Abstract: A steering apparatus includes an axle housing rotatably supporting a wheel hub on which a steered road wheel is installed, and a lower suspension-system control arm adapted to be oscillatingly supported at one end on a vehicle body and having a turning portion provided at the other end for pivotably supporting the axle housing by the turning portion. An electric motor is installed on the lower arm for turning the axle housing by a driving force produced by the motor. A rotation axis of the motor and a pivot of the axle housing are arranged to be offset from each other.

Abstract: A steering system for an industrial vehicle includes a drive wheel configured to steerably align with a first radius of curvature. The steering system further includes an electronically controlled idler wheel configured to steerably align with a second radius of curvature different than the first radius of curvature. The first and second radii of curvature share a common center point of turning radius. A controller is configured to command the electronically controlled idler wheel to steerably align with the second radius of curvature according to a determination of the first radius of curvature.

Abstract: 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.

Abstract: A materials handling vehicle is provided comprising: a frame comprising an operator's compartment; wheels supported on the frame, at least one of the wheels being a steerable wheel; a steer-by-wire system and control apparatus. The steer-by-wire system is associated with the steerable wheel to effect angular movement of the steerable wheel about a first axis.

Abstract: The present invention discloses a transmission and steering system of a double-head vehicle, comprising a first steering wheel; a front wheel group; a first signal acquisition and transceiver device which can output steering information according to the steering angle of the first steering wheel; a first motor group; a second signal acquisition and transceiver device which can receive the steering information output from the first signal acquisition and transceiver device; a rear wheel group; and a second motor group; such that through the aforementioned structure, when the first steering wheel is turned, the first motor group may be controlled by the first steering wheel to drive the front wheel group to turn and in the mean time, the second signal acquisition and transceiver device may receive the steering information and transmit it to the second motor group to drive the rear wheel group.

Abstract: A steering system (10) for a vehicle, such as a gantry crane (12). The gantry crane (12) generally includes a support structure (14) having a first front wheel (32) and a second opposing front wheel (36) connected proximate a front portion of the crane (12), and a first rear wheel (30) and a second opposing rear wheel (34) connected proximate a rear portion of the crane (12). A control system connected to the crane includes a user interface (111) electronically coupled to a command potentiometer (114) and a programmable controller responsive to the command potentiometer for controlling the angular position of each of the first front wheel (32), the second front wheel (36), the first rear wheel (30) and the second rear wheel (34) to effect a steering mode selected through the user interface (111).

Abstract: A control system for controlling a safety system of an automotive vehicle having a transmission and a differential. The system includes left and right wheel speed sensors associated with respective vehicle wheels and generating left and right wheel speed signals, and a transmission output shaft speed sensor generating a transmission output shaft speed signal. A controller is coupled to the wheel speed sensors and the transmission output speed sensor, and determines a reference wheel speed for one of the left or right wheels as a function of the other of the left or right wheel speed signal and the transmission output shaft speed signal. The controller controls the safety system in response to the determined reference wheel speed.

Abstract: A steering control device can shorten a braking distance during straight-traveling deceleration and can efficiently acquire the acceleration performance during straight-traveling acceleration with a simple control while maintaining the stability of a vehicle by steering the wheel on a higher road surface friction coefficient road side with a predetermined steering angle when either one of the straight-traveling braking state and the straight-traveling acceleration state of the vehicle is detected.

Abstract: A torque control element for a steering system in a motor vehicle, and such a steering system are provided. The torque control element includes at least two electrical units, each of the electrical units being assigned a separate power supply unit, connected via at least one fuse.

Abstract: A steering system for steering a machine having opposing first and second sides with first and second pairs of rotatably mounted rear wheels disposed along the respective sides and at least one rotatably mounted, spaced front wheel. The system includes at least one first drive unit and at least one second drive unit for rotating the rear wheels of the respective pairs, and a steering input device that provides a signal to a controller that produces drive unit request signals to control the drive units to rotate the associated rear wheels along one side at rotational speeds greater than those along the other side to facilitate turning.

