KR101311226B1 - A multi-shaft steering apparatus for controlling individual wheel - Google Patents

Abstract

One embodiment of the independent wheel control multi-axis steering device of the present invention, the composite steering device provided in each wheel mounted on the vehicle; A traveling control device for independently controlling each of the multiple steering devices provided in the respective wheels; A driver operating device in which a steering command is input by the driver; And a sensing device for sensing a state of a vehicle and each wheel, wherein the driving control device is configured to detect a steering command input by the driver operating device through the sensing device according to a state of each vehicle and each wheel. Independently distributed and controlled by the compound steering device provided in each of the wheels.

Description

Independent Wheel Control Multi-Axis Steering {A MULTI-SHAFT STEERING APPARATUS FOR CONTROLLING INDIVIDUAL WHEEL}

The present invention relates to a wheel-type special vehicle to which a new concept propulsion device is applied for the construction of a future ground platform in the defense field. More specifically, the independent wheel-controlled multi-axis which can control each wheel independently has improved maneuverability and stability. It relates to a steering apparatus and a control method.

A typical vehicle converts the driving force generated by the engine to suit the driving situation through the transmission, distributes power to the front and rear wheels through the transfer case, and is driven by the rotation of the front and rear wheels. Therefore, a configuration for transmitting power to each wheel inevitably is required.

In the case of the land vehicle of the type which transmits the driving force generated by the engine to the wheels as in the prior art, some limitations occur in the maneuverability and stability because each wheel is not driven independently. In addition, there is a problem that the space inside the vehicle is narrowed by the configuration of transmitting the driving force to the wheel. In particular, in the case of ground vehicles in the defense sector, high maneuverability and survivability are required, and the space inside the vehicle is required to perform a special mission.

In order to solve the above-described problem, an in-wheel motor in which a motor generating the driving force of each wheel is located inside the wheel may be used. In-wheel motor is a technology used in a vehicle that uses electricity as a power source, and unlike a method in which wheels are driven to rotate by power transmission through a drive shaft in a gasoline or diesel vehicle, power is driven by a motor disposed inside the wheel. To be passed directly to the.

Here, a method of applying an in-wheel motor to a ground vehicle in the defense field may be considered. In the case of applying the in-wheel motor, the space inside the vehicle is increased, and each wheel can be independently controlled to have the advantage of improved maneuverability and stability.

However, in the case of ground vehicles in the defense sector, there are cases where the wheels are larger than the general vehicles. In such a case, effectively controlling these wheels has a difficult problem compared to a general vehicle. In addition, adjusting the direction of movement of the vehicle is an important factor in the mobility and stability of the vehicle, when having a plurality of wheels has a problem that the control is difficult.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems of the prior art.

In other words, an object of the present invention is to provide an independent wheel controlled multi-axis steering device with a new concept of composite steering device for the construction of a future ground platform in the defense field, significantly improved maneuverability and survivability.

In addition, the present invention is equipped with a high-performance electric motor directly to the wheel, and equipped with a steering device equipped with a turning angle steering motor to the wheel, a new concept of advanced electric steering device that can significantly improve maneuverability and survivability. It is an object to provide a wheel controlled multi-axis steering device.

In addition, an object of the present invention is to provide an independent wheel-controlled multi-axis steering device which is a high efficiency, high performance composite steering system that can be applied to a future low-carbon eco-friendly new concept vehicle platform.

In addition, an object of the present invention is to provide a control method capable of efficiently controlling the independent wheel control multi-axis steering apparatus.

The present invention provides the following configuration to achieve the above object.

One embodiment of the independent wheel control multi-axis steering device of the present invention, the composite steering device provided in each wheel mounted on the vehicle; A traveling control device for independently controlling each of the multiple steering devices provided in the respective wheels; A driver operating device in which a steering command is input by the driver; And a sensing device for sensing a state of a vehicle and each wheel, wherein the driving control device is configured to detect a steering command input by the driver operating device through the sensing device according to a state of each vehicle and each wheel. Independently distributed and controlled by the compound steering device provided in each of the wheels.

