The disclosure relates to automated driving systems for a motor vehicle, in particular for chassis, braking, steering and associated communications.
The increasing availability of technology has led to automotive vehicle becoming more automated. In particular, safety systems which assist in braking and steering in emergency situations make driving such vehicles safer. Further communications between vehicles, or vehicle and infrastructure is also becoming more popular to provide traffic and safety information to and/or from vehicles.
Vehicle-to-X communications is currently in a phase of development and standardization. This term is understood to mean in particular communication between vehicles (vehicle-to-vehicle communication) and communication between vehicles and infrastructure (vehicle-to-infrastructure communication).
With the increase in technology the driver interaction with the vehicle control systems is decreasing. With fully autonomous guidance the vehicle can maneuver itself independently in traffic and thus completely unburden the driver of the vehicle operation. As these systems become more independent the need to provide HMI and other controls available in the passenger compartment to the driver is less important.
The background description provided herein is for the purpose of generally presenting the context of the disclosure. Work of the presently named inventors, to the extent it is described in this background section, as well as aspects of the description that may not otherwise qualify as prior art at the time of filing, are neither expressly nor impliedly admitted as prior art against the present disclosure.
An end module for assembly on a vehicle body comprising at least two wheels, a frame having connection points for removably securing the end module to the vehicle body, a drive system connected to the wheels and capable of providing torque to drive the wheels, wherein the drive system includes at least a drive controller for controlling an electric motor and an inverter to drive the wheels, a brake system connected to the wheels having a brake controller, an actuator and at least one wheel brake located at each wheel, wherein the brake controller is capable of determining a desired braking action and actuating the actuator apply the wheel brakes to slow rotation of the wheels, a suspension system located between the frame and the at least two wheels, wherein the suspension system provides shock absorption and damping to the frame and vehicle body relative to the wheels, a steering system connected to each of the at least two wheels, wherein the steering system having a steering controller capable of providing a steering input for each of the at least two wheels, and a communication system having a communications module, wherein the communication system is capable of communicating from at least one of the drive controller, brake controller, and steering controller of the end module with one of: another end module, a vehicle controller; an autonomous drive controller; another vehicle, infrastructure, and a wireless data server.
A corner module for assembly on a vehicle body comprising a wheel, a frame having connection points for removably securing the corner module to the vehicle body a drive system connected to the wheel and capable of providing torque to drive the wheel, wherein the drive system includes at least a drive controller for controlling an electric motor and an inverter to drive the wheel, a brake system connected to the wheel having a brake controller, an actuator and a wheel brake located at the wheel, wherein the brake controller is capable of determining a desired braking action and actuating the actuator apply the wheel brake to slow rotation of the wheel, a suspension system located between the frame and the wheel, wherein the suspension system provides shock absorption and damping to the frame and vehicle body relative to the wheel, a steering system connected to the wheel, wherein the steering system having a steering controller capable of providing a steering input for the wheel, and a communication system having a communications module, wherein the communication system is capable of communicating from at least one of the drive controller, brake controller, and steering controller of the end module with one of: another corner module, a vehicle controller; an autonomous drive controller; another vehicle, infrastructure, and a wireless data server.
The present disclosure will become more fully understood from the detailed description and the accompanying drawings, wherein:
The following description is merely exemplary in nature and is in no way intended to limit the disclosure, its application, or uses. For purposes of clarity, the same reference numbers will be used in the drawings to identify similar elements.
The Figures illustrate schematic views of exemplary end modules 10 or corner modules 110, which are able independently operable to brake and steer themselves. The end/corner module(s) 10, 110 each have drive systems 12, 112, brake systems 14, 114, suspensions systems 16, steering systems 18 and communication systems 20. The drive system 12, 112, brake systems 14, 114, suspensions systems 16, steering systems 18 and communications systems 20 may be combined with one another in various combinations to form an end module 10 or corner module 110 as described herein.
