JP2007320482A - Automatic braking control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To achieve automatic braking control in a truck or a bus. <P>SOLUTION: When TTC derived based on the relative distance and the relative speed of an object and one's own vehicle is under a preset value, automatically stepped braking control for gradually increasing the braking force in two or more stages is time-series conducted. At this time, when a driver's sudden braking operation is detected in the process of executing stepped braking control, the stepped braking control is suspended, and braking is performed with predetermined braking force or at braking deceleration (e.g. the maximum braking force or braking deceleration of the own vehicle). Alternatively, when the braking force or the braking deceleration estimated to generate by the detected sudden braking operation of the driver is larger than the braking force or the braking deceleration generated by the stepped braking control at the current time, stepped braking control is suspended and the priority is given to the driver's sudden braking operation. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention is used for large vehicles (trucks, buses) for transporting cargo and passengers. In particular, the present invention relates to a device that uses ABS (Anti Lock Breaking System) for automatic braking control.

  The electronic control of automobiles has progressed steadily, and events that have so far depended solely on the judgment of the driver have been carried out by onboard computers.

  As an example, the distance between the preceding vehicle and the host vehicle (inter-vehicle distance) is monitored by a radar, and when the inter-vehicle distance approaches abnormally, appropriate braking control is automatically performed to prevent a collision. Sometimes, there is an automatic braking control device that minimizes the damage (see, for example, Patent Document 1).

JP 2005-31967 A

  The above-described automatic braking control device has already been put into practical use in passenger cars, but it must be solved when a similar function is to be used for large vehicles (trucks, buses) for transporting cargo and passengers. There is a problem that must be done.

  In other words, large vehicles have an extremely large mass compared to passenger cars, and in addition to the driver's own safety, the safety of passengers and cargo must be ensured. It is difficult to achieve the intended purpose with simple simple braking control, and it is necessary to perform more advanced automatic braking control than in the case of passenger cars. However, since such means has not been established, automatic braking control devices for trucks and buses have not yet been put into practical use.

  The present invention has been made under such a background, and an object thereof is to provide an automatic braking control device that can realize automatic braking control in a truck or a bus.

  The present invention includes a control unit that automatically performs braking control based on a sensor output including a distance to an object in the traveling direction of the host vehicle without a driving operation, and the control unit is obtained from the sensor output. When the estimated time required for the object and the vehicle to be derived based on the relative distance and relative speed between the object and the vehicle is less than a predetermined distance is automatically less than a set value, It is an automatic braking control device provided with a gradual braking control means for performing gradual braking control for gradually increasing braking force or braking deceleration over a plurality of stages in a time series.

  The predicted time required for the object and the vehicle to be derived based on the relative distance and relative speed between the object and the vehicle is equal to or less than a predetermined distance is, for example, a collision between the object and the vehicle This is the estimated time required to do this (hereinafter referred to as TTC (Time To Collision)).

  Thereby, the braking control for gradually increasing the braking force or the braking deceleration can be performed over a plurality of stages, and the braking control suitable for large vehicles such as trucks and buses can be performed.

  Here, a feature of the present invention is that the host vehicle is provided with an ABS, and the stepwise braking control means includes means for diverting the braking force adjustment function in the ABS to perform the stepwise braking control. And a sudden braking operation detecting means for detecting a sudden braking operation by the driver is provided, and the stepwise braking control means is configured so that the sudden braking operation detecting means performs the sudden braking by the driver during the execution of the stepwise braking control. When an operation is detected, there is provided a braking interrupt means for stopping the stepwise braking control and executing braking by a predetermined braking force or braking deceleration.

  Here, diverting the braking force adjustment function in the ABS and performing stepwise braking control will be described. As is well known in the ABS, when the driver performs excessive braking operation, the gripping force of the tire against the ground is lost, and when the wheel starts to idle, the idle state of the wheel is detected and automatically detected. By weakening the braking force of the idling wheel, the tire grip force is recovered to stop the idling of the wheel. Therefore, the ABS originally has a function of adjusting the braking force. Therefore, by separating this braking force adjusting function from the ABS original control function and controlling based on the stepwise braking control, the braking force adjusting function in the ABS can be diverted to perform stepwise braking control. .

  The automatic braking control device of the present invention has an object of interpolating lack of attention due to the driver's drowsiness or looking aside, and is usually a braking pattern suitable for such a situation (ie, lack of attention of the driver). However, when automatic braking control is performed, if there is a sudden braking operation by the driver, it can be understood that the driver recognizes the necessity of sudden braking of the own vehicle. It is desirable to change to a braking pattern that is suitable for a rough situation (that is, a state where the driver's attention is not lacking).

  Therefore, in the present invention, a means for detecting a sudden braking operation by the driver is provided, and when a sudden braking operation by the driver is detected during the execution of the stepwise braking control, a predetermined braking force or braking deceleration is used. Perform braking. The predetermined braking force or braking deceleration is, for example, the maximum braking force or braking deceleration that the host vehicle has.

