IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
UP-0315197
(2008-11-13)
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등록번호 |
US-7857085
(2011-02-24)
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발명자
/ 주소 |
|
인용정보 |
피인용 횟수 :
5 인용 특허 :
1 |
초록
▼
The invention describes vehicles where the steering effect of the driver-selected wheel angles is made identical to the steering effect of positively and independently driving the driven wheels. Means of delivering most of the power to each of the driven wheels by means of shaft drives is also descr
The invention describes vehicles where the steering effect of the driver-selected wheel angles is made identical to the steering effect of positively and independently driving the driven wheels. Means of delivering most of the power to each of the driven wheels by means of shaft drives is also described. Here speed-correcting differentials are close coupled to each driven wheel where the first input to the said differentials is by means of shaft drives, and the second input to the said differentials is provided by means of speed-correcting hydraulic or electric motors.
대표청구항
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The invention claimed is: 1. A vehicle comprising four or more wheels, at least two of which are driven wheels and at least two of which is steerable, where the axes of rotation of all wheels lie substantially in the same horizontal plane, and where the steerable wheels are turnable about substanti
The invention claimed is: 1. A vehicle comprising four or more wheels, at least two of which are driven wheels and at least two of which is steerable, where the axes of rotation of all wheels lie substantially in the same horizontal plane, and where the steerable wheels are turnable about substantially vertical axes by means of hydraulic or electric actuators, where the speed of each driven wheel is controlled by means of a speed-correcting differential which is close-coupled to each driven wheel, where the first input to the said differential is from an engine via a main gear box and a series of right angle drives, and the second input to the said speed correcting differential is provided by means of a speed correcting electric or hydraulic motor which is close coupled to the said differential, where the speed of each driven wheel is determined by the speed of the first input, which will be the same for all driven wheels, and the speed and direction of rotation of the speed correcting electric or hydraulic motor, where the speeds of the driven wheels are independently and positively controlled so that they tend to produce a single centre of curvature for the path of the vehicle, and where all the wheel angles are positively controlled to produce a single driver-selected centre of curvature for the path of the vehicle, and where the driven wheel speeds and all the wheel angles are integrated so that the first centre of curvature is made identical to the second centre of curvature which is selected by the driver. 2. A vehicle according to claim 1 where each speed correcting hydraulic motor is singly connected in series to a variable displacement pump. 3. A vehicle according to claim 1 where each speed correcting gear box which is close coupled to a driven wheel, is incorporated into a speed reduction gear box which is also close coupled to each driven wheel. 4. A vehicle according to claim 1 wherein: The driver selects the centre of curvature for the path of the vehicle with a rotatable joystick, where the line on which the said centre of curvature lies is at right angles to the direction of displacement of the joystick, and the position of the said centre of curvature on this line is determined by the rotation of the joystick from its null position, and the root mean square wheel speed for all wheels and their direction of rotation is determined by the amount of displacement of the joystick from its null position. 5. A vehicle according to claim 1 wherein: The driver selects the centre of curvature for the path of the vehicle with two joysticks, where the line on which the said centre of curvature lies is at right angles to the direction of displacement of the second joystick, and the position of the said centre of curvature on this line is determined by the sideways displacement of the first joystick from its null position, and the root mean square wheel speed for all wheels and their direction of rotation is determined by the amount of displacement of the first joystick from its null position. 6. A vehicle according to claim 1 wherein: The driver selects the centre of curvature for the path of the vehicle with a steering wheel and a single joystick, where the line on which the said centre of curvature lies is at right angles to the direction of displacement of the single joystick, and the position of the said centre of curvature on this line is determined by the rotation of the steering wheel from its null position, and the root mean square wheel speed for all wheels and their direction of rotation is determined by the amount of displacement of the single joystick from its null position. 