法国专利FR3043049A1 ASSISTANCE DEVICE FOR DOCKING APPROACHES AT DOCK LEVEL

专利PDF首页>>法国专利

专利附录

专利说明

权利要求

类似技术

同族专利

引用文献

法律状态

优先权

专利摘要:
The assistance device (1) operates in a road mode in which the rear wheels (9) are at first straight then, beyond a certain steering angle of the front wheels (11), the rear wheels (9) are slaved in a proportional manner with respect to the steering control received by the front wheels (11). This device (1) also functions in a docking mode in which the rear axle (5) is steered and in which the steering angle of the rear wheels (9) is controlled via a steering device in the direction (10) of the rear axle (5). It then controls the steering of the rear wheels (9) which depends on the distances of the vehicle relative to the dock and other obstacles in the environment. These distances are measured by distance sensors (15, 16, 17, 18).
公开号:FR3043049A1
申请号:FR1560531
申请日:2015-11-03
公开日:2017-05-05
发明作者:Geoffroy Richert；Dominique Bebon
申请人:Newtl SAS；
IPC主号:

专利说明:

ASSISTANCE DEVICE FOR DOCKING APPROACHES AT DOCK LEVEL
Technical area
The present invention relates to a road vehicle comprising an assistance device for docking maneuvers at a platform. The invention relates to any type of articulated axle vehicle, more particularly a bus-type public transport road vehicle, comprising a device that assists the driver during approach and departure maneuvers of a platform so that the vehicle does not collide with its surroundings and is closer to the wharf at the end of the approach maneuver.
State of the art
It is known, particularly in the field of special road transport vehicles, for example in the field of logging trucks, to equip vehicles with steering axles that can be controlled by the driver during difficult maneuvers. This type of device is usually controlled by a remote control, with the driver leaving his driving position to control the various movements of the axles from outside the vehicle. This type of device is not suitable for driving in urban areas where it is particularly dangerous for the driver to leave his driving position.
It is also known to equip the road vehicles with various sensors or cameras to assist the driver during difficult maneuvers by providing him with many visual or sound information including the presence, position and distance of obstacles around his driver. vehicle.
Sometimes these sensors or cameras are associated with electronic intelligence to control the front axle of the vehicle automatically. Thus, there are anti-collision devices and trajectory correction devices that act on the forward direction of the vehicle at high speed to avoid accidents.
Anti-collision devices and trajectory-correcting devices are also known for vehicles whose rear axle wheels may be slightly steered at a steering angle whose absolute value is usually less than 2 °. This very limited steering angle does not help the driver for low speed berthing maneuvers.
There are, however, no sensors associated with electronic intelligence to automatically control a steering rear axle of a road vehicle to assist the driver in low speed maneuvers, including docking maneuvers at the level of the vehicle. 'a dock.
In fact, docking maneuvers at a wharf with a public transit road vehicle are often difficult in urban areas. Due to the presence of pedestrians likely to walk on bus lanes, poorly parked cars that sometimes encroach on these locations at bus stops, or various urban obstacles, it is sometimes difficult for the driver to approaching and departing from a wharf so that the vehicle does not collide with its surroundings and is closer to the wharf at the end of the approach maneuver.
DESCRIPTION OF THE INVENTION The object of the present invention is therefore to overcome the disadvantages of the prior art by proposing a new road vehicle comprising an assistance device for docking maneuvers at a platform.
This assistance device is of automatic operation when it is switched on. Thus, when docking maneuvers at a dock, the driver is not concerned about the assistance device once it activated. The driver drives his vehicle in a conventional manner, by orienting the front steering axle in a conventional manner with his steering wheel, while the assistance device of the invention is concerned with orienting a rear axle which is modified so as to be director, without the driver having to worry about it.
According to this invention, the wheels of the rear axle can be steered at an angle whose absolute value is much greater than 2 °, for example greater than 10 °, preferably greater than 20 ° and even more preferably greater than 30 °.
The fact that a rear axle is steerable allows the road vehicle to make docking maneuvers for a shorter distance, which is particularly advantageous when the locations reserved for the bus stops for the public transport vehicles are of reduced size. This also allows to approach the rear of the vehicle closer to the dock during the approach maneuvers so that the vehicle is both closer to the dock and parallel to it. This is particularly important in the field of public transport vehicles that can carry passengers in wheelchairs, with strollers or roller baskets.
Another object of the present invention is to provide a new method of docking at a dock for a road vehicle equipped with the assistance device of the invention.
According to a first variant of the invention, the objects assigned to the invention are achieved by means of a road vehicle comprising front wheels mounted on a steering front axle and rear wheels mounted on a rear axle, characterized in that it comprises an assistance device for docking maneuvers at a platform and in that the rear axle is steered and equipped with a steering, the assistance device being designed to operate in a road or in a docking mode and comprising the following means: - a steering device in the direction provided for controlling the steering angle Aar of the rear wheels; a distance sensor provided at the rear of the vehicle for measuring the distance DARquai from the rear of the vehicle relative to the wharf; in which: - in road mode, either the rear wheels are straight or their steering angle Aar is controlled by the steering device in the direction according to the steering angle Aav of the front wheels; - in docking mode, the steering angle of the rear wheels is controlled by the steering device in the direction of the distances measured by the distance sensor and the front wheel angle Aav
Thus, the assistance device controls the steering of the rear wheels fully automatically, so as to optimize and facilitate the various maneuvers performed by the driver when docking at a dock.
According to a second variant of the invention, the assistance device further comprises the following means: a distance sensor provided at the front for measuring the distance ÜAVquai of the front of the vehicle relative to the platform; a distance sensor provided at the rear of the vehicle for measuring the distance DARenv from the rear of the vehicle relative to other obstacles in the environment; in which: - in road mode, either the rear wheels are straight or their steering angle Aar is controlled by the steering device in the direction according to the steering angle Aav of the front wheels; - In docking mode, the steering angle of the rear wheels is controlled by the steering device in direction according to the distances measured by the distance sensors and according to the steering angle Aav of the front wheels.
Thus, thanks to additional distance sensors, the assistance device controls the turning of the rear wheels even more optimized to facilitate the various maneuvers performed by the driver when docking at a dock.
According to an exemplary implementation of the invention, the assistance device further comprises a distance sensor provided at the front of the vehicle for measuring the distance ÜAVenv from the front of the vehicle relative to the other obstacles of the vehicle. environment.
According to another example of implementation of the invention, the rear wheels can be steered at an angle whose absolute value is greater than 10 °, preferably greater than 20 ° and more preferably greater than 30 °. This steering angle, which is much higher than that of the existing rear axles, makes it possible to optimize the different docking maneuvers compared with the vehicles of the prior art.
According to an exemplary implementation of the invention, in road mode, the steering control device controls the steering angle Aar of the rear wheels so that the rear wheels are at first straight then, beyond a certain steering angle of the front wheels, the rear wheels are slaved in a proportional and linear manner with respect to the steering control received by the front wheels.
According to a further example of implementation of the invention, in road mode the rear axle is fixed with the right rear wheels when the vehicle speed is greater than the maximum speed of Svar road mode This avoids any risk of dangerous behavior of the vehicle when it is traveling at a certain speed.
According to an exemplary implementation of the invention, the assistance device automatically switches from the docking mode to the road mode when the vehicle speed is greater than a maximum speed for docking VMAXaccostage or when the steering angle AAv the front wheels is greater than an ashered angleMessage exit steering. This allows in particular to avoid any risk of dangerous behavior of the vehicle when it runs at a certain speed.
According to another example of implementation of the invention, the assistance device comprises sensors for measuring the steering angle Aav of the front wheels and the steering angle Aar of the rear wheels. These sensors provide information necessary for the operation of the assistance device, especially in road mode.
According to this exemplary implementation of the invention, when the front axle comprises a steering box, and in that the steering angle Aav of the front wheels can be measured by an angle sensor which is connected to this case management.