  At this time, in the braking control according to the present invention, the sudden braking operation by the driver is not simply given priority over the automatic braking control as it is, but a predetermined (for example, maximum) sharper than the sudden braking operation performed by the driver. Braking control for exerting braking force or braking deceleration can be performed. That is, the braking interrupting means stops the stepwise braking control and executes braking with a predetermined braking force or braking deceleration according to the maximum braking force or braking deceleration increasing rate of the own vehicle. Means for increasing the braking force or braking deceleration may be provided.

  Alternatively, a braking operation level detecting means for estimating a braking force or a braking deceleration strength that is expected to be generated by a driver's sudden braking operation is provided, and the stepwise braking control unit is configured to perform the stepwise braking control. During the execution of the control, the braking operation level detection means detects a sudden braking operation by the driver that is estimated to generate a braking force or braking deceleration that is stronger than the braking force or braking deceleration in the current stage braking control. Sometimes, there is provided braking control stopping means for stopping the stepwise braking control.

  As a result, even when the stepwise braking control is being executed, the braking operation by the driver requires a braking force or braking deceleration stronger than the current braking force or braking deceleration by the stepwise braking control. In this case, the braking force or braking deceleration required by the driver can be prioritized.

  In addition, when the host vehicle speed is less than a predetermined value and the value taken by the steering angle or yaw rate is out of the predetermined range, a means for prohibiting activation of the stepwise braking control means can be provided.

  That is, the stepwise braking control performed by the automatic braking control device of the present invention is, for example, when the vehicle speed before starting the braking control is 60 km / h or more, and a large steering wheel operation such as when changing lanes or driving sharp curves is performed. Since it is assumed to be used in a state where it is not performed, the start of the stepwise braking control can be restricted in other traveling states.

  For example, if the vehicle speed before the start of braking control is less than 60 km / h, the vehicle has less kinetic energy, so there is no problem even if simple sudden braking control as conventionally applied to passenger cars is performed. Limit the start of stepwise braking control. Also, for example, if the steering angle before starting the braking control is + 30 ° or more or −30 ° or less, this means that the vehicle is changing lanes or driving in a sharp curve. Restrict. In this case, a yaw rate may be used instead of the steering angle.

  According to the present invention, automatic braking control in a truck or bus can be realized. In particular, since the automatic braking control device of the present invention can be realized by diverting the ABS provided in most vehicles in recent years, the number of remodeled parts of the vehicle for realizing the present invention can be reduced. There is an effect that can be done. In addition, the braking pattern can be changed depending on whether or not there is a sudden braking operation by the driver after the start of automatic braking control, and automatic braking control suitable for the situation at that time can be performed.

(First Example)
An automatic braking control apparatus according to an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a control system configuration diagram of the present embodiment. FIG. 2 is a diagram showing a braking pattern at the time of idle loading that the braking control ECU has. FIG. 3 is a diagram showing brake pedal strokes during normal braking operation and sudden braking operation. FIG. 4 is a flowchart showing a sudden braking operation detection procedure in the sudden braking operation detection unit. FIG. 5 is a diagram showing the rate of increase in brake pressure during normal sudden braking and emergency braking. FIG. 6 is a diagram showing a braking pattern when emergency braking is interrupted in the warning braking stage. FIG. 7 is a diagram showing a braking pattern when emergency braking is interrupted in the enlarged region braking stage. FIG. 8 is a diagram showing a braking pattern when emergency braking is interrupted in the full-scale braking stage. FIG. 9 is a diagram showing a braking pattern when emergency braking is interrupted in full-scale braking. FIG. 10 is a diagram showing a braking pattern at the time of half product of the braking control ECU. FIG. 11 is a diagram showing a braking pattern at the time of fixed volume possessed by the braking control ECU. FIG. 12 is a diagram showing a full-scale braking pattern possessed by the braking control ECU. FIG. 13 is a flowchart showing a control procedure of a braking control ECU (Electric Control Unit) in the braking pattern at the time of the idle product of the first embodiment.

  As shown in FIG. 1, the braking control ECU 4, the gateway ECU 5, the meter ECU 6, the engine ECU 8, the axle weight meter 9, and the ABS_ECU 10 are connected to each other via a VehicleCAN (J1939) 7.

  Further, the steering sensor 2, the yaw rate sensor 3, the vehicle speed sensor 13, the brake operation sensor 14, and the wheel speed sensor 24 are connected to the VehicleCAN (J1939) 7 via the gateway ECU 5, respectively. It is taken into ABS_ECU10. The engine ECU 8 performs fuel injection amount control of the engine 12 and other engine control. Note that the injection amount control instruction to the engine ECU 8 is performed by the accelerator operation of the driver's seat. Further, the alarm display and buzzer sound output by the braking control ECU 4 are displayed on the display unit (not shown) of the driver's seat by the meter ECU 6. Since the control system related to steering other than the steering sensor 2 is not directly related to the present invention, the illustration is omitted.