7. A vehicle according to claim 4 comprising four rectangularly arranged wheels, where all wheels are both driven and steered wherein a control system adjusts the rotational velocity and steering angle of each said wheel according to the following equations: R/t=cot(90° θ/θmax)=(RX2+RY2)1/2/t; tan ψ−RY/RX; RY=R/(tan2ψ+1)1/2=R sin Ψ; RX=R tan ψ/(tan2ψ+1)1/2=R cos Ψ; tan φ1=(b/2−RY)/(Rx−t/2); tan φ2=(b/2−RY)/(RX−t/2); tan φ3=(b/2−RY)/(RX−t/2); tan φ4=(b/2−RY)/(RX−t/2); ω1=KdR1/RMSR where R12=(b/2−RY)2+(RX−t/2)2; ω2=KdR2/RMSR where R22=(b/2−RY)2+(RX−t/2)2; ω3=KdR3/RMSR where R32=(b/2−RY)2+(RX−t/2)2; ω4=KdR4/RMSR where R42=(b/2−RY)2+(RX−t/2)2; Where RMSR is the root mean square radius which is given by the equation: RMSR=(R12+R22+R32+R42)1/2/2=(RX2+RY2+t2/4+b2/4)1/2; and RMSWS is the root mean square wheel speed which is given by the equation: RMSWS=Kd=(ω12+ω22+ω32+ω42)1/2/2; where ω1 and φ1 are the rotational velocity and the steering angle (clockwise positive) of the front right hand wheel respectively ω2 and φ2 are the rotational velocity and the steering angle (clockwise positive) of the front left hand wheel respectively ω3 and φ3 are the rotational velocity and the steering angle (anticlockwise positive) of the rear right hand wheel respectively ω4 and φ4 are the rotational velocity and the steering angle (anticlockwise positive) of the rear left hand wheel respectively R is the radius of curvature of the path of the vehicle RX is the distance of the centre of curvature of the path of the vehicle to the right of the vehicle centre RY is the distance of the centre of curvature of the path of the vehicle forward of the vehicle centre b is the wheel base of the vehicle t is the track of the vehicle R1, R2, R3, and R4 are the distances of the front right hand wheel, the front left hand wheel, the rear right hand wheel and the rear left hand wheel respectively from the centre of curvature of the path of the vehicle d is the displacement of the joy stick, where the centre of curvature of the path of the vehicle is at right angles to the direction of displacement of the joystick ψ is the angle of displacement of the joystick to the left of the straight ahead position K is a suitable constant θ is the angle of rotation of the joystick, and θmax is the maximum angle of rotation of the joystick. 8. A vehicle according to claim 5 comprising four rectangularly arranged wheels, where all wheels are both driven and steered wherein a control system adjusts the rotational velocity and steering angle of each said wheel according to the following equations: R/t=cot(90° θ/θmax)=(RX2+RY2)1/2/t; tan ψ−RY/RX; RY=R/(tan2ψ+1)1/2=R sin Ψ; RX=R tan ψ/(tan2ψ+1)1/2=R cos Ψ; tan φ1=(b/2−RY)/(Rx−t/2); tan φ2=(b/2−RY)/(RX−t/2); tan φ3=(b/2−RY)/(RX−t/2); tan φ4=(b/2−RY)/(RX−t/2); ω1=KdR1/RMSR where R12=(b/2−RY)2+(RX−t/2)2; ω2=KdR2/RMSR where R22=(b/2−RY)2+(RX−t/2)2; ω3=KdR3/RMSR where R32=(b/2−RY)2+(RX−t/2)2; ω4=KdR4/RMSR where R42=(b/2−RY)2+(RX−t/2)2; Where RMSR is the root mean square radius which is given by the equation: RMSR=(R12+R22+R32+R42)1/2/2=(RX2+RY2+t2/4+b2/4)1/2; and RMSWS is the root mean square wheel speed which is given by the equation: RMSWS=Kd=(ω12+ω22+ω32+ω42)1/2/2; where ω1 and φ1 are the rotational velocity and the steering angle (clockwise positive) of the front right hand wheel respectively ω2 and φ2 are the rotational velocity and the steering angle (clockwise positive) of the front left hand wheel respectively ω3 and φ3 are the rotational velocity and the steering angle (anticlockwise positive) of the rear right hand wheel respectively ω4 and φ4 are the rotational velocity and the steering angle (anticlockwise positive) of the rear left hand wheel respectively R is the radius of curvature of the path of the vehicle RX is the distance of the centre of curvature of the path of the vehicle to the right of the vehicle centre RY is the distance of the centre of curvature of the path of the vehicle forward of the vehicle centre b is the wheel base of the vehicle t is the track of the vehicle R1, R2, R3, and R4 are the distances of the front right hand wheel, the front left hand wheel, the rear right hand wheel and the rear left hand wheel respectively from the centre of curvature of the path of the vehicle d is the forward or backward displacement of the first joy stick, where the centre of curvature of the path of the vehicle is at right angles to the direction of displacement of the second joystick ψ is the angle of displacement of the second joystick to the left of the straight ahead position K is a suitable constant θ is the sideways displacement of the first joystick, and θmax is the maximum sideways displacement of the first joystick. 