Similarly, when the steering control device comprises a movable rod actuator, the steering angle Aar of the rear wheels can be measured by a position sensor connected to the actuator of the steering device in the direction of the steering angle. Aar steering of the rear wheels being calculated according to the position of the rod of the actuator.
According to an exemplary implementation of the invention, the distance sensors are provided on the right side of the vehicle, especially in the case where the vehicle is intended to circulate on the right.
According to another exemplary implementation of the invention, the distance sensors provided at the front of the vehicle are provided in front of the front wheels, the distance sensor at the platform provided at the rear of the vehicle is provided in front of the rear wheels , and the rear environmental sensor is provided at the rear of the rear wheels. This allows the sensors to be located closer to the obstacles they must detect.
According to a further example of implementation of the invention, the distance information at the front and at the back which are received by the distance sensors are transmitted to the driver visually, which helps him in his driving. .
According to an exemplary implementation of the invention, the assistance device comprises a docking / road mode switch that switches the assistance device from the road mode to docking mode and vice versa when it is activated.
According to this exemplary implementation of the invention, the docking / road mode switch can be operated manually by the driver by means of a button provided in the driving position of the vehicle.
The berthing / road mode switch can also be operated by a contactless dialogue between the infrastructure and the vehicle. Thus the driver does not need to worry about operating the mode switch docking / road, this is done automatically for example when the vehicle approaches or away from a dock equipped with a dialogue device without contact with the vehicle.
According to an exemplary implementation of the invention, the docking / road mode switch does not make it possible to switch the assistance device from the road mode to the docking mode as long as the vehicle is traveling at a speed greater than the maximum speed for docking VMAXaccostage This avoids any risk of dangerous behavior of the vehicle when it is traveling at a certain speed.
According to an exemplary implementation of the invention, the assistance device also comprises an onboard intelligence that drives the steering device towards the rear axle.
This embedded intelligence is for example connected to the distance sensors, the sensors to measure the steering angle Aav front wheels and the steering angle Aar rear wheels, and the mode switch docking / road. The embedded intelligence may include a memory in which are stored the mathematical formulas used by the assistance device to control the steering angle of the rear wheels in road mode and in docking mode, as well as the values of the constants used in these formulas. .
The objects assigned to the invention are also achieved by means of a quay docking method for a road vehicle as described above, characterized in that it comprises the following successive stages: a) a phase of rolling, when the vehicle is traveling in a conventional manner, in which the assistance device is switched to road mode and in which the rear wheels are straight or slaved to the forward direction; (b) an approach phase, when the vehicle begins docking at a platform, in which the assistance device is switched to docking mode, in which the rear wheels remain in road mode until the forward distance sensor has not sensing the dock, and wherein, when the forward distance sensor detects the dock, the rear wheels are driven by the assist device and steered so that the rear axle is moved toward the dock; (c) a stopping phase, when the vehicle is docked; d) a departure phase, when the vehicle leaves the platform, in which the assistance device is switched to docking mode and in which the rear wheels are steered so that the rear axle is moved away from the dock; e) a driving phase, when the vehicle is traveling in a conventional manner after having left the platform, in which the assistance device is switched to road mode and in which the rear wheels are straight or slaved to the forward direction.
According to this docking method, during the stopping phase, when the vehicle is docked, the rear wheels can be driven so as to be returned to the non-steered position. Indeed, this allows the vehicle to be closer to the dock, and steered wheels can sometimes interfere with the opening of the side doors of said vehicle.
This process greatly facilitates docking maneuvers for the driver. This docking is thus optimized automatically by the assistance device, allowing the vehicle to dock in a parallel manner and close to a dock much easier, safer and a much shorter distance than with vehicles classics.
Thanks to the invention, the gap is reduced between the vehicle and the platform for easy access to the vehicle. The distance to the dock being controlled, the sides of the wheels do not come rubbing against the dock, which prevents their premature wear.
Likewise, the length necessary to achieve the docking is reduced, which allows the vehicle to dock even when the available space would be too low for a conventional vehicle.
By optimizing the time and the number of maneuvers necessary for a docking, the invention also makes it possible to optimize the fuel consumption of the vehicle.
Finally, the sensors of the invention allow a visual assistance to driving that is independent of the weather and visibility.
BRIEF DESCRIPTION OF THE DRAWINGS Other features and advantages of the present invention will emerge more clearly on reading the description which follows, made with reference to the appended drawings, given by way of non-limiting examples, in which: FIG. 1 is a graph illustrating the mathematical law giving the steering angle of the rear wheels with respect to the steering angle of the front wheels when the rear axle operates in road mode; - Figure 2 is a schematic view illustrating a road vehicle equipped with an assistance device for the docking maneuvers at a platform according to a first embodiment of the invention; - Figure 3 is a schematic view illustrating a road vehicle equipped with an assistance device for docking maneuvers at a platform according to a second variant of the invention; and FIGS. 4 to 11 are diagrammatic views illustrating approach and departure maneuvers of a platform for a road vehicle equipped with an assistance device according to the invention, on which the trajectory of the front axle is represented in dotted lines.
Mode (s) of realization of the invention
The structurally and functionally identical elements present in several separate figures are assigned a same numerical or alphanumeric reference.
The assistance device (1) for the docking maneuvers at a platform (2) according to the invention is provided for a road vehicle (3) comprising a steering front axle (4) equipped with a steering wheel ( 6) conventional actuated by the steering wheel of the vehicle (3). The forward direction (6) is for example assisted by a variable power assisted hydraulic steering box (not shown).
In the remainder of this description, for reasons of convenience, we have used the term "platform" to designate any type of border, access to the vehicle or any other physical, fixed, or mobile means in relation to the ground, on which travelers stand before boarding a vehicle. Also, the term "wharf" should not be interpreted in a limiting manner, but as referring to any similar type of border.
The assistance device (1) of the invention is preferably provided for a road transport vehicle (3), for example a bus, but it can be adapted to any type of road vehicle (3).
The assistance device (1) according to the invention is also intended to operate the rear axle (5) of a road vehicle (3) in two modes, namely a road mode and a docking mode. According to the invention, the rear axle (5) is also steering and equipped with a steering (7), but it is not controlled by the driver of the road vehicle (3). Indeed, the rear direction (7) is fully automatically controlled by the assistance device (1) according to the invention.
In order to control the steering angle of the rear wheels (9) in its two modes of operation, the assistance device (1) according to the invention comprises a steering device in the direction (10) of the rear axle (5). ). This steering device in direction (10) comprises an actuator, preferably in the form of a hydraulic cylinder associated with a proportional distributor, or in the form of an electric cylinder.
Generally, in road mode, the rear wheels (9) are straight at first and then, beyond a certain steering angle of the front wheels (11), the rear wheels (9) are slaved in a proportional manner relative to the steering control received by the front wheels (11).
According to a less advantageous variant of the invention, in road mode the rear wheels (9) are always straight, in the manner of a conventional vehicle.
By straight wheels is meant wheels that are not steered, that is to say with a steering angle of 0 ° corresponding to wheels aligned in the longitudinal direction of the vehicle.
In docking mode, the steering angle of the rear wheels (9) is controlled by the assistance device (1) according to the distances of the vehicle (3) from the platform (2) and other environmental obstacles. .
The two modes of operation of the assistance device (1) of the invention will now be described in more detail.
Road mode
In road mode, the rear axle (5) is provided for the normal driving of the vehicle (3) on the road (8), according to a maximum speed respecting the speed limits of the highway code. In this mode, the rear wheels (9) are slaved to the position of the front wheels (11) by a mathematical law taking into account the steering angle of the front wheels (11). This mathematical law governing the road mode is shown in FIG.
