Title of Invention	"A DUAL CHAMBER AIR SPRING"
Abstract	A dual chamber air spring (5) for use in a vehicle suspension, the air spring having a base piston (13), a fixed-volume chamber (7) and a compressible variable-volume chamber (6) between the base piston (13) and the fixed-volume chamber (7), with a partition (11) separating said variable-volume and fixed-volume chambers (6,7) and having at least one orifice (12) therein opposed to the base piston (13) and providing gas flow communication between the chambers (6,7), a post-like orifice closer (20) being mounted on said base piston (13) in the variable-volume chamber (6) opposite the orifice (12) to co-operate with the orifice (12) when the volume of the variable-volume chamber (6) is reduced during suspension jounce in use, wherein the orifice closer (20) has a pliant portion (22) engageable with the corresponding orifice (12) and a relatively rigid portion (21), disposed such that during jounce the pliant portion (22) initially engages and closes the corresponding orifice (12) to block said gas flow communication between the chambers (6,7), while on further compression of the variable-volume chamber (6) the relatively rigid portion (21) of the orifice closer (20) comes into engagement to resist further jounce movement.

Title of Invention

"A DUAL CHAMBER AIR SPRING"

Abstract

A dual chamber air spring (5) for use in a vehicle suspension, the air spring having a base piston (13), a fixed-volume chamber (7) and a compressible variable-volume chamber (6) between the base piston (13) and the fixed-volume chamber (7), with a partition (11) separating said variable-volume and fixed-volume chambers (6,7) and having at least one orifice (12) therein opposed to the base piston (13) and providing gas flow communication between the chambers (6,7), a post-like orifice closer (20) being mounted on said base piston (13) in the variable-volume chamber (6) opposite the orifice (12) to co-operate with the orifice (12) when the volume of the variable-volume chamber (6) is reduced during suspension jounce in use, wherein the orifice closer (20) has a pliant portion (22) engageable with the corresponding orifice (12) and a relatively rigid portion (21), disposed such that during jounce the pliant portion (22) initially engages and closes the corresponding orifice (12) to block said gas flow communication between the chambers (6,7), while on further compression of the variable-volume chamber (6) the relatively rigid portion (21) of the orifice closer (20) comes into engagement to resist further jounce movement.

