JP3700334B2 - Vehicle travel control device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a vehicular travel control device having a constant speed travel control function.
[0002]
[Prior art]
Conventionally, as a control means of a throttle valve disposed in an intake pipe of an internal combustion engine, the throttle valve is opened and closed by driving a throttle lever via a throttle cable and a link mechanism connected to an accelerator pedal. There are a mechanical method and an electronic control method in which an accelerator pedal operation is converted into an electric signal, and an actuator for driving a throttle valve is operated in accordance with the movement. This electronic control method is called drive-by-wire (hereinafter referred to as DBW).
In this electronic control method, the output adjustment of the internal combustion engine can be suitably controlled independently of the driver's arbitrary accelerator operation. For example, the amount of intake air supplied to the engine by the control device or the fuel injection timing is set. A method of controlling has been proposed.
[0003]
In addition, there is constant speed running control as a device for controlling the throttle valve, and this function automatically runs the vehicle at a speed desired by the driver. An example of a conventional constant speed traveling control device will be described with reference to FIG.
The throttle valve 22 disposed in the intake pipe 33 of the engine is driven to open and close via the link mechanism 32. The link mechanism 32 is connected to the accelerator pedal 1 operated by the driver by a cable 34 and is also connected to the actuator 31 of the constant speed traveling device 30 so that it can be driven from either side.
Reference numerals 11a, b, and c are command switches for inputting a speed instruction of the driver, and in particular, 11c is a stop lamp brake switch for prohibiting or stopping the constant speed traveling control. The vehicle speed sensor 13 for detecting the vehicle speed and the constant speed traveling control device 30 to which the command switches 11 are input outputs a signal for driving the throttle actuator 31 so that the vehicle speed and the traveling speed desired by the driver are matched.
[0004]
Next, the operation of the constant speed traveling control device 30 will be described with reference to the block diagram of FIG.
Reference numeral 14 denotes a traveling speed detecting means for detecting the current traveling speed from the vehicle speed sensor 13. For example, when the set switch 11a in FIG. 12 is pressed and the command input 11a is input, the target speed setting means 12 sets the target speed that is the driver's desired speed from the current travel speed. The constant speed travel control amount calculation means 15a calculates a constant speed travel control amount for controlling the throttle valve 22 so that the target speed matches the current travel speed. The actuator driving means 35 controls a throttle actuator, for example, a vacuum pump or a motor, which opens and closes the throttle valve 22 and adjusts the intake air amount in accordance with the control amount.
Currently, the constant speed traveling control device is often installed separately from the fuel control device.
[0005]
Further, there are devices described in Japanese Patent Application Laid-Open Nos. 5-288092 and 8-156641, and it has been proposed that the engine, fuel, and constant speed running control be integratedly controlled. These proposals have two throttle valves in the intake pipe, one is a main throttle and mainly corresponds to the accelerator, and the other is a sub-throttle and is mainly used for constant speed running control. In a particularly transitional phase of vehicle speed control during constant speed traveling, the control performance is to be improved by driving not only the sub-throttle but also both throttles.
[0006]
[Problems to be solved by the invention]
The conventional constant speed traveling control device has a structure having a dedicated throttle actuator for controlling the throttle valve. In addition, it must operate in conjunction with the accelerator pedal, and a cable and a link mechanism are also required. In this configuration, there is a problem that control performance, particularly responsiveness, is poor due to cable play and mechanical play, and it is difficult to improve control accuracy.
[0007]
Further, the above publication has a problem that not only the throttle actuator but also a throttle valve must be added.
Furthermore, there is a problem that the degree of freedom is low from the viewpoint of mounting space in the engine room, such as cable routing, a link mechanism, and a second throttle valve.
[0008]
The present invention has been made to solve the above-described problems, and a first object is to include a constant speed traveling control function in the fuel control device, and a throttle that is conventionally mounted redundantly, The actuator and the link mechanism are deleted.
The second object is to determine which of the fuel control and the throttle control of the constant speed traveling control is selected when the fuel control device includes the constant speed traveling control function.
The third object is to ensure prohibition of the constant speed traveling control function when the fuel control device includes the constant speed traveling control function.
[0009]
The fourth object is to assist the constant speed traveling control function by the fuel control function when the fuel control device includes the constant speed traveling control function.
The fifth object is to detect when the fuel control device includes a constant speed traveling control function and when it does not include it, and to avoid unnecessary processing when it does not include it.
