Patent Description:
Hydraulic steering systems are commonly used in vehicles such as forklift trucks. Typically, a hydraulic cylinder controls the rotation of a wheel carrier about a generally vertical steering axis. The extension or retraction of the cylinder's connecting rod pushes or pulls an offset point on the wheel carrier and causes the carrier to rotate about the steering axis, thereby steering a wheel mounted on the carrier.

An example of such a steering system is disclosed in <CIT>. A pair of steerable wheels are disclosed, each controlled by a hydraulic cylinder, with the cylinders being connected in series such that they operate in synchronicity on their respective wheels. Each hydraulic cylinder is immovably mounted to the vehicle chassis and has an active connecting rod that is capable of reciprocating movement in conventional manner. A steering lever acts as a linkage between the free (distal) end of the connecting rod and the wheel carrier, with the steering lever being pivotally linked to both the connecting rod and the wheel carrier. The immovable mounting of the cylinder allows rigid hydraulic lines (e.g. metal pipes) to be connected to the cylinder in place of conventional flexible lines.

A drawback with such a system is that the force vector acting through the steering lever varies in direction throughout the range of steering angles. At some points in the steering cycle, the force vector is directed at an angle towards the connecting rod where it has a significant lateral component. This places a strain on the cylinder seals and may lead to a failure of the hydraulic sealing. It also necessitates a larger and stronger connecting rod to withstand the buckling forces, and strengthened seals for the connecting rod on the cylinder. Because the cylinders are hydraulically linked, a passive connecting rod extends from the rear of each hydraulic cylinder to seal the chamber behind the piston, and the lateral forces are also transmitted to the passive connecting rod and the seals at the rear of the cylinder. Furthermore, the alleged advantage of rigid hydraulic lines over flexible ones is not necessarily present. Rigid hydraulic lines are more expensive to make, more expensive to replace, and can be less reliable especially on mobile equipment due to vibration.

<CIT> relates to a vehicle having at least two steerable wheels mounted on either side of its chassis. A first hydraulic steering system is associated with a first wheel, with a similar second hydraulic system associated with a second wheel. A hydraulic pressure connecting and pressure control circuit delivers pressurised fluid to the two steering systems. The control circuit is such as to allow steering of an inner wheel, during a curved trajectory of the vehicle, to be steered through an angle greater than that through which the outer wheel is steered, according to a predetermined relationship.

<CIT> relates to a self-propelled windrower including a rear axle having end sections which are adjustable to vary the tread width of caster-mounted rear wheels having upright spindles mounted for swiveling within cylindrical receptacles defining outer ends of the axle end sections. Front wheels of the windrower are steerable and a steering assist is provided including right and left steering cylinders having barrels respectively mounted to right and left reaction arms by a mounting permitting the cylinder to pivot vertically and horizontally, with the rods being coupled to respective steering arms fixed to the top of the spindles.

<CIT> relates to a highly maneuverable prime mover adapted for normal or orthogonal steering modes. In the normal mode true Ackermann steering is achieved. Either two or four wheel steering may be chosen. When in the orthogonal mode the vehicle is hybrid skid steered. In hybrid steering only one wheel of a side-by-side pair is steered. This greatly simplifies the necessary shifting mechanisms. Each wheel is driven by an individual hydraulic motor supplied from a main system. In the preferred version the prime mover has a turret capable of <NUM>° rotation. This turret preferably has a universal mounting capable of holding various types of lifting tools.

The invention provides a steering system for a vehicle wheel, comprising:.

By providing a pivotally mounted hydraulic cylinder with a rigid connecting rod assembly that extends directly to the pivot point on the wheel carrier, the use of a doubly pivoted steering lever or linkage is avoided. The hydraulic cylinder can change its orientation to accommodate the angular change in position of the pivot point on the wheel carrier. In this way, lateral buckling forces are minimized.

While the steering system is hydraulic, it can be used in vehicles having any kind of drive system (in other words not only in hydraulic drive vehicles). Thus, for example it can be used in hydraulic drive trucks, vehicles with internal combustion engines, hybrid vehicles, electrical vehicles and so on.

Preferably, said first section is a straight linear rod section and said pivot point is disposed in linear alignment with the first section.

In this way, the force vector from the pivot point is assured to be directed along the line of the straight linear connecting rod section and along the axis of the hydraulic cylinder itself, thereby completely eliminating any additional lateral strain on the seals of the cylinder.

Further, preferably, said pivot point, the point at which the second and first sections are rigidly coupled, the axis of the first section, the axis of the cylinder, and the position at which the cylinder is pivotally mounted on the vehicle, are all collinear.

