• 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 invention relates to a process for the actuation of an hydrodynamic retarder brake for motor vehicles, which is controlled by an electrohydraulic valve system. The rotational velocity of some part of the drive system (or an average of a plurality thereof) is indicated by a continuously generated electrical signal. When the throttle is released, or the brake pedal, having been depressed is then released, the vehicle velocity at that moment is stored as a reference signal in a memory. If the actual velocity thereafter exceeds the stored value, the hydrodynamic retarder is actuated. The momentary velocity of the vehicle is thereafter continuously compared with the stored reference velocity, and the retarder controlled accordingly. Rapidly applied retarder action is realized by controlling the same using PD control.
    公开号:SU1612992A3
    申请号:SU884355729
    申请日:1988-05-20
    公开日:1990-12-07
    发明作者:Шимоньи Шандор;Теречик Ласло;Тот Иштван;Валоци Дьердь
    申请人:Чепел Аутодьяр (Инопредприятие);
    IPC主号:
    专利说明:

    I - .. J
    17 9ig.2

    cm
    This invention relates to control methods for a 1H vehicle in a retarder,
    The purpose of the invention is to provide the most desirable speed of movement without using the wheel brakes.
    Fig. 1 shows a functional diagram of the automobile in which the steering method is constructed; in fig. 2 is a block diagram of the control system: NIN of the slow-speed brake of FIG. 3; block diagram of the electronic control unit.
    A car, in particular a bus i, (Fig. 1), is driven by engine 1, which is a six-cylinder diesel engine of external combustion. To the engine 1, a automatic transmission of 2 gears containing hydrodynamic conversion is attached. momentum and f-rikkkonnoe coupled; the In addition, in the automatic gearbox of the two gears, the hydrodynamic brake is slowed down together with 3 transmissions with electro-hydraulic 1-1 valves: 4, as well as with a proportional valve regulating the hydrodynamic
    brake retarder 8, ...
    The output shaft of the automatic gearbox 2 gears is connected with the differential mechanism 6 of the rear axle using the drive shaft 5, transmitting the torque to the wheels 7 through the half-shafts 8. The described units form the drive line of the jubilee.
    The invention is also suitable for use in passenger cars. However, in some passenger cars, namely, in vehicles with a rear-wheel drive engine, the gearbox and differential mechanism are made as a single unit, therefore there is a drive shaft in their drive line;
    The dual circuit braking system (Fig. 1) consists of a braking valve controlled by the brake cylinder brake pedal 9 of the Jupresiver 11 and connecting pipelines.
    Engine supply 1 fuel. It is provided through a feed system 12 (FIG. 1), which can be adjusted by the accelerator pedal 13. Basic information is needed to control the hydrodynamic retarder 3; produced by appropriate signaling sensors,
    One of the components of the basic information is the instantaneous speed of the car, respectively, its change. If the car is equipped with an anti-lock braking system,
    the signal of the angular velocity signal sensor located at the wheels, respectively, its average value, is in accordance with the purpose of the invention. In vehicles not equipped with an anti-lock braking system, the task can also be solved more simply, since each gearbox
    It has an output for a speedometer from which this signal can be obtained. In accordance with this, the signal sensor 14 of the angular velocity is built into the drive shaft of the automatic box 2
    gears
    The main components of basic information are the driver’s desire to express a car in relation to the speed of the car.
    ne ;; ali 13 and the position of the brake pedal 9. For this, the brake pedal 9 has a built-in brake pedal position sensor 15 that signals the different positions of the TODMO pedal.
    ABOUT
    five
    0
    for, and pedal 13 has a built-in alarm sensor 16 for the initial position of the gas pedal.
    All three signal sensors (Fig. 2) are connected to the input of the electronic unit 17, the latter consisting of the unit 18, and the control unit 19 connected to it. The sensors are connected to the memory unit 8 and also to the control unit 19 "The output of the latter, which is simultaneously the output of the electronic unit 17t, is connected to the corresponding valve electromagnets 4,
    The electronic unit 17 can be performed in various ways.