[0010]
[Means for Solving the Problems]
  In the vehicle travel device according to the present invention,An accelerator operated by the driver, an accelerator opening detecting means for detecting the actual accelerator opening of the operated accelerator, and a fuel control amount for inputting the accelerator opening and calculating a fuel injection control amount in accordance with the accelerator opening Calculation means, a throttle valve disposed in an intake pipe of the internal combustion engine, first target opening degree conversion means for converting to a target throttle opening degree corresponding to the calculated fuel control amount, and opening of the throttle valve Provided with a fuel control system having a throttle opening sensor for detecting the degree and a throttle valve driving means for driving the throttle valve so that the detected throttle opening and the target throttle opening coincide with each other. Command input means for inputting a speed instruction, vehicle speed sensor, travel speed detecting means for detecting a travel speed by the vehicle speed sensor, and the travel speed and the speed instruction input Target speed setting means for setting a target travel speed, constant speed travel control amount calculation means for calculating a control amount for performing constant speed travel control based on the target speed and the travel speed, and the throttle valve during constant speed travel control. And a second target opening degree converting means for converting the target throttle opening degree corresponding to the constant speed travel control amount to operate the driving means, and one of the first and second target opening degree converting means. And selecting means for transmitting the selected target throttle opening to the throttle valve driving means, determining whether or not constant speed running control is prohibited from the speed instruction input, and if constant speed running is prohibited, A constant speed travel prohibiting means for outputting a signal for prohibiting selection of a signal based on the constant speed travel control amount to the selection means, and the constant speed travel control amount calculating means is configured to output a constant speed based on information from the speed instruction input; Judgment whether or not driving is prohibited Together, if there is a difference in the constant-speed running prohibition information input from the determination and constant speed running prohibiting means is obtained so as to determine a constant speed running inhibition state.
[0011]
  In the vehicle travel device according to the present invention,The accelerator operated by the driver, the first accelerator opening detecting means for detecting the first actual accelerator opening of the operated accelerator, and the control amount of fuel injection corresponding to the input of the accelerator opening Fuel control amount calculation means for calculating, throttle valve disposed in an intake pipe of the internal combustion engine, target opening degree conversion means for converting to a target throttle opening degree corresponding to the calculated fuel control amount, and the throttle valve A fuel control system having a throttle opening sensor for detecting the opening of the throttle valve, and a throttle valve driving means for driving the throttle valve so that the detected throttle opening and the target throttle opening coincide with each other,
Command input means for inputting the speed instruction of the driver, vehicle speed sensor, travel speed detecting means for detecting the travel speed by the vehicle speed sensor, and target speed for setting the target travel speed from the travel speed and the speed instruction input Setting means, constant speed traveling control amount calculating means for calculating a control amount for performing constant speed traveling control based on the target speed and the traveling speed, and conversion to a second accelerator opening corresponding to the constant speed traveling control amount A second accelerator opening conversion means; and a selection means for selecting one of the first actual accelerator opening and the second accelerator opening and transmitting the selected one to the fuel control amount calculation means, Determine whether or not constant speed travel control is prohibited from the speed instruction input. If constant speed travel is prohibited, output a signal prohibiting selection of signals based on the constant speed travel control amount to the selection means. Means. The travel control amount calculation means determines whether or not the constant speed travel prohibition state is based on the information from the speed instruction input, and there is a difference between this determination and the constant speed travel prohibition information input from the constant speed travel prohibition means. Thus, it is determined that the vehicle is in a constant speed travel prohibition state.
[0013]
  In the vehicle travel device according to the present invention,The accelerator operated by the driver, the first accelerator opening detecting means for detecting the first actual accelerator opening of the operated accelerator, and the control amount of fuel injection corresponding to the input of the accelerator opening Fuel control amount calculation means for calculating, throttle valve disposed in an intake pipe of the internal combustion engine, target opening degree conversion means for converting to a target throttle opening degree corresponding to the calculated fuel control amount, and the throttle valve A fuel control system having a throttle opening sensor for detecting the opening of the throttle valve, and a throttle valve driving means for driving the throttle valve so that the detected throttle opening and the target throttle opening coincide with each other,
Command input means for inputting the speed instruction of the driver, vehicle speed sensor, travel speed detecting means for detecting the travel speed by the vehicle speed sensor, and target speed for setting the target travel speed from the travel speed and the speed instruction input Setting means, constant speed traveling control amount calculating means for calculating a control amount for performing constant speed traveling control based on the target speed and the traveling speed, and conversion to a second accelerator opening corresponding to the constant speed traveling control amount A second accelerator opening conversion means; and a selection means for selecting one of the first actual accelerator opening and the second accelerator opening and transmitting the selected one to the fuel control amount calculation means, Receiving a control amount calculated by the fuel control amount calculating means and a signal indicating that constant speed running control is being performed, and having target opening degree correcting means for transmitting to the throttle valve driving means so as to correct the throttle opening degree. One in which the.