According to the invention, the second section is a curved member extending between the first section and the pivot point connection, the curved member defining a concavity which may accommodate a portion of the wheel carrier.

This concavity can extend the range of steering angles by allowing the pivot point to be driven "around" a part of the wheel carrier, such as a hub or bearing.

Preferably, the concavity accommodates a portion of the wheel carrier when the steering angle is at a maximum in one direction.

Preferably, said second section is an arcuate member.

The connecting rod assembly can be an integrally formed structure having said first and second sections. (In other words, the term "assembly" does not imply that the first and second sections must be separate entities connected together, as an integrally formed member can be fabricated to include both sections.

In currently preferred embodiments, the connecting rod assembly comprises a connecting rod as said first member and an extension member rigidly affixed to the connecting rod as said second member.

The rigid affixing of the extension member to the connecting rod excludes the use of a pivoting connection at this point.

The steering system preferably further comprises a passive rod extending from the cylinder in the opposite direction to the connecting rod and mounted on a common piston or piston assembly therewith, the passive rod sealing the cylinder in the direction away from the wheel and permitting synchronization of the cylinder with another hydraulic cylinder in a push-pull arrangement.

Such a passive rod may be omitted if synchronization is not required, or if an alternative method of synchronization is to be employed.

The system may also include a wheel mounted on said wheel carrier.

Preferably, the system further comprises a hydraulic circuit including a hydraulic pump, a connection from the hydraulic pump to the hydraulic cylinder, and means for controlling the flow of hydraulic fluid within the hydraulic circuit in response to a steering input.

In another aspect there is provided a vehicle steering system comprising a first steering system for a first vehicle wheel according to any of claims <NUM>-<NUM>, a second steering system for a second vehicle wheel according to any of claims <NUM>-<NUM>, and a hydraulic circuit connecting the hydraulic cylinders of the first and second steering systems in series.

There is also provide a vehicle comprising a steering system according to any of claims <NUM>-<NUM>.

The invention will now be illustrated by the following description of embodiments thereof, given by way of example only, with reference to the accompanying drawings, in which:.

Referring to <FIG>, a steering system <NUM> for a vehicle wheel <NUM> is shown in perspective view.

<FIG> shows the system when the wheel <NUM> is steered straight ahead. <FIG> shows the system when the wheel <NUM> is steered at right angles, i.e. having been turned <NUM>° to steer in a sideward direction. <FIG> shows the system when the wheel <NUM> is steered to its maximum extent, beyond <NUM>°, to a steering angle of approximately <NUM>°.

The wheel <NUM> is mounted on a wheel carrier <NUM> which in turn is mounted on a bearing or hub <NUM> which permits the wheel to be rotated about a vertical axis relative to the chassis <NUM> of a vehicle. A drive motor <NUM>, which may for example be hydraulic or electric, is mounted on the wheel <NUM> permitting the wheel to be driven in a forward or a reverse direction. It will be appreciated that the nature of the vehicle drive system, and the coupling of the drive system to the wheel, is not essential to the steering system and can be varied according to the preferences of the designer or manufacturer. So, for example, instead of a hydraulic or electric motor mounted on the wheel, an engine could be coupled to the wheel using a drive shaft or a gearing assembly. The engine could be internal combustion, hybrid, electrical, hydraulic or of any other kind.

Steering of the wheel is controlled by a hydraulic cylinder <NUM> which has an active connecting rod <NUM> (<FIG> and <FIG>, hidden in <FIG>) and a passive rod <NUM>. The connecting rod <NUM> constitutes a first section of a rigid connecting rod assembly, and is adapted to reciprocate into and out of the cylinder.

<FIG> shows the system when the connecting rod is withdrawn fully into the cylinder <NUM>, <FIG> shows the connecting rod <NUM> having been driven out partway from the cylinder, and <FIG> shows the connecting rod at its maximum extension from the cylinder.

A second section <NUM> of the rigid connecting rod assembly is provided in the form of a rigid steel plate which is rigidly coupled (i.e. with no freedom of movement, rotation or pivoting) to the connecting rod <NUM>. Thus, as the connecting rod <NUM> is reciprocated into and out of the cylinder <NUM>, the second section is driven correspondingly towards and away from the cylinder in a straight line.

The passive rod <NUM> is uncoupled at its free end and serves to allow the cylinder to be hydraulically coupled to and synchronized with a cylinder of a steering system for another wheel in a push-pull manner described further below. This passive rod could be dispensed with if such synchronization is not required, or could be substituted by an alternative synchronization mechanism such as a separate synchronizing cylinder or by appropriate hydraulic pumping circuits driving a steering mechanism on another wheel.

