JPH05214977A - Engine brake force control device - Google Patents

Abstract

PURPOSE:To further increase the engine brake force when a driver desires further deceleration and depresses a brake in a device controlling the engine brake force when an accelerator is set to the off state. CONSTITUTION:In step SS21, a throttle is controlled to increase the engine brake force as the actual vehicle speed is increased against the vehicle speed when an accelerator is judged to be in the off state. In step SS11, if a brake action is judged to be taken by the output signal from a brake lamp switch, step SS21 is not executed. In step SS22, a throttle valve is fully closed, and the engine brake force is increased.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an engine braking force control device in a vehicle equipped with an automatic transmission, and in particular,
The present invention relates to control of engine braking force when the brake pedal is depressed from the accelerator off state on a downhill.

[0002]

2. Description of the Related Art Generally, an automatic transmission of a vehicle is designed to change a gear ratio steplessly or continuously based on an accelerator operation amount or a throttle valve opening and a vehicle speed.
FIG. 10 is an example of a shift map (shift condition) of an automatic transmission having four shift stages. The shift stages can be switched based on the accelerator operation amount and the vehicle speed, and the solid line indicates the shift on the upshift side. In the map, the broken line is the shift map on the downshift side. Such a shift map is usually
Even if the accelerator operation amount is zero, that is, it is in the OFF state, upshifting is performed according to the vehicle speed, so even if the accelerator pedal is released on a downhill, if the vehicle speed increases without sufficient engine braking force being obtained. However, there was a problem that the engine braking force was further reduced due to an upshift. As a measure against this, the applicant sets a target vehicle speed when the driver turns off the accelerator in the engine braking force control device described in Japanese Patent Application No. 3-352777 filed earlier, dislikes further acceleration. We proposed an engine braking force control device that can quickly obtain the engine braking force as intended by the driver by controlling the engine braking force so that the actual vehicle speed does not exceed the target vehicle speed.

[0003]

However, since such an engine braking force control device controls the engine braking force so as to prevent an increase in vehicle speed, further deceleration is performed after the driver releases the accelerator pedal. When the driver depresses the foot brake in the desired way, if the actual vehicle speed falls below the target vehicle speed due to the brake operation, the engine braking force does not increase any more, and sufficient engine braking is performed despite the driver's strong demand for deceleration. You will not get the power. For this reason, the braking force for decelerating the vehicle mainly depends on the braking force of the foot brake that has been depressed, and after the depression of the brake, the driver's burden of deceleration rather increases. The engine may be driven depending on the degree of deceleration.

The present invention has been made in view of the above circumstances. An object of the present invention is to reduce the burden on the driver when the brake pedal is operated in the hope of further deceleration from the accelerator off state. Especially.

[0005]

In order to achieve the above object, when the brake pedal is depressed, the control up to that point is removed to forcibly increase the engine braking force. As shown in the claim correspondence diagram of FIG. 1, in a vehicle provided with an automatic transmission that changes a gear ratio according to a predetermined gear change condition,
An engine braking force control device for controlling the engine braking force when the accelerator is in an off state, comprising:
An accelerator operation amount sensor that detects the accelerator operation amount,
(B) a vehicle speed sensor for detecting a vehicle speed; and (c) an accelerator off, in which the accelerator operation amount is substantially zero or less, which is equal to or less than a predetermined value based on an output signal of the accelerator operation amount sensor.
Accelerator off determination means for determining whether or not the state,
(D) The accelerator O is judged by the accelerator OFF judging means.
When it is determined that the vehicle is in the FF state, the first control means for increasing the engine braking force according to the increase in the actual vehicle speed detected by the vehicle speed sensor, and (e) the brake pedal is operated. And (f) when it is determined that the brake pedal has been operated based on the output signal of the brake detection unit when the engine braking force is controlled by the first control unit. , And second control means for increasing the engine braking force as compared with the case where the brake is not depressed, prior to the control of the first control means.

[0006]

In such an engine braking force control device, the accelerator operation amount sensor detects the accelerator operation amount and the vehicle speed sensor detects the vehicle speed, and the accelerator OFF determination means determines the accelerator operation amount to be substantially zero. It is determined whether or not the accelerator is in the OFF state which is equal to or less than the predetermined value, and in the accelerator OFF state, the engine braking force is increased by the first control means as the actual vehicle speed increases. That is, if the driver releases the accelerator on a downhill because he / she does not want to increase the speed further, the engine braking force is increased as the vehicle speed increases thereafter.

On the other hand, when the driver depresses the brake in order to further decelerate during such engine braking, the brake is detected based on the output signal of the brake detection means for detecting whether or not the brake is depressed. When the depression state is judged, the engine braking force is forcibly increased by the second control means in preference to the control by the first control means as compared with the case where the brake is not depressed. As a result, even when the vehicle speed decreases due to the depression of the brake, a large engine braking force can be obtained and the braking force by the foot brake operation is assisted.