[0014]
  In the vehicle travel device according to the present invention,It has a target opening correction means that receives the control amount calculated by the fuel control amount calculation means and a signal indicating that the constant speed traveling control is being performed and transmits the signal to the throttle valve driving means so as to correct the throttle opening. Is.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
Embodiment 1 FIG.
Embodiment 1 of the present invention will be described below with reference to the drawings.
FIG. 1 is a block diagram showing a vehicular travel control apparatus according to Embodiment 1 of the present invention, in which 1 is an accelerator operated by a driver and 2 is an accelerator opening detection for detecting the actual accelerator opening operated. Means. Reference numeral 5 denotes a fuel control amount calculation means for inputting the accelerator opening and calculating a fuel injection control amount in accordance with the accelerator opening. Reference numeral 22 denotes a throttle valve disposed in the intake pipe of the internal combustion engine, and reference numeral 23 denotes a throttle opening sensor that detects the opening of the throttle valve. Reference numeral 6 denotes first target opening degree conversion means for converting the target throttle opening degree corresponding to the fuel control amount. Reference numeral 21 denotes a throttle valve driving means for driving the throttle valve 22 so that the target opening and the throttle opening by the throttle opening sensor 23 coincide with each other.
The driver's accelerator operation is input, and the throttle valve is driven based on the operated accelerator by the fuel control amount calculation means 5, that is, computer control. This is called the DBW system, which is different from the conventional system in which the accelerator operation directly drives the throttle valve. It performs precise fuel control by electronic control and improves controllability such as exhaust gas adjustment, fuel consumption, and acceleration / deceleration. It can be done.
[0019]
In FIG. 1, the fuel control device further includes a constant speed traveling control function. Reference numeral 11 denotes a command input for inputting a driver's speed instruction. Similarly to the conventional example in FIG. 12, a set switch 11a for setting the target speed of the driver, a resume switch 11b for returning to the set target speed, and constant speed driving are set. It consists of a brake switch 11c to be stopped. Reference numeral 14 denotes a travel speed detecting means for detecting the current travel speed from the vehicle speed sensor 13, and reference numeral 12 denotes a target speed setting means for setting a target speed desired by the driver from the current travel speed in response to the command input 11a. Reference numeral 15 denotes a constant speed travel control amount calculation means for calculating and outputting a constant speed travel control amount based on a deviation between the target speed and the travel speed. 11 to 15 constitutes the constant speed traveling control function. However, there is no throttle valve and throttle valve driving means dedicated to constant speed running as in the conventional apparatus.
[0020]
Therefore, the constant speed travel control amount for controlling the throttle valve 22 has the second target opening degree conversion means 16 for converting into the target throttle opening degree, and the first target opening degree conversion means 6 for the fuel control amount. And a selection means 20 for selecting one of the second and the second. One control amount selected by the selection means 20 is transmitted to the throttle valve drive means 21. For example, during the constant speed traveling control, the selecting means 20 selects a signal based on the constant speed traveling control amount, that is, the second target throttle opening. By having the second target opening degree conversion means 16 and the selection means 20, it becomes easy to include the constant speed traveling function in the fuel control device.
In the fuel control device, the target throttle opening corresponding to the accelerator opening is set and the throttle valve is driven. Therefore, if the constant speed travel control amount is converted to this target throttle opening, the fuel control side is almost This is because the constant speed running function can be inserted without change.
[0021]
Details of the operation of a microcomputer (hereinafter referred to as a CPU) responsible for processing of the fuel control amount calculation means 5, the constant speed travel control amount calculation means 15, the selection means 20, the target opening degree conversion means 6, 16 and the like will be described.
An interrupt routine as shown in FIG. 9 is used for input relating to time such as travel speed or engine speed. A pulse train signal having a frequency proportional to the speed / revolution is input to the CPU, and the speed / revolution is obtained by measuring the time of the pulse train interval (FIG. 9B). When the rising edge of the pulse train is input, the interrupt routine shown in FIG. In step S10, a time tn is input, and in step S11, a time difference Δt from the previous interrupt time tn-1 is calculated. When this time difference Δt is obtained, the interrupt routine ends. In the main routine described later, the speed and the number of rotations are obtained by the following equation (1).