Abstract: The present invention refers to a high tonnage ultra light mining truck with a greater load efficiency for off-road applications that, in addition to the body, comprises a lightweight curved dump body and a knuckle joined lightweight power and traction system, a steering system, and a lateral suspension and tipping system for the lightweight curved dump body. The truck of the present invention has a payload capacity up to three times greater than that of similar trucks of the prior art.

Abstract: An apparatus (10) for use in turning steerable wheels of a vehicle (12) upon manual rotation of a steering wheel (14) comprises a front steering motor (36) coupled to a front steerable wheel (18) of the vehicle (12) for turning the front steerable wheel. A rear steering motor (66) is coupled to a rear steerable wheel (22) of the vehicle (12) for turning the rear steerable wheel. A position sensor (34) senses a rotational position of the steering wheel (14) and provides an output indicative of said rotational position. A controller (90) receives the output of the position sensor (34) and controls the front and rear steering motors (36, 66) to turn the front steerable wheel (22) in response to the output from the position sensor (34) indicating rotation of the steering wheel (14) in a first portion of a range of rotation of the steering wheel.

Abstract: A steering drive for a steeled wheel of an industrial truck, particularly a rear wheel of a three-wheeled industrial truck, comprising a steering bolster supporting the rear wheel which is supported to be pivotable about a vertical steering axle inside the flame of the industrial truck, a steeling motor coaxial with the steering axle, a bearing assembly between the flame of the industrial truck and the bolster, and a steering transmission between the steering motor and bolster, wherein the steering transmission has a single-stage or multi-stage stepped planetary mechanism or planetary coupler mechanism which is coaxial with the steering axle and the bearing assembly for the bolster is arranged within the steering transmission.

Abstract: A steering mechanism for a wheel of a self-propelled vehicle includes a wheel spindle on which the wheel is rotatably mounted, a steering motor turning a steering tube defining a generally vertical steer axis, a propulsion drive motor turning a propulsion drive shaft extending through the steering tube, and a plurality of gears providing a gear reduction ratio between the propulsion drive motor and the wheel. The wheel is offset from the steer axis and rotates on the wheel spindle if the steering motor turns the steering tube while the propulsion drive shaft is stationary.

Abstract: Methods and apparatus are provided for automatically determining the steering system calibration of a vehicle in accordance with vehicle loading. The apparatus comprises a combination of a load monitor and a steering controller. The load monitor senses the actual loading of the vehicle and provides a corresponding feedback signal to the steering controller. The steering controller determines a steering calibration appropriate for the load represented by the feedback signal. As a result, the handling performance of the vehicle can be improved over that of a single, fixed steering calibration for a wide range of load conditions.

Abstract: A steering and driving system (1, 53, 54) for an industrial truck with a driving engine (2), a driving transmission (21), a steering engine (4) and a steering transmission (5, 32, 32?), through that one rotor (23) arranged on a wheel hub (22) could be driven and is swivelable at a vertical axis (V). For the realization of the compact design form as well as lesser manufacturing costs for this steering and driving system is considered, that the driving engine (2), the steering engine (4) and the steering transmission (5, 32, 32?) are arranged co-axially to each other.

Abstract: A front steering gear (18) is connected with steerable front wheels (12 and 14) of a vehicle (10). A rear steering gear (28) is connected with steerable rear wheels (30 and 32) of the vehicle (10). A torque sensor (40) connected with a steering wheel (16) provides an output to a controller (42). The controller (42) effects operation of the rear steering gear (28) in response to an output of the torque sensor (40) corresponding to manual application of at least a predetermined force to the steering wheel (16). Alternatively or in addition, the controller (42) may effect operation of a rear wheel brake (50 or 52) which is disposed on a radially inner side of a turn in response to the output from the torque sensor (40).

