This invention relates to improvements in air suspension systems for load carrying prime mover and trailer vehicles having multiple axles supported by air bags on either side of each axle.
Air suspension systems for load carrying prime mover vehicles can include as many as eight air suspension bags supporting the two driven axles in pairs on either side of each axle. In one well-known prime mover, the pairs of air bags are connected by a common large diameter air lines extending between correspondingly positioned air bags on adjacent axles.
The common air lines are each connected by an air line to a control valve which controls the air supply to the common air lines to adjust the inflation of the air bags to ensure that the prime mover is kept level as it is driven over variable road conditions.
In other air suspension systems, such as the Hendrickson HAS Series suspension, each axle is supported at either side by a single large air bag mounted on a frame hanger to which the axle is connected.
While the known air suspension systems may be adequate for slowly changing road conditions, they are not sufficiently responsive to rapidly changing conditions such as are experienced in cornering and on rough sections of road. As a result the vehicle becomes unstable, reducing driver control, increasing driver fatigue, causing increased tyre wear and potential damage to the freight.
It is an object to provide an improved air suspension system which is more responsive under changing driving conditions.
The invention provides an air suspension system for a multi-axle vehicle having at least one air bag supporting each side of each axle, a level controlling valve for separately controlling air flow to the air bags on each side respectively, separate air lines connecting each valve and each of the air bags on either side respectively, said separate air lines being such that substantially the same volume of air is supplied to each air bag to maintain stability under changing driving conditions.
The invention further provides an air suspension system for a multi-axle vehicle having at least one air bag supporting each side of each axle, a level controlling valve for separately controlling air flow to the air bags on each side respectively, a separate air line connected between each valve and a distribution manifold, separate air lines connected between each manifold and each of the air bags on either side respectively, the first mentioned air lines being of substantially the same size and length, and the second mentioned airlines between the respective manifolds and the respective air bags being of the same size and length whereby substantially the same volume of air is supplied to each air bag to maintain stability under changing driving conditions.
In comparison with the known air suspension systems, in which the air lines to each air bag are of variable length, a system embodying the invention will allow the air bags to respond to the changing road conditions maintaining stability and enabling the vehicle to be more easily controlled.
In one form, each axle has a pair of air suspension bags supporting each side of the axle and separate air lines extend from the valve controlling each side to the separate air bags.
In one such arrangement, the air bags on each side are interconnected by common air lines extending between air bags in similar positions on adjacent axles, the separate air lines being connected to the common air lines adjacent the respective air bags.
In another form, each axle is supported by a single air bag at each side of the axle.
The vehicle may take the form of a prime mover having driven axles, or a trailer having passive axles.
To further improve responsiveness, each level controlling valve has a separate air feed line from the air supply tank of the prime mover. The size and length of the separate feed lines is preferably the same.
The level controlling valves are preferably actuated by control means extending to a common rigid bar fixed to the means attaching the air bags on either side to one axle.
In another form the invention provides an air suspension system for a multi-axle vehicle having at least one air bag supporting each side of each axle, a level controlling valve for separately controlling air flow to the air bags on each side respectively, separate air lines connecting each valve and each of the air bags on either side respectively, each level controlling valve having a separate air feed line from an air supply tank of the vehicle to improve the responsiveness of the system.
In the drawings:
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The air bags 4 and 8, 5 and 9, 6 and 10 and 7 and 11 are connected in a known manner by common large capacity air lines 12 to 15 respectively, which are usually about 5 cm (2 inches) in diameter. The air suspension system so far described is typical of a Kenworth Airglide 200 as found on a Kenworth T 904 prime mover.
Under normal circumstances, the common lines 12 to 15 on either side of the axles are connected by an air line (not shown) to suitable ride height or level controlling valves 16 and 17, such as Hadley valves, but in the present embodiment they are supplied with air, at the air line connector fittings of each air bag, by separate air lines 18 to 21 respectively on one side and 22 to 25 on the other side, connected to junction fittings 26 and 27 which are supplied with air by lines 28 and 29 extending from the level control valves 16 and 17. To ensure an adequate supply of air to each valve 16 and 17, separate air lines 30 and 31 are connected to an air supply tank (not shown) mounted on the prime mover in the usual manner. The length and size of these lines are also the same.
To ensure a balanced supply air of substantially the same volume and pressure to each air bag, the separate air lines 18 to 21 and 22 to 25 are of substantially the same size or internal diameter and length. For similar reasons, the air lines 28 and 29 between the valves 16 and 17 are of substantially the same size and length.
The lines to the front air bags 4 and 6 are connected, in the usual manner, as indicated by the arrows, to the gauges and dump switch (not shown) in the cabin of the prime mover. Since this aspect does not from part of the invention it will not be further described.
The provision of the separate air lines 18 to 21 and 22 to 25, and the connection of these lines to the separately supplied level control valves 16 and 17, ensure that an equal volume of air is rapidly supplied to each of the air bags so that they respond appropriately to changes in road conditions relayed to the valves 16 and 17 by their control rods 32 and 33 via a rigid bar 34 mounted under the bags 9 and 11 as illustrated. The air lines 18 to 21 and 22 to 25 suitably have a bore diameter of about 12 mm (½ inch).
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In each of the embodiments the separate air lines suitably have a bore diameter of 12 mm. Other sizes may be used with similar results provided the size and length of the air lines in each set or group (eg 18 to 25, 28 and 29, 30 and 31 etc) are the same.
While embodiments of the invention have been described in connection with an air suspension typical of Kenworth prime movers, such as the Airglide 200 on the T 904 prime mover, it will be appreciated that the invention is equally applicable to other Kenworth suspensions, such as the Airglide or AG 400, AG 460 or the AG 690. Similar comments apply to the schematically illustrated Hendrickson HAS suspension. The invention is equally applicable to any air bag suspension system having one or more air bags supporting each driven axle.
This application is a divisional of U.S. Ser. No. 11/993,235 filed Dec. 20, 2007, which is a 35 U.S.C. 371 National Phase Entry Application from PCT/AU2005/000925 filed Jun. 24, 2005, the disclosures of which are incorporated herein in its entirety by reference.
Number | Date | Country | |
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Parent | 11993235 | Dec 2007 | US |
Child | 13087442 | US |