    The electronic unit 17. (Fig. 3) consists of the MHKponpojieccopa 205 programmable block 21 input-flow: a run, programmable three-channel blocks 22 and 23 of account adjustment and time, block 24 and ROM block 26, clock generator 265 of restart block 27, block 28 fowak and digital-analog decode 29,
    The points of connection of addresses, data and control, have the same function, the GF of the coprocessor 20, the programmable block 21 in the output-output, the prog. G frames: the supported three-channel blocks 22
    and 23, the counting control and the time, the RAM unit 24, the ROM unit 25 and the decoding unit 28 are connected to each other.
    The restarting unit 27 is connected to a point. Restarting the microprocessor 28, the programmable input-output unit 21, the programmable three-channel units 22 and 23 of the control of counting and time.
    The outputs of decoding unit 28 are individually connected to the chip select inputs of the programmable input-output unit 21, the programmable three-channel counting and time adjustment units 22 and 23, the BAM unit 24 and the ROM unit 25,
    The clock generator 26 is connected to the clock input of the microprocessor 20 and the three-channel unit 23 for controlling the counting and time. With the output of the programmable block 21 of the input-output connected inputs of the digital-analog unit 29.
    Functionally separated (FIG. 2, two parts of the electronic unit 17, i.e., real parts of the structure of the memory unit 18, the control unit 19
    five
    20
    25
    The hydrodynamic retarding brake 3 is further regulated by such a voltage, which regulates the proportional valve in the pressure range of 0-1 Mlla. ,
    The method is carried out as follows.
    Until the bus travels so that the driver presses the pedal, the hydrodynamic retarder 3 does not function. Although the angular velocity signal sensor 14 signals continuously about the speed of the bus, however, the electronic unit 17 does not process a signal
    If the driver returns pedal 1 to its initial position, memory unit 18, corresponding to RAM 24, under the influence of a signal from the initial g of the signal sensor 16 of the initial position of the pedal 13, remembers that speed that the angular velocity signal sensor 14 when the pedal 13 returns its initial position is directed as an angular velocity signal.
    Simultaneously with the source gas signal of the signal sensor 16 of the source
    ctropic unit 17 in terms of the position of the pedal control unit 19
    commands the monitored unit to act as a hydrodynamic deceleration brake 3; From this point, in control unit 19, the start of speed, stored in memory block 18, is continuously compared with the current speed value, 1 continuously directed further in the quality of the signal is the velocity angle, 1m sensor 14 is the angular velocity, however, only under the influence of the source gas signal of the signal sensor 16 of the initial position, the pedal 13 control unit 19 still does not supply the control signal to the solenoid valve system ..
    35
    40
    The views do not overlap exactly one another. The electronic control unit 17 can be performed more simply with electronic components specialized in individual tasks, then the electronic control unit 17 also performs other tasks not related to the invention (anti-blocking control by a hydrodynamic retarder, automatic transmission control).
    The electronic unit 17 is connected via an input of a programmable three-channel counting control unit and time to a signal sensor 16 of the initial-accelerator pedal position and through inputs of a programmable three-channel count control unit 23 and time signal sensor 14 of a brake pedal position and an angle sensor 15 speed.
    The output of block 29 is simultaneously the output of the electronic unit 17 to the electrohydraulic hydrodynamic control valve 4, which sends a command to set the operation of the hydrodynamic retarder 3 at this point. At this point, in control unit 19, the speed is stored in memory block 18 , is continuously compared with the current speed value, 1 continuously directed further as an angle-velocity signal, 1m by the 14-angular velocity sensor "However, only under the influence of the signal of the source gas of the signal sensor 16 similar position pedal 13, the control unit 19 has not yet delivers to the electromagnetic valve system control signal ..