In road mode, the vehicle (3) can travel at a speed the size of which is incompatible with the maneuvers necessary when docking at a platform (2). For example, although it may be authorized by the Highway Code, it is not possible for a vehicle (3) to dock at a platform at a speed of 50 km / h.
In road mode, the rear wheels (9) are straight until the front wheels (11) are pointed in either direction beyond a certain angle, designated as the SAR release threshold -debioc, from which the rear wheels (9) are automatically steered by the assistance device (1) of the invention at a steering angle proportional to that of the front wheels (11).
Thus, as shown in FIG. 1, when the steering angle Aav of the front wheels (11) reaches the SAR-debioc threshold, the wheels (9) of the rear axle (5) are also pointed, according to a Aar angle proportional to the steering angle Aav of the front wheels (11).
According to a preferred embodiment of the invention, the servo-control of the rear wheels (9) to the front wheels is progressively carried out, which results in a curve at the level of the transition between the right position of the rear wheels (9 ) and their enslaved position in steering. This transition is obtained by a polynomial law of degree 2.
The mathematical laws governing the road mode are given below:
then Αλκ = 0
so
so
with:
in which the terms used have the following meaning: - Aav: steering angle of the front wheels (11), expressed in degrees - Aw-max: maximum steering angle of the front wheels (11), expressed in degrees - Aare: angle of rear wheel deflection (9), expressed in degrees - Aar -mav: maximum steering angle of the rear wheels (9), expressed in degrees - ATr: angle range for the transition, expressed in degrees - SAR-debioc: threshold for unlocking the rear wheels (9), expressed as a percentage
In the context of this description, it is considered that a steering angle of 0 for wheels corresponds to straight wheels, aligned along the longitudinal axis of the vehicle. The maximum steering angle Aar-mav of the rear wheels (9) intrinsically depends on the vehicle (3) and its construction. It is usually between about -35 ° and + 35 °. The steering angle Aav of the front wheels (11) is preferably measured by an angle sensor (12) which is connected to the steering box (13) of the front axle (4), while the steering angle Aar rear wheels (9) is preferably measured by a position sensor (14) connected to the actuator of the steering device in the direction (10) to measure the linear displacement. By means of a proportional integral proportional regulator (PID) the position sensor (14) then calculates the steering angle Aar of the rear wheels (9) as a function of the position of the actuator rod.
According to a variant of the invention (not shown), the steering angle Aav of the front wheels (11) is measured by an angle sensor which is housed in the pivot of at least one of the front wheels (11), while the steering angle Aar of the rear wheels (9) is measured by an angle sensor which is housed in the pivot of at least one of the rear wheels (9).
The angle range for the transition ΑχΓ is between 0 ° and 40 °. By default, it is 6 ° but can be refined empirically by real-world tests for each type of vehicle (3).
The threshold SAR-debioc unlocking of the rear wheels (9) is chosen according to the degree of control desired for the rear axle (5). The lower this threshold SAR-debioc, the more the driver may feel that the rear of the vehicle (3) "sweeps" too much. On the contrary, the higher the SAR-debioc threshold, the more the driving sensation approaches that of a conventional vehicle without assistance device (1) for docking maneuvers and the steering wheel movement is important. . The threshold for unlocking SAR-debioc of the rear wheels (9) is preferably chosen at 25%, but may for example be greater than 25%, the final value retained being obtainable empirically by real-life tests for each type of vehicle. vehicle (3).
In road mode, it is also possible to slave the rear wheels (9) by a modified mathematical law taking into account the speed of the vehicle (3).
According to this modified mathematical law, the steering angle Aar of the rear wheels (9) is multiplied by a coefficient kvit which depends on the speed of the vehicle, according to the following formulas: A'ar = Aar * kvit with: kyit = max ( 0; min (l; (pv * V) + (-SVar * Pv)) in which the terms used have the following meaning: - Aar: steering angle of the rear wheels (9), expressed in degrees and calculated according to the laws previous mathematics - A'ar: steering angle of the rear wheels (9), taking into account the speed, expressed in degrees - Aav: steering angle of the front wheels (11), expressed in degrees - pv: slope of the servo in speed, between -1 and 0 - Svar: maximum speed of the road mode, expressed in km / h - V: Speed of the vehicle, expressed in km / h
The maximum speed of the road mode Svar represents the maximum speed beyond which the rear axle (5) is fixed with the rear wheels (9) straight (0 °) when the assistance device (1) is in road mode. Indeed, beyond a certain speed of the vehicle (3), it is considered that it would be dangerous for the rear axle (5) to be steered as this could cause instability of the vehicle (3) at the rear. when the driver takes a turn. The maximum speed of the Svar road mode is 40 km / h by default in urban areas, but can be empirically refined by real-life tests for each type of vehicle (3) taking into account the specificities of the route on which it is based. is planned to circulate.
The slope of the servo-speed is between -1 and 0. By default it is equal to -0.1 but can be refined empirically by real-world tests for each type of vehicle (3).
Berthing mode
In docking mode, the rear axle (5) is provided to facilitate the docking of a vehicle (3) at a reduced speed at a platform (2). In this mode, the turning of the wheels (9) of the rear axle (5) is automatically controlled by the assistance device (1) according to the invention, with a large angle allowing the optimization of the berthing of the vehicle (3) at the wharf (2).
In docking mode, the vehicle (3) must travel at a reduced speed which is compatible with the maneuvers required when docking at a platform (2). Indeed, when a vehicle docked at a platform, it usually rolls slowly so as not to collide with its environment.
This reduced speed also makes it possible to secure the assistance device (1) in the event of a malfunction.
In order to optimize the docking of the vehicle (3), the assistance device (1) according to the invention comprises various sensors that make it possible to locate the vehicle (3) with respect to its environment, particularly with respect to the other vehicles, and with respect to the platform (2) at which the driver wishes to dock.
Note that some platforms are not equipped with specific borders and that in this case it is the sidewalk that serves as dock (2). Also, a platform may be the same height as a sidewalk and it is not possible to distinguish platform (2) and sidewalk in terms of height. For other platforms (2), on the contrary, the sidewalk may be located higher or lower than the platform (2).
According to a first variant of the invention shown in FIG. 2, the assistance device (1) comprises at least one distance sensor (16) situated at the rear of the vehicle (3) and designed to detect and measure specifically the distance ÜARquai from the rear of the vehicle (3) to the platform (2).
According to a second variant of the invention shown in FIG. 3, the assistance device (1) also comprises at least one distance sensor (17) located at the front and at least one distance sensor (18) located at the rear, each being intended to detect and measure distance ÜAVenv, Darchv to other environmental obstacles (cars, pedestrians, etc.). According to this second variant of the invention, the assistance device (1) also comprises at least one distance sensor (15) located at the front of the vehicle (3) and designed to specifically detect and measure the distance ÜAVquai at the wharf (2) at the front of the vehicle (3).
The distance sensor (17) to the environment located at the front can be optional because the assistance device (1) according to the invention does not take into account this distance to control the steering of the rear wheels (9) and the driver does not need this information if the visibility is good because he can estimate it himself from his driving position.
In these two variants of the invention, the distance sensors (15, 16, 17, 18) can be of any type. It can thus be radar, laser, infra-red, ultrasonic or optical devices, such as cameras.
Likewise, in these two variants, in addition to measuring the distance between the platform (2) and the vehicle (3), the distance sensors (15, 16) at the platform can also be provided for measuring the height of the obstacles, in particular the height of the wharf (2). This makes it possible, for example, in the case of public transport vehicles, to adjust the height of the vehicle (3) according to that of the platform (2) so that the floor of the vehicle (3) is at the same level as that of the vehicle. from the dock (2).
Thus, one may consider using the distance sensors (15, 16) at the dock, or other specific sensors, to measure the height of the dock so that the vehicle (3) can adjust its height and / or deploy a ramp when necessary to facilitate the ascent and descent of passengers. This adjustment of the height of the vehicle (3) is for example performed by acting on the suspensions thereof. The height adjustment of the vehicle (3) can be automatic during the stopping phase of the vehicle (3) and / or be triggered manually by the driver or the users, for example by means of a button located at the outside of the vehicle so as to be accessible for a disabled person in a wheelchair.