Full Text	The present invention relates to a dual chamber air spring. Background of the Invention Air springs are widely used on vehicle suspension systems since they generally result in a lower system spring rate and a lower vehicle natural frequency than other available types of springs. A low spring rate and low natural frequency result in superior isolation of road-induced disturbances and improved contact between the wheels and road surface (in outer words a better ride). Unfortunately, decreasing the spring rate also decreases roll stability and increases suspension travel, both of which can be a negative feature in some applications. A number of methods have been employed to overcome this trade-off. Many suspensions employ a bump-stop to limit axle travel and body roll. However, when the bump-stop is contacted very high loads are transmitted directly into the vehicle frame resulting in undesirable harshness. Other designs have made use of costly valves or control units to vary the spring rate and natural frequency. Brief Summary of the Invention The present invention provides an innovation in air springs when used in suspensions, particularly for heavy duty trucks and trailers. The air springs of the invention have dual volumes, one being a compressible variable chamber and the other being a fixed volume chamber. The interiors of the two chambers are separated by a partition which has an orifice therein providing air or gas flow communication between the chambers. A post-like orifice closer or plug is mounted within the compressible variable volume chamber for closing the orifice during jounce action of the associated suspension. The post-iike closer has a deformable or resilient portion which has a low spring rate and a relatively rigid portion which has a high spring rate. During a jounce of the associated suspension of sufficient severity the deformable portion of the post-like orifice closer engages and closes the orifice thereby isolating the fixed volume chamber from the variable volume chamber. In the event of a sufficiently severe jounce the rigid portion of the post-Jike closer comes into play and arrests further jounce movement. Brief Description of the Drawings For a complete understanding of the nature and scope of the invention and a description of a preferred embodiment reference may now be had to the accompanying drawings wherein: Fig. 1 is a semi-vertical sectional and side elevationai view of a dual chamber air spring forming a presently preferred embodiment of the invention; Fig.2 is a vertical sectional view of the air spring of Fig. 1 in a compressed condition with its post-like orifice closer in contact with and closing the orifice in the partition between the chambers; Fig.3 is a top plan view of the air spring of Fig. 1; Fig.4 is a bottom plan view of the air spring of Fig. 1; and Fig.5 is a perspective view of the post-like orifice closer incorporated in the air spring of Fig. 1. Detailed Description of the Invention Referring to the drawings, in Figs. 1-4 a dual volume air spring is indicated generally at 5 embodying the invention and comprising a compressible variable volume chamber indicated generally at 6 and a fixed volume rigid chamber indicated generally at 7. The interiors 8 and 10, respectively, pf the chambers 6 and 7 are separated by a rigid partition plate 11 provided in the center with an orifice or opening 12. The variable volume chamber 6 has a construction corresponding generally to that of known commercially available air springs for truck and trailer suspensions. It has a generally cylindrical compressible body formed rubber, or rubber-like sheet material 9 the upper end of which is closed by the rigid plate 11 while the lower end is closed by a base 13 usually referred to as the air spring "piston". The rigid upper chamber 7 is also generally cylindrical in shape and formed from sheet metal or other suitable.rigid or non- expandable material. The rigid plate 11 closes die bottom end of the chamber 7 with the periphery of the plate being welded to the interior of the chamber 7 as indicated at 14. The circumferential lip 15 of the air bag 9 is hermetically sealed or crimped between the underside of the rigid plate 11 and the inwardly curled lip 16 of the rigid chamber 7. The lower lip 17 of the air bag 9 is hermetically sealed and secured between the periphery of a washer-like plate 18 and a corresponding dish-like surface of the base 13. Thus, the variable volume compressible chamber 6 is hermetically sealed in accordance with the known construction of commercially available air springs. A post-like orifice closer for the orifice 12 is indicated generally at 20 formed by a frusto-conical base 21 forming a bump stop and formed of a rigid, or semi-rigid material and a compressible plug 22 formed of a pliant material- From Fig.2 it will be seen that when the chamber 6 is in its compressed condition during jounce of the associated suspension the plug or stopper 22 engages the underside of the rigid separator or partition 11 so as to close the orifice 12. The plug 20 has a relatively low spring rate until it is firmly compressed onto the bump stop 21 which has a high spring rate. The plug or stopper portion 22 