the passages and thereby control the damping of the piston means in each direction, said independently controllable valve means each comprising a metering plug within its respec-tive passage on a rotatable shaft which passes through the damper body transversely of its respective passage.
2. A damper as claimed in Claim 1, wherein each control valve means includes a means external of the body to rotate the shaft, the metering plug being eccentric to the shaft, and so disposed in the passage so that as the shaft is rotated, the effective cross sectional area of the passage past the plug is altered.
3. A damper as claimed in Claim 1, wherein the passage has a pair of ports leading into and out of a chamber containing the metering plug, and the plug is movable to obturate at least one of the ports to provide substanti-ally 100% damping.
4. A damper as claimed in Claim 1, 2 or 3, wherein each body part contains one of said one way valve means and one of said independently controllable valve means, and the passageways defined in each of said body parts are similar.
5. A damper as claimed in Claim 1, 2 or 3, wherein each one way valve means includes:
a valve seat in the passage; and a ball engage able with the valve seat to close the pas-sage, the ball being urged into engagement with the valve seat in the presence of damping fluid at higher pressure upstream of the ball relative to the valve seat.
a valve seat in the passage; and a ball engage able with the valve seat to close the pas-sage, the ball being urged into engagement with the valve seat in the presence of damping fluid at higher pressure upstream of the ball relative to the valve seat.
Applications Claiming Priority (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| PCT/AU1983/000153 WO1984001605A1 (en) | 1982-10-20 | 1983-10-20 | A vibration damper |
| AU83/00153 | 1983-10-20 |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1235157A true CA1235157A (en) | 1988-04-12 |
Family
ID=3761201
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA000449386A Expired CA1235157A (en) | 1983-10-20 | 1984-03-12 | Vibration damper |
Country Status (4)
| Country | Link |
|---|---|
| CA (1) | CA1235157A (en) |
| ES (1) | ES8503584A1 (en) |
| IT (1) | IT1180058B (en) |
| NZ (1) | NZ207460A (en) |
-
1984
- 1984-03-09 NZ NZ207460A patent/NZ207460A/en unknown
- 1984-03-12 CA CA000449386A patent/CA1235157A/en not_active Expired
- 1984-04-13 IT IT67373/84A patent/IT1180058B/en active
- 1984-04-18 ES ES531731A patent/ES8503584A1/en not_active Expired
Also Published As
| Publication number | Publication date |
|---|---|
| IT8467373A1 (en) | 1985-10-13 |
| NZ207460A (en) | 1986-12-05 |
| IT1180058B (en) | 1987-09-23 |
| IT8467373A0 (en) | 1984-04-13 |
| ES531731A0 (en) | 1985-03-01 |
| ES8503584A1 (en) | 1985-03-01 |
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