The composite steering apparatus includes: a turning angle steering apparatus for adjusting an angle of the wheel; A skid steering device provided on the wheel for skid steering; And a steering controller for controlling the turning angle steering device and the skid steering device, wherein the traveling control device controls the turning angle steering device and the skid steering device through the steering controller.

The turning angle steering device includes a steering motor for generating a driving force for changing the angle of the wheel, and a linear motion guide for transmitting the driving force of the steering motor to the wheel to guide the angle change of the wheel. The swing angle steering device may further include a double wishbone suspension device and an organic pressure buffer.

The skid steering device includes an in-wheel motor provided inside the wheel; reducer; And a braking device. Here, the in-wheel motor, the reducer, and the braking device may be integrally combined to form one module.

The driver operating device, the accelerator pedal; Braking pedal; Steering wheel; And a sensor signal processor, wherein the sensor signal processor is configured to transmit not only an operation signal of an accelerator pedal, a brake pedal, and a steering wheel, but also a state of the vehicle and each wheel detected from the sensing device to the driving controller. have.

The sensing device, the sensor; And a state estimator.

The driving control apparatus may include a steering determiner configured to determine a steering mode according to a steering command from the driver operating apparatus and a vehicle state detected by the sensing apparatus; An upper controller configured to determine a target steering angle and a target yaw speed of the vehicle according to an input signal from the driver operating apparatus, and determine a target yaw moment according to the vehicle state measured from the sensing device; And a lower controller for distributing steering angles and steering forces to the respective wheels so as to satisfy the steering angle and yaw moment determined by the upper controller, wherein the lower controller distributes driving signals from the upper controller to the respective steering controllers. It is characterized by.

The driving control device may further include a safety controller for controlling the skid steering device according to the lateral acceleration and the yaw speed of the vehicle detected by the sensing device.

The driving control apparatus may further include a slip controller controlling the skid steering apparatus according to sliding of each wheel detected by the sensing apparatus.

On the other hand, the vehicle is provided with six wheels, the compound steering apparatus of the six wheels can be independently controlled respectively.

The vehicle includes a vehicle body; A compound steering device provided in each wheel provided in the body; A traveling control device controlling each of the multiple steering devices provided in the respective wheels; A sensing device for sensing a state of the vehicle and each wheel; And a driver operating device to which a steering command is input by a driver, wherein the driving control device is provided in each of the wheels according to a steering command by the driver operating device and a state of the vehicle detected by the sensing device. Characterized in that the steering device is independently controlled.

On the other hand, in the control method of the multi-axis steering device to independently control the combined steering device of each wheel provided in the vehicle of the present invention, the vehicle is detected by the steering command and the sensing device from the steering operation of the steering control device of the driving control device Determining a steering mode according to the state; Determining, by the upper controller of the traveling control device, a target steering angle and a target yaw rate according to a steering command from the driver operating device, and determining a target yaw moment according to a vehicle state detected by the sensing device; And determining, by the lower controller of the traveling control device, the steering angle and the steering force of each wheel according to the determination of the upper controller, and distributing and driving the steering wheel of the combined steering device.

The determining of the steering mode is selected by the steering determiner from a plurality of preset steering modes.

The steering mode includes a turning angle steering mode for adjusting a turning angle of the vehicle; A skid steering mode for generating a speed difference of each wheel of the vehicle; A compound steering mode for simultaneously driving the swing angle steering mode and the skid steering mode; An avoidance steering mode for starting the vehicle by aligning the wheels in the same direction; And a steering mode for allowing the vehicle to rotate in place.

The determining of the target yaw moment determines the target yaw moment according to the difference between the actual yaw rate and the target yaw rate detected by the sensing device.

The control method may further include determining, by the stability controller of the traveling control device, the required stability driving according to the vehicle state detected from the sensing device, wherein the determining of the required stability driving of the vehicle may include lateral acceleration. The difference between the lateral acceleration measured by the sensor and the target lateral acceleration of the vehicle is calculated to determine whether the predetermined reference value is exceeded.