may be formed of a relatively low durometer rubber or polymethane material of known commercial type . While the bump-stop 21 may be formed of high durometer natural rubber, high durometer polyurethane, Hydril a (DuPont thermoplastic elastomer) or similar materials of known commercial type. The base of the bump stop 21 is provided with a stud 23 which projects through apertures in the washer 18 and the base 13. A nut 24 secures post-like orifice closer in place. The top of the rigid chamber 7 is provided with a pair of studs 25 and 26 whereby the air spring S may be mounted in known manner on a suspension and attached at its upper end to a rigid part of a vehicle chassis. The stud 26 has a passageway 27 through which air or other gas may be introduced into the air spring 5 as required. Lower mounting studs 30-30 are implanted or press fitted into the bottom of the base 13. In operation, one or more air springs 5 will be mounted in known manner on each opposite side of a vehicle suspension so as to support a vehicle chassis on an axle and associated ground wheels. Depending on the load on the vehicle, the variable chamber 6 will be partially compressed with the portion of the load on each air spring 5 being supported by the air or gas under compression in the volume formed by the combined volumes of the chambers 8 and 10 which are in communication through the orifice 12. Because of these combined volumes the air spring 5 initially will have a relatively low spring rate in accordance with the following equation: (Equation Removed) Where: n = The gas constant (~ 1.4 for air) A = Effective area P = Air spring pressure PAT = Atmospheric pressure V - Air spring volume As can be seen from the equation the volume is inversely proportional to spring rate. To minimize the spring rate many deigns increase the air volume to be as large as practical. la operation, an air spring 5 installed in a conventional manner in a vehicle suspension, such as a heavy duty truck-tractor, will re-act to road irregularities in a conventional air spring operating manner except that the ride will be softer or easier than normal due to the combined volumes of the chambers 8 and 10 acting in concert. However, when the vehicle encounters a severe irregularity the compressible air bag 9 will be compressed during jounce to the point that the plug 22 closes the orifice 12 as shown and illustrated in Fig,2. Thereupon, only the volume of the chamber 8 will be operational and in accordance with the foregoing equation the volume V will be lower than normal and consequently the spring rate will be proportionately higher than normal. In the event that further jounce travel occurs the air spring 5 becomes progressively staffer as plug 22 becomes fully compressed and the bump stop 20 begins to provide resistance to jounce travel. The action of the post-like orifice closer 20 can be varied in several ways such as by altering its shape and selecting different materials for forming the plug 22 and the base 21. Further, more than two different materials may be used so as to provide a plurality of spring rates ranging between the highest spring rate and the lowest spring rate. We claim: 1. A dual chamber air spring (5) for use in a vehicle suspension, the air spring having a base piston (13), a fixed-volume chamber (7) and a compressible variable-volume chamber (6) between the base piston (13) and the fixed-volume chamber (7), with a partition (11) separating said variable-volume and fixed-volume chambers (6,7) and having at least one orifice (12) therein opposed to the base piston (13) and providing gas flow communication between the chambers (6,7), a post-like orifice closer (20) being mounted on said base piston (13) in the variable-volume chamber (6) opposite the orifice (12) to co-operate with the orifice (12) when the volume of the variable-volume chamber (6) is reduced during suspension jounce in use; characterize in that the orifice closer (20) has a pliant portion (22) engageable with the corresponding orifice (12) and a relatively rigid portion (21), disposed such that during jounce the pliant portion (22) initially engages and closes the corresponding orifice (12) to block said gas flow communication between the chambers (6,7), while on further compression of the variable-volume chamber (6) the relatively rigid portion (21) of the orifice closer (20) comes into engagement to resist further jounce movement. 2. The dual chamber air spring as claimed in claim 1, wherein, the dual chamber air spring(5) is generally cylindrical in shape and said orifice(12) in said partition(ll) and said post-like orifice closer(20) are co-axially aligned in said spring(5). 3. The dual chamber air spring as claimed in claim 1, wherein, said postlike orifice closer (20) provides a relatively low spring rate when said orifice(12) is initially closed during jounce and subsequentiy on continued jounce provides a substantially higher spring rate. 4. The dual chamber air spring as claimed in claim 1, wherein, said postlike orifice closer (20) has an orifice (12) closing portion which is pliant and a rigid or semi-rigid portion which acts as a bump stop when said pliant portion (22) is substantially completely compresse.