Vn = K / Δt (1)
Here, for example, V is a vehicle speed, K is a constant, and n is a suffix indicating the current time.
[0022]
Next, a main routine processed by the CPU will be described with reference to FIG.
First, when the power is turned on by starting the engine key, the RAM and the like in step S20 are initialized. Next, in step S21, the opening degree of the accelerator operated by the driver is input. In step S22, information is input from various sensors that detect information around the engine (not shown in FIG. 1). The engine speed, the cooling water temperature, etc. are input as the various sensor information, or the engine speed and the cooling water temperature are calculated from the various sensor information. In the fuel control, there is not only the operation of the throttle valve linked to the accelerator operation, but also a control that operates differently from the accelerator operation so as to open the throttle valve even when there is no accelerator operation at a low temperature, for example. Therefore, information is obtained by various sensors. In addition, throttle opening sensor information to be described later can be input in advance. A comprehensive determination is made from the information obtained in the input steps S21 and S22, and the control amount F of fuel injection is calculated in step S23. In the fuel control, not only the throttle valve control of the intake air amount but also the control of the fuel injection amount, the fuel injection timing, etc. are well known, but here the throttle control is considered. In step S24, the control amount F is converted into a target throttle opening (target TPS1). Steps S21 to S24 are related to fuel control.
[0023]
Subsequently, in step S25, the vehicle speed, that is, the traveling speed Vn is calculated from the information of the vehicle speed sensor 13 using the information of the interrupt routine. In step S26, command switch information operated by the driver is input. Next, it is checked in step S27 whether or not the set command switch is operated. For example, when the set switch 11a in FIG. 12 of the conventional example is operated, the target travel speed Vm is set from the current travel speed Vn in step S28. In step S29, a flag indicating that constant speed running control is being performed is set ("H"). On the other hand, if the command switch is not set in step S27, it is checked in step S30 whether constant speed traveling control is prohibited. The brake switch 11c shown in FIG. 12 is input, or the determination is made by checking whether the deviation between the target speed Vm and the actual vehicle speed Vn exceeds a predetermined range. Here, prohibition of constant speed traveling includes stopping or interrupting constant speed traveling control. If it is not in the prohibited state, it is checked in step S31 whether the vehicle is traveling at a constant speed. If the vehicle is traveling at a constant speed or after the processing of step S29, the constant speed traveling control amount An is calculated by, for example, the following equation (2) in step S32.
An = Lαn + Mβn (2)
βn = Vm−Vn (3)
Here, L and M are constants, α is the vehicle acceleration, and β is the deviation between the target speed Vm and the vehicle speed Vn. n is a suffix indicating the current time.
[0024]
Subsequently, in step S33, a process for converting the control amount An into a target throttle opening is performed. For example, the following equation (4) can be used.
Target TPS2 = f1 (An) (4)
Here, TPS means the throttle opening, and f1 is a function of the control amount An.
On the other hand, if NO is determined in step S30 or S31, the constant speed travel control is prohibited, so the constant speed travel flag is reset ("L") in step S34, and the constant speed travel control amount An is set to zero in step S35. In step S36, the target TPS2 is set to zero.
Steps S25 to S36 are the constant speed travel control unit.
[0025]
Next, in step S37, it is checked whether constant speed traveling control is being performed. If the flag is set ("H"), that is, if the vehicle is traveling at a constant speed, the value of the target TPS2 is substituted for the target throttle opening (hereinafter referred to as the target TPS) in step S38. On the other hand, if the vehicle is not traveling at a constant speed, the value of the target TPS1 is substituted for the target TPS in step S39. Steps S37 to S39 are selection means 20 for transmitting the obtained fuel or the target TPS1 and 2 converted to the constant speed travel control amount to the throttle valve driving means.
[0026]
In step S40, the actual throttle opening (hereinafter referred to as actual TPS) is compared with the target TPS and information from the throttle opening sensor. If the target TPS and the actual TPS are substantially equal, a signal for holding the throttle valve is output in step S41. If the target TPS is greater than the actual TPS, a signal is output in a direction to open the throttle valve in step S42. Conversely, if the target TPS is smaller than the actual TPS, a signal is output in a direction to close the throttle valve in step S43. Steps S40 to S43 show the control part of the throttle valve drive means 21. In step 44, since this main routine is executed every predetermined time, it is checked whether or not the predetermined time has elapsed. When the predetermined time has elapsed, the process returns to step S21 to execute each process again.
As described above, when a constant speed travel control unit is added to the fuel control unit, the fuel control unit can be simplified with little change by converting the constant speed travel control amount into the target throttle opening.