[0008]

As described above, according to the engine braking force control device of the present invention, when the brake pedal is operated in the hope of further deceleration from the accelerator off state, a larger engine braking force than before the braking operation can be obtained. As a result, deceleration is promoted, and the driver's burden on deceleration is reduced.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described in detail below with reference to the drawings.

In FIG. 2, in the combustion chamber 12 of the gasoline engine 10, an air cleaner 14, an air flow meter 16, an intake passage 18, a throttle valve 20, a bypass passage 22, a surge tank 24, an intake manifold 26,
And air is taken in through the intake valve 28,
Fuel gas injected from a fuel injection valve 30 provided in the intake manifold 26 is mixed with the air. The air flow meter 16 measures the intake air amount, and outputs a signal indicating the intake air amount to the engine control computer 32. Throttle valve 20
Is for continuously changing the amount of air taken into the engine 10. The throttle valve opening θ is controlled according to the throttle control signal DTH supplied from the throttle control computer 35, and the throttle The valve 20 is provided with a throttle position sensor 36, and outputs a throttle valve opening signal Sθ representing the throttle valve opening θ to the engine control computer 32, the transmission control computer 34, and the throttle control computer 35. Bypass passage 2
2 is arranged in parallel with the throttle valve 20, and the idle speed control valve 3 is provided in its bypass passage 22.
8 is provided, and an engine control computer 32
By controlling the opening degree of the idle speed control valve 38, the amount of air that bypasses the throttle valve 20 is adjusted to control the engine speed during idling. The injection timing and the injection amount of the fuel injection valve 30 are also controlled by the engine control computer 32. An intake air temperature sensor 40 for measuring the temperature of intake air is provided upstream of the air flow meter 16, and a signal representing the intake air temperature is sent to the engine control computer 32.
Output to.

The engine 10 includes an intake valve 28 and an exhaust valve 4
2, a piston 44, and an ignition plug 46. The ignition plug 46 generates an ignition spark by a high voltage supplied from an igniter 48 controlled by the engine control computer 32 through a distributor 50. , The crankshaft is rotated by exploding the mixed gas in the combustion chamber 12 and moving the piston 44 up and down. The intake valve 28 and the exhaust valve 42 are adapted to be opened and closed by a cam shaft which is rotationally driven in synchronization with the rotation of the crankshaft, and by a variable valve timing mechanism (not shown) controlled by the engine control computer 32. The opening / closing timing is adjusted by changing the rotation phases of the camshaft and the crankshaft. The exhaust gas burned in the combustion chamber 12 is exhausted from the exhaust valve 42 to the exhaust manifold 5
4, the exhaust passage 56, and the catalyst device 58 to be discharged to the atmosphere. The engine 10 is provided with a water temperature sensor 60 for measuring the engine cooling water temperature, which outputs a signal representing the engine cooling water temperature to the engine control computer 32, and the exhaust manifold 5
4 is an oxygen sensor 62 for detecting the oxygen concentration in the exhaust gas.
Is provided and outputs a signal indicating the oxygen concentration to the engine control computer 32. Further, the distributor 50 is provided with a rotation angle sensor that generates a pulse in synchronization with the rotation of the crankshaft. The pulse signal, that is, the engine rotation speed signal SNE representing the engine rotation speed NE is sent to the engine control computer 32 and the transmission. Output to the control computer 34.

The engine control computer 32, the transmission control computer 34, and the throttle control computer 35 are all CPU, RAM, R.
The transmission control computer 34 includes an OM, an input / output interface circuit, an A / D converter, and the like, and performs signal processing according to a program stored in advance in the ROM while utilizing the temporary storage function of the RAM. In addition to the above signals, is a pattern signal SP indicating a selection pattern from the pattern select switch 70, a brake signal SB indicating that the brake is operated by the brake lamp switch 72, and an overdrive switch 74 to an O / D shift stage. O / indicating gear shift permission
The D signal SO and the accelerator operation amount signal SA indicating the operation amount Ac of the accelerator pedal are supplied from the accelerator operation amount sensor 76, respectively. The accelerator operation amount signal SAc is also supplied to the engine control computer 32 and the throttle control computer 35. The pattern select switch 70 has at least an automatic engine braking pattern that automatically increases engine braking on a downhill road, etc., and also has a power pattern for performing shift control of the automatic transmission 78 based on a shift map that emphasizes power performance and fuel consumption. This is for the driver to select a desired driving pattern from a plurality of predetermined driving patterns such as an economy pattern in which the shift control is performed according to the emphasized shift map. Further, the brake lamp switch 72 is arranged in the vicinity of the brake pedal and is turned on or off depending on whether or not the brake pedal is depressed.
It is composed of an ON-OFF switch or the like for switching F.

