STEERING APPARATUS FOR A STEERED VEHICLE

Abstract

A steering apparatus comprises a rotatable steering shaft and a sensor which senses angular movement of the steering shaft. An electromagnetic actuator actuates a stop mechanism to releasable engage the steering shaft. There is a microcontroller which causes the electromagnetic actuator to actuate the stop mechanism to fully engage the steering shaft and prevent rotation of the steering shaft in a first rotational direction, which corresponds to movement towards the hardstop position, while allowing rotational play between the steering shaft and the stop mechanism in a second direction, which corresponds to rotational movement away from the hardstop position, when the sensor senses that the steering shaft has reached a hardstop position. A driver applies a reverse polarity pulse to the electromagnetic actuator when the stop mechanism is fully engaged and the steering shaft is rotated, as permitted by the rotational play, in the second rotational direction.

Claims

1. A steering apparatus for a steered vehicle, the steering apparatus comprising: a rotatable steering shaft; a sensor which senses angular movement of the steering shaft as the vehicle is being steered; a stop mechanism which releasably engages the steering shaft to prevent rotation of the steering shaft; an electromagnetic actuator which actuates the stop mechanism to engage or release the steering shaft; a microcontroller which causes the electromagnetic actuator to actuate the stop mechanism to fully engage the steering shaft when the sensor senses that the steering shaft has reached a hard stop position to prevent rotation of the steering shaft in a first rotational direction, which corresponds to movement towards the hard stop position, while allowing rotational play between the steering shaft and the stop mechanism in a second direction, which corresponds to rotational movement away from the hard stop position; a driver which applies a reserve polarity pulse to the electromagnetic actuator when the stop mechanism is fully engaged with the steering shaft and the steering shaft is rotated, as permitted by the rotational play, in the second rotational direction.

2-15. (canceled)

Description

BRIEF DESCRIPTIONS OF DRAWINGS

[0009] The invention will be more readily understood from the following description of the embodiments thereof given, by way of example only, with reference to the accompanying drawings, in which:

[0010] FIG. 1 is a perspective view of a marine vehicle provided with an improved steering apparatus;

[0011] FIG. 2 is an exploded view of the steering apparatus of FIG. 1;

[0012] FIG. 3 is a diagrammatic view of the steering apparatus of FIG. 1;

[0013] FIGS. 4A to 4C are schematics of switches integrated into the H-driver bridge of the steering apparatus of FIG. 1;

[0014] FIG. 5 are graphs illustrating H-Bridge PWM control logic of the steering apparatus of FIG. 1;

[0015] FIG. 6 is a state diagram of the control logic of the steering apparatus of FIG. 1; and

[0016] FIG. 7 is a perspective view of a land vehicle provided with the improved steering apparatus.

DESCRIPTIONS OF THE PREFERRED EMBODIMENTS

[0017] Referring to the drawings and first to FIG. 1, this shows a vehicle in the form of a marine vessel 10 which is provided with propulsion units in the form of outboard engines 12a and 12b. In this example there are two engines, namely, a port engine 12a and a starboard engine 12b. However, in other examples, the marine vessel may be provided with any suitable number of engines. It is common to have one engine or as many as five engines in pleasure marine vessels. The marine vessel 10 is also provided with a control station 14 that supports a steering wheel 16 mounted on a helm or steering apparatus 18. The steering wheel 16 is conventional and the steering apparatus 18is shown in greater detail in FIG. 2.

[0018] The steering apparatus 18 is improved over the helm disclosed in U.S. Pat. No. 7,137,347 which issued on Nov. 21, 2006 to Wong et al. and the full disclosure of which is incorporated herein by reference. The steering apparatus 18 includes a housing 20 which is shown partially broken away in FIG. 2. There is a plurality of circumferentially spaced-apart axially extending grooves, for example groove 22, on an inner wall 24 the housing 20. There is also a plurality of resilient, channel-shaped inserts, for example insert 26, each of which is received by a corresponding one of the grooves on the inner wall of the housing. A steering shaft 28 extends through the housing 20. The steering wheel 16, shown in FIG. 1, is mounted on the steering shaft 28. The steering shaft 28 includes a hollow drum portion 30 which has a cylindrical outer wall 32. There is a plurality of circumferentially spaced-apart grooves, for example groove 34, extending axially on the cylindrical outer wall 32 of the hollow drum 30. There is also a plurality of resilient, channel-shaped inserts, for example insert 36, each of which is received by a corresponding one of the grooves on the cylindrical outer wall of the hollow drum.

