AN ARRANGEMENT AND METHOD FOR SUPPORTING A CRUISE CONTROL BRAKE IN A VEHICLE

Abstract

A cruise control arrangement for a vehicle is provided with a cruise control brake function that is set to a brake cruise speed. The cruise control arrangement is adapted to activate at least one auxiliary brake when the vehicle speed reaches the set brake cruise speed, and at the same time to apply a service brake of the vehicle to keep the speed of the vehicle at the set brake cruise speed, and is further adapted to decrease the brake power of the service brake at the same time as the brake power of the at least one auxiliary brake increases, such that the speed of the vehicle is kept at the set brake cruise speed. The speed of the vehicle can be held at the set cruise speed when an auxiliary brake is activated, regardless of the activation time of the auxiliary brake. In this way, an overshoot in speed can be avoided during the activation time of the auxiliary brake.

Claims

1. A cruise control arrangement for a vehicle, where the cruise control arrangement is provided with a cruise control brake function, where the cruise control brake function is set to a brake cruise speed, wherein the cruise control arrangement is adapted to activate at least one auxiliary brake when the vehicle speed reaches the set brake cruise speed, the auxiliary brake being activated by a preset amount which corresponds to a requested brake power, a response time being a time from the activation of the auxiliary brake until the auxiliary brake is fully applied such that it delivers the requested brake power, and to apply at the same time as the auxiliary brake activation a service brake of the vehicle to keep the speed of the vehicle at the set brake cruise speed, and further adapted to decrease the brake power of the service brake at the same time as the brake power of the at least one auxiliary brake increases, such that the speed of the vehicle is kept at the set brake cruise speed, whereby when the brake power of the auxiliary brake increases during the response time, the brake power of the service brake is decreased with the corresponding amount.

2. The arrangement according to claim 1, wherein the service brake is deactivated when the at least one auxiliary brake is fully applied.

3. The arrangement according to claim 1, wherein the at least one auxiliary brake is a compression brake or a hydraulic retarder brake.

4. The arrangement according to claim 3, wherein the cruise control arrangement is adapted to activate both the compression brake and the hydraulic brake simultaneously.

5. The arrangement according to claim 1 wherein the arrangement will only apply the service brake if a predefined vehicle condition is met.

6. The arrangement according to claim 5, wherein the predefined vehicle condition is at least one of; the inclination of the downhill slope, the vehicle weight, the vehicle speed or the vehicle acceleration.

7. Vehicle comprising an arrangement according to claim 1.

8. A method for supporting a cruise control function in a vehicle when the vehicle is travelling downhill and when the cruise control function is active, where the cruise control function comprises a cruise control brake function which is set to a brake cruise speed, comprising: activating at least one auxiliary brake when the vehicle speed reaches the set brake cruise speed, the auxiliary brake being activated by a preset amount which corresponds to a requested brake power, a response time being a time from the activation of the auxiliary brake until the auxiliary brake is fully applied such that it delivers the requested brake power, applying a service brake of the vehicle at the same time as the auxiliary brake activation in order to keep the speed of the vehicle at the set brake cruise speed, decreasing the brake power of the service brake at the same time as the brake power of the at least one auxiliary brake increases, such that the speed of the vehicle is kept at the set brake cruise speed, whereby when the brake power of the auxiliary brake increases during the response time, the brake power of the service brake is decreased with the corresponding amount.

9. The method, according to claim 8, further comprising the following step: deactivating the service brake when the at least one auxiliary brake is fully operational.

10. The method according to claim 8, further comprising the following step: applying the service brake only if the acceleration of the vehicle is larger than a predetermined value.

11. The method according to claim 8, where the at least one auxiliary brake is a compression brake or a hydraulic retarder brake.

12. The method according to claim 11, where both the compression brake and the hydraulic brake are activated simultaneously.

13. The method according to claim 8, where the activation of an auxiliary brake comprises the step of performing a down shift of the transmission.

14. A computer comprising a computer program for performing all the steps of claim 8 when the program is run on the computer.

15. A non-transitory computer program product comprising a computer program stored on a non-transitory computer readable medium for performing all the steps of claim 8 when the program product is run on a computer.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0024] The invention will be described in greater detail in the following, with reference to the attached drawings, in which

[0025] FIG. 1 shows a schematic view of a cruise control arrangement of a vehicle, and

[0026] FIG. 2 shows a schematic flow chart of an inventive method for supporting a cruise control system of a vehicle.

DETAILED DESCRIPTION

[0027] The embodiments of the invention with further developments described in the following are to be regarded only as examples and are in no way to limit the scope of the protection provided by the patent claims. The arrangement is suitable for all kinds of vehicles, but is especially suitable for heavy vehicles such as trucks and busses, having brake cruise control functionality using auxiliary brakes.

