The present invention relates to a control apparatus and method for use with a vehicle speed retarder utilizing closed-loop and adaptive control logic configured to alternately provide steady-state and zero deceleration irrespective of the vehicle's weight and axle ratio.
Transmission output speed retarders are non-wearing auxiliary braking devices used in conjunction with a rotatable vehicle transmission output member or driveshaft in order to safely augment the conventional friction-based braking system or service brakes used on certain large vehicles, such as diesel-powered medium and heavy trucks or busses. Such speed retarding devices or retarders are useful in helping to slow or stop a vehicle, particularly under continuous-braking or start-stop conditions and while the vehicle is descending a relatively long, steep slope, such as a descending stretch of mountain highway. Without the use of a transmission output speed retarder, a conventional vehicle braking system operating continuously under such aggressive slope or traffic conditions may tend to wear more rapidly, potentially reducing the working life of the service brake.
Because of their added safety and maintenance benefits, retarder devices of varying designs or styles are popular transmission add-ons or accessories. Hydrodynamic and electrodynamic retarders are two of the more commonly used retarder devices. Hydrodynamic/hydraulic retarders circulate pressurized fluid within a rotor that is enclosed within a separate, vaned stationary housing in order to induce a viscous drag by way of an opposing fluid coupling effect, thus slowing the rotating driveshaft in proportion to the fluid pressure and/or flow, i.e. the retarder request. Likewise, electrodynamic/electric retarders produce a magnetic field in an opposite rotational direction to that of the driveshaft, thus slowing the vehicle. Other retarder methods or devices may also be used to slow a vehicle, such as exhaust brakes, engine brakes, or Jake Brakes, which act to load a vehicle engine and thereby slow its rate of rotation.
Various operator-directed control systems exist for the purpose of controlling a fixed amount of retarder capacity to be applied to the vehicle transmission. For example, an operator-actuated lever, switch, and/or brake pedal may be used to command a predetermined amount of retarder request based on, for example, a predetermined percentage of available retarder capacity or retarder torque. However, such devices may be less than optimal, as they generally require an operator to actuate a retarder mechanism each time the operator wishes to engage the retarder. Likewise, such mechanisms may provide inadequate vehicle speed control, as a given vehicle's rate of deceleration will necessarily vary along with its gross weight and/or axle ratio as the vehicle travels over different terrain and through various traffic conditions, thus requiring frequent retarder adjustments in order to maintain even a generally constant speed.
Accordingly, a vehicle retarder control apparatus is provided having a transmission with a rotatable output member and a detectable actual transmission output speed, a speed sensor operable for measuring the detectable actual transmission output speed, a plurality of user-commandable input devices for selecting a desired transmission output speed, including a retarder input device configured for selecting a relative amount of retarder request, and a controller having an algorithm for commanding a variable actual amount of retarder request in response to the desired output speed to thereby provide a controlled rate of deceleration to the vehicle.
In another aspect of the invention, the controlled rate of deceleration is determined by one of a plurality of selectable deceleration modes including a constant deceleration rate and a zero deceleration rate.
In another aspect of the invention, a retarder selector switch is operable for selecting between the plurality of selectable deceleration modes.
In another aspect of the invention, the algorithm is continuously adaptive for determining an optimal amount of actual retarder request as determined by one of a throttle level, brake level, retarder input level, and detected output speed.
In another aspect of the invention, a method is provided for precisely controlling the rate of deceleration of a vehicle having a transmission with a rotatable output member and a retarder configured to retard the speed of the rotatable output member, including measuring the actual output speed of the output member, determining a desired output speed using a plurality of user-commandable speed input devices, communicating the actual output speeds to a controller, and commanding the retarder to apply a variable amount of retarder torque to the rotatable output member based on the actual and desired output speeds to thereby achieve a controlled rate of deceleration.
In another aspect of the invention, the controller is configured with a plurality of selectable deceleration control modes including off/disabled, steady-state/zero deceleration, and constant deceleration.
The above features and advantages and other features and advantages of the present invention are readily apparent from the following detailed description of the best modes for carrying out the invention when taken in connection with the accompanying drawings.