When the difference between the lateral acceleration of the vehicle and the target lateral acceleration of the vehicle measured by the lateral acceleration sensor exceeds a preset reference value, the driving control device issues a driving command to the steering controller provided in the compound steering device of each wheel. Distribution to reduce the speed of the vehicle or generate yaw moments.

The control method may further include determining a slip ratio of the vehicle according to a vehicle state detected by the sensing device in a slip controller of the traveling control device, wherein determining the slip ratio of the vehicle may include: The slip ratio is calculated by comparing the rotation speed and the vehicle speed at each wheel.

When the slip ratio at each wheel exceeds a preset limit value, the travel control device determines and controls the input torque to be distributed of each wheel.

The present invention has the following effects by the above configuration.

The present invention is applied to a hybrid steering system of an independent wheel-controlled multi-axis hybrid / electric combat vehicle, a combat / surveillance robot, a future low-carbon ground-manned and unmanned combat vehicle using an inwill motor and a steering motor, and a driver's steering command. By operating the skid steering and turning angle steering according to the vehicle driving state in the driving controller, it has the effect of improving the maneuverability, such as in-situ turning and avoiding maneuver and to minimize the steering radius.

This increases the mobility and survivability of combat vehicles. It also has the effect of increasing energy efficiency. In addition, it improves the maneuverability and the driving stability of the vehicle, such as turning the vehicle in place and reducing the steering radius.

1 is a schematic diagram of a vehicle of the present invention.
Figure 2 is a perspective view showing a turning angle steering device provided in the wheel.
3 is a cross-sectional view showing a skid steering device provided in the wheel.
4 is a schematic view showing a system capable of independently controlling a compound steering device.
5A-5E are schematic diagrams showing examples of various steering modes.
Figure 6 is a flow chart showing one embodiment of a control method of the independent wheel control multi-axis steering apparatus of the present invention.
7 is a flow chart showing another embodiment of the control method of the independent wheel control multi-axis steering apparatus of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 shows an embodiment of a vehicle equipped with an independent wheel controlled multi-axis steering device of the present invention. Referring to Figure 1, the body 100 of the vehicle of the present embodiment is provided with a plurality of wheels (202).

The vehicle body 100 may have various appearances that can be used in a defense vehicle. Although schematically illustrated in FIG. 1, the present invention is not limited thereto.

In FIG. 1, the vehicle body 100 includes six wheels 202. However, this is merely illustrative of the embodiment provided with six wheels, and if each wheel can be independently controlled by the method described below all fall within the scope of the present invention.

Each wheel 202 is provided with a compound steering device (200). The composite steering apparatus 200 includes a turning angle steering device 210 for adjusting an angle of a wheel, a skid steering device 220 provided on a wheel for skid steering, and a steering for controlling the turning angle steering device and a skid steering device. It is configured to include a controller 230. In FIG. 1, six compound steering apparatuses 200 are provided to correspond to the number of wheels. However, as mentioned above, this is merely illustrative.

2, the turning angle steering device 210 is shown in more detail. The turning angle steering device 210 is configured to function as a turning angle steering function of the vehicle so that the turning angle steering is performed by independently adjusting the angle of each wheel.

Referring to FIG. 2, the turning angle steering device 210 transmits a steering motor 211 and a steering motor driving force of the steering motor to the wheel to generate a driving force to change the angle of the wheel 202 to change the angle of the wheel. It comprises a linear motion guide (212) for guiding.

The steering motor 211 is connected to the knuckle 216 through the linear motion guide 212. The knuckle 216 does not rotate relative to the vehicle body. The knuckle 216 serves to connect the skid steering device and the body of the vehicle. The shaft 217 of the wheel penetrates through the knuckle. However, the shaft 217 does not rotate about the knuckle.