The automatic transmission 78 includes a torque converter 110, a first transmission 112, and a second transmission 114, as shown in FIG. 3, for example. The pump impeller of the torque converter 110 is connected to the crankshaft 118 of the engine 10, and the turbine impeller of the torque converter 110 is the input shaft 1.
It is connected to the carrier 122 of the first transmission 112 via 20. The first transmission 112 is configured to include a sun gear 124, a ring gear 126, and a planetary gear device that includes a planetary gear 128 that is rotatably disposed on the carrier 122 and meshes with the sun gear 124 and the ring gear 126. 124 and carrier 1
22 and a clutch C ₀ and a one-way clutch F _0.
Are provided in parallel, and the sun gear 124 and the housing 130
A brake B ₀ is provided between and.

The second transmission 114 is rotatably disposed on the sun gear 132, the pair of ring gears 134 and 136, and the carrier 138 so as to be rotatable on the sun gear 132, the planetary gear 140 meshed with the ring gear 134, and the carrier 142. The planetary gear 1 that is arranged and meshes with the sun gear 132 and the ring gear 136.
And a ring gear 126 of the first transmission 112. A clutch C ₁ is provided between the ring gear 136 and the ring gear 126 of the first transmission 112, and between the sun gear 132 and the ring gear 126. Clutch C
₂ is provided, and a brake B ₁ and a one-way clutch F ₁ and a brake B ₂ that are arranged in series are provided in parallel between the sun gear 132 and the housing 130, and between the carrier 138 and the housing 130. A brake B ₃ and a one-way clutch F ₂ are provided in parallel with each other. Further, the ring gear 134 and the carrier 142 are the output shaft 1
46, and its output shaft 146 is connected to the drive wheels via a differential gear device or the like.

The clutches C _{0 to} C ₂ and the brake B
_{0 to} B ₃ (hereinafter, unless otherwise specified, the clutch C,
The brake B) is a hydraulic friction engagement device that is engagement-controlled by a hydraulic actuator such as a multi-plate clutch or band brake, and hydraulic oil is supplied from the hydraulic control circuit 150 to the hydraulic actuator. Is becoming The hydraulic control circuit 150 is provided with a large number of switching valves and the like, and by switching the excitation and non-excitation of the solenoids S1, S2, and S3 in accordance with a signal from the transmission control computer 34, the hydraulic circuit is switched. The clutch C and the brake B are selectively engagement-controlled, and as shown in FIG. 4, any one of the four forward gears is established. In FIG. 4, the mark “◯” in the column of solenoid means excitation, and the mark “◯” in the column of clutch and brake means engagement. Shift position "D", "S",
“L” is the operating range of the driver's shift lever,
In the "D" range, the shift control is performed in the four stages from 1st to O / D, in the "S" range, the shift control is performed in the three stages from 1st to 3rd, and in the "L" range, 1st and 2nd. The shift control is performed in each stage. The gear ratio (the rotation speed of the input shaft 120 / the rotation speed of the output shaft 146) is 1 s.
It is the largest at t and becomes smaller as it becomes 2nd, 3rd, and O / D, and the gear ratio of 3rd is 1.0. Also,
In the "D" range, the engine brake acts at 3rd and O / D, and at the 1st and 2nd, the engine brake does not work due to the action of the one-way clutches F ₂ and F ₁ , but is shown in parentheses (1st). , (2nd), the brakes B ₃ and B ₁ are engaged by exciting the solenoid S3, and the engine brake operates. The engine brake is adapted to act on the 2nd of the "S" range and the 1st and 2nd of the "L" range. Although illustration is omitted, when the shift lever is operated to the “R” range, the manual shift valve of the hydraulic control circuit 150 is switched to establish the reverse shift stage.

The automatic transmission 78 is provided with a pair of rotation speed sensors 80 and 82. The rotation speed sensor 80 is the input shaft 120, that is, the torque converter 11.
The rotation speed sensor 82 detects the rotation speed N _T of the turbine impeller of 0, and the rotation speed sensor 82 detects the rotation speed N _O of the output shaft 146. The rotation speed signals representing the rotation speeds N _T and N _O , respectively. SN _T, and outputs the SN _O to the transmission control computer 34. Further, a neutral start switch 84 is provided in the hydraulic control circuit 150, and the "D", "S", from the position of the manual shift valve which is switched by operating the shift lever.
A shift range such as "L" or "R" is detected, and a shift range signal SR representing the shift range is output to the transmission control computer 34.

The control computers 32 and 3 are
Necessary information is transmitted and received between Nos. 4 and 35, and the throttle valve opening signal Sθ, the engine speed signal SNE, and the accelerator operation amount signal SAc are at least one of the control computers 32, 34, Alternatively, it may be supplied to 35. In addition, various other signals that represent the operating state of the automobile, such as the steering angle of the steering wheel, the gradient of the road surface, and the exhaust temperature, can be captured and used for engine control, shift control of the automatic transmission 78, and throttle control. It is possible.