In the case of the second variant of the invention, the distance sensors (15, 17) provided at the front of the vehicle (3), in addition to measuring the distance ÜAVquai from the front of the vehicle (3) relative to at the platform (2) and the distance DAVenv from the front of the vehicle (3) relative to other obstacles in the environment to control the turning of the rear wheels (9) in an optimized manner, also provide a driving aid for the driver. Indeed, by a progressive feedback, preferably visual, the driver can optimize the placement of the front wheels (11) he directs with the vehicle steering wheel (3).
Thanks to the information of the distance sensors (16, 18) and the wheel angle sensor (14) provided at the rear of the vehicle (3), the driver also receives information about the steering angle Aar rear wheels (9) relating to the distance ÜARquai of the rear of the vehicle (3) from the platform (2) and concerning the distance Darchv from the rear of the vehicle (3) with respect to other obstacles in the environment for an even more optimized docking.
In the case of the second variant of the invention, for the front and the rear, the same distance sensor can fulfill both the function of a distance sensor (15, 16) intended to detect and measure specifically the distance ÜARquai, DAVquai at the platform (2) and that of a sensor (17, 18) intended to detect and measure the distance ÜARenv, DAvcnv to other obstacles in the environment.
In most cases, however, these are separate distance sensors because the sensors (15, 16) intended to specifically detect and measure the distance ÜARquai, ÜAVquai at the platform (2) are not necessarily located at the same height on the vehicle (3) that the sensors (17, 18) provided for detecting and measuring the distance ÜARenv, ÜAVenv to other obstacles in the environment. Thus, the distance sensors (15, 16) provided for specifically detecting and measuring the distance ΔARquai, ÜAVquai at the platform (2) can be provided at a lower level than the distance sensors (17, 18) provided for detecting and measuring the distance ÜARenv, ÜAVenv to other obstacles of the environment.
Indeed, certain environmental obstacles, such as the underside of a car (19) located on the floor (8) for example, may be located higher than the platform (2), but without touching the ground and would not be detected by a distance sensor located too low, while other obstacles in the environment could be located lower than the dock (2) and would not be detected by a distance sensor located too high.
According to another variant of the invention, it is possible to envisage a redundancy of the sensors (15, 16, 17, 18), for example by providing distance sensors (17, 18) to the environment and / or distance sensors. (15, 16) at the platform provided both at the front and at the rear of the wheels (9, 11) of the vehicle (3).
For a public transport vehicle intended to circulate on the right side of the road (8), the distance sensors (15, 16, 17, 18) of the invention are provided on the right side of the vehicle (3).
Preferably, the front distance sensors (15, 17) of the invention are provided in front of the front wheels (11), while the rear distance sensor at the platform (16) is provided in front of the rear wheels (9) and the distance sensor to the rear environment (18) is provided behind the rear wheels (9).
The distance sensors at the platform (15, 16) are preferably provided in front of the wheels (9, 11) because the approaching of the vehicle (3) is generally in the forward direction.
The distance sensors to the environment (17, 18) are preferably located at the front and rear ends of the vehicle (3) to be located closer to the obstacles of the environment they must detect.
In addition to the distance sensor at the rear environment (18), a second optional sensor (not shown) of the same type can be installed at the front of the rear wheels (9) so as to improve the detection accuracy of the environment.
In general, the distance sensors (15, 16, 17, 18) are provided on the vehicle (3) so as to detect and locate the obstacles as effectively as possible so that the road vehicle (3) does not collide with its environment, and that, during the approach phase of the platform (2), the steering angle Aar rear wheels (9) is optimized so that the wheels (9, 11) of the vehicle (3) does not do not collide with the platform (2), that the rear of the vehicle (3) does not approach the platform (2) faster than the front of the vehicle (3) and that the vehicle (3) finds itself parallel to the wharf (2) at the end of the approach phase, with the front (6) and rear (5) axles located closest to the wharf (2).
The distance information received by the distance sensors (15, 16, 17, 18) at the front and rear of the vehicle (3) is transmitted to the driver, preferably visually, and not audibly. because of the ambient noise usually encountered in public transport vehicles. The driver thus knows in real time the positioning of his vehicle (3) relative to the dock (2) and the environment.
The distance sensors DRAV and D4 are preferably provided with a detection range of between 0 and 1.5 meters.
For both variants of the invention, the assistance device (1) according to the invention also comprises a docking / road mode switch (20) which switches the assistance device (1) from the road mode to the docking mode. and vice versa when activated.
This docking / road mode switch (20) is preferably operated manually by means of a button (21) provided in the driving station of the vehicle (3), thus allowing the driver to switch the assistance device himself. (1) from the road mode in docking mode and vice versa.
According to a variant of the invention, this docking / road mode switch (20) can also be actuated by a contactless dialogue between the infrastructure (ground, platform, beacon, etc.) and the vehicle (3).
For the safety reasons already mentioned above, this docking / road mode switch (20) does not make it possible to switch the assistance device (1) from the road mode to the docking mode as long as the vehicle is traveling at a speed which corresponds to that of a road mode. Indeed, the assistance device (1) can not be accidentally switched from road mode to docking mode when the vehicle is traveling at a speed where it would be dangerous, and the assistance device (1) automatically switches to road mode in case of exceeding this speed.
Thus, the docking / road mode switch (20) does not allow to switch to docking mode as long as the vehicle is traveling at a speed greater than the maximum speed for docking VMAXoosting ·
In addition, when the vehicle speed (3) is greater than the maximum speed for docking VMAXaccostage, the assistance device (1) automatically switches to road mode
This maximum speed for VMAXaccostage docking is by default 25 km / h, but it can be empirically refined by real-life tests for each type of vehicle, depending on the specificities of the environment in which it is planned. that it circulates.
Finally, as shown diagrammatically in FIGS. 2 and 3, the assistance device (1) according to the invention also comprises an on-board intelligence (22), which is in particular connected to all the sensors (12, 14, 15, 16, 17, 18) of the invention, the steering device in the direction (10) of the rear axle (5) and the docking / road mode switch (20).
This embedded intelligence (22) comprises in particular a memory (not shown) in which are stored the mathematical formulas used by the assistance device (1) according to the invention, as well as the values of the constants used in these formulas. Of course, means (not shown) are provided to be able to enter and modify these mathematical formulas and constants in the embedded intelligence (22), whether directly or remotely. The embedded intelligence (22) may include means (not shown) for transmitting information to the driver, preferably visually.
Preferably, the assistance device (1) according to the invention also comprises a monitoring device (not shown) of the rear axle (5), designed to detect any anomaly at the level thereof, for example a electronics failure, hydraulic failure, general malfunction, inconsistency, etc. In the case where an anomaly is detected, the rear axle (5) is put in the safety position, fixing the rear wheels (9) in their central position, parallel to the longitudinal axis of the vehicle.
It will be noted that the first variant of the invention, which comprises for example only one distance sensor (16) at the platform (2) situated at the rear of the vehicle (3), is a rudimentary and simplified version of the invention, while the second variant of the invention, which includes many other distance sensors (15, 17, 18), is a more elaborate and more complex version of the invention. The first variant of the invention is therefore less expensive than the second, but it also provides assistance less optimized for the driver during his approach and departure maneuvers of a platform (2).
We will now focus on the operation of the assistance device (1) for the docking maneuvers at a platform (2) according to these two variants of the invention during the different phases encountered during a docking.
Driving phase
When the vehicle (3) is traveling at a normal speed, to move quickly from one place to another, the assistance device (1) according to the invention is switched to road mode. The rear wheels (9) are straight, as in a conventional vehicle (FIG. 4), or slaved in position relative to the front wheels (11) if the driver steers the front wheels (11) beyond a certain angle of robbery SAR-debioc ·
Approach phase (for the first variant ^
During the approach phase during docking at a platform (2), the driver drives his vehicle (3) at a reduced speed and the assistance device (1) according to the invention is switched to docking mode.