    When the bus travels on a slope, it can In spite of gas discharge, if this occurs, the magnitude of the angular velocity signal sent by the angular velocity signal sensor 14, i.e. the current velocity value becomes greater than the memorized magnitude of the velocity,
    If this situation occurs, the control unit delivers the valves. 4 ups retarder. Block 29 produces a signal signal proportional to the value of O-T O B, which is due to the difference, and the proportional valve
    RW1St actuated padrodynamic retarder Sv required for
    proprietary proportional valve control electronics
    The hydrodynamic retarder 3 is further regulated to a voltage that controls the proportional valve in the pressure range of 0-1 Mlla. ,
    The method is carried out as follows.
    Until the bus travels so that the driver presses the pedal, the hydrodynamic retarder 3 does not function. Although the angular velocity signal sensor 14 signals continuously the speed of the bus, however, the electronic unit 17 does not process the signal about
    If the driver returns the pedal 13 to its initial position, the memory unit 18 corresponding to the RAM block 24, under the influence of the initial gas signal of the signal sensor 16 of the initial position of the pedal 13, remembers the speed value that the angular velocity signal sensor 14 when the pedal 13 returns to its original the position directs as a signal: angular velocity.
    Simultaneously with the source gas signal of the signal source sensor 16
    Pedal position control unit 19
    five
    0
    with Q
    gives the command monitored unit to the action of the hydrodynamic retarder 3, at this point. in control unit 19, the start of speed, stored in memory block 18, is continuously compared with the current speed value, 1 continuously directed as a corner signal speed, 1m sensor 14 - angular velocity "However, only under the influence of the source gas signal of the signal sensor 16 of the initial position of the pedal 13, the control unit 19 still does not send a control signal to the electromagnetic valve system ..
    When the bus travels on a slope, it can In spite of gas discharge, if this occurs, the magnitude of the angular velocity signal sent by the angular velocity signal sensor 14, i.e. the current velocity value becomes greater than the memorized magnitude of the velocity,
    If this situation occurs, the control unit delivers the valves. 4 pack20
    slowing down to a memorized value of the speed of the degree. This automatic adjustment continues as long as the control unit 19, based on the angle signal of the angular velocity signal sensor 14, can monitor that the bus without activating the hydrodynamic retarder 3 would accelerate - Q, regulation is carried out with the maintenance of speed,
    In the case that the driver considers the speed limit,. memorized, “: in accordance with what was said, as being too high, it slows down the bus by depressing brake pedal 9 to the speed that it considers completely safe. Hydrodynamic retarder 3 is also involved in this.
    The signal sensor 1.5 of the brake pedal position sends to the control unit 19 proportional to the position of the brake pedal 9 a brake signal and the control unit 19 supplies the proportional valve of the valves 4 proportional to this signal to the control signal. Thus, the hydrodynamic braking-retarding effect 3 has a braking effect proportional to the brake cylinders 10 produced by the braking cylinders 10 to the braking force, „
    At the same time, the brake signal erases the speed value memorized in the memory unit 18 ,.
    After Toroj, the bus slowed down its speed even as it was necessary. The bus driver released the brake pedal 9 and the brake signal dimmed,
    If the pedal 13 and remains in its original position, the memory bhük 18 under dg
    the signal of the signal sensor 16 of the initial position of the pedal 13 now stores the signal of the angular velocity; from the signal sensor 14 of the angular velocity 5, the corresponding velocity ––. This measured at the time of releasing the brake pedal Next, the control block 19 compares the angular velocity signal corresponding to the instantaneous speed with the stored memory; - the angular velocity signal Supportive speed control of the hydrodynamic retarder 3 coincides with that described
    35
    0
    Q
    “:
    5 o
    0
    g
    .
    five
    Readiness for shredding control block 19 may be prevented
    two u TYAMI ,.
    When the driver starts to accelerate the bus, he presses the pedal 13. Due to this, the source gas signal of the signal sensor 16 of the initial position of the pedal 13 is extinguished. As a result, the memory signal 18 erases the signal of the corner speed and is also eliminated the control signal of the control unit 19 supplied to the valves 4 o
    If the bus slows down for a long time (below the memorized speed value), this slowdown can not be eliminated by the control unit 19 only by completely turning off the hydrodynamic, the a-retarder brake. In this case, the memorized signal is erased in memory block 18. control unit 19 account
    If a brake pedal position sensor is not used, the proposed method is carried out as follows.
