According to at least one embodiment, the present disclosure provides an electrohydraulic brake system including main brake assemblies, electronic parking brakes (EPBs), a main control unit, and a redundancy control unit (RCU). The main brake assemblies generate a braking force in one or more front wheels and one or more rear wheels of a vehicle. The electronic parking brakes (EPBs) generate a braking force to one of the front wheels and rear wheels. The main control unit is configured to control the operation of the main brake assembly. The redundancy control unit (RCU) is configured to control the operation of the electronic parking brake. Here, the redundancy control unit performs, upon determining that a malfunction occurs in a braking function of the main control unit, a slip control on the vehicle by using the electronic parking brake based on signals from one or more wheel speed sensors.

At least one embodiment of the present disclosure provides an apparatus for braking a vehicle, including a plurality of electro-mechanical braking (EMB) systems respectively installed for a plurality of vehicle wheels and configured to generate a braking force to the plurality of wheels, respectively, a driving information detecting unit for measuring driving information of the vehicle, an electronic power steering (EPS) system generating a steering torque in a direction opposite to a braking torque generated in the vehicle, and an electronic control unit (ECU) controlling the electro-mechanical braking systems and the electronic power steering system, wherein the electronic control unit is configured to control, upon determining that one or some of the plurality of electro-mechanical braking systems are malfunctioning, the vehicle by using the electronic power steering system, and the electronic power steering system is configured to generate the steering torque according to the driving information including wheel speeds.

At least one embodiment of the present disclosure provides an apparatus for braking a vehicle, including a plurality of electro-mechanical braking (EMB) systems respectively installed for a plurality of vehicle wheels and configured to generate a braking force to the plurality of wheels, respectively, a driving information detecting unit for measuring driving information of the vehicle, an electronic power steering (EPS) system generating a steering torque in a direction opposite to a braking torque generated in the vehicle, and an electronic control unit (ECU) controlling the electro-mechanical braking systems and the electronic power steering system, wherein the electronic control unit is configured to control, upon determining that one or some of the plurality of electro-mechanical braking systems are malfunctioning, the vehicle by using the electronic power steering system, and the electronic power steering system is configured to generate the steering torque according to the driving information including wheel speeds.

The present invention relates to an electromechanical brake system (7) and a control method of the electromechanical brake system (7). The electromechanical brake system (7) comprises an electric power source and at least one electric brake device powered by the electric power source to generate a braking force responsive to a braking demand, the electromechanical brake system (7) is configured to adjust braking performance of the electric brake device according to an actual energy level of the electric power source. The present invention can timely adjust the braking performance of the electric brake device, and promptly inform the driver of the braking situation, so that the driver can obtain an intuitive braking feeling during the driving process, thereby effectively improving the safety of the vehicle, and at the same time it saves the energy of the electric power source, and avoids unnecessary energy consumption, thereby playing a good role in protecting the electromechanical brake system (7).

The present invention relates to an electromechanical brake system (7) and a control method of the electromechanical brake system (7). The electromechanical brake system (7) comprises an electric power source and at least one electric brake device powered by the electric power source to generate a braking force responsive to a braking demand, the electromechanical brake system (7) is configured to adjust braking performance of the electric brake device according to an actual energy level of the electric power source. The present invention can timely adjust the braking performance of the electric brake device, and promptly inform the driver of the braking situation, so that the driver can obtain an intuitive braking feeling during the driving process, thereby effectively improving the safety of the vehicle, and at the same time it saves the energy of the electric power source, and avoids unnecessary energy consumption, thereby playing a good role in protecting the electromechanical brake system (7).

A braking system for vehicles may have a first brake group, a second brake group and a third brake group. A first and a second control unit may be provided for the brake groups. The first control unit may be connected to the first brake group by a piloting device for an actuator of the first brake group. The second control unit may be connected to the second brake group by a piloting device actuator of the second brake group. The second control unit may be connected to the third brake group by a piloting device for an actuator of the third brake group. The first control unit may be connected to a first power source, and the second control unit may be connected to a second power source. Each control unit may be programmed to implement a standard braking strategy and a fault braking strategy.

A braking system for vehicles may have a first brake group, a second brake group and a third brake group. A first and a second control unit may be provided for the brake groups. The first control unit may be connected to the first brake group by a piloting device for an actuator of the first brake group. The second control unit may be connected to the second brake group by a piloting device actuator of the second brake group. The second control unit may be connected to the third brake group by a piloting device for an actuator of the third brake group. The first control unit may be connected to a first power source, and the second control unit may be connected to a second power source. Each control unit may be programmed to implement a standard braking strategy and a fault braking strategy.

An object of the present invention is to provide a brake control apparatus including a backup brake, which brake control apparatus makes it possible both to ensure deceleration, and to attain vehicle running stability.

The present invention includes: a front-wheel-side braking mechanism 4 that includes a front-wheel-side electric hydraulic mechanism 6, and a hydraulic circuit system, and applies braking force to front wheels 2L, and 2R; a rear-wheel-side braking mechanism 5 that applies braking on a rear wheel side; a backup brake that is actuated in accordance with a switch to the hydraulic circuit system 15 when the front-wheel-side electric hydraulic mechanism 6 fails, and applies braking force to the front wheels 2R, and 2L; and a skid determination threshold setting section 43 that sets a skid determination threshold. When the backup brake is actuated, the skid determination threshold setting section 43 sets the skid determination threshold for the rear wheels 3L, and 3R on the basis of braking force information of the backup brake.

An object of the present invention is to provide a brake control apparatus including a backup brake, which brake control apparatus makes it possible both to ensure deceleration, and to attain vehicle running stability.

The present invention includes: a front-wheel-side braking mechanism 4 that includes a front-wheel-side electric hydraulic mechanism 6, and a hydraulic circuit system, and applies braking force to front wheels 2L, and 2R; a rear-wheel-side braking mechanism 5 that applies braking on a rear wheel side; a backup brake that is actuated in accordance with a switch to the hydraulic circuit system 15 when the front-wheel-side electric hydraulic mechanism 6 fails, and applies braking force to the front wheels 2R, and 2L; and a skid determination threshold setting section 43 that sets a skid determination threshold. When the backup brake is actuated, the skid determination threshold setting section 43 sets the skid determination threshold for the rear wheels 3L, and 3R on the basis of braking force information of the backup brake.

The present disclosure relates to a motor driving circuit of an electronic parking brake system, which is configured to include a first motor and a second motor for releasing or applying a parking brake applied to different wheels, respectively; and a first ECU and a second ECU for controlling the driving of the first motor and the second motor, respectively, wherein the second ECU is prevented from intervening in the driving of the first motor and the second motor while the first ECU drives the first motor and the second motor, and controls the driving of the first motor and the second motor only when there is an abnormality in the first ECU.