Referring to the drawings wherein like reference numbers correspond to like or similar components throughout the several figures, there is shown in
The output member 24 is driveably connected to a rear differential 31, which is configured to distribute rotational force or torque from the output member 24 to a rear drive axle 26 for powering or driving a plurality of wheels 28. Although not shown in
The retarder 20 is preferably a hydrodynamic, i.e. hydraulically-actuated, speed retarding system which is configured to deliver a controllable supply of pressurized fluid (not shown) opposite the transmission 16 to thereby induce a viscous drag capable of providing a variable opposing torque suitable for slowing or retarding the speed or rate of rotation of the rotatable transmission 16. However, other transmission speed retarding devices such as electrodynamic retarders are also usable in accordance with the invention. For the preferred hydrodynamic retarder, the pressure and/or flow of the controllable supply of pressurized fluid, collectively referred to hereinafter as the actual retarder request, is rapidly and continuously variable in response to various user-commandable or selectable input devices, such as brake 12, retarder selector switch 41, and throttle 40. A detectable braking input level (Bi) corresponds to the detectable position or level of the brake 12, a detectable throttle input level (Ti) corresponds to the position of the throttle 40, and a detectable retarder input level (Ri) corresponds to a relative amount or level of desired retarder request as determined by the position of the selector switch 41. The selector switch 41 is preferably operable to communicate with the controller 18 and ultimately with the retarder 20 via data-link message, although direct/hard wiring and other control connections are also useable within the scope of the invention.
An integrated control unit or controller 18 is configured with a suitable amount of memory 19 and an adaptive control algorithm 100, as will be described in more detail hereinbelow. The controller 18 is configured to receive the communicated or transmitted transmission output speed ωTo from the speed sensor 13, as well as detect the levels of the plurality of user-selectable or user-commandable input devices including the throttle 40, brake 12, and retarder selector switch 41. The user-commandable input devices 40, 12, and 41 collectively generate a detectable desired speed input ωVi, with ωVi preferably including at least a detectable throttle level or input Ti, a detectable brake level or input Bi, and a detectable retarder level or input level Ri. The controller 18 temporarily records or stores the values ωTo and ωVi in memory 19 for ready access by algorithm 100 of the invention, as described later hereinbelow. To provide adequate storage for capturing the rapidly changing speed data ωVi and ωTo, memory 19 preferably includes a circular buffer and/or array having a suitable capacity, wherein the oldest stored values are dropped or deleted from the buffer and/or array as the newest or most recent values are stored or recorded. Alternately, the newly recorded values may be averaged or filtered in real time in order to reduce the required amount of storage space of memory 18.
The invention includes closed-loop and adaptive control logic to precisely control the deceleration of a vehicle irrespective of the vehicle's weight, mass, and/or axle ratio. While the retarder 20 is applied, the closed-loop control feature maintains a constant or zero rate of deceleration independent of the weight of the vehicle, and independent of the axle ratio, by continuously adapting or modifying the relative amount of retarder request as needed in order to maintain the selected rate of deceleration as described hereinbelow. The continuously adaptive feature is used to learn or determine an optimal amount of retarder request based in part on the amount of deceleration requested by the operator and changing vehicle speed.
Preferably, for start-stop operations, the driver or operator would determine a desired retarder input Ri using the selector switch 41, which is then communicated or transmitted to the controller 18 as one of the input variables useable within the algorithm 100. For downhill speed control, for example, the operator would preferably select a steady-state, i.e. a constant speed, cruise-control, or zero deceleration condition. The controller 18 would in turn command the appropriate amount of actual retarder request from the retarder 20 to safely achieve and maintain the desired deceleration rate of the vehicle while preventing overload of the braking system.
Turning to
Turning to
The algorithm 100 begins with step 102 preferably being performed once upon each start-up of the engine 25 (see
In step 104, the algorithm 100 determines whether the retarder 20 is turned on or activated. This selection is preferably made by the operator or driver of the vehicle before or shortly after engine start-up by activating a retarder selector switch 41 that is readily accessible to the driver within the passenger compartment or cabin of the vehicle and operable to turn enable/disable the retarder 20 as well as select a retarder input Ri, as described later hereinbelow. If the retarder 20 is off or not activated, the retarder deceleration control capability is temporarily disabled, and the algorithm 100 proceeds to step 124. If, however, the retarder 20 is turned on or activated, the algorithm 100 proceeds to step 106.
In step 106, the algorithm 100 determines the retarder input Ri, which as explained previously hereinabove is preferably selected by an operator using a retarder selector switch 41. A selected Ri level preferably corresponds to a position of selector switch 41 wherein “1” and “2” relate back to retarder or deceleration modes MR 1 and MR 2, respectively, as explained previously hereinabove and shown in
In step 108, with Mode 1, i.e. a steady-state/zero deceleration condition, having been selected in the preceding step, the algorithm 100 determines the desired speed input ωVi by using any or all of the detectable throttle, brake, and retarder inputs or levels Ti, Bi, and Ri, respectively, and temporarily records or stores the value ωVi in memory 19. The algorithm 100 utilizes the detectable throttle input Ti to continuously increase or revise the stored value ωVi until the operator commands zero throttle, i.e. stops depressing the accelerator pedal, and utilizes the detectable braking input Bi to reduce or decrease the stored value ωVi in relation to the duration and/or level of commanded braking. Once the target or desired speed input ωVi is determined, the algorithm 100 proceeds to step 110.