[0028] FIG. 1 shows a schematic cruise control arrangement of a vehicle. The arrangement 1 comprises a cruise control electronic control unit 4 which may be either a standalone control unit comprising the cruise control system or may be integrated e.g. as a software module in another electronic control unit in the vehicle. The cruise control arrangement further comprises a user interface 2. The user interface comprises buttons used by a driver to input cruise control parameters and to engage and disengage the cruise control system. The user interface may farther comprise display means showing part of or all selected cruise control parameters.

[0029] In this example, the vehicle 10 is powered by an engine 7 with a gearbox 6, preferably an automated manual transmission or an automatic transmission. The engine is provided with an exhaust brake 9 and the transmission is provided with a hydraulic retarder 8. The vehicle is further provided with a service brake 5 which is controlled by a brake control unit 3.

[0030] in the arrangement, a cruise speed can be set or selected, which is the reference speed that the vehicle will maintain when the cruise control is engaged and the vehicle travels on a horizontal road. The cruise control system is provided with a preset speed interval around the set cruise speed, e.g. +1 km/h, in which the cruise speed will be held during cruise control regulation. When the vehicle travels on a substantially even road and the cruise speed is set to 70 km/h, the speed may vary between 69 km/h to 71 km/h.

[0031] The driver can also set a brake cruise speed value, which is the speed value that the brake cruise control will maintain when the vehicle is travelling downhill. The brake speed value is normally set as a positive speed offset value that is added to the set cruise speed. If the brake speed offset is set to 6 km/h, the resulting brake cruise speed would in this case be 76 km/h. This speed will be maintained by the auxiliary brakes of the vehicle when the vehicle travels down a descent and where the vehicle will be coasting faster than the cruise speed. By allowing an excessive speed when travelling downhill, the travel efficiency can be improved. At the same time, the excessive speed should not be allowed to be too high, such that the vehicle will not be able to stop or such that it will exceed speed limits for a longer time.

[0032] The arrangement further comprises a brake control unit 3, which is used to control the service brake and additional service brake functions, such as an automated brake system (ABS) or an electronic stability program (ESP).

[0033] The cruise control system is adapted to activate the auxiliary brake when the speed of the vehicle exceeds the set brake cruise speed. Due to the rolling resistance and the air drag of the vehicle, this situation will only occur when the vehicle is travelling downhill. When travelling along a horizontal road, the cruise control decreases the throttle before the brake cruise speed is reached. Preferably, all auxiliary brakes of the vehicle are engaged at the same time in order to increase the available brake power, but it is also possible to use only one auxiliary brake when the requited brake power is relatively low.

[0034] In the inventive cruise control arrangement, the arrangement is adapted to activate the service brake at the same time as the auxiliary brake. The response time of the service brake is instant, such that there is no delay in the brake response. An auxiliary brake may have a response time of several seconds depending on the type of auxiliary brake. A hydraulic retarder normally have a relatively short response time, in the range of a few seconds, and an exhaust brake normally have a response time of up to 5 seconds or more, depending on the required brake power. The response time is measured from the activation of the auxiliary brake until the auxiliary brake is fully applied and delivers the requested brake power.

[0035] By applying the service brake simultaneously with the auxiliary brake, the acceleration of the vehicle can be reduced instantaneously which means that there will not be an overshoot in vehicle speed of the vehicle. When the speed of the vehicle reaches the set brake cruise speed when the vehicle travels downhill, the speed of the vehicle can thus be held at the set brake cruise speed until the auxiliary brake is fully applied. Normally, the speed of the vehicle will continue to increase somewhat when the set brake cruise speed is reached, since the vehicle will continue to accelerate during the response time of the auxiliary brake.

[0036] This acceleration during the response time of the auxiliary brake, will lead to a vehicle speed that is higher than the set brake cruise speed.

[0037] Depending on the inclination of the slope, the weight of the vehicle, the actual vehicle speed and the acceleration rate, this excessive speed is more or less severe. In most cases, the excessive speed will only result in an overshoot in the vehicle speed, where the speed is brought back to the set brake cruise speed when the auxiliary brake is fully applied. However, such a speed overshoot may be uncomfortable for the driver, which may feel that he has no control of the vehicle. In order to avoid such an overshoot in speed, the driver may set a lower brake cruise speed value in order to be on the safe side, which in turn will affect the fuel efficiency of the vehicle in a negative way.

[0038] In some cases, the auxiliary brake will not be able to bring the excessive vehicle speed back to the set brake cruise speed when it is fully engaged, since the excessive speed is too high. In such a case, the driver is forced to reduce the speed of the vehicle manually by applying the service brake. Such a situation may well be uncomfortable for the driver, and should be avoided if possible. Further, such a situation will wear the service brake unnecessarily. If the vehicle travels with an excessive speed for a longer time, e.g. 1 minute, the excessive speed may also be recorded by the tachograph, which may lead to a fine.