A priming valve (not shown) is provided in the piston. As is known in the art, such a priming valve is useful for priming the system on initial start-up and for keeping the cylinders primed and synchronized in use in a multi-cylinder system such as is described in relation to <FIG>.

The hydraulic cylinder is pivotally mounted on the vehicle such that it is prevented from translational movement relative to the vehicle but capable of changing its orientation with respect to the vehicle. The pivot mount is provided by a collar <NUM> affixed to the outside of the cylinder, with the collar being trunnion mounted in a fixed bracket <NUM> that is welded to the vehicle chassis <NUM>.

Referring additionally to <FIG>, the operation of the steering system for a vehicle wheel is shown in plan view.

It can be seen, moving from <FIG>, that the rigid connecting rod assembly is progressively pushed away from the cylinder. The second section <NUM>, being rigidly mounted on the first section (connecting rod) <NUM>, maintains its angular disposition and is linearly translated away from the cylinder <NUM>.

The distal end of the second section <NUM> (i.e. the end remote from the cylinder) is pivotally coupled to the wheel carrier <NUM> at a pivot point <NUM>. As this pivot point <NUM> is offset from the centre of rotation <NUM> of the bearing <NUM>, it translates laterally relative to the cylinder <NUM> as the connecting rod is extended. Due to the pivot mounting of the cylinder <NUM> on the chassis, the cylinder orientation changes as the connecting rod extends, as can be seen in the progression from <FIG>.

The lack of lateral movement between the cylinder <NUM>, the first section <NUM> and the second section <NUM>, eliminates strains on the cylinder seals. Furthermore, it can be observed that all points of the steering cycle, the pivot point <NUM>, the point at which the second section <NUM> and first section <NUM> are rigidly coupled, the axis of the first section <NUM>, the axis of the cylinder <NUM>, and the position at which the cylinder is pivotally mounted on the vehicle (i.e. the pivot between collar <NUM> and bracket <NUM>), are all collinear. The force vectors (indicated by the broad arrows in <FIG> are all directed along this collinear axis, ensuring that there are never any lateral forces on the cylinder or connecting rods <NUM>, <NUM>.

The second section <NUM> is in the form of a curved member extending between the first section <NUM> and the pivot point connection <NUM>. The curved member defines a concavity <NUM> which may accommodate a portion of the wheel carrier. This can be seen in <FIG> where the concavity <NUM> accommodates part of the wheel carrier below the hub as the steering angle extends beyond <NUM>° to its maximum angle (in this embodiment) of <NUM>°. Thus, the arcuate shape of the second section <NUM> transmits the forces from the pivot point in a straight line passing through a part of the hub.

Depending on the shapes and dimensions chosen, the maximum steering angle may be more or less than <NUM>°, according to the wishes of the designer. The second member could be mounted above the wheel carrier and accommodate part of the hub or bearing <NUM> in an alternative arrangement.

In the illustrated embodiment, the connecting rod <NUM> is fitted into and rigidly affixed (such a by welding) within a socket formed in the proximal end of the second section. However other rigid mounting arrangements can be employed also. Furthermore, the use of the term "assembly" (as in the rigid connecting rod assembly) does not imply that the first and second sections must be separate members that are assembled together. The rigid connecting rod assembly could be an integrally formed component with identifiable portions including a first portion or section adapted to reciprocate within the cylinder and a second portion or section extending from the first portion to the wheel carrier.

The steering system for a vehicle wheel shown in <FIG> can be incorporated in an overall steering system for a vehicle, as shown in <FIG>. The vehicle in question is a forklift truck but the steering system can be implemented in any vehicle for which hydraulic steering is suitable.

Referring first to <FIG>, a forklift truck is shown in plan view. The view of the vehicle is simplified to show the chassis <NUM>, the forks <NUM>, the fork-lifting mechanism <NUM>, and the wheels and steering arrangement, which will now be described.

A left front wheel <NUM> and steering system <NUM>, exactly as previously described in relation to <FIG>, is mounted at the front left side. A right front wheel <NUM>' is controlled by a steering system <NUM>' which is a mirror image of the steering system <NUM>. At the rear of the vehicle a steerable, driven rear wheel is mounted with its own (conventional) steering cylinder <NUM>. However, the conventional steering cylinder could be replaced with a steering system for a vehicle wheel according to the invention.