Then, the engine control computer 32 uses the intake air amount, the throttle valve opening θ, the engine rotation speed NE, the cooling water temperature of the engine 10, the intake air temperature, the oxygen concentration in the exhaust passage 56, the accelerator operation. Quantity Ac
In accordance with the above, for example, the fuel injection valve 3 is based on a predetermined data map or an arithmetic expression so as to reduce fuel consumption and harmful exhaust gas while securing a required engine output.
It controls the injection amount and injection timing of the fuel gas by 0, the ignition timing by the igniter 48, the idle speed by the idle speed control valve 38, and the opening and closing timing of the intake and exhaust valves 28, 42 by the variable valve timing mechanism. The transmission control computer 34 controls the throttle valve opening θ, the engine speed NE, the selection pattern represented by the pattern signal SP, the presence / absence of a brake operation represented by the brake signal SB, and the O / D shift stage represented by the O / D signal SO. Whether or not shifting is possible, accelerator operation amount Ac, automatic transmission 78
Of the solenoid S based on the output shaft rotation speed N _{O of the}
By switching the excitation and non-excitation of 1, S2, and S3, the shift stage of the automatic transmission 78 is switched and controlled. The transmission control computer 34 also switches the lockup clutch of the torque converter 110 between full engagement, a slip state, and release by duty-controlling a solenoid (not shown) provided in the hydraulic control circuit 150. In addition, the throttle valve opening θ of the throttle valve 20 is controlled according to the accelerator operation amount Ac, and the throttle valve opening θ is adjusted to control the engine braking force when the accelerator operation amount Ac is zero. Therefore, the throttle command signal SQ is output to the throttle control computer 35. Throttle control computer 35
Is basically a throttle control signal D for controlling the throttle valve opening θ according to the throttle command signal SQ.
It is designed to output TH.

The shift control and throttle control by the transmission control computer 34 will be described below in detail with reference to the flow charts of FIGS. The flowcharts of FIGS. 5 and 6 relate to the shift control for switching the shift stage of the automatic transmission 78, and the flowcharts of FIGS. 7 to 9 relate to the throttle control. It should be noted that the following control is performed when the "D (drive)" range in which shifting is performed in four forward speeds is selected, and is repeatedly executed with a cycle time of about 8 to 32 msec.

The automatic transmission 7 is executed after step S1 in FIG.
8 is a portion for performing a shift determination as to whether or not to switch the shift speed, and if step S40 is NO, that is, flag F3
Is not "1". The flag F3 is shown in FIG.
When all the conditions of steps SS1 to SS5 are satisfied and the automatic engine braking control is executed, it is set to “1” in step SS14 or SS19 of FIG. 8, and any one of the conditions of steps SS1 to SS5 is satisfied. If not, it is set to "0" in step SS6,
Steps S1 and subsequent steps are executed in the case of normal shift control in which automatic engine braking control is not performed.

In step S1, it is judged based on the O / D signal SO whether or not shifting to the O / D shift stage is possible, and the O / D signal SO is OFF, that is, the O / D shift stage is prohibited. If so, the current O /
It is determined whether or not it is the D shift stage. The current shift speed is determined by the output state of the excitation signal for exciting the solenoids S1, S2, S3. Here is now O /
Being in the D shift stage means that the overdrive switch 74 is turned off during traveling in the O / D shift stage, and in this case, the flag F2 is set in step S14.
Is set to "1" and then "3rd" is set as the next gear in step S15. The judgment in step S1 is YE
Even if it is S, if it is not the current O / D gear and the determination in step S2 is NO, it is determined in step S3 whether it is currently the 3rd gear. Currently 3rd instead of step S3
If the determination is NO, or the determination in step S1 is NO
That is, if the O / D gear is permitted, then step S4 is executed. In step S4, it is determined whether or not the current shift speed is the O / D shift speed. If it is not the O / D shift speed, steps S5 and thereafter are executed to determine whether or not an upshift is performed. ..

In step S5, a predetermined upshift map is searched for the upshift vehicle speed Vu. As shown by the solid line in FIG. 10, the upshift map is predetermined for each type of shift based on the accelerator operation amount Ac and the vehicle speed V. The smaller the accelerator operation amount Ac is, the larger the vehicle speed V is. It is designed to be upshifted to the high speed side. Shift up vehicle speed Vu
It is determined according to the upshift map based on the accelerator operation amount Ac, at the next step S6, the current vehicle speed V and the shift-up vehicle speed Vu that corresponds to the output shaft rotational speed N _O of the rotational speed signal SN _O represents Compare
Determine whether to upshift. That is, V ≦
If it is Vu, it is not necessary to perform an upshift, and in step S8 it is determined whether or not the current gear is 1st. If it is 1st, in step S9 a flag indicating an upshift state when it is "1". A series of shift determination is ended by setting F1 to “0”. However, when V> Vu, the flag F1 is set to “1” in step S7, and then in step S15, the next shift speed is higher than the current shift speed. Set the gear on the gear side. In this case, even if the current shift speed is, for example, 2nd, the accelerator operation amount Ac sharply decreases after the shift determination to 3rd is made and before the shift speed is actually changed to 3rd. And then "3
When the "→ O / D" upshift line is exceeded, the O / D shift speed is set. In step S5, the shift-up vehicle speed Vu for all upshift lines is obtained from the current accelerator operation amount Ac, and in step S6, the respective shift-up vehicle speed Vu and the current vehicle speed V are compared to determine the upshift shift. Do it.