[0019] The steering apparatus 18 further includes a multi-plate clutch 38. There are two types of interposed substantially annular clutch plates in the multi-plate clutch 38. Clutch plate 40 is an exemplar of a first type of the clutch plate and clutch plate 42 is exemplar of a second type of clutch plate. The first type of clutch plate each have exterior projections, for example spline 44 shown for clutch plate 40, which are positioned to engage the grooves 22 on the inner wall 24 of the housing 20. The clutch plates 40 are thus axially slidable but non-rotational within the housing 20. The inserts 26 in the grooves 22 on the inner wall 24 of the housing 20 may provide dampened motion and additional position control. The second type of clutch plate each have interior projections, for example spline 46 as shown for clutch plate 42, that are positioned to engage the grooves 34 on the cylindrical outer wall 32 of the hollow drum 30 of the steering shaft 28. The clutch plates 42 are thus axially slidable with respect to the steering shaft 28. A limited amount of rotational movement is also permitted between the clutch plates 42 and the steering shaft 28 because the grooves 34 on the steering shaft 28 are wider than the splines 46 on the clutch plates 42. The inserts 36 in the grooves 34 may provide dampened motion and additional position control.

[0020] The steering apparatus 18 further includes an actuator in the form of an electromagnetic actuator which, in this example, includes an electromagnetic coil 48 and an armature 50. The electromagnetic coil 48 is mounted on a circular mounting plate 52. The circular mounting plate has exterior projections, for example spline 54, which are positioned to engage the grooves 22 on the inner wall of the housing 20 such that the mounting plate 52 is axially slidable but non-rotational within the housing 20. The armature 50 is coupled to the steering shaft 28. When the electromagnetic coil 48 is energized, the electromagnetic coil 48 and the mounting plate 52 are drawn along the armature 50 to force the clutch plates 40 and 42 together. Since the first type of clutch plates 40 are non-rotatable with respect to the housing 20 and the second type of clutch plates 42 are non-rotatable with respect to the steering shaft 28, apart from the rotational play discussed above, friction between the clutch plates 40 and 42, when the electromagnetic coil 48 is energized, causes the stop mechanism to brake the steering apparatus 18, i.e. stop rotation of the steering shaft 28 relative to the housing 20.

[0021] There is a spring 56 which preloads the clutch plates 40 and 42 for improved gap control between the clutch plates 40 and 42. The spring 56 performs two functions, namely, counteracting gravitational forces which may pull the clutch plates 40 and 42 apart and providing passive background steering resistance by partially forcing the clutch plates 40 and 42 together. The steering apparatus 18 may also be provided with a shim 58 between the electromagnetic coil 48 and the mounting plate 52. The shim 58 is a liquid shim in this example. The shim 58 sets the electromagnetic coil 48 and the mounting plate 52 apart by a predetermined clearance and which allows for consistency in the attractive force of the magnetic field.

[0022] The steering apparatus 18 further includes a circuit board 60 upon which is mounted a microcontroller 62, an H-bridge driver 64, and a rotational sensor 66. The microcontroller 62 controls current supplied to the electromagnetic coil 48 to provide dynamic steering resistance. The H-bridge driver 64 is responsible for energizing or applying current to the electromagnetic coil 48 to both vary steering resistance and brake the steering apparatus 18. The H-bridge driver 64 may also apply a reverse polarity pulse to the electromagnetic coil 48 when the steering shaft is rotated away from a hardstop. The rotational sensor 66 detects rotation of the steering shaft 28. In this example, a magnet 68 is disposed on an end of a shaft 70 of the armature 50 which rotates with the steering shaft 28. The rotational sensor 66 detects rotation of the magnet 68 and, accordingly, rotation of the steering shaft 28 and steering wheel 16.