  When the driver depresses the brake pedal 15, the pressure in the brake valve 16 increases. When the increased pressure reaches the relay valve 18 via the selection valve 17, the air in the air tank 20 is changed to the relay valve 18 and the ABS. It flows into the cylinder 21 via the modulator 11. At this time, the relay valve 18 causes the air in the air tank 20 to flow into the cylinder 21 via the ABS modulator 11 according to the air pressure of the brake valve 16. A brake pad 22 is attached to the cylinder 21, and the brake pad 22 presses the disk or drum of the wheel 23. Thereby, the rotation of the wheel 23 is braked.

  At this time, the ABS_ECU 10 acquires wheel speed information from the wheel speed sensor 24, and controls the ABS modulator 11 to adjust the braking force when it detects idling of the wheel caused by excessive braking operation. That is, the air in the air tank 20 flows into the cylinder 21 via the relay valve 18 and the ABS modulator 11. At this time, the ratio (duty ratio) for opening and closing the ABS modulator 11 per unit time is changed. The amount of air flowing into the cylinder 21 can be adjusted, whereby the air pressure applied to the cylinder 21 can be adjusted. Therefore, when an excessive braking operation is performed and the wheel slips, the pressure applied to the cylinder 21 can be reduced until the idling stops. This description is a description of the known ABS operation.

  Next, a method for realizing the stepwise braking control of the present embodiment by diverting such an ABS braking force adjustment function will be described. The instruction of the stepwise braking control to the ABS_ECU 10 is performed by the braking control ECU 4. In addition, information on the stepwise braking control being executed by the ABS_ECU 10 is taken into the braking control ECU 4 as braking control information.

  When the braking control ECU 4 gives a stepwise braking control instruction to the ABS_ECU 10, the ABS_ECU 10 stops the control as the original ABS and controls the ABS modulator 11 to adjust the braking force based on a braking pattern described later. . This braking force adjustment is performed by adjusting the amount of air flowing into the cylinder 21 by changing the ratio (duty ratio) for opening and closing the ABS modulator 11 per unit time, as in the ABS control described above.

  That is, when the ABS_ECU 10 receives the stepwise braking control instruction from the braking control ECU 4, the ABS_ECU 10 fully opens the braking control valve 19. As a result, the air pressure in the air tank 20 is transmitted to the selection valve 17 via the brake control valve 19. The selection valve 17 selects the larger air pressure of the brake valve 16 or the brake control valve 19 and allows the air to pass therethrough. Therefore, during normal operation, the brake control valve 19 is closed, and the selection valve 17 transmits the air pressure of the brake valve 16 to the relay valve 18, but when the brake control valve 19 is fully opened, the selection valve 17 Transmits the air pressure of the brake control valve 19 to the relay valve 18.

  As a result, the air in the air tank 20 flows into the ABS modulator 11 via the brake control valve 19, the selection valve 17, and the relay valve 18. The ABS modulator 11 adjusts the amount of air flowing into the cylinder 21 by controlling the duty ratio, and adjusts the air pressure in the cylinder 21 to adjust the braking force.

  At this time, when the driver depresses the brake pedal 15, the air pressure in the brake valve 16 increases, but the brake control valve 19 is fully open, so the air pressure of the brake control valve 19 is higher than the brake valve 16. Therefore, the selection valve 17 continues to select the air pressure of the brake control valve 19, so that the driver's brake operation is ignored.

  Therefore, in this embodiment, the brake operation sensor 14 and the sudden braking operation detection unit 40 that detect the driver's sudden braking operation are provided. The brake operation sensor 14 is an air pressure sensor that detects a change in air pressure in the brake valve 16. Information on the change in air pressure in the brake valve 16 is braked via the gateway ECU 5 and VehicleCAN (J1939) 7 as brake operation information. Based on the brake operation information received from the brake operation sensor 14, the sudden braking operation detector 40 of the braking control ECU 4 detects the sudden braking operation by the driver.

  The braking control ECU 4 stops the stepwise braking control and executes the braking with a predetermined braking force when the sudden braking operation detecting unit 40 detects the sudden braking operation by the driver during the stepwise braking control. To do. In this embodiment, the predetermined braking force is the maximum braking force that the host vehicle has. The maximum braking force corresponds to the braking force of “full-scale braking” in the stepwise braking control.

  Further, the driver's braking operation acts as a brake instruction for the relay valve 18, and normally, the relay valve 18 appropriately adjusts the braking force of the cylinder 21 in proportion to the amount of depression of the driver's brake pedal. In this embodiment, when the sudden braking operation detection unit 40 detects the driver's sudden braking operation after the stepwise braking control is started, the braking control ECU 4 increases the maximum braking force with respect to the ABS_ECU 10. Instructs emergency braking at a rate.

  In the following, the first embodiment will be described in more detail.

  In this embodiment, as shown in FIG. 1, a millimeter wave radar 1 for measuring a distance from a preceding vehicle or a falling object such as a falling object in the traveling direction of the own vehicle, a steering sensor 2 for detecting a steering angle, This is an automatic braking control device including a braking control ECU 4 that automatically performs braking control based on sensor outputs such as a yaw rate sensor 3 for detecting the yaw rate and a vehicle speed sensor 13 for detecting the host vehicle speed without any driving operation. .