If the determination in step S3 is YES,
If the determination in step S4 is YES, or
If the determination in step 8 is NO, steps S10 and subsequent steps are executed to determine whether to downshift. Step S
In step 10, a predetermined downshift map is searched to obtain the downshift vehicle speed Vd. As indicated by the broken line in FIG. 10, the downshift map is predetermined for each type of shift based on the accelerator operation amount Ac and the vehicle speed V, and as the accelerator operation amount Ac increases and the vehicle speed V decreases. It is designed to downshift to the lower speed side. The downshift vehicle speed Vd is the accelerator operation amount A.
It is determined according to the downshift map based on c, and in the next step S11, the current vehicle speed V corresponding to the output shaft rotation speed N _O is compared with the above-mentioned downshift vehicle speed Vd, and it is determined whether or not a downshift is performed. To do. That is,
If V> Vd, it is not necessary to perform a downshift, and in step S13, the flag F2 indicating the downshift state is set to "0" at the time of "1" to end the series of shift determination, but if V≤Vd In step S12, the flag F2 is set to "1", and then, in step S15, the shift speed lower than the current shift speed is set as the next shift speed. In this case, even if the current gear stage is, for example, O / D, after the shift determination to 3rd is made, 3r is actually performed.
Before the gear is switched to d, the accelerator operation amount A
When c exceeds the “2 ← 3” downshift line by suddenly increasing, the 2nd shift speed is set. In step S10, the shift-down vehicle speed Vd for all downshift lines is obtained from the current accelerator operation amount Ac, and in step S11, the respective shift-down vehicle speed Vd and the current vehicle speed V are compared to determine the downshift. Do it.

If YES at step S40, that is, if automatic engine braking control is being executed, step S41 is executed after step S40,
It is determined whether the flag F5 is "0". The flag F5 is
When the automatic engine braking control is executed and all the conditions of steps SS1 to SS5 in FIG. 7 are satisfied and the brake pedal is depressed, it is set to “1” in step SS23 in FIG. It is set to "0" in step SS6 or SS12, and the flag F
If 5 = 0, step S42 is executed and the flag F5
When = 1, step S45 is executed. In step S45 executed when the brake pedal is depressed, a predetermined downshift map for engine braking is searched to obtain the downshift vehicle speed Ved for engine braking. The downshift map during engine braking is predetermined for each type of shift based on the accelerator operation amount Ac and the vehicle speed V, similar to the normal downshift map shown by the broken line in FIG. ,
It is easier to downshift because it is shifted to the higher vehicle speed side than the normal downshift map. Downshift vehicle speed Ve
d is obtained according to the downshift map during engine braking based on the accelerator operation amount Ac, and in the next step S46, the current vehicle speed V corresponding to the output shaft rotation speed N _O and the downshift vehicle speed Ved are compared. Then, it is determined whether or not the downshift is performed. That is,
If V> Ved, it is not necessary to perform a downshift, and the flag F2 is set to "0" in step S44 to complete the shift determination. However, if V≤Ved, step S4 is performed.
After setting the flag F2 to "1" in step 7, step S4
In step 8, a shift speed lower than the current shift speed is set as the next shift speed. The gears set here are those to which engine braking is applied, and the gears shown in parentheses in FIG. 4 are set in the 2nd or 1st. In this case, even if the current gear stage is, for example, O / D, the vehicle speed V decreases sharply after the gear shift judgment to 3rd is made and before the gear shift to 3rd is actually performed. If the "2 ← 3" downshift line is exceeded, the 2nd shift speed is set. In step S45, the downshift vehicle speed Ved for all downshift lines is obtained from the current accelerator operation amount Ac, and in step S46, each downshift vehicle speed Ved is compared with the current vehicle speed V to make a downshift determination. Do it.

In step S42 executed when the brake pedal is not depressed, it is determined whether the flag F4 is "1". The flag F4 is set to "1" in step R7 of FIG. 9 when the downshift is performed to increase the engine braking force in the automatic engine brake control, and is set to "1" in step S31 of FIG. 6 when the downshift is completed. If F4 = 0, the flag F2 is set to "0" in step S44 to complete the shift determination, and if F4 = 1, step S43 is executed. In step S43, the next low speed stage where the engine brake acts as the next shift stage, that is, 2nd or 1s.
In the case of t, the gear stage shown in parentheses in FIG. 4 is set.

