A hydraulic brake system for a land vehicle including a hydraulic connection between a master cylinder and wheel brakes that is established or blocked by valve arrangements in dependence upon trigger signals from an electronic control with the electronic control unit devised and programmed in such a
A hydraulic brake system for a land vehicle including a hydraulic connection between a master cylinder and wheel brakes that is established or blocked by valve arrangements in dependence upon trigger signals from an electronic control with the electronic control unit devised and programmed in such a way that, in order to set a brake pressure characteristic required for a specific vehicle behavior, the electronic control unit supplies trigger signals through which the setting of a respective brake pressure characteristic in two brake circuits in predefined pressure stages (delta-p) is staggered in terms of time by a substantially predefined time stage (delta-t).
대표청구항▼
1. A hydraulic brake system for a land vehicle, comprising: a master cylinder, which is actuable by the driver by means of a pedal by one of directly and via a brake booster disposed downstream of the pedal, for generating brake pressures in a first brake circuit and in a second brake circuit, each
1. A hydraulic brake system for a land vehicle, comprising: a master cylinder, which is actuable by the driver by means of a pedal by one of directly and via a brake booster disposed downstream of the pedal, for generating brake pressures in a first brake circuit and in a second brake circuit, each of which first and second brake circuits comprises at least two wheel brakes and contains hydraulic brake fluid,an electronic control unit,a hydraulic connection between the master cylinder and the wheel brakes that includes valve arrangements, the valve arrangements connected to the electronic control unit and operable to control one of the establishment and blocking of the hydraulic connection in dependence upon trigger signals from the electronic control unit in order to implement one of normal braking operations brought about directly by the driver and braking operations influenced by the electronic control unit in dependence upon measured variables, which are supplied to the electronic control unit and reflect the vehicle behaviour and the driver request, in that the brake pressure characteristic in the wheel brakes is varied by activating the valve arrangements associated therewith, characterized in thatthe electronic control unit is devised and programmed to set a brake pressure characteristic required for a specific vehicle behaviour by supplying trigger signals, by means of which:starting from an initial brake pressure value at an initial point of time, a pressure increase phase is implemented in the first brake unit, during which the brake pressure in the first brake circuit rises during a first time increment by a pressure increment to a first increased brake pressure value,after attainment of the first increased brake pressure value, a pressure keeping phase is implemented in the first brake unit, during which the brake pressure in the first brake circuit is held substantially constant for the duration of a second time increment,in parallel to the raising of the brake pressure in the first brake circuit by a pressure increment to the first increased brake pressure value, a pressure keeping phase is implemented in the second brake unit, during which the brake pressure in the second brake circuit from the initial point of time for the duration of the first time increment remains substantially constant at the initial brake pressure value,then, beginning at the end of the first time increment, a pressure increase phase is implemented in the second brake unit, during which the brake pressure in the second brake circuit rises during the second time increment by a pressure increment to a second increased brake pressure value, andthe electronic control unit is devised and programmed to alternatingly implement the pressure increase and pressure keeping phases between the two brake circuits continuously from the end of the second time increment so as to generate a linearly-shaped brake pressure characteristic and thereby perform a smooth brake application. 2. The hydraulic brake system according to claim 1, wherein a pump, which is actuable by the electronic control unit by means of a trigger signal, is provided for both raising and lowering the brake pressure in the wheel brakes. 3. The hydraulic brake system according to claim 2, wherein the pump varies its delivery rate in dependence upon the trigger signal of the electronic control unit. 4. The hydraulic brake system according to claim 2, wherein each of the brake circuits includes a pump for both raising and lowering the brake pressure in each of the first and second brake circuits and further wherein an electric motor actuates the pumps of both brake circuits simultaneously. 5. The hydraulic brake system according to claim 1, wherein the electronic control unit is devised and programmed to set a brake pressure characteristic by supplying trigger signals, by means of whichstarting from an initial brake pressure value at an initial point of time in the second brake circuit the brake pressure drops during a first time increment by a pressure increment to a first reduced brake pressure value andafter attainment of the first reduced brake pressure value, the brake pressure in the second brake circuit remains substantially constant for the duration of second time increment. 6. The hydraulic brake system according to claim 5, wherein the electronic control unit is devised and programmed to set a brake pressure characteristic by supplying trigger signals, by means of whichin parallel to the dropping of the brake pressure in the second brake circuit by a pressure increment to the first reduced brake pressure value, the brake pressure in the first brake circuit from the initial point of time remains substantially constant at the initial value for the duration of the first time increment,then, beginning at the end of the first time increment, the brake pressure in the first brake circuit drops during the second time increment by a pressure increment to a second reduced brake pressure value. 7. The hydraulic brake system according to claim 6 wherein the electronic control unit is devised and to alternate pressure reduction and pressure keeping phases between the two brake circuits continuously from the end of the second time increment. 8. The hydraulic brake system according to claim 1, wherein the electronic control unit is devised and programmed to set a brake pressure characteristic by supplying trigger signals, by means of whichstarting from an initial brake pressure value at a first point of time the brake pressure in the first brake circuit rises during a preliminary time increment by a preliminary pressure increment to a first increased brake pressure value, which has been reached at the end of the preliminary time increment, andafter attainment the first increased brake pressure value, the brake pressure in the first brake circuit remains substantially constant for the duration of a first non-preliminary time increment. 9. The hydraulic brake system according to claim 8, wherein the first non-preliminary time increment lasts a multiple of two times the preliminary time increment. 