The knuckle 216 is connected to the skid steering device 220 to be described later through the shaft 217 penetrating the center. The wheel 202 is connected to the skid steering device 220. Therefore, the driving force generated by the steering motor 211 rotates the knuckle 216 through the linear motion guide 212. Accordingly, the skid steering device 220 and the wheels 202 connected to the knuckle 216 are integrally steered in steering angle.

On the other hand, the knuckle 216 is connected to the double wishbone suspension devices (213, 214) and the suspension pressure of the organic pressure buffer 215. The double wishbone suspension device includes an upper support 213 and a lower support 214, and the knuckle 216 is rotatably coupled between the upper support and the lower support. The suspension 215 is connected to the lower support 214. Accordingly, the knuckle 240 does not rotate relative to the vehicle body, but may be connected to the suspension 215 to vibrate.

The swing angle steering device 210 has a steering motor and a linear motion guide excellent in reliability and space utilization to implement a swing angle steering function. In addition, by applying a double wishbone suspension device and an organic pressure buffer to improve the driving performance.

3 shows a skid steering device 220. Each wheel 202 is provided with a skid steering device (220). Referring to FIG. 3, the skid steering device 220 includes an in-wheel motor 221, a complex braking device 223, and a speed reducer 222 for independently controlling wheels.

In this case, the in-wheel motor 221, the reduction gear 222, and the combined braking device 223 may be modularly coupled and provided inside the wheel 202. Such in-wheel motors, reduction gears, and modules of the braking device may be referred to as in-wheel modules. The in-wheel module corresponds to a structure for minimizing space and increasing energy efficiency.

The in-wheel module is shown in more detail in FIG. 3. Referring to FIG. 3, the in-wheel module includes an in-wheel motor 221, a braking device 223, and a reduction gear 222.

The in-wheel module is connected to a knuckle 216 that does not rotate relative to the vehicle body as described above. The knuckle 240 serves to connect the in-wheel module and the body of the vehicle. The shaft 217 of the wheel penetrates through the knuckle. However, the shaft 217 does not rotate about the knuckle.

The in-wheel motor 221 includes a stator 221b and a rotor 221a. The stator is connected to the shaft 217 in a fixed configuration. The rotor 221a is spaced apart from the stator 221b at a predetermined interval, but rotates around the stator by an electromagnetic action with the stator. That is, the rotor 221a rotates about the shaft 217.

The rotation of the rotor 221a is transmitted to the reducer 222 connected to the rotor. The reduction gear is provided inside the reduction gear to reduce the rotational speed of the rotor according to the gear ratio of the planetary gear.

Rim 201 is connected to the reducer 222. The rim 201 functions to support the wheel in a configuration mounted on the inner circumferential surface of the wheel 202. The rotation generated through the in-wheel motor 221 is transmitted to the rim 201 through the speed reducer 222. Accordingly, the rim 201 can rotate about the fixed shaft 217. Furthermore, wheels are rotated about the shaft 217.

The braking device 223 includes a mechanical braking device 223a for performing mechanical braking and a regenerative braking device 223b for performing an electric regenerative braking function. The mechanical braking device 223a refers to a device that mechanically generates friction to reduce the brake. The regenerative braking device 223b uses a stator and a rotor provided in the in-wheel motor 221, and refers to a device that generates electric power in parallel with generating a reverse rotational force to the rotor.

The steering controller 230 is provided in each wheel 202 to control the combined steering device and the skid steering device and perform a power conversion function. In this case, the steering controller which is electrically connected to the traveling control device to be described later and provided in the respective vehicles may be controlled. That is, the steering command in the steering controller drives the steering motor, the torque command is transmitted to the in-wheel motor to drive, driving the wheel through the reducer.

4 shows a configuration for controlling the above-described complex steering apparatus. In FIG. 4, since six wheels are provided in the vehicle of FIG. 1, the compound steering apparatuses 200a, 200b, 200c, 200d, 200e, and 200f mounted to the respective wheels are subdivided to correspond to the wheels of FIG. 1.