[0027]
Embodiment 2. FIG.
FIG. 2 shows Embodiment 2 of the present invention. The same reference numerals as those in FIG. 1 denote the same or corresponding parts. The difference from FIG. 1 is that the selection means 20 a is arranged between the first accelerator opening degree detection means 2 and the fuel control amount calculation means 5. Therefore, the second accelerator opening conversion means 17 for converting the constant speed travel control amount is added so as to have the same dimension as the detected first accelerator opening. Therefore, the control amount obtained by the constant speed travel control amount calculation means 15 is converted into the same format as the accelerator opening and output. The previous equation (4) can also be used here, and the function is changed to a function representing the accelerator opening instead of the throttle opening. In the second embodiment as well, the fuel control unit can easily include the constant speed traveling function in the fuel control device by converting the control amount on the constant speed traveling side into the accelerator opening degree with almost no change. .
[0028]
Based on the flowchart of FIG. 11, CPU processing will be described in the same manner as in FIG. Since the same reference numerals as those in FIG. 10 indicate the same or corresponding parts, only the steps different from those in FIG. 10 will be described. In step S37a, it is determined whether or not the vehicle is traveling at a constant speed, and the accelerator opening (referred to as APS2) converted to be traveling at a constant speed is selected to proceed to the next fuel control amount calculation. On the other hand, when the vehicle is not traveling at a constant speed, the accelerator opening (referred to as APS1) operated by the driver is selected and the process proceeds to step S23a. This step S37a shows the selection means 20a. Immediately after the power is turned on, the accelerator opening APS1 is selected because the constant speed running flag is reset ("L") in step S20.
Further, when the constant speed travel control amount is obtained in step S32, step S33a is processed in order to convert it to the target accelerator opening APS2. This conversion can also use the following equation (5) in the same manner as described above.
Target APS2 = f2 (An) (5)
Here, APS means the accelerator opening, and f2 is a function of the control amount An. This APS2 has the same dimension as the accelerator opening APS1 operated by the driver.
If the vehicle is not traveling at a constant speed, APS2 is set to zero in step S36a.
As can be seen from the flowchart of FIG. 11, there is almost no program change with respect to the fuel control amount, and it is possible to insert a constant speed traveling function. On the other hand, the constant speed traveling side only needs to convert the final control amount to that corresponding to the accelerator opening. This method has the feature that both functions can be combined very easily.
[0029]
In FIG. 1, the selection means 20 is inserted between the throttle valve driving means 21 and the first and second target opening degree conversion means 6 and 16. On the other hand, in FIG. 2, it is inserted between the fuel control amount calculation means 5 and the first accelerator opening degree detecting means 2 or the second accelerator opening degree converting means 17. Furthermore, the selection means can be inserted after the fuel control amount calculation means 5 or the constant speed travel control amount calculation means 15. In this case, the control amount selected by the selection means is transmitted to the throttle valve drive means 21 via the target opening degree conversion means for converting the target throttle opening degree into the target throttle opening degree. In this case as well, when calculating the constant speed travel control amount, it is possible to convert it to the target throttle opening and to have the same format and dimensions as the fuel control amount. This makes it easy to insert the constant speed running function into the fuel control device.
[0030]
Embodiment 3 FIG.
Next, Embodiment 3 will be described with reference to FIG. The same reference numerals as those in FIG. 1 denote the same or corresponding parts. The difference from FIG. 1 is the selection means 24. This selection means is to select the larger one of the first target throttle opening and the second target throttle opening, that is, the throttle valve opening direction. As a result, when the driver operates the accelerator during constant speed traveling control, the throttle valve is controlled to open based on this operation, and control can be performed faithfully to the driver's will. 3 applies to FIG. 1, the same selection means 24 can be applied to FIG. In the case of FIG. 2, the one having the larger accelerator opening is selected.
[0031]
Embodiment 4 FIG.
FIG. 4 shows a fourth embodiment of the present invention. The same reference numerals as those in FIG. 1 or 2 denote the same or corresponding parts. The difference from FIG. 1 is that a constant speed travel prohibiting means 18 for monitoring the command input of the command input means 11 by another means is provided.
When the constant speed running function is included in the fuel control device, command input is monitored by a separate means, and when the constant speed running is prohibited, the selection means 20 selects a signal based on the fuel control amount. For this reason, there are two systems in which constant speed travel is prohibited, and there is an effect that the prohibition of constant speed travel is ensured. Here, prohibition of constant speed travel includes cancellation and interruption.