Abstract: A steering system (10) for a vehicle, such as a gantry crane (12). The gantry crane (12) generally includes a support structure (14) having a first front wheel (32) and a second opposing front wheel (36) connected proximate a front portion of the crane (12), and a first rear wheel (30) and a second opposing rear wheel (34) connected proximate a rear portion of the crane (12). A control system connected to the crane includes a user interface (111) electronically coupled to a command potentiometer (114) and a programmable controller responsive to the command potentiometer for controlling the angular position of each of the first front wheel (32), the second front wheel (36), the first rear wheel (30) and the second rear wheel (34) to effect a steering mode selected through the user interface (111).

Abstract: A control device capable of moving a vehicle in a direction with an angle larger than at least the maximum steering angle of wheels. When the wheels (2) are brought into a parallel movement arrangement as shown in FIG. 3(a) and rotatingly driven according to the depressed amount of an accelerator pedal (53), the wheels (2) are slippingly moved on a road surface. Thus, while the vehicle forward component of a drive force generated by the right and left front wheels (2FR) and (2FL) and the vehicle rearward component of a drive force generated by the right and left rear wheels (2RR) and (2RL) balance each other out, the vehicle rightward component of a drive force generated by the right and left front wheels (2FR) and (2FL) and the vehicle rightward component of a drive force generated by the right and left rear wheels (2RR) and (2RL) act as a drive force for moving the vehicle (1) rightward. As a result, the vehicle (1) can be moved, in parallel, in the right side direction of the vehicle.

Abstract: A steering apparatus for steering wheels (1) of a vehicle (2) comprises support means (4) arranged for supporting said wheels (1), driving means (27) arranged for rotating said support means (4) around respective longitudinal axis means (Z) and connecting means arranged for connecting said driving means (27) with said support means (4), said connecting means comprising transmission gear means (26); a vehicle comprises steered wheel means (1) and steering means (3) arranged for controlling said steered wheel means (1), said steering means (3) comprising support means (4) arranged for supporting said steered wheel means (1), driving means (27) arranged for rotating said support means (4) around respective longitudinal axis means (Z) and connecting means arranged for connecting said driving means (27) with said support means (4) , said connecting means comprising transmission gear means (26).

Abstract: A steering system (10) for a vehicle, such as a gantry crane (12). The gantry crane (12) generally includes a support structure (14) having a first front wheel (32) and a second opposing front wheel (36) connected proximate a front portion of the crane (12), and a first rear wheel (30) and a second opposing rear wheel (34) connected proximate a rear portion of the crane (12). A control system connected to the crane includes a user interface (111) electronically coupled to a command potentiometer (114) and a programmable controller responsive to the command potentiometer for controlling the angular position of each of the first front wheel (32), the second front wheel (36), the first rear wheel (30) and the second rear wheel (34) to effect a steering mode selected through the user interface (111).

Abstract: An electrically actuated, hydraulic power steering system is provided. The steering system includes a hydraulic pump for generating hydraulic pressure, a hydraulic fluid reservoir, a hydraulic cylinder, and a control valve arrangement that selectively connects the hydraulic cylinder to the pump and the hydraulic fluid reservoir. The control valve arrangement is characterized during the on-center position by a first and a second chamber of the hydraulic cylinder being in fluid communication with each other but not with the fluid reservoir. In one embodiment, the steering system has a steering sensor, a control box, and two pressure accumulators for providing at least two levels of steering assist.

Abstract: 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. A method of compensating for the linear portions of the slip angles of all wheels and the linear portions of the longitudinal slip of the driven wheels is described where the slip angles and longitudinal slips are deduced from the forces acting on the wheels. Methods of measuring the slip angles and longitudinal slips of all wheels by means of two dummy castors are also described. Vehicles where the steering effect of the driver-selected wheel angles is made identical to the steering effect of positively and independently braking all wheels are also described. Means of applying the above principles to vehicles with either hydrostatic or mechanical drives are also described, including simplified vehicles with only two steerable wheels.