[0023] Dynamic steering resistance is accomplished through pulse width modulation (PWM) of current supplied to the electromagnetic coil 48. The electromagnetic coil 48 may thereby only be partially energized, resulting in some friction between the clutch plates 40 and 42 but not sufficient to friction to stop the steering shaft 28 from rotating. The amount of steering resistance can be adjusted by the microcontroller 62 for different circumstances. For example, when the steering wheel 16 and steering shaft 28 are rotated too fast or the outboard engines 12a and 12b are heavily loaded. The outboard engines may be prevented from keeping up with the steering apparatus 18. The steering resistance can then be made greater to provide feedback to the operator, slowing down the rate of rotation of the steering wheel 16 and steering shaft 28. The steering resistance can also be made greater at higher boat speeds and lower at low boat speeds as encountered during docking. Greater steering resistance can also be used to indicate that the battery charge is low to discourage fast or unnecessary movements of the steering apparatus. Steering resistance can also be made greater to provide a proactive safety feature for non-safety critical failures. By imposing a slight discomfort to the operator, this intuitive sensation feedback alerts the operator that the steering system behaves in a reduced performance steering mode, encouraging the operator to slow down the boat or return to dock. It will be appreciated that the spring 56 also provides steering resistance and, accordingly, there may be steering resistance even when the electromagnetic coil 48 is not energized. This allows for power conservation while still having steering resistance.

[0024] The microcontroller 62 also drives the H-Bridge driver 64 to energize the electromagnetic coil 48 to actuate a stop mechanism 72, shown in FIG. 3, to brake the steering apparatus 18, i.e. to stop rotation of the steering shaft 28. Braking occurs when the rotational sensor 66 senses that the steering shaft has reached a hardstop position based on a steering angle. The stop mechanism 72 is generally comprised of the multi-plate clutch 38, shown in FIG. 2, the plates of which are urged into frictional engagement with one another by the electromagnetic actuator to restrict rotation of the steering shaft 28. In particular, the stop mechanism 72 is actuated to fully engage the steering shaft 28 to prevent rotation of the steering shaft 28 in a first rotational direction, which corresponds to movement towards the hardstop position, while allowing rotational play between the steering shaft 28 and the stop mechanism 72 in a second direction, which corresponds to rotational to rotational movement away from the hardstop position, when the sensor senses the steering shaft has reached a hardstop position.

[0025] The H-bridge driver 64 applies a reverse polarity pulse to the electromagnetic actuator when the stop mechanism 72 is fully engaged with the steering shaft 28 and the steering shaft is rotated, as permitted by the rotational play, in the second rotational direction. In this example, the H-bridge driver is a STMicroelectronics VNH2SP30-E but any suitable H-bridge driver may be used. As shown in FIGS. 4A to 4C, four switches S1, S2, S3 and S4 are integrated into the H-bridge driver 64 and are arranged as an H-bridge 74 to switch the polarity of the current going to the electromagnetic coil 48. There is a current shunt Rs, in this example, for measuring the current passing through the electromagnetic coil 48, but this is not required. In this example, the PWM to the H-bridge 74 is a signed magnitude of 20 kHz PWM. The function of the H-bridge 74 is to reduce the magnetic remanence/hysteresis effect. This results in a steering effort for a given steering PWM remaining substantially the same before and after a hardstop. In alternative examples the H-bridge 74 may have another means such as an internal current sensing sensor to measure current passing through the electromagnetic coil.

[0026] In operation, when a hardstop is reached a hardstop PWM of, for example, +100% is applied and S2 and S3 are open while S1 and S4 are closed as shown in FIG. 4A. Current flows from a 12V power source through S1 into the electromagnetic coil 48 and then through S4 to ground. When the rotational sensor 66 senses that the steering shaft 28 is being rotated away from the hardstop, as permitted by the rotational play, the microcontroller 62 drives the H-bridge driver 64 to apply a reverse polarity pulse for a fixed duration of time which is determined by the characteristics of the electromagnetic coil 48. In this example, a reverse polarity pulse is applied for approximately 15 to 20 milliseconds at a moment when steering away from the hardstop occurs. During the application of the reverse polarity pulse, S2 and S3 are closed while S1 and S4, are open as shown in FIG. 4B. A reverse polarity pulse of, for example, 100% is applied. Current flows to ground through S2, electromagnetic coil 48, S3 and then back to the 12V power source. This transition from current flowing in one polarity, as shown in FIG. 4A, to current flowing in the reverse polarity, as shown in FIG. 4B, causes the electromagnetic coil 48 current to rapidly decay as it is flowing against the full force of the power voltage supply. As steering continues away from the hardstop there is a steering PWM of, for example +10% to +20%, and S1 and S4 are closed as shown FIG. 4C. The current flows in the same direction as when the stop mechanism 72 of the steering mechanism is fully engaged but the PWM is reduced to provide a steering resistance. A reduced steering effort is accordingly required when steering away from a hardstop.

