Method/device for improving braking performance on wheeled vehicle

Abstract

The present invention provides a method/device to improve braking performance on a wheeled vehicle comprising at least one driving axle, the wheeled vehicle further comprising a collision warning system and an emergency braking system and an air suspension system, the air suspension system comprising at least one air suspension module associated with the at least one driving axle and the air suspension system being configured to control the air pressure in the at least one air suspension module associated with the at least one driving axle, the collision warning system being configured to monitor the environment of the wheeled vehicle, and to determine if and when the emergency braking system may need to be actuated, so that when the collision warning system determines the emergency braking system may need to be actuated, the method being implemented by the collision warning system and comprising one step implemented before eventually actuating the emergency braking system, said step comprising actuating the air suspension system to increase the air pressure on the at least one of air suspension module associated with the at least one driving axle.

Claims

1. A wheeled vehicle comprising at least one driving axle, a collision warning system, an emergency braking system, and an air suspension system comprising at least one air suspension module associated with the at least one driving axle and configured to control air pressure in the at least one air suspension module wherein: the collision warning system is configured to: monitor an environment of the wheeled vehicle, determine whether to actuate the emergency braking system based on the environment, when the collision warning system determines to actuate the emergency braking system, actuate the air suspension system to increase the air pressure on the at least one air suspension module prior to actuating the emergency braking system; and actuate the emergency braking system.

2. The wheeled vehicle of claim 1 wherein the collision warning system comprises a sensor for collecting information on the environment of the wheeled vehicle, and the collision warning system uses the information collected from the sensor to determine whether to actuate the emergency braking system.

3. A method of operating a collision warning system of a wheeled vehicle comprising at least one driving axle, an emergency braking system, and an air suspension system comprising at least one air suspension module associated with the at least one driving axle and configured to control air pressure in the at least one air suspension module, the method comprising: monitoring the environment of the wheeled vehicle, determining whether to actuate the emergency braking system based on the environment, when the collision warning system determines to actuate the emergency braking system, actuating the air suspension system to increase the air pressure on the at least one air suspension module prior to actuating the emergency braking system; and actuating the emergency braking system.

4. The method of claim 3 wherein the collision warning system comprises a sensor for collecting information on the environment of the wheeled vehicle, and the collision warning system uses the information collected from the sensor to determine whether to actuate the emergency braking system.

5. A non-transitory computer-readable storage medium for a collision warning system of a wheeled vehicle comprising at least one driving axle, an emergency braking system, and an air suspension system comprising at least one air suspension module associated with the at least one driving axle and configured to control air pressure in the at least one air suspension module, the non-transitory computer-readable storage medium comprising a computer program product including instructions to cause at least one processor to: monitor an environment of the wheeled vehicle, determine whether to actuate the emergency braking system based on the environment, when the collision warning system determines to actuate the emergency braking system, actuate the air suspension system to increase the air pressure on the at least one air suspension module prior to actuating the emergency braking system; and actuate the emergency braking system.

6. The non-transitory computer-readable storage medium of claim 5 wherein the collision warning system comprises a sensor for collecting information on the environment of the wheeled vehicle, and the information collected from the sensor is used to determine whether to actuate the emergency braking system.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Below follows a more detailed description of embodiments of the invention cited as examples, in reference to the figures.

(2) FIG. 1 is a schematic bottom view of a truck comprising three pairs of axles.

(3) FIG. 2 is a schematic side view of a truck comprising four pairs of axles, with one pair of driving axles.

(4) FIG. 3 is a schematic illustration of a method according to the invention.

DETAILED DESCRIPTION OF EXAMPLE EMBODIMENTS OF THE INVENTION

(5) One embodiment of the invention will now be described by taking a truck as an example of a wheeled vehicle. But the vehicle could be any other wheeled vehicle.

(6) FIG. 1 represents a bottom view of a truck 100, showing in particular the wheels of the truck, each wheels being associated with an axle; an air suspension module or air pillow 10, 11, . . . , 15 is associated with each axle. Some axles are driving axle, others are simple axle. Driving axles are put in motion by the engine, through a gearbox. Simple axles are not motioned by the engine.

(7) Also represented on FIG. 1 is a collision warning system installed on the truck 100 and composed of a first electronic control unit 1 and of sensors 16, 17 configured to gather information from the environment of the truck and communicating this information to the first electronic control unit 1 which is configured to determine from this information whether the truck is approaching a dangerous traffic situation. As an example, the sensors 16, 17 may be a radar, a lidar, and/or a camera. Information from these sensors is communicated to the first electronic control unit 1 to be processed; as a result of the processing of information communicated by the sensors, the electronic control unit determines if an alert shall be communicated to the driver as well as if the emergency braking system must be actuated.

(8) The first electronic control unit 1 is connected to a second electronic control unit 2; the second electronic control unit 2 is configured to control the air-pressure in each air suspension module 10, 11, . . . , 15 corresponding to each axles of the truck; the air pressure in each air suspension modules is regulated through electro-valves electrically connected and controlled by the second electronic control unit 2. The air pressure regulation depends on the truck weight repartition and vehicle altitude, in order to maintain the vehicle at a correct attitude while cruising.

(9) FIG. 2 illustrates the repartition of air pressure among the different axles on a truck having four pair of axles. On the example illustrated by FIG. 2, the air pressure allocated by the air suspension system to the front pair of axles is P1% of the total air pressure; the air pressure allocated by the air suspension system to the rear pair of axles is P4% of the total air pressure; the air pressure allocated by the air suspension system to the two median pair of axles is, respectively, P2% and P3% of the total air pressure.

(10) When the air pressure allocated to a chosen axle is increased, the grip between the wheel attached to this chosen axle and the road is immediately increased; and consequently, if the grip is increased the braking performance will be improved, provided the braking is applied on this wheel.

(11) Since the braking applies with maximum power on wheels attached to driving axles, air pressure must be increased on driving axles to improve the braking performance.

(12) FIG. 3 illustrates a schematic illustration of a method according to the invention. Therefore the method 200 according to the invention comprises the following step 201, implemented by the first electronic control unit 1 of the collision warning system, as soon as it has determined that the emergency braking system may need to be actuated, this step 201 being implemented before the emergency braking system is actuated: actuate the air suspension system to increase the air pressure on at least one of air suspension module associated with at least one driving axle.

(13) The invention concerns also a wheeled vehicle 100, such as a truck, implementing the previously described method 200.

(14) The invention also concerns a computer program comprising program code means suitable for performing the previously described method 200, when the program code means are implemented on the first electronic control unit 1 of the collision warning system of a wheeled vehicle 100 according to the invention, as well as computer-readable means comprising such a recorded computer program.