In step 110, the algorithm 100 detects or measures the actual transmission output speed ωTo, preferably using the speed sensor 13 as shown in
In step 112, the algorithm 100 compares the stored value of the measured transmission output speed ωTo to the desired speed input ωVi, to determined if and to what extent the retarder 20 should be applied. If ωVi is less than or equal to ωTo, the algorithm 100 recognizes that the vehicle is traveling at a faster rate than desired and commanded by the operator, and therefore proceeds to step 114. If, however, ωVi is determined to be greater than ωTo, the algorithm 100 recognizes that the vehicle is traveling at a slower rate than desired or commanded by the operator and proceeds to step 122.
In step 114, the algorithm 100 increases the retarder input Ri as required, targeting ωVi to be equal to ωTo, that is, an equilibrium condition wherein the desired speed input is equal to the actual transmission output speed. The required rate of increase of Ri may be determined by a variety of factors including the braking input Bi and the difference between ωTo and ωVi. In order to increase the response time of the control loop and to frequently check for more recent vehicle speed inputs, i.e. Ti, Bi, and/or Ri, step 114 is preferably sustained only for a fixed period of time. Therefore, the desired equilibrium condition where ωVi actually equals ωTo may not be fully realized until a number of control loop cycles have been completed. For this reason, the term “targeting” is employed within
In step 116, the algorithm 100 is now operating in the second mode, or MR 2 (see
Preferably, a switch, lever, or other input device is configured with three or more input levels corresponding to three or more retarder request levels that the driver can select between as desired. The algorithm 100 is also preferably configured to adjust the selected retarder input Ri upward or downward as required by the changing external operating conditions or vehicle speed as needed, such as when a low level of retarder control is initially selected on a flat stretch of highway and the vehicle suddenly and unexpectedly enters a steep downgrade, thereby requiring an aggressive amount of braking represented by braking input Bi. Once Ri has been determined, the algorithm 100 proceeds to step 118.
In step 118, the driver or operator-selected level of retarder input Ri selected in step 116 is used to determine if the actual rate of deceleration of the vehicle (−αVA) is greater than the desired or input rate of deceleration (−αVi). Since acceleration and deceleration are a function of vehicle speed over time, the controller 18 is preferably configured to rapidly derive these variables directly from the transmission output speed ωTo and throttle input Ti, and to store the derived deceleration variables in memory 19. If the value −αVA is determined to be greater than the value −αVi, a condition in which the vehicle is decelerating at a more rapid rate than desired, the algorithm proceeds to step 120. If, however, the value −αVA is determined to be less than the value of −αVi, i.e. the vehicle is determined to be decelerating at a lesser rate than desired, and the algorithm proceeds to step 121.
In step 120, the algorithm 100 evaluates the differential between the values −αVA and −αVi and adjusts the retarder request accordingly. By decreasing the retarder request, the vehicle is permitted to decelerate at a lesser rate. As described for step 114, step 120 is preferably not held or sustained until −αVA actually equals −αVi, and thus a suitable amount of movement toward the desired equilibrium condition, i.e. αVA=−αVi, occurs in step 120 within the amount of control loop time allocated to this step. The algorithm 100 then proceeds to step 124.
In step 121, the algorithm 100 evaluates the differential between the values −αVA and −αVi and increases the retarder request accordingly. By increasing the retarder request, the vehicle is permitted to decelerate at an increased rate. As with steps 114 and 120, step 121 is preferably not held or sustained until −αVA actually equals −αVi, and thus a suitable amount of movement toward the desired equilibrium condition, i.e. αVA=−αVi occurs in step 121 within the amount of control loop time allocated to this step. The algorithm 100 then proceeds to step 124.
In step 122, the algorithm 100 decreases the retarder input Ri as required, targeting ωVi to be equal to ωTo, that is, an equilibrium condition wherein the desired speed input is equal to the actual transmission output speed. As described for steps 114 and 120, step 122 is preferably not held or sustained until ωVA actually equals ωVi, and thus a suitable amount of movement toward the desired equilibrium condition, i.e. ωVA=ωVi, occurs in step 122 within the amount of control loop time allocated to this step. The algorithm 100 then proceeds to step 124.
In step 124, the algorithm 100 has reached a condition where the desired mode, i.e. disabled, Modes 1 or 2 (see
As described hereinabove, step 124 could be programmed to provide a safety backup to the situation in which an operator selects “off” at step 104. Under those circumstances, the algorithm 100 could determine whether activation of the retarder system is required in light of the transmission output speed ωTo, braking input level Bi, and throttle input Ti. If such automatic override is not desired, step 124 would read retarder input Ri as a zero value for the off/disabled mode MR 1, with no arbitration result relative to the operation of the retarder system.
While the best modes for carrying out the invention have been described in detail, those familiar with the art to which this invention relates will recognize various alternative designs and embodiments for practicing the invention within the scope of the appended claims.
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