Referring to FIG. 4, the driving control device 300, the driver operating device 400 receiving a steering command by the driver, and the vehicle and the state of each wheel as a configuration for controlling the compound steering device of each wheel. It is configured to include a sensing device 500 for sensing.

The sensing device 500 includes various sensors 510 and a state estimator 520 for estimating a state required for driving control. This makes it possible to detect the state of the vehicle and each wheel to provide information for the control of the drive device.

The driver operating apparatus 400 is configured to receive a driving and steering signal of a driver and transmit the same to a driving control apparatus to be described later, so that the driver's steering command can be received. The driver operating apparatus 400 may include an accelerator pedal 410, a brake pedal 420, and a steering wheel 430. The sensor signal processor may detect the manipulation thereof and transmit the same to the driving controller 300. 440 may also be provided.

The sensor signal processor 440 may process to transmit the state of each vehicle and each wheel detected by the sensing device 500 to the driving control device 300 as well as the driver's operation signal.

The travel control device 300 independently distributes and controls the steering command input by the driver operating device to the compound steering device provided in each wheel according to the state of the vehicle and each wheel detected through the detection device. Function.

The driving control apparatus 300 may include a steering determiner 350 that determines a steering mode according to a steering command from the driver operating apparatus and a vehicle state detected by the sensing apparatus, and a vehicle according to an input signal from the driver operating apparatus. A higher steering wheel 320 for determining a target steering angle and a target yaw rate of the vehicle and determining a target yaw moment according to the vehicle state measured from the sensing device, and to satisfy the steering angle and the yaw moment determined by the upper controller. Lower controller 330 for distributing steering angle and steering force, safety controller 310 for controlling the skid steering apparatus according to the lateral acceleration and yaw speed of the vehicle detected by the sensing device, respectively detected by the sensing device It comprises a slip controller 340 for controlling the skid steering device according to the sliding of the wheel.

The steering determiner 350 determines the steering mode according to a steering command from the driver operating apparatus and a vehicle state detected by the sensing apparatus. That is, even the same steering command determines the optimal steering mode according to the state of the vehicle.

5A to 5E show various examples of such a steering mode. 5A shows the turning angle steering mode. The turning angle steering mode refers to a steering mode that adjusts the turning angle steering device 210 to turn a part of the plurality of wheels 202 in a target direction of the vehicle to adjust the turning angle of the vehicle. In FIG. 5A, only the two front wheels 202 are turned in the target direction to adjust the turning angle of the vehicle.

5b gathers skid steering modes. The skid steering mode refers to a steering mode that adjusts the skid steering device to generate a speed difference of a wheel to adjust a turning angle of the vehicle. In FIG. 5B, the left and right wheels are controlled to have different speeds.

5C shows the compound steering mode. The combined steering mode is to simultaneously perform the swing angle steering mode and the skid steering mode. That is, as shown in FIG. 5C, the turning angle steering device 210 is adjusted to turn some of the wheels 202 in the target direction of the vehicle, and the skid steering device is adjusted to generate the speed difference of the wheels. In this case, a lower controller to be described later may be performed by simultaneously distributing a skid steering command and a turning angle steering command to the steering controller.

5d shows the avoidance steering mode. The avoidance steering mode refers to a steering mode for starting a vehicle by aligning wheels in the same direction. 5E illustrates a steering mode in which the vehicle is rotated in place by skid steering in a state in which several wheels are arranged in a rounded manner.

The lower controller 330 distributes the driving signal from the upper controller 320 to each of the steering controllers. That is, the steering angle and steering force of each wheel are determined to satisfy the steering angle and yaw moment determined by the upper controller and are distributed to the steering controller. Therefore, if the vehicle is provided with six wheels, the compound steering device of the six wheels can be independently controlled by the travel control device, respectively.

Meanwhile, referring to FIG. 4, a power supply device 600 may be further provided. The power supply device 600 includes a low power supply 610 for supplying control and signal power and a high power supply 620 for supplying driving power.

On the other hand, the present invention relates to a control method of a multi-axis steering device to independently control the compound steering device of each wheel provided in the vehicle. 5 shows such a control method.