[0027] FIG. 5 illustrates the H-Bridge PWM control logic when steering away from a hardstop occurs. The top graph is a steering angle versus time plot and the bottom graph is a signed magnitude PWM versus time plot. The steering shaft 28 is at a hardstop at time to and a hardstop PWM is applied to electromagnetic coil 48 of the steering apparatus 18, causing the stop mechanism 72 to fully engage the steering shaft. At time t.sub.1 the steering shaft 28 starts to rotate away from the hardstop as permitted by the rotational play. At t.sub.2 the steering shaft has been steered an angular distance equal to a hysteresis threshold, i.e. the steering position reaches HardstopHysteresis. This triggers the beginning of the reverse polarity pulse logic in the microcontroller 62. The microcontroller 62 drives the H-bridge driver 64 to apply a PWM voltage to the electromagnetic coil that has a reverse polarity compared to the hardstop PWM. This quickly decays the current in the electromagnetic coil 48 and neutralizes the magnetic hysteresis effect in the electromagnetic coil 48. The reverse polarity pulse also reduces the mechanical hysteresis effect in the stop mechanism assembly. The reverse polarity pulse duration in the example is between 15 and 20 ms. The reverse polarity pulse ends at time t.sub.3 and the H-bridge driver applies a steering resistance PWM to the electromagnetic coil that has the same polarity as the hardstop PWM. The steering effort at time t.sub.3 will accordingly be very similar to the steering effort before the hardstop was engaged at time t.sub.0. This is a result of the reverse polarity pulse.

[0028] FIG. 6 illustrates the state diagram of the steering apparatus control logic. There are three main states, namely, a Steering State, Hardstop State, and Reverse Polarity Pulse State. In the Steering State, the microcontroller controls and varies the steering resistance by monitoring the different inputs of different sensors on the vehicle. For example, this may include inputs from the rotational sensor 66, shown in FIGS. 2 and 3, which functions as asteering position sensor and/or a vehicle speed sensor (not shown) to allow steering resistance to be correlated to vehicle speed, e.g. the higher the marine vessel speed, the higher the steering resistance. The logic enters the Hardstop State when the rotational sensor 66 senses a hardstop has been reached. The Hardstop State can be further defined into three sub-states. There is a Brake on PWM Sub-State which executes when the hardstop is reached and the microcontroller 62 drives the H-bridge driver 64 to apply the hardstop PWM. After a predetermined time T.sub.2 has elapsed, one second in this example, the logic enters the Brake Hold PWM Sub-State and the microcontroller 62 drives the H-Bridge driver 64 to apply a lower PWM to the electromagnetic coil 48. The lower PWM is such that it maintains the same braking force but draws lower current. After a predetermined time T.sub.3 has elapsed, thirty seconds in this example, the logic enters a Reduce PWM Sub-State, and the PWM is lowered further to further lower current draw and prevent the electromagnetic coil from overheating. At any given time when the Hardstop State is being executed, if the steering shaft 28 has been steered away from a hardstop and reaches a position that is equal or less than hardstop anglehysteresis angle, the logic transitions to the Reverse Polarity Pulse State. In the Reverse Polarity Pulse State, a reverse polarity pulse is applied for a fixed duration to remove the magnetic and mechanical hysteresis effect resulting from the hardstop PWM generated during the Hardstop State. The logic enters the Steering State again after a preset reverse polarity timer T.sub.1 elapsed.

[0029] It will be understood by a person skilled in the art that the steering mechanism discloses herein may be used any steered vehicle, for example, FIG. 7 shows the steering apparatus 18 disclosed herein used to steer a land vehicle in form of a truck 76.

[0030] It will also be understood by a person skilled in the art that many of the details provided above are by way of example only, and are not intended to limit the scope of the invention which is to be determined with reference to the following claims.