Both types of modules 10, 110 can be quickly and easily removably secured to a vehicle body module 11. For example, the modules 10, 110 may have a support frame 24 secured to the wheels 22. Components for the drive systems 12, 112, such as a drive controller 26 can be secured and supported on the frame 24, e.g. mounted in the body module fastened by screws or rivets. The end/corner modules 10, 110 are able to provide drive, braking and steering to move a body module 11 which may be attached. In one embodiment the support frame is a space frame design. That is, the frame is tubular or extruded metal, and can be welded or bonded, including steel or aluminum or composite material.
The connection to the body module may be via traditional fasteners, e.g. bolts, nuts, etc. In another embodiment the means for and/or eccentric clamp devices. Additionally, if the end/corner module 10, 110 uses use central hydraulic brakes then we need hydraulic quick connectors may also be used. Alternately the hydraulic brakes are confined to an end module 10, 110 or even to a corner of a corner/end module 10, 110 and hydraulic connections to the body module 11 are not necessary.
The body module 11 may define wheel wells and a compartment to provide space for the modules 10, 110 and may be placed over the modules 11 and secured into position, as in the embodiment shown. Alternately the end portions of the body 10, 110 may be secured to the modules 10, 110 and when assembled joined to the central portion of the body 11 such that the body module 11 does not have to be raised and lowered to assemble with the modules 10, 110. Further, the body module 11 may define storage space that does not interfere with the packaging space for the modules 10, 110. Preferably such storage space could be accessed from the exterior of the vehicle for use by the passengers to store items.
Additionally, the body module 11 (or the portions of the module 11 secured to the end/corner modules 10, 110) have both headlights/tail lights and brake lights such that either end of the vehicle may act as the front or the rear of the vehicle, as discussed in detail below.
The frame 24 or suspension components (discussed below) may have connection points for quickly securing the module 10, 110 to a body module 11. Matching modules 10, 110 can be secured at each end of the body module 11, or at each of the four corners of the body module 11. In this manner, the assembled motor vehicle will have a lead module, located at the forward portion of the vehicle and a follow module located at the rear portion of the vehicle. As both modules 10, 110 are the same either end of the vehicle may be the forward/lead module 10, 110 and may switch back and forth during operation of the vehicle.
The end/corner modules 10, 110 may operate with one another in a lead/follow manner such that the end/corner modules 10, 110 on the front act as the lead and the end/corner modules 10, 110 on the rear are connected and act in a follow mode. When the vehicle changes direction the new end/corner modules 10, 110 will be the front and take the lead, while the other(s) follow. In the lead/follow mode of operation, the lead end/corner modules 10, 110 will be providing all of the necessary wheel torque for vehicle propulsion while the follow end/corner modules 10, 110 will be either disconnected so that no additional drag is provided or will be operated in a neutral (0 torque control) mode. In the case of an end/corner module 10, 110 disconnect, a disconnect clutch (not shown) may be used to mechanically decouple the drive system 12, 112 from the wheels 22. In this way, drag losses from the drive system 12, 112 would be minimized for the end/corner 10, 110 module in the follow mode.
The communication system 20 allows the lead end/corner module(s) 10, 110 to communicate instructions to the follow end/corner module(s) 10, 110 as needed for braking, power, etc. The drive controller determines the ‘lead module’ by the direction the vehicle moves. In an alternative mode of operation, both the end/corner modules 10, 110 on the front and the rear are all providing vehicle propulsion, i.e. the total required wheel torque is distributed among two axles or four wheel, etc. This mode of operation would primarily be used in a high wheel torque demand scenario such as driving up a hill, i.e. steep road grades. In yet another mode of operation, both the front and rear end/corner modules 10, 110 may be providing propulsion but not necessarily in equal levels to achieve optimum efficiency. In other words, the distribution of propulsion between front and rear may be determined based on best operating efficiency and consideration of vehicle stability events.
The end/corner module(s) 10, 110 will require sensor input to provide the autonomous instructions for driving, braking and steering themselves. Various cameras and sensors may be connected to a controller for determining the autonomous driving instructions. The sensors, cameras and controller may be mounted on and included in the end/corner module(s) 10, 110 or may be mounted on the body and communicate the various instructions to the necessary systems 12, 112, 14, 114, 16, 18 and 20 on the end/corner module(s) 10, 110. Redundant sensing and communication can be provided for safety between the autonomous controller and the drive 12, 112 brake 14, 114 and steering systems 16 of the end/corner module(s) 10, 110.