The vehicle is shown in <FIG> in normal steering mode. All three wheels <NUM>, <NUM>', <NUM> are aligned with the front-rear axis of the vehicle, i.e. aligned parallel with the forks <NUM>. In this steering mode, the steering systems <NUM>, <NUM>' may be inactive with the front wheels fixed, and the vehicle can be steered by the rear wheel alone, i.e. withdrawing or extending the rod from cylinder <NUM> to rotate the rear wheel <NUM> about its vertical axis.

In <FIG> the vehicle is shown in sideward mode. The rear wheel <NUM> has been turned through <NUM>°to be aligned perpendicular to the front-rear axis of the vehicle, so that the vehicle can be driven sideways and steered using the front wheels <NUM>, <NUM>'. In this mode, the rear wheel <NUM> is fixed in position and follows an arc whose direction of curvature and radius are determined by the angle of the front wheels <NUM>, <NUM>'.

The respective cylinders of the steering systems <NUM>, <NUM>' of each front wheel are synchronized so that, as shown in <FIG>, the angle adopted by left front wheel <NUM> is mirrored by wheel <NUM>' in the opposite direction. Thus, the two steering systems for a vehicle wheel together form part of an overall vehicle steering system, which is shown in <FIG>.

In <FIG> it can be seen that the cylinder of left-hand system <NUM> is coupled to the cylinder of right-hand system <NUM>' by a hydraulic circuit which comprises a control circuit <NUM>, a left-hand pressure line <NUM> leading to/from port L of the control circuit, a bridging line <NUM>, and a right-hand pressure line <NUM> leading to/from port R. Each cylinder has a front chamber (with the connecting rod <NUM>, see <FIG>) and a rear chamber (with the passive rod <NUM>), the chambers being filled with hydraulic fluid and separated by the piston on which the rods are mounted.

The front chamber of system <NUM> is connected to left-hand pressure line <NUM>. The rear chamber of system <NUM> is connected to the front chamber of system <NUM>' by the bridging line <NUM>. The rear chamber of system <NUM>' is connected to right-hand pressure line <NUM>. The cylinder volumes are equal and the system is balanced so that, as shown in <FIG>, both pistons adopt the same position along their respective cylinders.

Referring additionally to <FIG>, the control circuit <NUM> is shown in greater detail. The control circuit has ports P and T connecting to a hydraulic pump and tank, respectively. A rotary pump <NUM> is controlled by a shaft <NUM> of a steering column so that rotation of the steering column in one direction causes hydraulic fluid to be pumped through port L into line <NUM> (and a corresponding volume of fluid to be returned via port R), while rotation of the column in the other direction causes the opposite flow to occur. An arrangement of one-way valves and solenoid valves <NUM> handles the resulting flow of hydraulic fluid within the circuit.

When left-hand line <NUM> is pressurized, the piston of system <NUM> is driven rearwardly, withdrawing the connecting rod <NUM> of system <NUM> into the cylinder. Simultaneously, this pressurizes the rear chamber of system <NUM> and fluid flows through bridging line <NUM> into the front chamber of system <NUM>', driving the piston of the latter system rearwardly to the same degree. Pressurizing the right-hand line <NUM> has the opposite effect, with fluid flows being reversed and the pistons being driven forwardly in each case.

The overall vehicle steering system for the front wheels has the same advantages on each side as the single wheel steering system of <FIG>, providing accurate steering beyond <NUM> degrees with no lateral forces being exerted on the seals of the hydraulic cylinders.

Claim 1:
A steering system for a vehicle wheel, comprising:
a wheel carrier (<NUM>) for mounting a steered wheel, the wheel carrier (<NUM>) being rotatably mounted with respect to the vehicle about a steering axis to allow the wheel to be steered;
a hydraulic cylinder (<NUM>) having a piston therein and a rigid connecting rod assembly extending from the piston out of the cylinder;
wherein the rigid connecting rod assembly comprises a first section (<NUM>) adapted to reciprocate into and out of the cylinder and a second section (<NUM>) rigidly extending from the first section (<NUM>) to a pivot point connection where it is pivotally connected to the wheel carrier (<NUM>) at an offset from the steering axis;
wherein the second section (<NUM>) is a curved member extending between the first section (<NUM>) and the pivot point connection, the curved member shaped to define a concavity for accommodating a portion of the wheel carrier (<NUM>) within the concavity; and
wherein the hydraulic cylinder (<NUM>) is pivotally mounted on the vehicle such that it is prevented from translational movement relative to the vehicle but capable of changing its orientation with respect to the vehicle.