    The memory unit 18 memorizes the current value of the angular velocity of the signal sensor 14 of the angular velocity under the influence of the signal of the initial gas of the signal sensor 16 of the initial position of the pedal 13 and the activation and regulation of the hydrodynamic retarder 3 while maintaining speed. It is controlled by the control block 1 9, similar to the analog
    When the bus driver wants to maintain a speed lower than the memorized speed, he slows down the bus using the brake pedal 9 to that speed, then he moves the accelerator pedal 13 and returns it back. Here, the signal memorized in block 15 is

    the angular velocity is erased by the movement of the pedal 13, then in the memory block 18, a memory is stored, the corresponding angular velocity signal arises by setting the pedal 13 to the main position by decelerating. Next, the control unit 19 compares the angular velocity signal corresponding to the instantaneous velocity with the stored angular velocity signal described.
    The readiness for control of the control unit 19 and the memory unit 18 may be extinguished in the manner described.
    9t6l2992
    When no signal is provided in the system for the initial position of the pedal 13, the method proceeds as follows.
    The driver gives the command to memorize the signal of the angular speed of the signal sensor 14 of the angular speed by instantly pressing the brake pedal 9. The brake pedal position sensor 15 produces a signal for storing an angular velocity signal to a memory unit 18 corresponding to an instantaneous angular velocity, and
    ten
    Another way to stop the readiness for control of the control unit 19 and the memory block 18 is to automatically shut down due to the excessive slowdown already described. Again, another method is that when the driver wants to disperse the bus, the system can be activated by instantly pressing the brake pedal 9.
    The traditional braking system using the solution according to the invention can be unloaded when regulated with the maintenance of speed.
    for control block 19. Regulation is until the moment when one hydrodynamics is carried out similarly to that described. In order to drive at a low speed, the driver slows down the bus by appropriately pressing the brake pedal 9 in the manner described, and at the same time eliminates the regulation of the hydrodynamic retarder 3 while maintaining speed. Thereafter, by releasing and re-pressing the brake pedal 9, the known process begins again, i.e. Pressing the brake pedal 9, the signal for a long brake pedal position sensor 15 provides the memory unit 18 with a signal for storing the angular velocity signal corresponding to the instantaneous speed, and the control unit 19 for adjusting the hydrodynamic deceleration brake 3 with maintaining the speed. The regulation is carried out as described above.
    In order to drive at a lower speed, the driver slows down the bus by appropriately pressing the brake pedal 9 in the manner described, and at the same time eliminates the control of the hydrodynamic retarder .3 maintaining the speed, Using the brake pedal 9 and releasing the brake repeat again. Under the action of re-pressing the brake pedal 9, the signal brake pedal position sensor 15 supplies the memory unit 18 with a signal for storing the angular velocity signal corresponding to the instantaneous speed and the control unit 19 for adjusting the hydrodynamic deceleration brake 3 with maintaining the speed. Following this, the brake pedal 9 can be released again.
    20
    thirty
    a retarder is sufficient for effective braking,
    Gndrodin:; The natural retarder brakes have the negative characteristic that they slowly respond to control signals. However, when adjusting to maintain speed, it is required that they respond immediately and sensitively. For this reason, the program of control unit 14 is designed in such a way that proportional control with pre-emption is used. This means that the control signal consists of two parts. One part is proportional to the difference between the angular velocity signal stored in memory block 18 and the angular velocity signal sent further by the angular velocity signal sensor 14, since the other part is the first derivative the first part superimposed
    on the first part about i
    Using proportional control ahead of time, it is achieved that the proportional valve regulating the hydrodynamic retarder 3, under the influence of the control signal of the control unit 19, quickly opens and is gradually adjusted to linear regulation.
    I
    The control is also provided with a shut-off device (not shown). The control unit also performs other tasks and its manual shutdown is performed in conjunction with these tasks. In this case, it does not matter, since automatic shutdown is provided in several ways. However, in the case of other control units, this should also be ensured by "
    ten
    45
    50
    55
    ten
    Another way to stop the control readiness of the control unit 19. and the memory unit 18 is to automatically shut down due to the excessive slowdown already described. Again, another method is that when the driver wants to disperse the bus, the system can be activated by instantly pressing the brake pedal 9.