Thus, the approach phase is initiated when the vehicle is traveling at a speed below the maximum speed for docking VMAXaccostage and the docking / road mode switch (20) has been manually operated by the driver to switch the device. assistance (1) of the road mode in docking mode. The rear axle (5) is slaved so that it approaches closer to the platform (2) until the rear distance sensor (16) has detected the platform (2) (Figures 4 and 5). The steering angle Aar of the wheels (9) of the rear axle (5) is then proportional to the steering angle Aav of the wheels (11) of the front axle (4) multiplied by an angular ratio R-dockingSimpi as given in the following formula:
Aar - Aav * RAcostageSimpl
The angular ratio R-dockingSimpi is preferably between 0 and 10. Its default value is equal to 2, but it can be adjusted empirically by real-world tests for each type of vehicle.
When the rear distance sensor (16) detects the platform (2), the rear axle (5) is driven in docking mode and the rear wheels (9) are steered so that the rear axle (5) reaches the maximum near the wharf (2) without colliding with it (Figure 6). This operation can cause the vehicle (3) to move crab.
The steering of the rear wheels (9) is adapted according to the distance ÜARquai of the rear of the vehicle (3) relative to the platform (2), so that the wheels (9, 11) of the vehicle (3) enter not in collision with the platform (2). The steering angle Aar of the rear wheels (9) is thus calculated as a function of the previous measured distance, as given in the following formula:
Aar - min (Aav * RAcostageSimpl, f (DARquai)) f (pARquai) is a polynomial law of degree 2 of type:
(& quaiAR * X2) (bquaiAR * x) CquaiAR
The factors of the above formula can be empirically adjusted by real-world tests for each type of vehicle (3) taking into account the specificities of the type of place where it performs its docking maneuvers.
By default, these factors have the following values: aQUaiAR = -0.0305 bquaiAR 6.381 CquaiAR 44
Approach phase (for the second variant)
During the approach phase during docking at a platform (2), the driver drives his vehicle (3) at a reduced speed and the assistance device (1) according to the invention is switched to docking mode.
The wheels of the rear axle (5) remain driven in road mode as long as the front distance sensor (15) has not detected the platform (2) (Figure 5).
When the front distance sensor (15) detects the platform (2), the rear axle (5) is driven in docking mode and the rear wheels (9) are steered so that the rear axle (5) reaches the highest point. near the wharf (2) (Figure 6). This operation can cause the vehicle (3) to move crab if the environment allows it, or to move more conventionally in case of obstacle to avoid.
The steering of the rear wheels (9) is adapted according to the following measures: the distance ÜARenv from the rear of the vehicle (3) relative to the other obstacles of the environment, so that the vehicle (3) does not enter in collision with his environment; the distance ÜARquai from the rear of the vehicle (3) with respect to the platform (2), so that the wheels (9, 11) of the vehicle (3) do not collide with the platform (2); - the distance ÜAVquai from the front of the vehicle (3) relative to the platform (2), so that the rear of the vehicle (3) does not approach the platform (2) faster than the front of the vehicle ( 3). The steering angle Aar of the rear wheels (9) is thus calculated as a function of the three previous measured distances, as given in the following three formulas:
Aar = min (1 (Dar env) 3f (DARquai), f (DAVquai)) f (DARenv) is a polynomial law of degree 2 of type: (aenv * X2) + (benv * x) + Cenv f (DARquai ) is a polynomial law of degree 2 of type:
(& quaiAR * X2) + (bquaiAR * x) CquaiAR f (DAVquai) is a polynomial law of degree 1 of type:
3 <| u a i A V * (D AV wharf "DARquai) bquaiAV
The various factors of the three formulas above are interdependent on each other and are intrinsically related to the type of vehicle (3) equipped with the assistance device (1) according to the invention.
These factors can be empirically adjusted by real-world tests for each type of vehicle (3), taking into account the specificities of the type of place where it performs its docking maneuvers.
By default, these factors have the following values: & env - 0 benv - 4.4
Cenv 50 aQUaiAR 0.0305 bquaiAR - 6.381 CquaiAR 44 BquaiAV- 0.5 bquaiAV - 0
Stop phase (for both variants)
When the vehicle (3) is docked (2), it marks a stop on the spot. He enters temporarily stop phase.
In the case of a public transport vehicle, the driver authorizes the opening of the doors.
During the stopping phase, the rear wheels (9) are preferably controlled so as to be straight so as to be located closer to the platform (2), but this can increase the wear of the tires, also this orientation right rear wheels (9) can be optional.
The vehicle (3) is located closer to the platform (2), both at the front and at the rear, so as to facilitate the ascent and descent of the passengers (Figure 7) ·
Starting phase (for both variants')
Once the rise and descent of passengers is complete, the vehicle (3) can leave the dock (2).
In the case of a public transport vehicle, the driver then condemns the opening of the doors, which initiates the departure phase. For obvious safety reasons, this phase can only be effective once the doors are closed and locked
Thus, the rear axle (5) remains locked with the rear wheels (9) preferably in the upright position as the doors are not locked.
Once the doors are locked, traction is again available for the driver who can leave the dock (2).
The assistance device (1) according to the invention is then switched to docking mode.
During this starting phase, the assistance device (1) of the invention prohibits the rear axle (5) to steer the rear wheels (9) towards the dock (2). The rear wheels (9) are in fact turned in the opposite direction (FIG. 8) proportionally to the steering control received by the wheels (11) of the front axle (4) according to the following formula:
Aar - Aav * kpart in which kpart is a proportionality percentage expressed as a percentage.
By default, k start is chosen with a value of 20%. As before, this value can be refined empirically.
According to a variant of the invention, during the starting phase, the rear wheels (9) are not steered proportionally to the steering control received by the wheels (11) of the front axle (4), but steered according to a fixed steering angle, for example equal to 5 ° to the left.
According to another variant of the invention, the rear wheels (9) are turned in the same way as during the approach phase but in a reverse manner. Thus, the rear axle (5) leaves the platform (2) as quickly as possible without ever colliding with its environment and without moving away from the platform (2) faster than the front axle (6).
Driving phase (for both variants)
When the vehicle (3) has finished leaving the platform (2) (FIG. 9), the starting phase is completed and the assistance device (1) according to the invention is switched to road mode (FIG. 10). The vehicle (3) is then again in rolling phase (Figure 11).
Once the vehicle (3) has completed its starting phase, the tilting of the assistance device (1) of the invention in road mode can be done manually by the driver by means of the docking / road mode switch (20). ), automatically when the vehicle speed (3) is greater than the maximum speed for VMAXaccostage docking (by default equal to 10 km / h) or automatically when the steering angle Aav to the right of the front wheels (11) is greater than an ashing angleMessage exit steering angle. The asset angleMatching exit steering angle can be expressed as an absolute angle or as a percentage of the maximum steering angle AAv-max of the front wheels (11). This angle aspartageEstage is preferably equal to 5 ° to the right, this value can be refined empirically.
Reverse (for the first variant)
The assistance device (1) for docking maneuvers at a platform (2) according to the first variant of the invention is also provided to be able to be used during a reverse of the vehicle (3) which is equipped, for all driving modes of the rear axle (5).
In the driving phase, the assistance device (1) is in road mode and no modification of the driving law is necessary.
In the approach phase, as long as the rear distance sensor (16) does not detect the platform (2), the piloting law is not modified. When the rear distance sensor (16) detects the platform (2), then the piloting law is reversed, that is to say that the rear wheels (9) are driven so as to approach the dock, without never collide with it.
In the stopping phase and in the starting phase, the control law is reversed as before.
Reverse (for the second variant)
The assistance device (1) for docking maneuvers at a platform (2) according to the second variant of the invention is also provided during a reverse gear of the vehicle (3) which is equipped with it, for all the driving modes of the rear axle (5).
In the driving phase, the assistance device (1) is in road mode and no modification of the driving law is necessary.
In the approach phase, as long as the front distance sensor (15) does not detect the platform (2), the control law is not modified. When the front distance sensor (15) detects the platform (2), then the piloting law is reversed, that is to say that the rear wheels (9) are driven so as to approach the dock, without never collide with it.
In the stopping phase and in the starting phase, the control law is reversed as before.
It is obvious that the present description is not limited to the examples explicitly described, but also includes other embodiments and / or implementation. Thus, a technical characteristic described may be replaced by an equivalent technical characteristic without departing from the scope of the present invention and a described step of implementing the method may be replaced by an equivalent step without departing from the scope of the invention as defined by the claims.