Referring to FIG. 6, in one embodiment of the control method, the driving control apparatus detects a steering signal or a state signal of each vehicle and each wheel from a driver operating apparatus or the sensing apparatus (S50), The steering determiner determines the steering mode according to the steering command from the driver operating device and the vehicle state detected by the sensing device (S100), and the upper steering controller of the traveling control device according to the steering command from the driver operating device. And determining a target yaw rate, and determining a target yaw moment according to the vehicle state detected by the sensing device (S200), wherein a lower controller of the traveling control device determines the steering angle of each wheel according to the determination of the upper controller. And determining the steering force and distributing and driving the steering force to the steering controller of the hybrid steering apparatus (S300).

In step S50 of detecting the steering signal and the state signal of the vehicle and each wheel, the driver's steering command from the driver operating device 400 or the state of the vehicle and the wheel from the detection device 500 is detected. In this case, the signal is input to the driving control apparatus 300.

The determining of the steering mode (S100) refers to a step of being selected by the steering determiner from a plurality of preset steering modes. As described above with respect to the steering mode, various examples are shown in FIGS. 5A to 5E.

The determining of the target yaw moment (S200) may include determining a target steering angle and a target yaw speed according to a steering command from a driver operating device in the upper controller, and determining a target yaw moment according to a vehicle state detected by the sensing device. Says a step. Here, the target yaw moment is determined according to the difference between the actual yaw velocity and the target yaw velocity detected by the sensing device.

Distributing and driving to the steering controller of the hybrid steering apparatus (S300) refers to a step of determining and distributing the steering angle and steering force of each wheel in accordance with the determination of the upper controller in the lower controller. This is to optimally distribute the steering angle and steering force required for each wheel to independently steer each wheel. Accordingly, each wheel is independently steered and driven (S350).

7 shows another embodiment of the control method. Referring to FIG. 7, the control method may further include a step S210 of determining the required stability driving of the vehicle according to the state signal in the stability controller of the traveling control device. Determining the necessary stability driving of the vehicle (S210) reduces the lateral acceleration by reducing the speed of the vehicle in order to remove the instability of the vehicle caused by the rapid increase in the lateral acceleration and yaw speed of the vehicle, and the release of the yaw speed of the vehicle It creates the yaw moment to prevent it.

In the determining of the required stability driving of the vehicle (S210), the difference between the lateral acceleration of the vehicle and the target lateral acceleration of the vehicle measured by the lateral acceleration sensor included in the sensing device is determined to determine whether the predetermined reference value is exceeded. .

Here, when the difference between the lateral acceleration of the vehicle and the target lateral acceleration of the vehicle measured by the lateral acceleration sensor exceeds a predetermined reference value, the driving control device 300 is connected to the combined steering device 200 of each wheel. The driving command is distributed to the steering controller 230 provided to reduce the speed of the vehicle or generate the yaw moment. In this case, as described above, steering commands are formed independently on the respective wheels through the upper controller and the lower controller.

On the other hand, the control method further comprises the step of determining the slip ratio of the vehicle according to the state signal in the slip controller of the driving control apparatus (S220). The step of determining the slip ratio of the vehicle (S220) monitors the driving state of each wheel to determine the input torque so that slip does not occur.

In the determining of the slip ratio of the vehicle (S220), the slip rate is calculated by comparing the rotation speed and the vehicle speed at each wheel. Here, when the slip ratio at each of the wheels exceeds a preset limit value, the travel control device determines that the input torque of each wheel is distributed so as not to slip. Also in this case, as described above, the driving command is independently formed on each wheel through the upper controller and the lower controller.

On the other hand, the step of determining the required stability driving of the vehicle (S210) and the step of determining the slip ratio of the vehicle (S220) in parallel with the step of determining the target yaw moment based on the input of the driver operating device (S200). Can be done. In other words, these steps may be performed simultaneously or independently.