  The braking control ECU 4 automatically detects when the TTC derived based on the relative distance and relative speed between the object and the vehicle obtained from the sensor outputs from the millimeter wave radar 1 and the vehicle speed sensor 13 falls below a set value. Stepwise braking control. In this stepwise braking control, as shown in FIGS. 2, 10, and 11, the braking force is gradually increased over three stages in time series.

  In the example of FIG. 2B, the braking control ECU 4 first applies braking of about 0.1 G from TTC 2.4 seconds to 1.6 seconds in the first stage marked “alarm”. At this stage, the so-called sudden braking is not yet applied, and the stop lamp is lit to notify the following vehicle that the sudden braking will be performed. Subsequently, in the second stage labeled “enlarged area braking”, braking of about 0.3 G is applied from TTC 1.6 seconds to 0.8 seconds. Finally, in the third stage, marked as “full-scale braking”, the maximum braking (about 0.5 G) is applied from TTC 0.8 seconds to 0 seconds.

Here, the sudden braking operation detection procedure in the sudden braking operation detection unit 40 will be described with reference to FIGS. 3 and 4. In FIG. 3, the horizontal axis represents time (seconds), and the vertical axis represents the brake valve internal air pressure (kg / cm ² ). Comparing the normal braking operation of FIG. 3A and the sudden braking operation of FIG. 3B, the air pressure in the brake valve 16 is from the air pressure when the brake pedal 15 is not depressed to the maximum air pressure. It can be seen that the time is significantly shorter in the sudden braking operation shown in FIG. 3B than in the normal braking operation shown in FIG. Therefore, as shown in FIG. 4, the sudden braking operation detector 40 monitors the air pressure in the brake valve 16 from the brake operation information of the brake operation sensor 14 (S1), and the air pressure in the brake valve 16 depresses the brake pedal 15. When the time until the maximum air pressure is reached from the air pressure when there is no air pressure is equal to or less than the threshold value (S2), it is determined that the sudden braking operation is detected (S3).

Next, the brake pressure increase rate when the ABS_ECU 10 drives the ABS modulator 11 will be described with reference to FIG. The brake pressure increase rate is reflected in the braking force increase rate. In FIG. 5, the horizontal axis represents time (seconds), and the vertical axis represents brake pressure (kg / cm ² ). The brake pressure increase rate during normal sudden braking shown in FIG. 5A is the brake pressure increase rate due to the driver's sudden braking operation. On the other hand, the brake pressure increase rate during emergency braking shown in FIG. 5 (b) is a steeper brake pressure increase rate than the driver's sudden braking operation.

  In the present embodiment, when the sudden braking operation detection unit 40 detects the driver's sudden braking operation after the start of the stepwise braking control, the braking control ECU 4 instructs the ABS_ECU 10 regardless of the brake pedal depression amount by the driver. The ABS modulator 11 is instructed to be driven according to the brake pressure increase rate shown in FIG.

  Next, an example of a braking pattern when a driver's sudden braking operation is detected after the start of the stepwise braking control will be described with reference to FIGS. 6, 7, 8, and 9. In the example of FIG. 6, “alarm” braking control is started from TTC = 2.4 seconds, and immediately after that, an emergency braking operation by the driver is detected and emergency braking is started. In the example of FIG. 7, “extended area” braking control is started from TTC = 1.6 seconds, and immediately after that, a sudden braking operation by the driver is detected and emergency braking is started. In the example of FIG. 8, “full-scale braking” control is started from TTC = 0.8 seconds, and immediately after that, a sudden braking operation by the driver is detected and emergency braking is started. When emergency braking was not started, stepwise braking control as shown by the broken line was scheduled to be executed.

  As will be described later, when the vehicle speed before the start of the braking control is less than 60 km / h and 15 km / h or more, the stepwise braking control is not performed, but only the full-scale braking control is performed. . In such a case, in the example of FIG. 9, “full-scale braking” control is started from TTC = 0.8 seconds, and immediately after that, a sudden braking operation by the driver is detected and emergency braking is started.

  In this embodiment, as shown in FIGS. 2, 10, and 11, the braking pattern selection unit 41 selects a braking pattern according to the loaded cargo or the weight of the passenger. As a selection method, the braking pattern storage unit 42 of the braking control ECU 4 stores a plurality of control patterns for “empty product”, “half product”, and “constant product”, and the braking pattern selection unit 41 This can be realized by selecting a braking pattern that matches (or approximates) these braking patterns according to the weight. The weight information of the loaded cargo and passengers is obtained by the axle weight meter 9 shown in FIG. 1 and is taken into the braking control ECU 4. If the equal braking forces are compared with each other, the braking distance increases as the weight of the loaded cargo or passenger increases. Therefore, the start timing of the automatic braking control becomes earlier as the weight of the loaded cargo or passenger increases.