Abstract: An industrial truck has a steering axle with two axle tree bolster systems located at a lateral distance from each other. Each system has an axle body with an axle shaft (1) and an axle tree bolster (2) located on the lower end of the axle shaft (1). The axle tree bolster (2) and the axle shaft (1) are individual components that are connected with each other. The axle tree bolster (2) is preferably detachably fastened to the axle shaft (1). The rotational position of the axle tree bolster (2) relative to the axle shaft (1) can be adjustable. Means can also be provided for the positive and/or non-positive transmission of a torque from the axle shaft (1) to the axle tree bolsters (2).

Abstract: Steering logic for a self-propelled vehicle having a plurality of wheels includes the steps of receiving translational velocity and angular velocity commands, determining the resultant velocity and steer angle of each wheel, and determining the wheel offset correction for each wheel based on the scrub radius of each wheel and the angular velocity command.

Abstract: An automatic parking control is cancelled when a motor current has not yet reached a maximum current value Imax with a steering angle deviation exceeding a deviation threshold value. In addition, the automatic parking control is cancelled when a steering speed has not yet reached a maximum steering speed with a state where the motor current has reached and remains at the maximum steering speed continuing over a first time period. On the other hand, when a state where the steering speed has reached and remains at the maximum steering speed continues over a second time period, it is determined that there occurs an output shortage of a steering actuator, an automatic parking condition is recalculated, so as to allow the automatic parking continue to continue.

Abstract: A power transfer system is constituted under a simple construction (a worm gear, transfer rod integrally installed with a worm sector gear, and lower control arm), thereby improving the efficiency of the power transfer of the toe-angle controlling mechanism for vehicle wheels. The worm gear and worm sector gear are closed in a cover part of a housing, acquiring the durability and reliability of the toe-angle controlling mechanism for the vehicle wheels. The toe angle is prevented from being varied according to the exterior force transmitted from the vehicle wheel, by a unique characteristic (no inverse-transfer power) of the worm gear and worm sector gear, thus improving the vehicle stability.

Abstract: A forklift apparatus with improved all-wheel steering includes: a chassis; a plurality of wheels; at least one motor; a plurality of idler pulleys; a plurality a traction belts; and a plurality of actuators. The plurality of wheels supports the chassis from a ground surface and steer the chassis on the ground surface. The at least one motor is operatively connected to at least one of the wheels to rotate the wheel about a horizontal axis. Each wheel is rotationally mounted to the chassis about a vertical axis. Each wheel has a drive pulley oriented horizontally above the wheel and centered on the axis and connected to rotate with the wheel about the vertical axis. Each idler pulley is rotationally mounted to the chassis about a vertical axis and spaced from one of the drive pulleys. Each traction belt is wrapped around one pair comprising an idler pulley and a drive pulley.

Abstract: A loader type construction vehicle includes a chassis having a longitudinal axis, a plurality of wheeled ground-engaging structures pivotally coupled to the chassis, and a steering control system. Each of the plurality of ground-engaging structures includes a wheel pivotable about a steering axis and drivable about a drive axis, wherein each of the wheeled ground-engaging structures is shaped and configured so that the wheel of each of the ground-engaging structures can be pivoted from a first angular position in which the drive axis is perpendicular to the longitudinal axis, to a second angular position that is at least 90° degrees from the first angular position. The steering control system is operatively connected to each of the ground engaging structures for pivoting the wheel of each of the ground-engaging structures about the steering axis.

Abstract: Methods and apparatus for steering a vehicle are disclosed. A vehicle in accordance with an exemplary embodiment of the present invention is capable of operating in a first steering mode and a second steering mode. The vehicle may comprise an input device capable of providing an input signal indicating that operation in the second steering mode is desired. The vehicle may comprise an electronic control unit (ECU) capable of providing an enabling signal when the ECU determines that operation in the second steering mode is appropriate for the present riding conditions.

