This invention relates to a suspension system for commercial vehicles, and more particularly, the invention relates to a mechanical spring arrangement for use with air springs preferably in commercial trailer applications.
The trailer industry has historically employed mechanical style steel leaf spring suspensions that have the advantage of low maintenance, low initial investment costs, and good loading dock performance. The mechanical suspension has good dock performance because vehicle displacement is relatively small between unloaded and loaded conditions. Furthermore, the suspension provides a stable trailer deck with minimal bouncing during loading and unloading. The shortcoming of the mechanical style suspension is that the ride quality is harsh compared to that of an air spring suspension especially during the unloaded or lightly loaded conditions.
One mechanical leaf spring arrangement use in passenger car applications is shown in
Due to the shortcomings of mechanical leaf springs described above, air springs have gained a significant portion of the trailer suspension market in recent years. Air suspensions have good ride quality regardless of load. The drawbacks of the air suspension are that it typically has higher maintenance, higher initial investment costs, and inferior dock performance without additional devices. Air springs also are typically heavier and have poor axle-to-axle load equalization as compared to that of a mechanical suspension. Most air suspensions require additional devices to limit suspension travel so that the trailer deck height drop is minimized and the trailer is stable for loading and unloading. Therefore, what is needed is a trailer suspension that provides the benefits of both mechanical suspensions and air suspensions. Specifically, what is needed is a suspension having a ride quality similar to that of an air suspension with the low maintenance, superior load equalization, and good dock performance of a mechanical suspension.
The present invention provides a vehicle suspension system including a frame. A pair of laterally spaced apart upper control arms are pivotally supported by the frame at pivotal connections. A knuckle is connected to each of the upper control arms. A leaf spring is connected to the lower portion of the knuckles at pivotal connections and serves as the lower control arms. The upper control arms extend away from the knuckles, and air springs are arranged between the upper control arms and the frame. A pressurized air system is connected to the air springs to control the air springs for providing desired ride characteristics.
Accordingly, the above embodiments of the present invention provide the benefits of mechanical suspension by utilizing the lateral leaf spring while obtaining the benefits of an air suspension by utilizing air springs with the lateral leaf spring.
Other advantages of the present invention can be understood by reference to the following detailed description when considered in connection with the accompanying drawings wherein:
A vehicle suspension system 10 is shown schematically in
The system 10 includes upper control arms 14 that have portions 46 extending from the first pivotal connection 16 away from the connection 20. Air springs 36 may be arranged between the portions 46 and the frame 12. It is to be understood that the air springs 36 may also be arranged in other locations. For example, the air springs 36 may be arranged between the leaf spring 30 and the frame 12. The air springs 36 receive air from a pressurized air source 40. The pressure to the air springs 36 is metered by valves 42 that are controlled by a controller 44 that may also be connected to the pressurized air source 40. The pressurized air system may also provide load leveling and other desired suspension control features. In the preferred embodiment, each air spring 36 has its own independently control valve 42 so that different pressures may be maintained in the air springs 36 for maintaining lateral stability such as during dock loading conditions. Devices used for detecting vehicle stability during travel or loading conditions may also be connected to the controller 44, but are not shown.
A jounced condition is shown in
The invention has been described in an illustrative manner, and it is to be understood that the terminology that has been used is intended to be in the nature of words of description rather than of limitation. Obviously, many modifications and variations of the present invention are possible in light of the above teachings. It is, therefore, to be understood that within the scope of the appended claims the invention may be practiced otherwise than as specifically described.