    The traditional braking system using the solution according to the invention can be unloaded when regulated with the maintenance of speed.
    0
    0
    a retarder is sufficient for effective braking,
    Gndrodin:; The natural retarder brakes have the negative characteristic that they slowly respond to control signals. However, when regulating with maintaining speed, it is required that they react immediately and that they are sensitive. For this reason, the program of control unit 14 is designed in such a way that proportional control with pre-emption is used. This means that the control signal consists of two parts. One part is proportional to the difference between the angular velocity signal stored in memory block 18 and the angular velocity signal sent further by the angular velocity signal sensor 14, while the other part is the first derivative parts imposed
    on the first part about i
    By means of proportional control ahead, it is achieved that the proportional valve regulating the hydrodynamic retarder 3, under the influence of the control signal of the control unit 19, quickly opens and is gradually set to linear regulation.
    I
    The control is also provided with a shut-off device (not shown). The control unit also performs other tasks and its manual shutdown is performed in conjunction with these tasks. In this case, it does not matter, since automatic shutdown is provided in several ways. However, in the case of other control units, this should also be ensured by "
    ten
    five
    0
    five
    formula
    II and 3 about b p
    1612992
    e te n i.
    ro os os those neither for those q pr be te si na
    A method for controlling a hydrodynamic retarder of an automobile having an electro-hydraulic valve system, a drive line consisting of an internal combustion engine, kinematically coupled through
    In the control unit that performs the above comparison, the signals are generated to decelerate the retarder and, in case of a repeated increase in the current value of the angular velocity, a signal is generated to control the retarding brake, characterized in that, in order to ensure the most Q preferred driving speed without using wheel brakes, the current value of the angular velocity is fixed with the help of a memory unit by the signal of the pedal position sensor acceleration with the gearbox, to which it can be directly or through ardan; a new shaft connected at least one differential mechanism associated with at least one pair of half-shafts with wheels, consisting of a TOM, J rator at the moment of its release and release that the signal to turn on the brake-decelerated brake pedal or the signal is formed with the help of the jjy sensor of the position of the brake pedal of the accelerator pedal in its released position, with the help of the angular velocity sensor the current significant accelerator pedal is measured, and the comparison of the angular velocity of one of the elec- The values of the angular velocity of the drive line are compared with the specified fictitious value with the reference value of the angular value представ representing the lateral velocity and, if the current равен is equal, the corrected reference value of the angular velocity the angular velocity.
    at the time of termination of the braking phase using the wheel brakes during release
    In the control unit, which performs the indicated comparison, the signals are generated to decelerate the retarder brake, and in the case of a repeated increase in the current value of the angular velocity, a signal is generated to control the retarding brake, characterized in that, in order to ensure the most preferable speed of movement, without using wheeled brakes, the current value of the angular velocity is fixed with the help of the memory block by the signal of the accelerator pedal position sensor at the moment of its release and released by the brake pedal or si The jjy sensor of the position of the brake pedal of the valuable accelerator pedal, and the comparison of the current value of the angular velocity, is carried out with the indicated fixed value g representing the corrected reference angular velocity value.
    At the time of its release and release of the brake pedal or on the signal of the position sensor of the brake pedal of the valuable accelerator pedal, compared to the current value of the angular velocity, the rator is carried out with the fixed value of the corrected reference symbol the angular velocity.