Abstract: The present invention refers to a high tonnage ultra light mining truck with a greater load efficiency for off-road applications that, in addition to the body, comprises a lightweight curved dump body and a knuckle joined lightweight power and traction system, a steering system, and a lateral suspension and tipping system for the lightweight curved dump body. The truck of the present invention has a payload capacity up to three times greater than that of similar trucks of the prior art.

Abstract: A vehicle is provided having a steering system for selectively operating the vehicle in a zero-steer configuration. The system includes a forward steering assembly coupled to a steering wheel and a forward set of wheels. The forward steering assembly is arranged to receive an input from the steering wheel and includes a selectively actuateable forward motorized mechanism. A rear steering assembly is coupled to a rear set of wheels and includes a rearward motorized mechanism. Upon selective activation, the forward motorized mechanism is arranged to engage the forward steering assembly and rotate the forward set of wheels toward a centerline of the vehicle and the rearward motorized mechanism is arranged to engage the rearward steering assembly and rotate the rearward set of wheels toward the vehicle centerline such that the wheels are positioned to allow the vehicle to turn about a central point of the vehicle in a zero-steer configuration.

Abstract: A method for implementing anti-static steering for vehicle steering systems includes receiving a desired rear wheel angle input and receiving a vehicle speed input. An approved rear wheel angle output is generated using the desired rear wheel angle input and the vehicle speed input, wherein the approved rear wheel angle is based upon one of a plurality of defined operating states, the plurality of operating states including operation at a speed in a first range, operation at a speed in a second range, and transitions therebetween.

Abstract: There are two basic methods of steering a wheeled vehicle. One method is to turn one or more steerable wheels. The other is to drive one or more left hand wheels independently of one or more right hand wheels. Traditional vehicles address the potential conflict between the two steering systems by either disabling one system or by causing one to overpower the other. This leads to skidding or scuffing problems respectively. In the present invention both steering systems are enabled but are integrated by means of an on board computer so that they always act in unison. This mutual reinforcement will allow the invention to operate safely on steep or slippery slopes while minimizing fuel consumption and ground damage. The invention will also be more maneuverable than traditional vehicles since it is capable of both pure rotation and pure translation or any combination of rotation and translation.

Abstract: There is provided a support system for a forklift power train, having little vibration transmission to a body frame, but capable of effectively suppressing movement of the power train against even a quick movement of a vehicle occurred in such a case as when the vehicle is accelerated, decelerated, turned or the like, and simpler in construction for assembling workability. In the support structure for a power train of a forklift having a counterweight in the rear part of the body frame, while a front side support is provided at one location positioned at a differential gear case or a frame side cross member and in the vicinity of the roll axis of the power train, a rear side support is provided at two locations, on the right and left sides of the roll axis of the power train, respectively, in the rear part of the body frame, thereby supporting the power train at three locations in all.

Abstract: An improved system for achieving optimum steering angles for wheels incorporates a sensor which senses the steering angle of a first wheel. The sensed angle is sent to a control which then determines the optimum angle for the other steered wheel based upon known formulas. The optimum angle is determined, and an adjustment structure associated with the tie rod then drives the second wheel to achieve the optimum steered angle.

Abstract: A steering actuator of an independent type steer-by-wire system comprises a housing fixed to a vehicle body and an ultrasonic motor. The ultrasonic motor has a stator internally fixed to the housing and a rotator rotating relative to the stator when an electric current is applied. A steering rod having a first end and a second end penetrates through a center portion of the ultrasonic motor. The first end of the steering rod extends out of the housing for connection to a tie rod. In one embodiment, a ring gear, planetary gears, sun gear and/or racks formed at the steering rod are operably associated with converting rotating movement of the ultrasonic motor into linear movement of the steering rod. In another embodiment, a rotator ring, a plurality of pinions, worm gears and a plurality of racks formed at the steering rod are operably associated with converting rotating movement of the ultrasonic motor into linear movement of the steering rod.