When the next shift speed is set in step S15, S43, or S48, the shift timing time T1 is set in step S16.
The gear shift timing time T1 is a delay time from the time when the gear shift is determined to the time when the gear is actually switched, and it is possible to prevent a plurality of gear shifts (multiple gear shifts) from being performed in a short time, and to downhill. When the accelerator pedal is released quickly to activate the engine brake, and when the accelerator operation amount Ac becomes substantially zero before actually performing the upshift, the upshift to the O / D gear is prohibited. A fixed value may be set in advance, but different times may be set according to the type of shift such as upshift or downshift, or downshift in automatic engine braking control. You can Further, it may be set by a map, a calculation formula or the like according to the accelerator operation amount Ac at the time of gear shift determination, the vehicle speed V, the gear position and the like.

Next, the flow chart of FIG. 6 for actually changing the shift speed will be described. FIG. 6 is a portion for executing an upshift and a downshift for increasing the engine braking force in accordance with the shift determination of FIG. 5. In step S20, it is determined whether or not the flag F1 is "1", that is, the upshift shift determination. Determine whether or not If the flag F1 is "1", steps S21 and subsequent steps are executed, but if not, step S33 is executed. In step S33, it is determined whether or not the flag F4 is "1", that is, whether or not the downshift is for increasing the engine braking force. If the flag F4 is "1", the steps from step S21 are executed. If not, step S32 is immediately executed, the timer Ta is reset, and the process ends.

In step S21, the shift range signal SR
It is determined whether or not the shift range represented by is "D (drive)", and in step S22, the traveling pattern represented by the pattern signal SP is "automatic engine braking pattern".
Determining whether a determines whether larger than the lower limit vehicle speed V1 of the vehicle speed V is preset to correspond to the output shaft rotation speed N _O representing the rotational speed signal SN _O In step S23, in step S24 It is determined whether or not the vehicle speed V is equal to or lower than a predetermined upper limit vehicle speed V2, and in step S25, the accelerator is turned off, that is, whether or not the accelerator operation amount Ac represented by the accelerator operation amount signal SAc is substantially zero. In consideration of the above, it is determined whether or not it is about 5% or less. In step S26, it is determined whether or not the next gear stage set in step S15 is an O / D gear stage. The lower limit vehicle speed V1 and the upper limit vehicle speed V2 define a vehicle speed range in which special control for engine braking is performed. The lower limit vehicle speed V1 is set to, for example, about 20 km / h, and the upper limit vehicle speed V2 is, for example, about 110 km / h. Is set to. Then, if even one of the determinations in steps S21 to S26 is NO, in step S28, the change of the next shift speed set in step S15 is not performed, but step S28 is performed.
If the determinations in 21 to S26 are all YES, the next gear is changed to "3rd" in step S27. The step S26 is to determine whether the next gear set in step S15 is O / D. Even in the cycle after the next gear is changed from O / D to 3rd in step S27, The determination in step S26 is YES.

In step S29, it is determined whether or not the content measured by the timer Ta is not less than the shift timing time T1. The above steps S20 and thereafter are repeated until the shift timing time T1 is reached, but when the shift timing time T1 is reached, step S30 is executed and the solenoid S1,
The excitation and non-excitation of S2 and S3 are switched to switch the shift stage of the automatic transmission 78 to the next shift stage set in step S15 or S43 or the 3rd shift stage changed in step S27. After that, the flag F1 is set to "0" and the flag F4 is set to "0" in step S31, and the timer Ta is reset in step S32.

Here, in step S6, O / D
Even if an upshift determination to the shift stage is made, step S
Until the gear is actually changed at 30
That is, the shift timing time T after the shift determination is made.
If all of the conditions of steps S21 to S26 including the accelerator OFF are satisfied before the lapse of 1, the next shift stage is changed to 3rd, and further speedup is disliked on a downhill or the like. If the driver releases the accelerator pedal, the actual shift to the O / D shift stage is prevented even if the upshift shift determination is made as the accelerator operation amount Ac decreases, and the O / D shift stage is prevented. The reduction in engine braking force due to the shift to is favorably avoided. For example, when the driver releases the accelerator in the case of traveling for the second time at the point A in FIG. 10, “2
Since the accelerator operation amount Ac becomes zero across the "3" upshift line and the "3 → O / D" upshift line, a final shift determination from 2nd to O / D is made in step S6. , In step S15, the O / D shift stage is set as the next shift stage, but if the accelerator operation amount Ac becomes zero before the shift timing time T1 elapses after the "2 → 3" upshift determination is made, "3 → O /
Even if the next shift speed is changed to O / D by crossing the "D" upshift line, the next shift speed is changed to 3rd in step S27, and therefore the upshift to the O / D shift speed is not performed.

Even if the accelerator is turned off once,
If the pedal is depressed again before reaching the shift timing time T1, the determination in step S25 is NO, and in step S28 the next shift stage is set to the O / D set in step S15. When the pedal is depressed, the driver does not need the engine braking force so much, and therefore the driver may upshift to the O / D gear. The determination of step S29 may be inserted between steps S20 and S21, and when the shift timing time T1 has elapsed, step S21 and subsequent steps may be executed to switch the shift speed.