    at the time of termination of the phase of braking using wheel brakes at release / 5
    t
    Fg / g
    (y)
    P
    J
    权利要求:
    Claims (1)
    [1]
    Claim
    A method for controlling a hydrodynamic retarder of a vehicle having an electro-hydraulic valve system, a drive line consisting of an internal combustion engine kinematically connected through a clutch to a gearbox to which at least one differential mechanism is connected directly or via a propeller shaft a pair of half-wheels with wheels, which consists in the fact that the signal to activate the retarder is formed using the accelerator pedal position sensor in released it using the angular velocity sensor to measure the current value of the angular velocity of one of the elements of the drive line, compare this value with the reference value of the angular velocity and if the current and reference values of the angular velocity are equal to 2992 12
    In the control unit that performs the above comparison, the signals are generated to turn off the retarder brake, and in case of a repeated increase in the current value of the angular velocity, a signal is generated to turn on the deceleration brake, characterized in that, in order to ensure the most preferred speed without using wheel brakes, the current the value of the angular velocity is fixed with the help of the memory unit by the signal of the pedal accelero η5 position sensor датчика at the moment of its release and released by the brake pedal or by sig alu brake pedal position sensor in the end of the braking phase with the wheel brakes via at otpu20 gap of the accelerator pedal, and compares the current value of the angular velocity is carried out with said fixed value, which is a corrected reference zna25 chenie angular velocity.
    FIG. one
    1612992
    Fig.Z
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    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
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    GB2162341B|1984-07-27|1988-02-03|Ae Plc|Automatic vehicle speed control system|SE460781B|1988-03-31|1989-11-20|Saab Scania Ab|PROCEDURES AND ARRANGEMENTS FOR CONSTANT MAINTENANCE OF MOTOR VEHICLES DURING DOWN THE DOWN BACK|
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    US5983149A|1991-04-08|1999-11-09|Caterpillar Inc.|Automatic vehicle speed retarding control through actuation of wheel brakes|
    US5351795A|1992-08-31|1994-10-04|General Motors Corporation|Electronically controlled hydrodynamic retarder with adaptive duty cycles based on decelarations|
    US5535122A|1994-03-30|1996-07-09|Westinghouse Air Brake Company|Method of and an apparatus for providing a safety check of the brake retardation capability of a brake system on a vehicle|
    GB9420561D0|1994-10-12|1994-11-30|Rover Group|A wheeled vehicle|
    DE69622680T2|1996-01-12|2003-04-17|Eaton Corp|Shift control system / method for a vehicle provided with a powertrain retarder|
    DE19822860C2|1998-05-22|2002-08-08|Daimler Chrysler Ag|Method and device for braking a vehicle|
    SE514229C2|1999-12-13|2001-01-29|Scania Cv Ab|Device for controlling a braking arrangement, and a braking system for heavy vehicles comprising the braking arrangement|
    DE10360777A1|2003-12-23|2005-07-28|Robert Bosch Gmbh|Automotive speed control, with automatic shut-off function|
    US7214165B2|2004-05-14|2007-05-08|General Motors Corporation|Method of automatically flushing debris from an electrically-operated hydraulic valve|
    DE102004048120A1|2004-10-02|2006-04-06|Voith Turbo Gmbh & Co. Kg|Method for optimizing the operation of a hydrodynamic component integrated in a drive train of a vehicle|
    JP4473751B2|2005-03-04|2010-06-02|本田技研工業株式会社|Hydraulic brake device|
    DE602006017858D1|2005-08-30|2010-12-09|Sumitomo Chemical Co|PROCESS FOR PREPARING A SULPHONYL CHLORIDE COMPOUND|
    US7410447B2|2005-10-31|2008-08-12|General Motors Corporation|Vehicle speed control system|
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    US7762923B2|2006-12-01|2010-07-27|Clark Equipment Company|Shift assisted braking for a power machine or vehicle|
    US8033955B2|2008-03-06|2011-10-11|Toyota Motor Engineering & Manufacturing North America, Inc.|Methods and systems for regulating hill descent speed of an electric vehicle|
    US8473151B2|2010-03-30|2013-06-25|Toyota Motor Engineering & Manufacturing North America, Inc.|Excursion prevention methods and systems|
    CN106218618A|2016-09-07|2016-12-14|王明中|A kind of automobile oil pressure resistance device|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    HU872247A|HU198879B|1987-05-20|1987-05-20|Method for operating hydrodynamic decelerating brake controlled by electrohydraulic valve system at motor vehicles|
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