[0032]
Further, as indicated by a broken line in FIG. 4, the output of the constant speed travel prohibition means 18 is transmitted to the constant speed travel control amount calculation means 15, and the prohibition information and the constant speed travel control amount calculation means 15 are transmitted from the command input 11. It has a function of comparing with a uniquely determined whether or not it is in a constant speed travel prohibition state, and determining that it is in a constant speed travel prohibition state if there is a difference. Compared to the case where the fuel, constant speed travel control amount calculation means 5, 15 and the throttle valve drive means 21 are processed by one CPU, for example, when each control amount calculation means and the throttle drive means are separated and independent, This configuration is particularly useful.
[0033]
This configuration will be described with reference to FIG. 1 to 4 indicate the same or corresponding parts. The constant speed travel prohibiting means 18, the selecting means 20, and the throttle valve driving means 21 constitute a throttle driving device 25. The command input 11 may be transmitted to both the throttle driving device 25 and the target speed setting means 12 on the constant speed traveling control side as shown in FIG. 8, or may be transmitted only through the throttle driving device 25. The throttle driving device 25 has a built-in CPU for controlling the target throttle opening and the actual throttle opening to coincide. When this CPU is used to detect a constant speed travel prohibition signal from the command input 11, for example, the brake switch input 11 c in FIG. 12, it is determined that the constant speed travel is prohibited and the selection means 20 is informed of this. From this information, the selection means 20 switches from the second target throttle opening to the first target throttle opening for fuel control. On the other hand, the constant speed travel prohibition means 18 transmits constant speed travel prohibition information to the constant speed travel control amount calculation means 15. Further, the constant speed travel control amount calculation means 15 independently determines from the command input 11 whether or not it is in a constant speed travel prohibition state. If this determination and the information transmitted from the constant speed travel prohibiting means 18 do not match, it is determined that the constant speed travel is prohibited and the processing is performed.
As described above, there are two systems for prohibiting constant speed travel, and the prohibition of constant speed travel can be made more reliable.
[0034]
Embodiment 5. FIG.
Next, a fifth embodiment will be described with reference to FIGS. 1 to 4 indicate the same or corresponding parts. There is a target opening correction means 7 for determining the target throttle opening so as to further correct the control amount F obtained by the fuel control amount calculation means 5 by, for example, a rapid change in accelerator opening or a constant speed running control signal. .
The target throttle opening correction signal and the target throttle opening signal are added and input to the throttle valve driving means 21. This not only improves the running speed convergence performance in a transient state, such as when starting at a constant speed or when the target speed and the running speed are separated for some reason, for example, acceleration by the driver, or the vehicle in lean combustion A difference in characteristics can be compensated for, and a travel control device with high controllability can be obtained.
Specifically, it is conceivable to calculate the correction amount using the following equation (6).
Correction TPS = f3 (Fn) (6)
Here, f3 is a function of the fuel control amount F, and the gain is changed from that of the target opening conversion means 6.
[0035]
Further, in either case of FIG. 5 or FIG. 6, it can be determined that the fuel control amount calculation means 5 is performing the constant speed traveling control, and it is easy to correct the fuel control amount using this. For example, when traveling downhill at a constant speed, the traveling speed may be faster than the target speed. At this time, the constant speed travel control amount has the target throttle opening or accelerator opening substantially zero. On the other hand, the fuel control amount also becomes the target throttle opening degree corresponding to the low torque, and there is a case where the fuel cut or the ultra lean combustion mode is set. Since the fuel control amount calculation means 5 recognizes that the vehicle is traveling at a constant speed, for example, a fuel cut or an ultra lean combustion mode can be limited to suppress a surging phenomenon that is a vehicle shake in the front-rear direction. Further, the convergence of the running speed when the hill is finished can be improved by using this correction means and increasing the gain of the throttle opening control.
[0036]
Embodiment 6 FIG.
Next, Embodiment 6 will be described with reference to FIG. The same reference numerals as those in FIG. 1 denote the same or corresponding parts. Here, a main switch 26 for operating the constant speed running function is added. Many conventional constant speed traveling devices are equipped with a power main switch, and the constant speed traveling device does not operate unless the main switch 26 is operated. Therefore, the presence / absence of the constant speed traveling function can be determined by detecting the opening / closing of the main switch 26. Since some models do not have a constant-speed traveling device, it detects whether the constant-speed traveling device is not installed, or even if this device is installed, the current constant-speed traveling function is not activated. Constant speed running function setting means 19 is provided. This constant speed traveling function setting means 19 determines whether or not the constant speed traveling function is not activated, and outputs a signal to the constant speed traveling control amount calculating means 15 and the selecting means 20 when not activated.