  In the following description, the preceding vehicle will be described, but the automatic braking control device of this embodiment is also effective for falling objects on the road.

  Further, when the host vehicle speed is less than 60 km / h and the steering angle is not less than +30 degrees or not more than -30 degrees, the braking control ECU 4 prohibits the start of the stepwise braking control. A yaw rate may be used instead of the steering angle.

  In other words, the stepwise braking control performed by the automatic braking control device of this embodiment is such that the host vehicle speed before starting the braking control is 60 km / h or more, and a large steering wheel operation such as when changing lanes or driving sharp curves is performed. Since it is assumed that the vehicle is not used, it is possible to limit the start of the stepwise braking control in other driving conditions.

  Also, if the vehicle speed before the start of braking control is less than 60 km / h, the vehicle has less kinetic energy, so there is no problem even if simple sudden braking control as conventionally applied to passenger cars is performed. Since the usefulness of performing stepwise braking control is low, the activation of stepwise braking control is limited. Alternatively, if the steering angle before the start of the braking control is +30 degrees or more or -30 degrees or less, this means that the vehicle is changing lanes or traveling sharply. Restrict startup of. In this case, a yaw rate may be used instead of the steering angle.

  In the present embodiment, when the vehicle speed before the start of the braking control is less than 60 km / h and not less than 15 km / h, the stepwise braking control is not performed, but as shown in FIG. 12, FIG. Only the full-scale braking control shown in FIG. 11 is performed. When only such full-scale braking control is performed, braking control equivalent to conventional automatic braking control used in passenger cars can be applied. Note that when applying such automatic braking control equivalent to the conventional one, there is no need to determine whether or not the vehicle is changing lanes or traveling sharply.

  Next, the operation of the automatic braking control apparatus according to the present embodiment when the braking pattern at the time of idle loading shown in FIG. 2 is selected will be described with reference to the flowchart of FIG. FIG. 13 will be described by taking a braking pattern at the time of idle product (FIG. 2) as an example, but the procedure of the flowchart of FIG. 13 is also followed at the time of half product (FIG. 10) or constant product (FIG. 11). As shown in FIG. 13, the braking control ECU 4 measures and monitors the inter-vehicle distance from the preceding vehicle and the vehicle speed of the preceding vehicle by the millimeter wave radar 1. Further, the vehicle speed is measured by the vehicle speed sensor 13 and monitored. Further, the weight of the loaded cargo and passengers is measured and monitored by the axle weight meter 9. The sudden braking operation detection unit 40 of the braking control ECU 4 monitors the sudden braking operation from the brake operation information of the brake operation sensor 14. The braking pattern selection unit 41 of the braking control ECU 4 selects in advance one of the braking patterns (FIGS. 2, 10, and 11) based on the measurement result of the weight (S11). The following description is an example in which the braking pattern in FIG. 2 is selected.

Subsequently, the braking control ECU 4 calculates TTC from the inter-vehicle distance, the own vehicle speed, and the vehicle speed of the preceding vehicle (S12). The calculation method is
Distance between vehicles / (Self-vehicle speed-Vehicle speed of the preceding vehicle)
It is. The braking control ECU 4 has a vehicle speed before starting braking control of 60 km / h or more (S13), a steering angle before starting braking control is +30 degrees or less and -30 degrees or more (S14), and TTC is shown in FIG. If it exists in the area | region of (1) shown to (a) (S15), "alarm" braking control will be performed (S20). That is, the ABS_ECU 10 is instructed by the braking control ECU 4 to generate a braking force of 0.1 G corresponding to the “alarm” shown in FIG. 2B as a stepwise braking control instruction. In response to this instruction, the ABS_ECU 10 controls the duty ratio of the ABS modulator 11 to reduce the air pressure in the cylinder 21 so that the braking force of 0.1 G corresponding to the “alarm” shown in FIG. adjust.

  Here, when the sudden braking operation detection unit 40 detects a sudden braking operation by the driver (S18), the “alarm” braking control is stopped and emergency braking is executed (S19). This is as shown in FIG. That is, the ABS_ECU 10 is instructed by the braking control ECU 4 to generate the maximum braking force at the maximum braking force increase rate as a stepwise braking control instruction. In response to this instruction, the ABS_ECU 10 fully opens the ABS modulator 11 and adjusts the air pressure in the cylinder 21 to the maximum pressure with the maximum rate of increase.

  Further, if the TTC is in the region (2) shown in FIG. 2A (S16), “enlarged region braking” control is executed (S21). That is, the ABS_ECU 10 is instructed by the braking control ECU 4 to generate a braking force of 0.3 G corresponding to “enlarged area braking” shown in FIG. 2B as a stepwise braking control instruction. In response to this instruction, the ABS_ECU 10 controls the duty ratio of the ABS modulator 11 so that a braking force of 0.3 G corresponding to the “enlarged region braking” shown in FIG. Adjust the air pressure.