权利要求:
Claims (21)
[1" id="c-fr-0001]
Road vehicle (3) comprising front wheels (11) mounted on a front steering axle (4) and rear wheels (9) mounted on a rear axle (5), characterized in that it comprises a device assistance (1) for docking maneuvers at a platform (2) and in that the rear axle (5) is steered and equipped with a steering (7), the assistance device (1) being adapted to operate in a road mode or in a docking mode and comprising the following means: - a steering device in a direction (10) provided for controlling the steering angle Aar of the rear wheels (9); - a distance sensor (16) provided at the rear of the vehicle (3) for measuring the distance √ARquai of the rear of the vehicle (3) relative to the dock (2); in which: - in road mode, either the rear wheels (9) are straight, or their steering angle Aar is controlled by the steering device in the direction (10) according to the steering angle Aav of the front wheels (11). ); - in docking mode, the steering angle of the rear wheels (9) is controlled by the steering device in direction (10) as a function of the distances measured by the distance sensor (16) and as a function of the steering angle Aav front wheels (11).
[2" id="c-fr-0002]
2. Road vehicle (3) according to claim 1, characterized in that the assistance device further comprises the following means: - a distance sensor (15) provided at the front to measure the distance DAvquai forward the vehicle (3) with respect to the platform (2); - a distance sensor (18) provided at the rear of the vehicle (3) for measuring the distance ÜARenv from the rear of the vehicle (3) relative to other obstacles in the environment; in which: - in road mode, either the rear wheels (9) are straight, or their steering angle Aar is controlled by the steering device in the direction (10) according to the steering angle Aav of the front wheels (11). ); - In docking mode, the steering angle of the rear wheels (9) is controlled by the steering device in the direction (10) as a function of the distances measured by the distance sensors (15, 16, 18).
[3" id="c-fr-0003]
3. Road vehicle (3) according to any one of the preceding claims, characterized in that the assistance device further comprises a distance sensor (17) provided at the front of the vehicle (3) for measuring the distance ÜAVenv from the front of the vehicle (3) relative to other obstacles in the environment.
[4" id="c-fr-0004]
4. Road vehicle (3) according to any one of the preceding claims, characterized in that the rear wheels (9) can be steered at an angle whose absolute value is greater than 10 °, preferably greater than 20 ° and more preferably greater than 30 °.
[5" id="c-fr-0005]
Road vehicle (3) according to one of the preceding claims, characterized in that, in road mode, the steering device (10) controls the steering angle Aar of the rear wheels (9) so that the rear wheels (9) are at first straight then, beyond a certain steering angle of the front wheels (11), the rear wheels (9) are slaved in a proportional and linear manner with respect to the control of steering received by the front wheels (11).
[6" id="c-fr-0006]
6. Road vehicle (3) according to any one of the preceding claims, characterized in that in road mode the rear axle (5) is fixed with the rear wheels (9) straight when the vehicle speed (3) is greater than the maximum speed of the road mode Svar ·
[7" id="c-fr-0007]
Road vehicle (3) according to one of the preceding claims, characterized in that the assistance device (1) switches automatically from the docking mode to the road mode when the vehicle speed is greater than a maximum speed for the vehicle. VMAX docking or when the steering angle Aav of the front wheels (11) is greater than a corner angle.
[8" id="c-fr-0008]
8. Road vehicle (3) according to any one of the preceding claims, characterized in that the assistance device (1) comprises sensors for measuring the steering angle Aav of the front wheels (11) and the angle A steering wheel rear wheels (9).
[9" id="c-fr-0009]
9. Road vehicle (3) according to claim 8, characterized in that the front axle (4) comprises a steering box (13) and in that the steering angle Aav of the front wheels (11) is measured by an angle sensor (12) which is connected to this steering box (13).
[10" id="c-fr-0010]
10. Road vehicle (3) according to claim 8 characterized in that the steering device in the direction (10) comprises a movable rod actuator and in that the steering angle Aar of the rear wheels (9) is measured by a position sensor (14) connected to the actuator of the steering device in the direction (10), the steering angle Aar of the rear wheels (9) being calculated according to the position of the rod of the actuator.
[11" id="c-fr-0011]
11. Road vehicle (3) according to claim 1, 2 or 3, characterized in that the distance sensors (15, 16, 17, 18) are provided on the right side of the vehicle (3).
[12" id="c-fr-0012]
Road vehicle (3) according to claim 1, 2 or 3, characterized in that the distance sensors (15, 17) provided on the front of the vehicle (3) are provided in front of the front wheels (11), in the distance sensor at the dock (16) provided at the rear of the vehicle (3) is provided in front of the rear wheels (9), and in that the rear environmental sensor (18) is provided at the rear rear wheels (9).
[13" id="c-fr-0013]
Road vehicle (3) according to claim 1, 2 or 3, characterized in that the distance information at the front and at the rear which is received by the distance sensors (15, 16, 17, 18). are transmitted to the driver visually.
[14" id="c-fr-0014]
Road vehicle (3) according to one of the preceding claims, characterized in that the assistance device (1) comprises a docking / road mode switch (20) which switches the assistance device (1). from the road mode in docking mode and vice versa when activated.
[15" id="c-fr-0015]
15. Road vehicle (3) according to the preceding claim, characterized in that the docking / road mode switch (20) is actuated manually by the driver by means of a button (21) provided in the driving station of the vehicle ( 3) or that it is actuated by a contactless dialogue between the infrastructure and the vehicle (3).
[16" id="c-fr-0016]
16. Road vehicle (3) according to claim 14, characterized in that the docking / road mode switch (20) does not make it possible to switch the assistance device (1) from the road mode to the docking mode as long as the vehicle (3) rolls at a speed greater than the maximum speed for VMAxaccostage docking.
[17" id="c-fr-0017]
17. Road vehicle (3) according to any one of the preceding claims, characterized in that the assistance device (1) also comprises an onboard intelligence (22) which controls the steering device in the direction (10) of the rear axle (5).
[18" id="c-fr-0018]
Road vehicle (3) according to claims 8, 14 and 17, characterized in that the on-board intelligence (22) is connected to the distance sensors (15, 16, 18), to the sensors for measuring the angle of AAv steering of the front wheels (11) and the steering angle Aar of the rear wheels (9), and to the docking / road mode switch (20).
[19" id="c-fr-0019]
19. Road vehicle (3) according to claim 18, characterized in that the onboard intelligence (22) comprises a memory in which are stored the mathematical formulas used by the assistance device (1) to control the steering angle rear wheels (9) in road mode and in docking mode, as well as the values of the constants used in these formulas.
[20" id="c-fr-0020]
20. Docking method for a road vehicle (3) according to any one of the preceding claims, characterized in that it comprises the following successive stages: a) a rolling phase, when the vehicle (3) circulates in a conventional manner, wherein the assistance device (1) is switched to road mode and wherein the rear wheels (9) are straight or slaved to the forward direction; b) an approach phase, when the vehicle (3) starts docking at a platform (2), in which the assistance device (1) is switched to docking mode, in which the rear wheels (9) remain in road mode as long as the forward distance sensor (15) has not detected the platform (2), and in which, when the forward distance sensor (15) detects the platform (2), the rear wheels (9) are driven by the assistance device (1) and steered so that the rear axle (5) is moved towards the platform (2); c) a stopping phase, when the vehicle (3) is docked (2); d) a departure phase, when the vehicle (3) leaves the platform (2), in which the assistance device (1) is tilted in docking mode and in which the rear wheels (9) are steered so that the rear axle (5) is moved away from the platform (2); e) a driving phase, when the vehicle (3) circulates conventionally after having left the platform (2), in which the assistance device (1) is tilted in road mode and in which the rear wheels ( 9) are straight or slaved to the front direction.
[21" id="c-fr-0021]
21. Method of docking according to the preceding claim, characterized in that during the stopping phase, the rear wheels (9) are controlled so as to be returned to non-steered position.