[0037]
When receiving this signal, the constant speed traveling control amount calculation means 15 does not perform a series of processing of the control amount calculation. In the flowchart of FIG. 10, steps S25 to S33 are jumped, and step S34 and subsequent steps are processed. Further, the selection unit performs step S39 of selecting the target throttle opening TPS1 on the fuel control side.
By having the constant speed traveling function setting means 19, it is possible to automatically determine whether or not the constant speed traveling function is in operation, and to avoid unnecessary processing.
Although FIG. 7 is applied with respect to FIG. 1, it is possible to apply the same constant speed traveling function setting means in FIG. In this case, not only the processing of the constant speed traveling control amount calculation means 15 is omitted, but the processing of the second accelerator opening conversion means 17 can be omitted.
[0038]
The processing of the sixth embodiment will be described with reference to FIG. The determination during the constant speed running in step S37a jumps, and the accelerator opening APS1 is input to the fuel control amount calculating step S23a as usual. Further, steps S25 to S33a of the constant speed running function are jumped, and step S34 and subsequent steps are executed.
[0039]
【The invention's effect】
Since the present invention is configured as described above, the following effects can be obtained.
[0045]
  ThisAccording to the vehicle travel control apparatus of the present invention, the constant speed travel control amount calculation means determines whether or not the constant speed travel prohibition state is based on information from the speed instruction input, and this determination and the constant speed travel prohibition means. If there is a difference between the constant speed travel prohibition information input from the above, the constant speed travel prohibition state is determined, so that the constant speed travel can be reliably prohibited.
[0046]
According to the vehicle travel control apparatus of the present invention, the throttle valve is configured to receive the control amount calculated by the fuel control amount calculation means and the signal indicating that constant speed travel control is being performed, and correct the throttle opening. Since the target opening correction means for transmitting to the drive means is provided, there is an effect that the convergence property to the target speed and the control performance of the constant speed traveling control can be improved.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a vehicle travel control apparatus according to Embodiment 1 of the present invention.
FIG. 2 is a block diagram showing a vehicle travel control apparatus according to Embodiment 2 of the present invention.
FIG. 3 is a block diagram showing a vehicle travel control apparatus according to Embodiment 3 of the present invention.
FIG. 4 is a block diagram showing a vehicle travel control apparatus according to Embodiment 4 of the present invention.
FIG. 5 is a block diagram showing a vehicle travel control apparatus according to Embodiment 5 of the present invention.
FIG. 6 is a block diagram showing a vehicle travel control apparatus according to Embodiment 6 of the present invention.
FIG. 7 is a block diagram showing a vehicle travel control apparatus according to Embodiment 7 of the present invention.
FIG. 8 is a block diagram showing a vehicle travel control apparatus according to Embodiment 4 of the present invention.
FIG. 9 is an explanatory diagram showing a CPU interrupt routine flowchart and signals thereof;
FIG. 10 is a CPU flowchart of the vehicle travel control apparatus according to embodiment 1 of the present invention.
FIG. 11 is a CPU flowchart of a vehicle travel control apparatus according to Embodiment 2 of the present invention.
FIG. 12 is a block diagram showing a conventional constant speed traveling device.
FIG. 13 is a block diagram relating to control of a conventional constant speed traveling device.
[Explanation of symbols]
1 accelerator, 2 accelerator opening detecting means, 5 fuel control amount calculating means, 6 first target opening converting means, 7 target opening correcting means, 11 command input, 12 target speed setting means, 13 vehicle speed sensor, 14 travel Speed detection means, 15 constant speed travel control amount calculation means, 16 second target opening degree conversion means, 17 second accelerator opening degree conversion means, 18 constant speed travel prohibition means, 19 constant speed travel function setting means, 20, 24 selection means, 21 throttle valve drive means, 22 throttle valve, 23 throttle opening sensor, 25 throttle drive device.