  Here, when the sudden braking operation detection unit 40 detects a sudden braking operation by the driver (S18), the “enlarged area” braking control is stopped and emergency braking is executed (S19). This is as shown in FIG. That is, the ABS_ECU 10 is instructed by the braking control ECU 4 to generate the maximum braking force at the maximum braking force increase rate as a stepwise braking control instruction. In response to this instruction, the ABS_ECU 10 fully opens the ABS modulator 11 and adjusts the air pressure in the cylinder 21 to the maximum pressure with the maximum rate of increase.

  If the TTC is in the region (3) shown in FIG. 2 (a) (S17), "full-scale braking" control is executed (S22). That is, the ABS_ECU 10 is instructed by the braking control ECU 4 to generate a braking force of 0.5 G corresponding to the “full-scale braking” shown in FIG. In response to this instruction, the ABS_ECU 10 controls the duty ratio of the ABS modulator 11 so that the air pressure in the cylinder 21 is adjusted to a braking force of 0.5 G corresponding to the “full-scale braking” shown in FIG. Adjust.

  Here, when the sudden braking operation detection unit 40 detects a sudden braking operation by the driver (S18), the "full-scale braking" control is stopped and emergency braking is executed (S19). This is as shown in FIG. That is, the ABS_ECU 10 is instructed by the braking control ECU 4 to generate the maximum braking force with the maximum braking force increase rate as a stepwise braking control instruction. In response to this instruction, the ABS_ECU 10 fully opens the ABS modulator 11 and adjusts the air pressure in the cylinder 21 to the maximum pressure with the maximum rate of increase.

  The braking force of “full-scale braking” and the braking force of “emergency braking” are both the maximum braking force, and the magnitude of the braking force is the same. However, in the case of “full-scale braking”, the rate of increase of the braking force is based on the braking pattern shown in FIG. 2B, whereas in the case of “emergency braking”, the braking pattern shown in FIG. Regardless of this, the braking force is increased at a stretch to the maximum braking force by the maximum braking force increase rate. Therefore, as a result, the rate of increase in braking force in “emergency braking” is steeper than that in “full-scale braking”.

  Further, if the host vehicle speed before starting the braking control is less than 60 km / h and 15 km / h or more (S13, S23) and the TTC is in the region (4) shown in FIG. 2C (S24), the braking control ECU 4 Notifies the driver that the relative distance from the preceding vehicle is short (S25). Notification is performed by warning display or buzzer sound. Further, if the TTC is in the region (5) shown in FIG. 2 (c) (S26), "full-scale braking" control is executed (S26). Here, when the sudden braking operation detection unit 40 detects a sudden braking operation by the driver (S18), the "full-scale braking" control is stopped and emergency braking is executed (S19). This situation is as shown in FIG. The operation of the ABS_ECU 10 in this case is as described above.

  Here, FIGS. 2, 10, and 11 will be described. The straight lines c, f, i in FIGS. 2, 10, and 11 are called steering avoidance limit straight lines. Further, curves B, D, and F in FIGS. 2, 10, and 11 are called braking avoidance limit curves.

  That is, the steering avoidance limit straight line is a straight line indicating a limit at which a collision can be avoided by a steering operation within a predetermined TTC in the relationship between one relative distance to the obstacle and one relative speed with the obstacle. The braking avoidance limit curve is a curve indicating a limit at which a collision can be avoided by a braking operation within a predetermined TTC in the relationship between one relative distance to the obstacle and one relative speed with the obstacle.

  2, 10, and 11, a collision can no longer be avoided by a steering operation or a braking operation in a region where both of the lower sides of these straight lines or curves are involved.

  For example, in the case of the empty product in FIG. 2, the straight line c has TTC set to 0.8 seconds. In the present embodiment, a straight line b when the TTC is 1.6 seconds is provided above the steering avoidance limit straight line c, and a straight line a when the TTC is 2.4 seconds is provided. Further, a curve A with TTC set at 1.6 seconds is provided above the braking avoidance limit curve B with TTC set at 0.8 seconds.

  The initial state of the vehicle has a relative distance and a relative speed with respect to the obstacle indicated by the black point G in FIG. When the host vehicle speed before the start of braking control is 60 km / h or more, the relative distance gradually decreases, and when the vehicle reaches the position of the straight line a, the alarm mode is set (area (1)). In the alarm mode, braking of about 0.1 G is applied from TTC 2.4 seconds to 1.6 seconds. During this period, it is meaningful to turn on the stop lamp and inform the subsequent vehicle of braking. When the relative speed further decreases and reaches the position of the straight line b, the expansion area braking mode is set (area (2)). In the enlarged area braking mode, braking of about 0.3 G is applied from TTC 1.6 seconds to 0.8 seconds. When the position of the straight line c is reached, the full braking mode is set (area (3)). In the full-scale braking mode, the maximum braking force (about 0.5G) is applied from TTC 0.8 seconds to 0 seconds. According to the calculation in step S12 in FIG. 13, a collision occurs at this time. However, the actual TTC is longer than the calculation result of step S12.