In one embodiment each deceleration brake event is analyzed by the brake controller and then the brake controller decides what deceleration device e.g. EM regeneration, friction brake, EPB, etc., should be used to satisfy the deceleration request. For example, possibly only the EM regenerative braking is used primarily in order to extend range of the vehicle, and friction brakes are only additionally used if necessary to reach the required deceleration. Depending on speed and deceleration request only one module may be sufficient or both modules are used to complete the request.
The modules 10, 110 proposed would total chassis and powertrain systems to be provided in customizable modules having all the necessary functions available for integration, including Brake systems, Suspension Systems, Powertrain (Electric Traction Drive), Telematics, Transportation Services, Power Distribution, Tires and Tire Information Systems, Hoses, Tubes, Isolation devices as well as, axels , drive shafts, structural connections, and steering Components. This will allow the body module to focus customer/driver specific experience factors, while delegating responsibility for the propulsion and lateral actuation of a vehicle to the end/corner modules 10, 110. Additionally both modules may be identical and provide the same functions. This is additionally satisfies any safety requirements relating to redundancy of components, such as brake system components.
Therefore, an end/corner module 10, 110 can be built in a modular manner by selecting one of the drive systems 12, 112 one of the brake systems 14, 114 one of the suspensions systems 16, one of the steering systems 18 and one of the communication systems 20 and assembling them together on a frame 24 with the wheel(s) 22. The end/corner module(s) 10, 110 will be independently operable from one another to autonomously drive, brake and steer themselves. One or more end/corner module(s) 10, 110 may be assembled onto a body 11 to create a vehicle that can be autonomously controlled by the end/corner module(s) 10, 110.
Vehicles today have these components designed and purchased separately by OEMs, or in some limited combination thereof. By offering the end module or corner module 10, 110 as a single comprehensive assembly, OEMs will now have the opportunity to order substantial functional components as a single ‘bundle’. The critical chassis, powertrain and communications components can be included into modules that can implemented in different configurations. End modules 10 can include tires, wheels, brake actuation components, air suspension components, electric traction drive, steering actuators, linkages, along with the relevant sensors and control electronics. These modules 10 would be implemented on the front or rear of a vehicle. Corner modules 110 can include tires, wheels, brake actuation components, air suspension components, electric traction drive, steering actuators, linkages, along with the relevant sensors and control electronics. These modules 110 would be implemented for the corners of the vehicle.
Service could be by either swapping out worn components and or modules, outside of dealership as a convenience for end users. Data collected through various sensorics and or algorithms regarding the performance of components to improve their features and functions. Such customizable modules 10, 110 enables proactive preventive maintenance of components via prognostic capabilities and improves serviceability of components. Components may be serviced by replacing a module 10, 110 for service off line, while continuing to allow the vehicle to operate. By keeping the end module or corner module concept, there is considerably more flexibility and component interchangeability in the implementation.
The corner module and end module will allow for repair and replacement of complete modules in a very fast so that they can quickly be returned to service. Due to flexibility the end and corner modules 10, 110 provide various levels of performance by swapping out components to achieve different results (swapping out a relatively weaker electric motor traction drive in favor of a relatively stronger one in order to achieve improved performance).
The invention is not limited to the exemplary embodiment described above. To a far greater extent, other variants of the invention can be derived by persons skilled in the art without departing from the object of the invention. In particular, all individual features described in connection with the exemplary embodiment can also be combined in other ways with each other without departing from the object of the invention.
The present application claims the benefit of International Application No. PCT/US2017/065133 filed Dec. 7, 2017, which claims priority to U.S. Provisional Application No. 62/431,129, filed on Dec. 7, 2016, each of which is hereby incorporated by reference.
Number | Date | Country | |
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62431162 | Dec 2016 | US |
Number | Date | Country | |
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Parent | PCT/US2017/065133 | Dec 2017 | US |
Child | 16434573 | US |