Although the preferred embodiments of the present invention have been described above with reference to the accompanying drawings, the scope of the present invention is not to be construed as limited to such embodiments and / or drawings, and is determined by the matters set forth in the claims below. do. In addition, it should be clearly understood that improvements, changes, modifications, and the like apparent to those skilled in the art described in the claims are included in the scope of the present invention.

100: vehicle body 200: compound steering
201: rim 202: wheel
210: turning angle steering device 220: skid steering device
230: steering controller 300: driving control device
400: operator operating device 500: detection device
600: power supply

Claims (21)

A compound steering device provided in each wheel mounted to the vehicle;
A traveling control device for independently controlling each of the multiple steering devices provided in the respective wheels;
A driver operating device in which a steering command is input by the driver; And
It includes; sensing device for detecting the state of the vehicle and each wheel,
The driving control device independently distributes and controls a steering command input by the driver operating device to a compound steering device provided in each wheel according to a state of the vehicle and each wheel detected through the sensing device,
The composite steering device,
A turning angle steering device for adjusting an angle of the wheel; A skid steering device provided on the wheel for skid steering; And a steering controller for controlling the swing angle steering device and the skid steering device.
The traveling control device controls the turning angle steering device and the skid steering device through the steering controller,
The turning angle steering device includes a steering motor for generating a driving force to change the angle of the wheel; and a linear motion guide for guiding the wheel angle change by transferring the driving force of the steering motor to the wheel.
Independent wheel controlled multi-axis steering system.
delete delete The method of claim 1,
The turning angle steering device,
Further comprising: a double wishbone suspension device; and an organic pressure buffer;
Independent wheel controlled multi-axis steering system.
The method of claim 1,
The skid steering device,
An in-wheel motor provided inside the wheel; reducer; And a braking device;
Independent wheel controlled multi-axis steering system.
The method of claim 5,
The in-wheel motor and the reducer and the braking device are integrally combined to form a module,
Independent wheel controlled multi-axis steering system.
The method of claim 1,
The driver operating device,
Accelerator pedal; Braking pedal; Steering wheel; And a sensor signal processor,
The sensor signal processor may be configured to transmit not only an operation signal of an accelerator pedal, a brake pedal and a steering wheel, but also a state of each vehicle and each wheel detected from the sensing device to the driving control device.
Independent wheel controlled multi-axis steering system.
The method of claim 1,
The sensing device, the sensor; And a state estimator;
Independent wheel controlled multi-axis steering system.
The method of claim 1,
The traveling control device,
A steering determiner determining a steering mode according to a steering command from the driver operating apparatus and a vehicle state detected by the sensing apparatus;
An upper controller configured to determine a target steering angle and a target yaw speed of the vehicle according to an input signal from the driver operating apparatus, and determine a target yaw moment according to the vehicle state measured from the sensing device;
And a lower controller for distributing steering angles and steering forces to the respective wheels so as to satisfy steering angles and yaw moments determined by the upper controller.
Wherein the lower controller distributes a drive signal from the upper controller to each of the steering controllers.
Independent wheel controlled multi-axis steering system.
10. The method of claim 9,
The traveling control device further includes a safety controller for controlling the skid steering device according to the lateral acceleration and yaw speed of the vehicle detected by the detection device;
Independent wheel controlled multi-axis steering system.
10. The method of claim 9,
The driving control device further includes a slip controller for controlling the skid steering device according to the sliding of each wheel detected by the sensing device;
Independent wheel controlled multi-axis steering system.
The method of claim 1,
The vehicle has six wheels,
Characterized in that each of the six wheel compound steering device is independently controlled,
Independent wheel controlled multi-axis steering system.
Vehicle body;
A compound steering device provided in each wheel provided in the body;
A traveling control device controlling each of the multiple steering devices provided in the respective wheels;
A sensing device for sensing a state of the vehicle and each wheel;
And a driver operating device to which a steering command is input by the driver.
The traveling control device independently controls the compound steering device provided in each wheel according to the steering command by the driver operating device and the state of the vehicle detected by the detection device,