  In other words, in the calculation of TTC in the automatic braking control device targeted by the present invention, precise distance measurement and complicated calculation processing are omitted as much as possible, and a general-purpose simple distance measurement device (for example, millimeter wave radar) or a calculation device is used. It is assumed that. Such considerations are useful for keeping vehicle manufacturing costs or maintenance costs low.

  Therefore, strictly speaking, the preceding vehicle and the subject vehicle, which are the objects, are performing a uniform acceleration motion by braking (deceleration), and therefore the TTC calculation must also be calculated based on the uniform acceleration motion. By calculating the TTC as simply performing constant velocity motion, precise distance measurement and complicated arithmetic processing are omitted.

  In addition, by performing a calculation that is regarded as such a constant velocity motion, the calculated TTC value becomes smaller than the actual TTC value. There is no hindrance.

  Further, when the host vehicle speed before starting the braking control is 15 km / h or more and less than 60 km / h, the relative distance is gradually shortened, and when the vehicle reaches the position of the straight line b, the notification mode is set (region (4)). . In the notification mode, the driver is notified that the relative distance to the obstacle is shortened by an alarm display or a buzzer sound. In the notification mode, TTC starts from 1.6 seconds. Note that the notification mode can be maintained even in the next full-scale braking mode. When the position of the straight line c is reached, the full braking mode is set (area (5)). In the full-scale braking mode, the maximum braking force (about 0.5G) is applied from TTC 0.8 seconds to 0 seconds.

  FIG. 10 shows an example at half load, and FIG. 11 shows an example at fixed load. However, if equal braking forces are compared, the braking distance increases as the weight of loaded cargo and passengers increases. The avoidance limit straight line and the braking avoidance limit curve also move upward in the figure. Thereby, the area of area | region (1), (2), (3), (4), (5) becomes large according to the weight of a loaded cargo or a passenger.

  2 correspond to the straight lines d to f in FIG. 10 and the straight lines g to i in FIG. 11, and the curves A and B in FIG. 2 are the curves C and D in FIG. 10 and the curve E in FIG. , F, and the black point G in FIG. 2 corresponds to the black point H in FIG. 10 and the black point I in FIG.

  In this embodiment, as shown in FIGS. 6 to 8, the driver suddenly stops during the stepwise braking control at the time of empty product, half product, and constant product shown in FIGS. When the braking operation is detected, the stepwise braking control being executed is stopped and emergency braking is executed. Further, when the host vehicle speed before starting the braking control is 15 km / h or more and less than 60 km / h, as shown in FIG. 9, when a sudden braking operation by the driver is detected during the “full-scale braking” control. The “full-scale braking” control being executed is stopped and emergency braking is executed.

(Second embodiment)
A second embodiment will be described with reference to FIG. FIG. 14 is a flowchart showing a control procedure of the braking control ECU in the braking pattern at the time of idle product according to the second embodiment. Here, the difference between the first embodiment and the second embodiment will be described.

  In the first embodiment, when a sudden braking operation by the driver is detected, the “emergency braking” that immediately stops the stepwise braking control and generates the maximum braking force is executed. On the other hand, in the second embodiment, as shown in FIG. 14, when a sudden braking operation by the driver is detected by the brake operation sensor 14 (S38), the sudden braking operation detection unit 40 includes the brake operation information. The strength of the braking force expected to be generated by the driver's sudden braking operation is estimated from the air pressure information of the included brake valve 16.

  The braking control ECU 4 detects the driver's sudden braking operation, which is estimated to cause the sudden braking operation detection unit 40 to generate a braking force stronger than the braking force in the current stage braking control during the stepwise braking control. When it is done (S39), stepwise braking control is stopped (S40). As a result, the brake control valve 19 is closed.

  When the brake control valve 19 is closed, the selection valve 17 that has previously selected the air pressure of the brake control valve 19 selects the air pressure of the brake valve 16. Then, the air pressure from the brake valve 16 reaches the relay valve 18, and the relay valve 18 causes the air in the air tank 20 to flow into the ABS modulator 11 according to the air pressure of the brake valve 16. The ABS modulator 11 is controlled from the ABS_ECU 10 according to the ABS original control procedure.

  Thus, in the second embodiment, the driver performs a sudden braking operation while the stepwise braking control is being executed, and the braking force generated by the driver's sudden braking operation is being executed stepwise. If it is greater than the braking force generated by the braking control, this can be prioritized. Compared with the first embodiment, it is possible to more reflect the personality (technique based on personal experience) in the driver's sudden braking operation.

(Other examples)
In the first and second embodiments, the brake operation sensor 14 is described as an air pressure sensor that detects the air pressure in the brake valve 16, and as shown in FIG. Although the sudden braking operation is detected, the brake operation sensor 14 may be a stroke sensor that detects the stroke of the brake pedal 15, and the sudden braking operation may be detected based on the rate of change of the brake pedal stroke per unit time.