10. The hydraulic brake system according to claim 9 wherein the electronic control unit is devised and programmed to set a brake pressure characteristic by supplying trigger signals, by means of whichbeginning at the end of the first non-preliminary time increment, the brake pressure in the first brake circuit rises during a second non-preliminary time increment by a pressure increment to a second increased brake pressure value, wherein the duration of the second non-preliminary time increment corresponds substantially to the duration of the first non-preliminary time increment and the pressure increment corresponds substantially to a multiple of two times the preliminary pressure increment. 11. The hydraulic brake system according to claim 10, wherein the electronic control unit is devised and programmed to set a brake pressure characteristic by supplying trigger signals, by means of whichin parallel to the raising of the brake pressure in the first brake circuit by the preliminary pressure increment to the first increased brake pressure value and the keeping of the brake pressure in the first brake circuit substantially constant for the duration of the first non-preliminary time incrementthe brake pressure in the second brake circuit from the initial point of time remains substantially constant at the initial brake pressure value for the duration of the preliminary time increment,at the end of the preliminary time increment, the brake pressure in the second brake circuit rises during the first non-preliminary time increment by the pressure stage increment to an intermediate pressure value, which is between the first and second increased pressure values and which has been reached at the end of the first non-preliminary time increment, andfrom the point of time at the end of the first non-preliminary time increment, the brake pressure in the second brake circuit remains substantially constant for the duration of the second non-preliminary time increment. 12. The hydraulic brake system according to claim 11, wherein the electronic control unit is devised and programmed to alternate pressure build-up and pressure keeping phases between the two brake circuits continuously from the end of the second non-preliminary time increment. 13. The hydraulic brake system according to claim 1, wherein the electronic control unit is devised and programmed to set a brake pressure characteristic by supplying trigger signals, by means of whichstarting from an initial brake pressure value at an initial point of time in the second brake circuit the brake pressure drops during a preliminary time increment by a preliminary pressure increment to a first reduced brake pressure value, which has been reached at the end of the preliminary time increment, andafter attainment the first reduced brake pressure, the brake pressure in the second brake circuit remains substantially constant for the duration of a first non-preliminary time increment. 14. The hydraulic brake system according to claim 13, wherein the first non-preliminary time increment lasts a multiple of two times the preliminary time increment. 15. The hydraulic brake system according to claim 14 wherein the electronic control unit is devised and programmed to set a brake pressure characteristic by supplying trigger signals, by means of whichfrom the end of the first non-preliminary time increment, the brake pressure in the second brake circuit drops by a pressure increment to a second reduced brake pressure value, wherein the duration of the second non-preliminary time increment corresponds substantially to the duration of the first non-preliminary time increment and the pressure increment corresponds substantially to a multiple of two times the preliminary pressure increment. 16. The hydraulic brake system according to claim 15, wherein the electronic control unit is devised and programmed to set a brake pressure characteristic by supplying trigger signals, by means of whichin parallel to the dropping of the brake pressure in the second brake circuit by the preliminary pressure increment to the first reduced brake pressure value and the keeping of the pressure in the second brake circuit substantially constant for the duration of the first non-preliminary time increment,the brake pressure in the first brake circuit from the initial point of time remains substantially constant at the initial brake pressure value for the duration of the preliminary time increment,at the end of the preliminary time increment, the brake pressure in the first brake circuit drops during the first non-preliminary time increment by the pressure increment to an intermediate pressure value, which is between the first and second reduced pressure values and which has been reached at the end of the first non-preliminary time interval, andfrom the point of time at the end of the first non-preliminary time increment, the brake pressure in the first brake circuit remains substantially constant for the duration of the second non-preliminary time increment. 17. The hydraulic brake system according to claim 16, wherein the electronic control unit is devised and programmed to alternate pressure reduction and pressure keeping phases between the two brake circuits continuously from the end of the second non-preliminary time increment. 18. The hydraulic brake system according to claim 1 wherein the first and second increased brake pressure values are substantially the same, andthe first and second time intervals are substantially the same. 19. The hydraulic brake system according to claim 7 wherein the first and second reduced brake pressure values are substantially the same, andthe first and second time intervals are substantially the same. 20. A hydraulic brake system for a land vehicle comprising: a master cylinder that supplies pressurized hydraulic brake fluid through a hydraulic connection to both a first brake circuit and a second brake circuit, wherein the hydraulic connection includes valve arrangements, and wherein each of the first and second brake circuits includes at least two wheel brakes;an electronic control unit that is operable to control the valve arrangements to selectively establish and block the hydraulic connection in order to implement either normal braking operations effected directly by a driver or braking operations influenced by the electronic control unit in dependence upon measured variables supplied to the electronic control unit and reflecting the vehicle behaviour and a driver request, the electronic control unit being devised and programmed to set a brake pressure characteristic required for a specific vehicle behaviour by supplying trigger signals such that:(1) during a first time increment, both (a) a pressure increasing phase is implemented in the first brake unit in which the brake pressure in the first brake circuit rises from an initial brake pressure value to a first increased brake pressure value, and simultaneously (b) a pressure keeping phase is implemented in the second brake unit in which the brake pressure in the second brake circuit remains substantially constant at the initial brake pressure value; and(2) during a second time increment at the conclusion of the first time increment, a pressure keeping phase is implemented in the first brake unit in which the brake pressure in the first brake circuit is held substantially constant, and a pressure increasing phase is implemented in the second brake unit in which the brake pressure in the second brake circuit rises to a second increased brake pressure value; whereinthe electronic control unit is devised and programmed to alternatingly implement the pressure increasing and pressure keeping phases between the two brake circuits continuously from the end of the second time increment so as to generate a linearly-shaped brake pressure characteristic and thereby perform a smooth brake application.
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이 특허에 인용된 특허 (5)
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