Further, the accelerator return speed is relatively slow,
Even when the accelerator is not turned off within the shift timing time T1, the shift as set in step S15 is executed, but in this case as well, it is considered that the driver does not need so much engine braking force, so O / There is no problem in upshifting to the D gear. In other words,
When the driver needs the engine braking force, he / she should release the accelerator pedal promptly, and when he / she wants to coast or the like which does not require the engine braking force so much, he / she should release the accelerator pedal slowly. It's good.

Next, the throttle control of FIGS. 7 to 9 will be described. First, in steps SS1 to SS5 of FIG. 7, the same as steps S21 to S25 regarding the shift range, the traveling pattern, the vehicle speed V, and the accelerator operation amount Ac. If the judgment is made and all the conditions are satisfied, the automatic engine braking control of step SS8 and thereafter is executed,
If any one of them is NO, step SS6 in FIG.
Flag F3 is set to "0" and flag F5
Is set to "0" and normal throttle control is performed in step SS7. The normal throttle control in step SS7 is performed by the accelerator operation amount A indicated by the accelerator operation amount signal SAc.
Based on c, the throttle valve opening TH (Ac) is obtained from a predetermined map or an arithmetic expression, and the throttle valve opening TH (Ac) is set to the target throttle valve opening TH, and the target throttle valve TH A throttle command signal SQ indicating the opening TH is output to the throttle control computer 35. Throttle control computer 35
Indicates the actual throttle valve opening θ of the throttle valve 20 by the feedback control or the like and the throttle command signal SQ.
To match the target throttle valve opening TH represented by
The throttle control signal DTH is output to the throttle valve 20.

In step SS8, which is executed when all the conditions in steps SS1 to SS5 are satisfied, flag F is set.
It is determined whether or not 3 is "1", but this flag F3
Is set to "0" in step SS6, so it is "0" when step SS8 is first executed,
Subsequently, step SS10 is executed to set the vehicle speed V at that time to the target vehicle speed Vm. The flag F3 is set to "1" in step SS14 or SS19 of FIG.
In the subsequent cycles, the determination in step SS8 is YES and step SS9 is executed. In step SS9,
A vehicle speed (Vm-Vf) obtained by subtracting a predetermined constant value Vf from the target vehicle speed Vm and the vehicle speed V at that time are compared to obtain V
> (Vm-Vf), step SS11 and subsequent steps in FIG. 8 are executed, but if V≤ (Vm-Vf), step SS10 is executed again, and the target vehicle speed Vm is changed to the vehicle speed V at that time, and then step Perform SS11 and below. Considering the fluctuation of the vehicle speed V due to the feedback control of the throttle valve opening θ in steps R3 and R5 of FIG. 9, the constant value Vf is determined to be NO in step SS9 depending on the fluctuation of the vehicle speed V accompanying the throttle control. Although it does not occur, the target vehicle speed Vm is set to be changed in step SS10 when the judgment of step SS9 becomes NO when the vehicle speed V is relatively greatly decreased by the depression operation of the brake.

In step SS11 of FIG. 8, it is judged whether or not the brake pedal is operated based on the brake signal SB. If the brake is OFF, that is, if the brake pedal is not operated, step SS12 and the following steps are executed. If the person desires further deceleration and depresses the brake, the determination in step SS11 is NO, and steps SS22 and SS23 are executed. Step SS2
In 2, the target throttle valve opening TH is set to 0 in order to increase the engine braking force, and the throttle command signal SQ representing the target throttle valve opening TH is output to the throttle control computer 35, so that the throttle valve 20 is opened. Fully closed. Further, in step SS23, the flag F5 is set to "1" so that steps S45 and below in FIG. 5 are executed. At the beginning of the automatic engine braking control, that is, in the first cycle in which the accelerator is turned off, the brake is normally turned off.
Is YES and the result is Step SS14 or SS1.
In FIG. 9, the flag F3 is set to "1", and in FIG. 5, the steps from step S41 onward during engine braking are executed.

Step SS executed when the brake is OFF
In step 12, the flag F5 is set to "0", and in step SS13, it is determined whether or not the flag F1 is "1".
In step 6, it is determined whether or not the upshift is determined. When the flag F1 = 1, the flag F3 is set to "1" in step SS14, and then, in step SS15, if the vehicle is traveling on a flat ground based on the next shift speed and the current vehicle speed V, the shift speed is currently changed. The throttle valve opening degree that can maintain the vehicle speed V, that is, the throttle valve opening degree TH1 (%) at which the driving force in consideration of the running resistance becomes zero is calculated from a pre-stored data map as shown in FIG. 11, for example. Calculated by map interpolation. Then, the throttle valve opening TH1 is set as the target throttle valve opening TH, and the throttle command signal SQ indicating the target throttle valve opening TH is sent to the throttle control computer 35.
Output to the throttle valve 20 so that the actual throttle valve opening θ of the throttle valve 20 becomes the throttle valve opening TH1.