  ADVANTAGE OF THE INVENTION According to this invention, the automatic braking control in a truck or a bus | bath can be implement | achieved, and it can contribute to traffic safety. In addition, in recent years, the automatic braking control device of the present invention can be realized by diverting the ABS provided in most vehicles, so that the number of modifications of the vehicle for realizing the present invention can be reduced. It is also possible to contribute to traffic safety by accelerating the popularization of the automatic braking control device of the present invention. In addition, the braking pattern can be changed depending on whether or not there is a sudden braking operation by the driver after the start of automatic braking control, and automatic braking control suitable for the situation at that time can be performed.

The control system block diagram of a present Example. The figure which shows the braking pattern at the time of the idle product which braking control ECU has. The figure which shows the brake pedal stroke at the time of normal braking operation and sudden braking operation. The flowchart which shows the sudden braking operation detection procedure in the sudden braking operation detection part. The figure which shows the brake pressure increase rate at the time of normal sudden braking and emergency braking. The figure which shows the braking pattern when emergency braking interrupts in an alarm braking step. The figure which shows the braking pattern when emergency braking interrupts in an expansion area | region braking step. The figure which shows the braking pattern when emergency braking interrupts in the full-scale braking stage. The figure which shows the braking pattern when emergency braking interrupts in full-scale braking. The figure which shows the braking pattern at the time of the half product which braking control ECU has. The figure which shows the braking pattern at the time of the fixed volume which braking control ECU has. The figure which shows the full-scale braking pattern which braking control ECU has. The flowchart which shows the control procedure of braking control ECU in the braking pattern at the time of the idle product of 1st Example. The flowchart which shows the control procedure of braking control ECU in the braking pattern at the time of the idle product of 2nd Example.

Explanation of symbols

1 Millimeter wave radar 2 Steering sensor 3 Yaw rate sensor 4 Braking control ECU
5 Gateway ECU
6 Meter ECU
7 VehicleCAN (J1939)
8 Engine ECU
9 Axle weight scale 10 ABS_ECU
11 ABS modulator 12 Engine 13 Vehicle speed sensor 14 Brake operation sensor 15 Brake pedal 16 Brake valve 17 Selection valve 18 Relay valve 19 Brake control valve 20 Air tank 21 Cylinder 22 Brake pad 23 Wheel 24 Wheel speed sensor 40 Sudden braking operation detection unit 41 Braking Pattern selection unit 42 Braking pattern storage unit

Claims (5)

Control means for automatically performing braking control without a driving operation based on a sensor output including a distance from an object in the traveling direction of the host vehicle, wherein the control means is the object obtained by the sensor output. Automatically and in time series when the estimated time required for the object and the vehicle, which are derived based on the relative distance and relative speed between the vehicle and the vehicle, to fall below a predetermined distance falls below a set value. In an automatic braking control device provided with stepwise braking control means for performing stepwise braking control for gradually increasing braking force or braking deceleration over a plurality of steps,
The car is equipped with ABS (Anti Lock Breaking System)
The stepwise braking control means includes means for diverting the braking force adjustment function in the ABS to perform the stepwise braking control,
A sudden braking operation detecting means for detecting a sudden braking operation by the driver is provided,
The stepwise braking control means stops the stepwise braking control when the sudden braking operation detecting means detects a sudden braking operation by the driver during the execution of the stepwise braking control, and a predetermined braking force or An automatic braking control device comprising braking interruption means for executing braking by braking deceleration.   2. The automatic braking control device according to claim 1, wherein the predetermined braking force or braking deceleration is a maximum braking force or braking deceleration that the host vehicle has.   The braking interrupting means, when stopping the stepwise braking control and executing braking with a predetermined braking force or braking deceleration, applies a braking force based on the maximum braking force or braking deceleration increasing rate of the own vehicle. 3. The automatic braking control device according to claim 1, further comprising means for increasing the braking deceleration. Control means for automatically performing braking control without a driving operation based on a sensor output including a distance from an object in the traveling direction of the host vehicle, wherein the control means is the object obtained by the sensor output. Automatically and in time series when the estimated time required for the object and the vehicle, which are derived based on the relative distance and relative speed between the vehicle and the vehicle, to fall below a predetermined distance falls below a set value. In an automatic braking control device provided with stepwise braking control means for performing stepwise braking control for gradually increasing braking force or braking deceleration over a plurality of steps,
The car is equipped with ABS,
The stepwise braking control means includes means for diverting the braking force adjustment function in the ABS to perform the stepwise braking control,
Braking operation level detection means for estimating the strength of braking force or braking deceleration that is expected to be generated by a driver's sudden braking operation is provided,
The stepwise braking control means causes the braking operation level detecting means to generate a braking force or braking deceleration stronger than the braking force or braking deceleration in the current stage braking control during execution of the stepwise braking control. An automatic braking control device, comprising: braking control stopping means for stopping the stepwise braking control when a sudden braking operation by a driver estimated to be detected is detected.   5. The vehicle according to claim 1, further comprising means for prohibiting start of the stepwise braking control means when the host vehicle speed is less than a predetermined value and the value of the steering angle or yaw rate is outside the predetermined range. Automatic braking control device.

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