9. A vehicle according to claim 6 comprising four rectangularly arranged wheels, where all wheels are both driven and steered wherein a control system adjusts the rotational velocity and steering angle of each said wheel according to the following equations: R/t=cot(90° θ/θmax)=(RX2+RY2)1/2/t; tan ψ−RY/RX; RY=R/(tan2ψ+1)1/2=R sin Ψ; RX=R tan ψ/(tan2ψ+1)1/2=R cos Ψ; tan φ1=(b/2−RY)/(Rx−t/2); tan φ2=(b/2−RY)/(RX−t/2); tan φ3=(b/2−RY)/(RX−t/2); tan φ4=(b/2−RY)/(RX−t/2); ω1=KdR1/RMSR where R12=(b/2−RY)2+(RX−t/2)2; ω2=KdR2/RMSR where R22=(b/2−RY)2+(RX−t/2)2; ω3=KdR3/RMSR where R32=(b/2−RY)2+(RX−t/2)2; ω4=KdR4/RMSR where R42=(b/2−RY)2+(RX−t/2)2; Where RMSR is the root mean square radius which is given by the equation: RMSR=(R12+R22+R32+R42)1/2/2=(RX2+RY2+t2/4+b2/4)1/2; and RMSWS is the root mean square wheel speed which is given by the equation: RMSWS=Kd=(ω12+ω22+ω32+ω42)1/2/2; where ω1 and φ1 are the rotational velocity and the steering angle (clockwise positive) of the front right hand wheel respectively ω2 and φ2 are the rotational velocity and the steering angle (clockwise positive) of the front left hand wheel respectively ω3 and φ3 are the rotational velocity and the steering angle (anticlockwise positive) of the rear right hand wheel respectively ω4 and φ4 are the rotational velocity and the steering angle (anticlockwise positive) of the rear left hand wheel respectively R is the radius of curvature of the path of the vehicle RX is the distance of the centre of curvature of the path of the vehicle to the right of the vehicle centre RY is the distance of the centre of curvature of the path of the vehicle forward of the vehicle centre b is the wheel base of the vehicle t is the track of the vehicle R1, R2, R3, and R4 and are the distances of the front right hand wheel, the front left hand wheel, the rear right hand wheel and the rear left hand wheel respectively from the centre of curvature of the path of the vehicle d is the amount of displacement of the single joy stick, where the centre of curvature of the path of the vehicle is at right angles to the direction of displacement of the single joystick ψ is the angle of displacement of the single joystick to the left of the straight ahead position K is a suitable constant θ is the rotation of the steering wheel from its null position, and θmax is the maximum rotation of the steering wheel from its null position. 10. A vehicle according to claim 1 comprising four rectangularly arranged wheels, where all wheels are both driven and the front wheels are steered wherein a control system adjusts the rotational velocity and steering angle of each said wheel according to the following equations: RX/t=cot(90° θ/θmax) RY=−b/2 and ψ=0 so that: tan φ1=b/(Rx−t/2); tan φ2=b/(RX+t/2); tan φ3=tan φ1=0; ω1=KdR1/RMSR where R12=b2+(RX−t/2)2; ω2=KdR2/RMSR where R22=b2+(RX−t/2)2; ω3=KdR3/RMSR where R32=b2+(RX−t/2)2; ω4=KdR4/RMSR where R42=b2+(RX−t/2)2; Where RMSR is the root mean square radius which is given by the equation: RMSR=(R12+R22+R32+R42)1/2/2=(RX2+t2/4+b2/2)1/2; and RMSWS is the root mean square wheel speed which is given by the equation: RMSWS=Kd=(ω12+ω22+ω32+ω42)1/2/2; where ω1 and φ1 are the rotational velocity and the steering angle (clockwise positive) of the front right hand wheel respectively ω2 and φ2 are the rotational velocity and the steering angle (clockwise positive) of the front left hand wheel respectively ω3 and φ3 are the rotational velocity and the steering angle (anticlockwise positive) of the rear right hand wheel respectively ω4 and φ4 are the rotational velocity and the steering angle (anticlockwise positive) of the rear left hand wheel respectively R is the radius of curvature of the path of the vehicle RX is the distance of the centre of curvature of the path of the vehicle to the right of the vehicle centre RY=−b/2 and is the distance of the centre of curvature of the path of the vehicle forward of the vehicle centre b is the wheel base of the vehicle t is the track of the vehicle R1, R2, R3, and R4 are the distances of the front right hand wheel, the front left hand wheel, the rear right hand wheel and the rear left hand wheel respectively from the centre of curvature of the path of the vehicle d is the amount of displacement of the single joy stick, which now becomes a single lever K is a suitable constant θ is the rotation of the steering wheel from its null position, and θmax is the maximum rotation of the steering wheel from its null position. 11. A vehicle according to claim 10 where each speed correcting hydraulic motor is singly connected in series to a variable displacement pump. 12. A vehicle according to claim 10 where all speed correcting hydraulic motors are connected in series to a single variable displacement pump. 13. A vehicle according to claim 1 comprising six wheels, four of which not steerable and are located on the same axis and are independently driven, and two wheels are steerable but not driven. 14. A vehicle according to claim 13 where each speed correcting hydraulic motor is singly connected in series to a variable displacement pump. 15. A vehicle according to claim 13 where all speed correcting hydraulic motors are connected in series to a single variable displacement pump. 16. A vehicle according to claim 13 where the driver interface comprises a steering wheel and a speed control lever or pedal. 17. A vehicle according to claim 14 where the driver interface comprises a steering wheel and a speed control lever or pedal. 18. A vehicle according to claim 15 where the driver interface comprises a steering wheel and a speed control lever or pedal. 19. A vehicle according to claim 1 where the centre of curvature selected by the driver must lie on the transverse axis of the vehicle. 20. A vehicle according to claim 3 where the centre of curvature selected by the driver must lie on the transverse axis of the vehicle.
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