类似技术:

公开号 | 公开日 | 专利标题

EP3371035B1|2019-10-16|Device to assist with manoeuvres for parking alongside a platform

EP1892688B1|2010-09-01|Method for determining the passing of a vehicle in a bottleneck

EP1268255B1|2004-01-14|Method and device for managing slot parking of motor vehicles

FR2965778B1|2019-06-07|DEVICE AND METHOD FOR ASSISTING A VEHICLE DRIVER FOR A MANEUVER

CA2901305C|2021-01-05|Towable road motor vehicle

EP3152097B1|2019-04-03|Parking assistance device and vehicle provided with such a device

FR2976245A1|2012-12-14|METHOD AND DEVICE FOR DETERMINING A COMMITMENT TRACK IN A PARKING PLACE

FR2987588B1|2019-07-05|METHOD FOR AVOIDING OR MITIGATING THE CONSEQUENCES OF A COLLISION OF A VEHICLE WITH AN OBSTACLE IN THE SIDE AREA CLOSE TO THE VEHICLE AND DRIVING ASSISTANCE SYSTEM USING THE SAME

FR2969098A1|2012-06-22|METHOD AND DEVICE FOR ASSISTING THE DRIVER OF A VEHICLE

WO1994027854A1|1994-12-08|Unit for directionally guiding a transport vehicle along a rail

WO2019118219A1|2019-06-20|Methods and systems for controlling extent of light encountered by an image capture device of a self-driving vehicle

FR2961462A1|2011-12-23|AUTOMATIC FUNCTION STORAGE MANEUVER ASSIST SYSTEM

EP3115280B1|2018-04-18|Automatic driving method for inserting and removing a vehicle in a docking station, and monitoring device implementing such a method

EP3147180B1|2020-02-19|Driving assistance system and method for vehicle

FR3096327A1|2020-11-27|Driving test device for vehicle

WO2018069061A1|2018-04-19|Method of formulating a piloting supervision setpoint for a driving member of an automotive vehicle

WO2021047890A1|2021-03-18|Method for autonomous driving start-up of a motor vehicle

WO2020094639A1|2020-05-14|Method for determining a trajectory of an autonomous vehicle

WO2020099098A1|2020-05-22|Method and system for obstacle avoidance, involving the control of steering and differential braking systems

FR2913798A1|2008-09-19|Motor vehicle ability determining method for use in e.g. parking space, in roadway, involves detecting restricted gap in roadway, and defining vehicle image of vehicle, and comparing vehicle image with restricted gap