The composite steering device,
A turning angle steering device for adjusting an angle of the wheel; A skid steering device provided on the wheel for skid steering; And a steering controller for controlling the swing angle steering device and the skid steering device.
The traveling control device controls the turning angle steering device and the skid steering device through the steering controller,
The turning angle steering device includes a steering motor for generating a driving force to change the angle of the wheel; and a linear motion guide for guiding the wheel angle change by transferring the driving force of the steering motor to the wheel.
Vehicle with independent wheel controlled multi-axis steering.
In the control method of the multi-axis steering device for independently controlling the compound steering device of each wheel provided in the vehicle,
Determining, by the steering determiner of the traveling control device, the steering mode according to a steering command from the driver operating apparatus and a vehicle state detected by the sensing device;
Determining, by the upper controller of the traveling control device, a target steering angle and a target yaw rate according to a steering command from the driver operating device, and determining a target yaw moment according to a vehicle state detected by the sensing device;
And determining, by the lower controller of the traveling control device, the steering angle and the steering force of each wheel according to the determination of the upper controller, and distributing and driving the steering wheel of the compound steering device.
The composite steering device,
A turning angle steering device for adjusting an angle of the wheel; A skid steering device provided on the wheel for skid steering; And a steering controller for controlling the swing angle steering device and the skid steering device.
The traveling control device controls the turning angle steering device and the skid steering device through the steering controller,
The turning angle steering device includes: a steering motor for generating a driving force for changing the angle of the wheel; and a linear motion guide for guiding the wheel angle change by transferring the driving force of the steering motor to the wheel.
Control Method of Independent Wheel Controlled Multi-axis Steering System.
15. The method of claim 14,
The determining of the steering mode may be selected by the steering determiner from a plurality of preset steering modes.
Control Method of Independent Wheel Controlled Multi-axis Steering System.
16. The method of claim 15,
The steering mode,
A turning angle steering mode for adjusting a turning angle of the vehicle;
A skid steering mode for generating a speed difference of each wheel of the vehicle;
A compound steering mode for simultaneously driving the swing angle steering mode and the skid steering mode;
An avoidance steering mode for starting the vehicle by aligning the wheels in the same direction; And
Including; the steering mode to allow the vehicle to rotate in place;
Control Method of Independent Wheel Controlled Multi-axis Steering System.
15. The method of claim 14,
Determining the target yaw moment is characterized in that for determining the target yaw moment according to the difference between the actual yaw rate and the target yaw rate detected from the sensing device,
Control Method of Independent Wheel Controlled Multi-axis Steering System.
15. The method of claim 14,
Determining the required stability driving according to the vehicle state detected from the sensing device in the stability controller of the traveling control device;
The determining of the required stability driving of the vehicle may include determining whether the vehicle exceeds the preset reference value by calculating a difference between the vehicle lateral acceleration and the target lateral acceleration measured by the lateral acceleration sensor.
Control Method of Independent Wheel Controlled Multi-axis Steering System.
19. The method of claim 18,
When the difference between the lateral acceleration of the vehicle and the target lateral acceleration of the vehicle measured by the lateral acceleration sensor exceeds a preset reference value,
Characterized in that the driving control device to distribute the drive command to the steering controller provided in the compound steering device of each wheel to reduce the speed of the vehicle or to generate a yaw moment,
Control Method of Independent Wheel Controlled Multi-axis Steering System.
15. The method of claim 14,
Determining a slip ratio of the vehicle according to a vehicle state detected by the sensing device in a slip controller of the traveling control device;
Determining the slip ratio of the vehicle, characterized in that for calculating the slip ratio by comparing the rotation speed and the vehicle speed in each wheel,
Control Method of Independent Wheel Controlled Multi-axis Steering System.
21. The method of claim 20,
If the slip ratio at each of the wheels exceeds a preset limit,
Characterized in that the traveling control device determines and controls the input torque to be distributed of each wheel,
Control Method of Independent Wheel Controlled Multi-axis Steering System.

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