Full Text

The present invention relates to a dual chamber air spring.
Background of the Invention
Air springs are widely used on vehicle suspension systems since they
generally result in a lower system spring rate and a lower vehicle natural frequency
than other available types of springs. A low spring rate and low natural frequency
result in superior isolation of road-induced disturbances and improved contact
between the wheels and road surface (in outer words a better ride). Unfortunately,
decreasing the spring rate also decreases roll stability and increases suspension travel,
both of which can be a negative feature in some applications.
A number of methods have been employed to overcome this trade-off. Many
suspensions employ a bump-stop to limit axle travel and body roll. However, when
the bump-stop is contacted very high loads are transmitted directly into the vehicle
frame resulting in undesirable harshness. Other designs have made use of costly
valves or control units to vary the spring rate and natural frequency.
Brief Summary of the Invention
The present invention provides an innovation in air springs when used in
suspensions, particularly for heavy duty trucks and trailers. The air springs of the
invention have dual volumes, one being a compressible variable chamber and the
other being a fixed volume chamber. The interiors of the two chambers are separated
by a partition which has an orifice therein providing air or gas flow communication
between the chambers. A post-like orifice closer or plug is mounted within the compressible variable volume chamber for closing the orifice during jounce action of
the associated suspension. The post-iike closer has a deformable or resilient portion which has a low spring rate and a relatively rigid portion which has a high spring rate. During a jounce of the associated suspension of sufficient severity the deformable portion of the post-like orifice closer engages and closes the orifice thereby isolating the fixed volume chamber from the variable volume chamber. In the event of a sufficiently severe jounce the rigid portion of the post-Jike closer comes into play and arrests further jounce movement.
Brief Description of the Drawings
For a complete understanding of the nature and scope of the invention and a description of a preferred embodiment reference may now be had to the accompanying drawings wherein:
Fig. 1 is a semi-vertical sectional and side elevationai view of a dual chamber air spring forming a presently preferred embodiment of the invention;
Fig.2 is a vertical sectional view of the air spring of Fig. 1 in a compressed condition with its post-like orifice closer in contact with and closing the orifice in the partition between the chambers;
Fig.3 is a top plan view of the air spring of Fig. 1; Fig.4 is a bottom plan view of the air spring of Fig. 1; and Fig.5 is a perspective view of the post-like orifice closer incorporated in the air spring of Fig. 1. Detailed Description of the Invention
Referring to the drawings, in Figs. 1-4 a dual volume air spring is indicated generally at 5 embodying the invention and comprising a compressible variable volume chamber indicated generally at 6 and a fixed volume rigid chamber indicated generally at 7. The interiors 8 and 10, respectively, pf the chambers 6 and 7 are
separated by a rigid partition plate 11 provided in the center with an orifice or
opening 12.
The variable volume chamber 6 has a construction corresponding generally to
that of known commercially available air springs for truck and trailer suspensions. It
has a generally cylindrical compressible body formed rubber, or rubber-like sheet
material 9 the upper end of which is closed by the rigid plate 11 while the lower end
is closed by a base 13 usually referred to as the air spring "piston".
The rigid upper chamber 7 is also generally cylindrical in shape and formed
from sheet metal or other suitable.rigid or non- expandable material. The rigid plate
11 closes die bottom end of the chamber 7 with the periphery of the plate being
welded to the interior of the chamber 7 as indicated at 14. The circumferential lip 15
of the air bag 9 is hermetically sealed or crimped between the underside of the rigid
plate 11 and the inwardly curled lip 16 of the rigid chamber 7.
The lower lip 17 of the air bag 9 is hermetically sealed and secured between
the periphery of a washer-like plate 18 and a corresponding dish-like surface of the
base 13. Thus, the variable volume compressible chamber 6 is hermetically sealed in
accordance with the known construction of commercially available air springs.
A post-like orifice closer for the orifice 12 is indicated generally at 20 formed
by a frusto-conical base 21 forming a bump stop and formed of a rigid, or semi-rigid
material and a compressible plug 22 formed of a pliant material- From Fig.2 it will be
seen that when the chamber 6 is in its compressed condition during jounce of the
associated suspension the plug or stopper 22 engages the underside of the rigid
separator or partition 11 so as to close the orifice 12. The plug 20 has a relatively low
spring rate until it is firmly compressed onto the bump stop 21 which has a high
spring rate. The plug or stopper portion 22 may be formed of a relatively low durometer rubber or polymethane material of known commercial type . While the
bump-stop 21 may be formed of high durometer natural rubber, high durometer
polyurethane, Hydril a (DuPont thermoplastic elastomer) or similar materials of
known commercial type. The base of the bump stop 21 is provided with a stud 23
which projects through apertures in the washer 18 and the base 13. A nut 24 secures
post-like orifice closer in place.
The top of the rigid chamber 7 is provided with a pair of studs 25 and 26
whereby the air spring S may be mounted in known manner on a suspension and
attached at its upper end to a rigid part of a vehicle chassis. The stud 26 has a
passageway 27 through which air or other gas may be introduced into the air spring 5
as required. Lower mounting studs 30-30 are implanted or press fitted into the bottom
of the base 13.
In operation, one or more air springs 5 will be mounted in known manner on
each opposite side of a vehicle suspension so as to support a vehicle chassis on an
axle and associated ground wheels. Depending on the load on the vehicle, the variable
chamber 6 will be partially compressed with the portion of the load on each air spring
5 being supported by the air or gas under compression in the volume formed by the
combined volumes of the chambers 8 and 10 which are in communication through the
orifice 12. Because of these combined volumes the air spring 5 initially will have a
relatively low spring rate in accordance with the following equation:
(Equation Removed)
Where:
n = The gas constant (~ 1.4 for air)
A = Effective area
P = Air spring pressure
PAT = Atmospheric pressure
V - Air spring volume
As can be seen from the equation the volume is inversely proportional to spring rate. To minimize the spring rate many deigns increase the air volume to be as
large as practical.
la operation, an air spring 5 installed in a conventional manner in a vehicle suspension, such as a heavy duty truck-tractor, will re-act to road irregularities in a conventional air spring operating manner except that the ride will be softer or easier than normal due to the combined volumes of the chambers 8 and 10 acting in concert. However, when the vehicle encounters a severe irregularity the compressible air bag 9 will be compressed during jounce to the point that the plug 22 closes the orifice 12 as shown and illustrated in Fig,2. Thereupon, only the volume of the chamber 8 will be operational and in accordance with the foregoing equation the volume V will be lower than normal and consequently the spring rate will be proportionately higher than
normal.
In the event that further jounce travel occurs the air spring 5 becomes
progressively staffer as plug 22 becomes fully compressed and the bump stop 20
begins to provide resistance to jounce travel.
The action of the post-like orifice closer 20 can be varied in several ways such
as by altering its shape and selecting different materials for forming the plug 22 and
the base 21. Further, more than two different materials may be used so as to provide a
plurality of spring rates ranging between the highest spring rate and the lowest spring
rate.