EP3377386A1|2018-09-26|Driver assistance method for a motor vehicle

FR3056803A1|2018-03-30|DEVICE FOR ASSISTING THE DRIVING OF A VEHICLE BY DETERMINING AND DISPLAYING A SPEED ADAPTATION DISTANCE OF THE VEHICLE

WO2017097786A2|2017-06-15|Driver-assistance method and device

同族专利:

公开号 | 公开日

SG11201803554SA|2018-05-30|

FR3043049B1|2017-12-08|

ECSP18041810A|2018-07-31|

KR20180093901A|2018-08-22|

RU2719494C2|2020-04-20|

JP6845248B2|2021-03-17|

CO2018005482A2|2018-08-10|

JP2018536588A|2018-12-13|

MX2018005303A|2018-08-15|

CN108290608B|2021-08-17|

US20180319439A1|2018-11-08|

CN108290608A|2018-07-17|

CA3003916A1|2017-05-11|

PT3371035T|2020-01-22|

IL258948D0|2018-06-28|

EP3371035B1|2019-10-16|

RU2018120304A3|2020-02-28|

ES2765801T3|2020-06-11|

EP3371035A1|2018-09-12|

BR112018008871A2|2019-04-24|

RU2018120304A|2019-12-05|

PL3371035T3|2020-05-18|

WO2017077223A1|2017-05-11|

引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

EP1304278A2|2001-10-18|2003-04-23|Delphi Technologies, Inc.|Four wheel steering compensation for low coefficient of friction surface|

FR2916721A1|2007-06-04|2008-12-05|Renault Sas|Four wheel motor vehicle i.e. car, has side environment sensors provided on walls of vehicle for measuring distance between obstacle and vehicle, and control unit controlling steering angle of two steered rear wheels based on distance|

JPH0115431B2|1984-12-04|1989-03-17|Daihatsu Motor Co Ltd|

DE10128792B4|2001-05-08|2005-06-09|Daimlerchrysler Ag|Collision protection for vehicles|

US20060235590A1|2005-02-11|2006-10-19|Farhad Bolourchi|Parking assist utilizing steering system|

DE102005025203A1|2005-05-25|2006-12-07|Valeo Schalter Und Sensoren Gmbh|Parking method for parking a motor vehicle in a parking-space uses a longitudinal axis parallel to the vehicle's longitudinal axis|

JP2007030700A|2005-07-27|2007-02-08|Aisin Seiki Co Ltd|Parking support device|

DE102006027114A1|2006-06-12|2007-12-13|Robert Bosch Gmbh|Control device and method for driver assistance|

JP2008143430A|2006-12-12|2008-06-26|Toyota Motor Corp|Parking support device|

JP2008201178A|2007-02-16|2008-09-04|Toyota Motor Corp|Parking assist device|

DE102010021761B4|2010-05-27|2016-02-11|Audi Ag|Method and device for adjusting steering angles of a four-wheel steering system for a motor vehicle|

CN102514620A|2011-11-24|2012-06-27|华南农业大学|Tractor identical-track steering mechanism and steering method thereof|

RU2561188C2|2013-12-31|2015-08-27|Федеральное государственное бюджетное образовательное учреждение высшего профессионального образования "Московский автомобильно-дорожный государственный технический университет "|Urban vehicle|FR3072069B1|2017-10-10|2019-09-20|Commissariat A L'energie Atomique Et Aux Energies Alternatives|METHOD FOR AUTOMATICALLY DRIVING A VEHICLE, IN PARTICULAR A BUS IN A STORAGE CENTER, AND DEVICE IMPLEMENTING SAID METHOD|

CN111746393A|2019-03-29|2020-10-09|比亚迪股份有限公司|Vehicle control method, vehicle control device and vehicle|

CN112193243B|2020-10-20|2022-01-28|河北工业大学|Multi-steering mode control method based on obstacle avoidance system|

RU202907U1|2020-11-27|2021-03-12|Акционерное общество "Автомобильный завод "УРАЛ"|TRAINING HYDRAULIC DRIVE SYSTEM FOR REAR STEERED AXLE OF VEHICLE|

法律状态:
2016-10-10| PLFP| Fee payment|Year of fee payment: 2 |

2017-05-05| PLSC| Publication of the preliminary search report|Effective date: 20170505 |

2017-10-06| PLFP| Fee payment|Year of fee payment: 3 |

2017-11-03| CA| Change of address|Effective date: 20170928 |

2018-10-19| PLFP| Fee payment|Year of fee payment: 4 |

2020-02-07| PLFP| Fee payment|Year of fee payment: 5 |

2020-08-04| PLFP| Fee payment|Year of fee payment: 6 |

2020-10-30| TP| Transmission of property|Owner name: ALSTOM APTIS, FR Effective date: 20200917 |

2021-11-29| PLFP| Fee payment|Year of fee payment: 7 |

优先权:

申请号 | 申请日 | 专利标题

FR1560531A|FR3043049B1|2015-11-03|2015-11-03|ASSISTANCE DEVICE FOR DOCKING APPROACHES AT DOCK LEVEL|FR1560531A| FR3043049B1|2015-11-03|2015-11-03|ASSISTANCE DEVICE FOR DOCKING APPROACHES AT DOCK LEVEL|

PL16806230T| PL3371035T3|2015-11-03|2016-10-27|Device to assist with manoeuvres for parking alongside a platform|

PCT/FR2016/052788| WO2017077223A1|2015-11-03|2016-10-27|Device to assist with manoeuvres for parking alongside a platform|

MX2018005303A| MX2018005303A|2015-11-03|2016-10-27|Device to assist with manoeuvres for parking alongside a platform.|

PT168062305T| PT3371035T|2015-11-03|2016-10-27|Device to assist with manoeuvres for parking alongside a platform|

JP2018541567A| JP6845248B2|2015-11-03|2016-10-27|A device to assist in maneuvering to stop along the platform|

RU2018120304A| RU2719494C2|2015-11-03|2016-10-27|Device to assist with manoeuvres for parking alongside platform|

CN201680069855.7A| CN108290608B|2015-11-03|2016-10-27|Auxiliary device for docking operation at platform|

US15/772,927| US20180319439A1|2015-11-03|2016-10-27|Device to assist with maneuvers for parking alongside a platform|

CA3003916A| CA3003916A1|2015-11-03|2016-10-27|Device to assist with manoeuvres for parking alongside a platform|

EP16806230.5A| EP3371035B1|2015-11-03|2016-10-27|Device to assist with manoeuvres for parking alongside a platform|

ES16806230T| ES2765801T3|2015-11-03|2016-10-27|Assistive device for docking maneuvers in a dock|

KR1020187015168A| KR20180093901A|2015-11-03|2016-10-27|Auxiliary system for steering parking on platform|

BR112018008871-4A| BR112018008871A2|2015-11-03|2016-10-27|road vehicle with an assistance system for berthing maneuvers and berthing|

IL258948A| IL258948D0|2015-11-03|2018-04-26|Assistance system for the berthing manoeuvres at a pier|

CONC2018/0005482A| CO2018005482A2|2015-11-03|2018-05-25|Assistance system for docking maneuvers on a jetty|

[返回顶部]