Abstract: Steering angle is determined by the combined use of a potentiometer and a rotary encoder, and the correction of the error in the determination of the steering angle based on the time-dependent change of the potentiometer.

Abstract: A steering apparatus (10) for turning steerable wheels of a vehicle having first and second sets (14 and 16) of steerable wheels comprises a first steering gear (22) actuatable, in response to rotation of a handwheel (110), to effect turning of the first set (14) of steerable wheels. The steering apparatus (10) also comprises second and third steering gears (24 and 26), each of which is independently actuatable to effect turning of the second set (16) of steerable wheels and thereby providing redundancy for turning of the second set (16) of steerable wheels. A sensor (112) senses a steering position of the first set (14) of steerable wheels and provides a steering signal indicative of the sensed steering position. A controller (114) receives the steering signal and, in response to the steering signal, controls actuation of the second and third steering gears (24 and 26).

Abstract: A steer-by-wire system for a vehicle that provides synchronization capability to an actuator of a steerable device and an actuator of a steering input device includes a steering input device actuator operably connected to the steering input device of the vehicle and a steerable device actuator operably connected to the steerable device of the vehicle. The steerable device actuator is disposed in electronic communication with the steering input device actuator. The electronic communication is defined such that synchronous positioning of the steering input device actuator and the steerable device actuator can be effectuated by the system upon startup of the vehicle. A method of using the system includes initiating operation of the system by turning on an ignition switch of the vehicle and evaluating an initial condition of the vehicle. The initial condition is associated to the positions of the steering input device actuator and the steerable device actuator.

Abstract: A vehicle body (2) is provided with a pair of right and left front wheels (3) and a pair of right and left rear wheels (4), these wheels being adapted to be turned through 90 degrees. The front wheels (3) are attached to turning members (24) installed on the vehicle body (2) for turning around vertical axes (23), and turning means (40) are installed for turning the turning members (24). The front wheels (3) are operatively connected to travel drive means (30) respectively attached to the turning members (24). The travel drive means (30) extend rearward from the inner sides of the front wheels (3). Masts (6) are installed on the front end of the vehicle body (2), and forks (13) are installed on the masts (6). The front wheels are of the type in which they can be steered to turn sideways. And the travel drive means do not require the masts to be positioned more forwardly of the front wheels than necessary and the longitudinal balance can be satisfactorily maintained without increasing the self-weight.

Abstract: A vehicle control system that selectively provides rear-wheel steering to prevent a vehicle-trailer from jackknifing during a back-up maneuver. The system senses a steering angle of the vehicle, a speed of the vehicle and a hitch angle between the vehicle and the trailer. The system calculates an equilibrium hitch angle that is a steady-state hitch angle position based on the steering angle and the vehicle speed, and a pseudo-equilibrium hitch angle that is a steady-state hitch angle at a maximum rear-wheel steering input based on the steering angle and the vehicle speed. The system then determines whether the rear-wheel steering should be provided based on a predetermined relationship between the sensed hitch angle, the equilibrium hitch angle and the pseudo-equilibrium hitch angle.

Abstract: A vehicle includes a chassis supporting two front axle assemblies and two rear axle assemblies. Each of the front and rear axle assemblies includes an extendible and retractable axle supporting an independently steerable wheel and a steering mechanism. The axles of the respective front and rear axle assemblies are offset from each other. By providing independently steerable wheels, the vehicle is operable in a plurality of steering modes including two-wheel steer, crab steer and coordinated steer. A steering angle for each steering wheel is determined according to a steering angle of an inside front wheel on a turn-by-turn basis.