We claim:
1. A dual chamber air spring (5) for use in a vehicle suspension, the air spring having a base piston (13), a fixed-volume chamber (7) and a compressible variable-volume chamber (6) between the base piston (13) and the fixed-volume chamber (7), with a partition (11) separating said variable-volume and fixed-volume chambers (6,7) and having at least one orifice (12) therein opposed to the base piston (13) and providing gas flow communication between the chambers (6,7), a post-like orifice closer (20) being mounted on said base piston (13) in the variable-volume chamber (6) opposite the orifice (12) to co-operate with the orifice (12) when the volume of the variable-volume chamber (6) is reduced during suspension jounce in use;
characterize in that the orifice closer (20) has a pliant portion (22) engageable with the corresponding orifice (12) and a relatively rigid portion (21), disposed such that during jounce the pliant portion (22) initially engages and closes the corresponding orifice (12) to block said gas flow communication between the chambers (6,7), while on further compression of the variable-volume chamber (6) the relatively rigid portion (21) of the orifice closer (20) comes into engagement to resist further jounce movement.
2. The dual chamber air spring as claimed in claim 1, wherein, the dual chamber air spring(5) is generally cylindrical in shape and said orifice(12) in said partition(ll) and said post-like orifice closer(20) are co-axially aligned in said spring(5).
3. The dual chamber air spring as claimed in claim 1, wherein, said postlike orifice closer (20) provides a relatively low spring rate when said orifice(12) is initially closed during jounce and subsequentiy on continued jounce provides a substantially higher spring rate.
4. The dual chamber air spring as claimed in claim 1, wherein, said postlike orifice closer (20) has an orifice (12) closing portion which is pliant and a rigid or semi-rigid portion which acts as a bump stop when said pliant portion (22) is substantially completely compresse.

Documents:

627-delnp-2003-abstract.pdf

627-delnp-2003-assignment.pdf

627-delnp-2003-claims.pdf

627-delnp-2003-complete specification(granted).pdf

627-DELNP-2003-Correspondence-Others-(21-04-2010).pdf

627-delnp-2003-correspondence-others.pdf

627-delnp-2003-correspondence-po.pdf

627-delnp-2003-description (complete).pdf

627-delnp-2003-form-1.pdf

627-delnp-2003-form-18.pdf

627-delnp-2003-form-2.pdf

627-DELNP-2003-Form-3-(21-04-2010).pdf

627-delnp-2003-form-3.pdf

627-delnp-2003-form-5.pdf

627-delnp-2003-form-6.pdf

627-delnp-2003-gpa.pdf

627-delnp-2003-pct-210.pdf

627-delnp-2003-pct-304.pdf

627-delnp-2003-pct-332.pdf

627-delnp-2003-pct-409.pdf

627-delnp-2003-petition-137.pdf

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Patent Number

242679

Indian Patent Application Number

627/DELNP/2003

PG Journal Number

37/2010

Publication Date

10-Sep-2010

Grant Date

04-Sep-2010

Date of Filing

24-Apr-2003

Name of Patentee

HENDRICKSON INTERNATIONAL CORPORATION

Applicant Address

ILLINOIS HAVING ITS PRINCIPAL PLACE OF BUSINESS AT 500 PARK BOULEVARD, SUITE 1010, ITASCA, ILLINOIS, U.S.A.

Inventors:

#	Inventor's Name	Inventor's Address
1	JOHN W. STUART	1530 SOUTH STREET, NO. 907, CHICAGO, ILLINOIS 60605, U.S.A.

PCT International Classification Number

F16F 9/04

PCT International Application Number

PCT/US2001/45262

PCT International Filing date

2001-10-24

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	09/696,475	2000-10-24	U.S.A.