Claims (4)

An accelerator operated by the driver, an accelerator opening detecting means for detecting the actual accelerator opening of the operated accelerator, and a fuel control amount for inputting the accelerator opening and calculating a fuel injection control amount in accordance with the accelerator opening Calculation means, a throttle valve disposed in an intake pipe of the internal combustion engine, first target opening degree conversion means for converting to a target throttle opening degree corresponding to the calculated fuel control amount, and opening of the throttle valve A fuel control system having a throttle opening sensor for detecting the degree, and a throttle valve driving means for driving the throttle valve so as to match the detected throttle opening and the target throttle opening,
Command input means for inputting the speed instruction of the driver, vehicle speed sensor, travel speed detecting means for detecting the travel speed by the vehicle speed sensor, and target speed for setting the target travel speed from the travel speed and the speed instruction input A setting means, a constant speed traveling control amount calculating means for calculating a control amount for performing constant speed traveling control based on the target speed and the traveling speed, and this constant valve traveling means during the constant speed traveling control are operated. Second target opening degree conversion means for converting into a target throttle opening degree corresponding to the speed travel control amount,
Selecting one of the first and second target opening conversion means, and a selection means for transmitting the selected target throttle opening to the throttle valve driving means;
Determine whether or not constant speed travel control is prohibited from the speed instruction input. If constant speed travel is prohibited, output a signal prohibiting selection of signals based on the constant speed travel control amount to the selection means. Having means,
The constant speed travel control amount calculation means determines whether or not the constant speed travel prohibition state is in accordance with the information from the speed instruction input, and the difference between the determination and the constant speed travel prohibition information input from the constant speed travel prohibition means. When there is, the vehicle travel control apparatus characterized in that it is determined as a constant speed travel prohibition state. The accelerator operated by the driver, the first accelerator opening detecting means for detecting the first actual accelerator opening of the operated accelerator, and the control amount of fuel injection corresponding to the input of the accelerator opening Fuel control amount calculation means for calculating, throttle valve disposed in an intake pipe of the internal combustion engine, target opening degree conversion means for converting to a target throttle opening degree corresponding to the calculated fuel control amount, and the throttle valve A fuel control system having a throttle opening sensor for detecting the opening of the throttle valve, and a throttle valve driving means for driving the throttle valve so that the detected throttle opening and the target throttle opening coincide with each other,
Command input means for inputting the speed instruction of the driver, vehicle speed sensor, travel speed detecting means for detecting the travel speed by the vehicle speed sensor, and target speed for setting the target travel speed from the travel speed and the speed instruction input Setting means, constant speed traveling control amount calculating means for calculating a control amount for performing constant speed traveling control based on the target speed and the traveling speed, and conversion to a second accelerator opening corresponding to the constant speed traveling control amount Second accelerator opening conversion means,
Selecting means for selecting one of the first actual accelerator opening and the second accelerator opening and transmitting it to the fuel control amount calculating means;
Determine whether or not constant speed travel control is prohibited from the speed instruction input. If constant speed travel is prohibited, output a signal prohibiting selection of signals based on the constant speed travel control amount to the selection means. Having means,
The constant speed travel control amount calculation means determines whether or not the constant speed travel prohibition state is in accordance with the information from the speed instruction input, and the difference between the determination and the constant speed travel prohibition information input from the constant speed travel prohibition means. When there is, the vehicle travel control apparatus characterized in that it is determined as a constant speed travel prohibition state. The accelerator operated by the driver, the first accelerator opening detecting means for detecting the first actual accelerator opening of the operated accelerator, and the control amount of fuel injection corresponding to the input of the accelerator opening Fuel control amount calculation means for calculating, throttle valve disposed in an intake pipe of the internal combustion engine, target opening degree conversion means for converting to a target throttle opening degree corresponding to the calculated fuel control amount, and the throttle valve A fuel control system having a throttle opening sensor for detecting the opening of the throttle valve, and a throttle valve driving means for driving the throttle valve so that the detected throttle opening and the target throttle opening coincide with each other,
Command input means for inputting the speed instruction of the driver, vehicle speed sensor, travel speed detecting means for detecting the travel speed by the vehicle speed sensor, and target speed for setting the target travel speed from the travel speed and the speed instruction input Setting means, constant speed traveling control amount calculating means for calculating a control amount for performing constant speed traveling control based on the target speed and the traveling speed, and conversion to a second accelerator opening corresponding to the constant speed traveling control amount Second accelerator opening conversion means,
Selecting means for selecting one of the first actual accelerator opening and the second accelerator opening and transmitting it to the fuel control amount calculating means;
Receiving a control amount calculated by the fuel control amount calculating means and a signal indicating that constant speed running control is being performed, and having target opening degree correcting means for transmitting to the throttle valve driving means so as to correct the throttle opening degree. A vehicular travel control apparatus characterized by the above.   It has a target opening correction means that receives the control amount calculated by the fuel control amount calculation means and a signal indicating that the constant speed traveling control is being performed and transmits the signal to the throttle valve driving means so as to correct the throttle opening. The vehicle travel control apparatus according to claim 1.

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