Abstract: A method directed to improving the stability of a motor vehicle having front and rear steering capabilities includes determining a coefficient of friction of the road surface with which the motor vehicle is engaged and adjusting a phase gain function of a rear steering mechanism to compensate for the steerability of the motor vehicle over the road surface. A system for improving the stability of a motor vehicle having front and rear steering capabilities includes a control unit, a front steering mechanism in informational communication with the control unit, and a rear steering mechanism in informational communication with the control unit. The rear steering mechanism is responsive through the control unit to road conditions of the road surface.

Abstract: A working vehicle with a transverse system, wherein when a traveling mode is switched to transverse traveling, a switching valve is switched to feed a full flow of pressure oil from a hydraulic pump to a flow divider. The flow divider controls the flow to allow a specified amount of flow to flow to a control valve for a hydraulic operating device. The control valve controls only the pressure oil required for steering to allow oil to flow to the hydraulic operating device so as to operate a hydraulic operating device to rotate both swing members about a vertical axis, thereby to steer both front wheels through 90 degrees. After both front wheels are steered, the vehicle can run transversely in lateral directions by controllably rotating both front wheels.

Abstract: A vehicle includes a chassis supporting two front axle assemblies and two rear axle assemblies. Each of the front and rear axle assemblies includes an extendible and retractable axle supporting an independently steerable wheel and a steering mechanism. The axles of the respective front and rear axle assemblies are offset from each other. By providing independently steerable wheels, the vehicle is operable in a plurality of steering modes including two-wheel steer, crab steer and coordinated steer. A steering angle for each steering wheel is determined according to a steering angle of an inside front wheel on a turn-by-turn basis.

Abstract: Front wheels and rear wheels are mounted to a vehicle body to be steerable by 90 degrees. Right and left front wheels are connected to the turning members which are capable of rotating around vertical axes in relation to the vehicle body though individual electric drive motors. Each electric motor has an external casing integrally formed with each turning member, and allows a drive shaft and a rotor to be accommodated and rotatable therein. Each drive shaft is connected to the front wheel, and an apparatus for rotating the turning member is provided. This allows the driving front wheels to be steered straight sideways and the electric motor to be readily assembled and arranged compact.

Abstract: A fork lift with a laterally travelling system, wherein when a running mode is switched from a normal running in which right and left front wheels and rear wheels face in a longitudinal direction to a lateral running, rotating means is operated to rotate a turning member about a vertical axis in order to change the direction of the front wheels relative to that of a vehicle body, a change in running direction can be performed smoothly because the front wheels are formed integrally with a running drive device, and the front wheels are driven in forward and reverse directions by the running drive device after the front wheels are turned to face sideways so that a fork lift can run laterally and the rear wheels can be changed in direction in a follow-up manner by a turning caster system or can be changed in direction forcibly in the same manner as the front wheels, whereby the wheels of a drive system, though the fork lift is of a type capable of performing a normal forking operation, can be steered to face side

Abstract: A method and apparatus for controlling the steering of an automatic guided vehicle (AGV) includes simultaneously correcting the vehicle's heading and position errors. The vehicle may include first and second steering control loops that determine the vehicle's position and heading errors, respectively. Separate commands are generated from these control loops to steer the vehicle in a manner that tends to reduce these errors. The vehicle may include a forward and a rearward pair of wheels. For correcting position errors, the first control loop issues the same steering command to both the forward and rearward pair of wheels. For correcting heading errors, the second control loop issues a steering command to the rearward pair of wheels that is summed together with the first control loop's steering command prior to being applied to the rearward pair of wheels.

Abstract: An improved arrangement for adjusting crawler-type transport assemblies in a self-propelled construction vehicle between two differing “home” positions. The crawler transport assembly comprises a steering mechanism including a collar assembly operated via an actuator mounted to the frame of the apparatus for driving steering rotation of the transport assembly via the collar assembly. The collar assembly comprises a driving element integrally coupled to the actuator and a driven element integrally coupled to the transport assembly. The driven element can be affixed to the driving element selectively in two differing dispositions corresponding to the two “home” positions of the transport assembly.