[0039] With the inventive arrangement, those situations can be avoided by activating the service brake at the same time as the auxiliary brake. The service brake will respond instantly, and will thus be able to reduce the acceleration of the vehicle and to hold the speed at the set brake cruise speed during the response time of the auxiliary brake. When the brake power of the auxiliary brake increases during the response time, the brake power of the service brake is decreased with the corresponding amount. In this way, the speed is held constant at the set brake cruise speed. When the auxiliary brake is fully applied such that it delivers the requested brake power, the service brake can be disengaged, and the auxiliary brake can continue to hold the vehicle speed at the set brake cruise speed.

[0040] It is of advantage to deactivate the service brake when the auxiliary brake is fully applied. In this way, the wear of the service brake is minimized. Further, the service brake will not heat up very mach which means that the service brake is fresh and can be used to decrease the speed of the vehicle further if conditions changes, e.g. if a new speed limit appears in the middle of the downhill slope.

[0041] Depending on the actual speed and acceleration of the vehicle, the arrangement is adapted to perform a down shift of the transmission. In this way, the engine speed can be increased which in turn will increase the available brake power of an engine auxiliary brake. A down shift will also increase the available brake power of a hydraulic retarder, since the available brake power of a hydraulic retarder is dependent on the speed of the shaft to which the retarder is mounted. However, a down shift will increase the time until the auxiliary brake is fully applied, since the time for the down shift will be added to the response time of the auxiliary brake. By using the service brake to hold the speed at the set brake cruise speed during the downshift, it can be ensured that there will not be an overshoot in vehicle speed.

[0042] The arrangement may be set to only apply the service brake simultaneously with the auxiliary brake if a predefined vehicle condition is met. Such a predefined vehicle condition can be the inclination of the downhill slope, i.e. the inclination of the vehicle, which will affect the acceleration of the vehicle. Such a condition can also be dependent on the vehicle weight, the vehicle speed or the vehicle acceleration. Since the problem with an undesired overshoot in vehicle speed will only occur when the vehicle travels downhill a relatively steep slope, the wear of the service brake can be further minimized. If the auxiliary brakes are applied on a horizontal road or on a slight descend, there is no need to apply the service brakes simultaneously with the auxiliary brake since there is no risk of an overshoot in vehicle speed. The same applies if the speed of the vehicle is very low, e.g. below 50 km/h. It is also unnecessary to apply the service brakes if the acceleration of the vehicle is low or if the weight of the vehicle is low, e.g. if the vehicle is empty. In those cases, the overshoot in vehicle speed will at the most be very low.

[0043] FIG. 2 shows a schematic flow chart of a method for supporting a cruise control function in a vehicle according to the invention. The method is adapted to activate a service brake at the same time as an auxiliary brake when the vehicle reaches a brake cruise speed, such that the service brake can compensate for the response time of the auxiliary brake.

[0044] In step 100, the cruise control function compares the actual vehicle speed with the set brake cruise speed. In step 110 an activation signal is sent to the control unit of the auxiliary brake and the control unit of the service brake, if the actual vehicle speed reaches the set brake cruise speed. The auxiliary brake is activated in step 120 and the service brake is activated in step 130. The auxiliary brake is activated by a preset amount which corresponds to a requested brake power. The service brake is activated such that the brake power of the service brake corresponds to the requested brake power of the auxiliary brake. The service brake will provide all the requested brake power at the activation time.

[0045] In step 140, the brake power of the service brake is decreased by an amount that corresponds to the increase in brake power of the auxiliary brake. In this way, the total brake power delivered by the service brake and the auxiliary brake will be same, which means that the vehicle will be able to keep a constant speed, i.e. to keep the set cruise speed. The decrease of brake power for the service brake may be controlled in different ways. One way is to use a predefined map including e.g. vehicle weight, road slope angle, vehicle speed, activation time for the auxiliary brake etc. which is used to control the service brake power. Another way is to control the service brakes such that the acceleration of the vehicle is zero, i.e. such that the speed of the vehicle does not increase. If the brake power of the auxiliary brake is sufficient to hold the set brake cruise speed when the auxiliary brake is fully applied, such a control will decrease the brake power to the service brake when the brake power of the auxiliary brake increases.

[0046] In step 150, the actual brake power of the auxiliary brake is compared with the requested brake power. When the auxiliary brake is fully applied, such that the auxiliary brake delivers the requested brake power, the service brake is deactivated in step 160.

[0047] It is further possible to perform a downshift of the transmission. This may be advantageous if it is decided that a higher brake power is required, since the available brake power from an auxiliary brake is dependent on the engine speed or the speed of the shaft where the auxiliary brake is mounted. The service brake will in this case be activated at the same time as the downshift is activated, such that the service brake can hold the speed of the vehicle at the set brake cruise speed during the downshift. When the downshift is completed, the brake power of the service brake is reduced when the brake power of the auxiliary brake increases.

[0048] It is possible to activate the service brake only when a predefined vehicle condition is met. Such a predefined vehicle condition can be the inclination of the downhill slope, the vehicle weight, the vehicle speed or the vehicle acceleration as described above.

[0049] The invention is not to be regarded as being limited to the embodiments described above, a number of additional variants and modifications being possible within the scope of the subsequent patent claims.