In the data map of FIG. 11, the throttle valve opening at which the driving force matches the running resistance is obtained for each shift speed and vehicle speed based on the data shown in FIG. 12 which has been experimentally obtained in advance. It is a thing. The data of FIG. 12 shows that in the vehicle equipped with the engine having the output characteristics shown in FIG. 13, the gear position of the automatic transmission 78 is O / D (total gear ratio = 2.8905), and the gear transmission efficiency is 0.855.
When the tire effective radius is 0.306 m, for example, when the vehicle speed is 80 km / h, the throttle valve opening TH1
(%) Indicates that the throttle valve opening (angle) at point B, which coincides with the running resistance on a flat ground, is about 7.4 °. 4/8
0) × 100 = 9.3. That is, in the data map of FIG. 11, the throttle valve opening TH ₄₅ when the vehicle speed is 80 km / h at the O / D speed is specifically 9.3%.
In this way, the throttle valve opening TH _{41 to} TH _{47 at} each vehicle speed at the O / D gear is obtained. Three
Regarding the second gear shift stage and the first gear shift stage where the rd gear shift stage and the engine brake act, the throttle valve openings TH _{31 to} TH ₃₇ , TH are set in the same manner as in the case of the O / D gear shift stage.
_{21 to} TH ₂₇ and TH _{11 to} TH ₁₇ are required. As is clear from the data in FIG. 12, the throttle valve opening TH1 increases as the vehicle speed increases, and if the vehicle speed remains the same, the throttle gear opening TH1 increases as the gear shift ratio decreases.

On the other hand, if the upshift gearshift determination is not made, or if the upshift gearshift output is made and the flag F1 is set to "0" in step S31 of FIG. 6, step SS13 is executed. The determination is NO, and it is determined in step SS16 whether the flag F6 indicating the throttle change standby state is "0" when it is "1". If the flag F6 is "0", step SS
At 17, it is determined whether the flag F3 is already "1". If flag F3 = 1, step SS18
It is determined whether or not the gear shift is being performed in (1) by, for example, whether or not the following expression (1) is satisfied. That is, in step S30 of FIG. 6, the shift output is performed and the solenoid S1,
When the excitation and non-excitation of S2 and S3 are switched, the clutch C and the brake B of the automatic transmission 78 start to slip, and the rotation speed ratio of the turbine rotation speed N _T and the output shaft rotation speed N _O is changed, that is, Since the gear shift ends when the gear ratio i of the current gear stage after the gear shift output substantially matches, the rotational speeds N _T , N _O , and the gear ratio i of the current gear stage are expressed by the following equation (1). If it is satisfied, the gear is not being changed, and if the following equation (1) is not satisfied, the gear is being changed. The expression (1) is set to satisfy a predetermined width in consideration of detection errors of the rotation speeds N _T and N _O.

[0039]

## EQU1 ## N _T ≈N _O × i (1)

If the determination in step SS18 is YES, that is, if the gear shift is not in progress, the automatic engine brake throttle processing routine in step SS21 is executed, but if the gear shift is in progress, step SS20 is executed.
Further, the flag F3 is not "1" in the first cycle of the automatic engine braking control, and the determination in step SS17 is N.
In the case of O, the flag F3 is set to "1" in step SS19, and then step SS20 is executed. In step SS20, based on the current gear and the vehicle speed V,
If the vehicle is traveling on a flat ground, the throttle valve opening degree that can maintain the current vehicle speed V, that is, the throttle valve opening degree TH2 (%) at which the driving force in consideration of running resistance becomes zero, is shown in the same manner as the throttle valve opening degree TH1. 11 is calculated by map interpolation from the data map, and the throttle valve opening TH is calculated.
By setting 2 to the target throttle valve opening TH and outputting the throttle command signal SQ representing the target throttle valve opening TH to the throttle control computer 35,
The actual throttle valve opening θ of the throttle valve 20 is controlled to be the throttle valve opening TH2. Engine 10
The intake air amount to the throttle valve opening θ is increased / decreased to become the intake air amount corresponding to the throttle valve opening TH2. Be reduced.

In the automatic engine braking control which is first executed after the accelerator is turned off, step SS1
7. After executing SS19, step SS20 is executed and the throttle valve opening θ is once opened so that the driving force becomes 0. This prevents the engine braking force from becoming excessively large, and it corresponds to the inclination of the downhill. This is so that the optimum engine braking force can be obtained. Also, during shifting, step SS
20 is executed to open the throttle valve opening θ so that the driving force becomes 0. Especially, when the downshift (the downshift of the flag F4 = 1) is performed to increase the engine braking force, This is because the speed NE is rapidly increased to shorten the time required to switch the shift stage (shift time), and this suppresses an increase in vehicle speed during a shift in which sufficient engine braking force cannot be obtained.

In the automatic engine brake throttle processing routine of step SS21, the vehicle speed V is substantially equal to the target vehicle speed Vm in this embodiment so that the actual vehicle speed V does not exceed the target vehicle speed Vm set in step SS10 of FIG. The throttle valve opening degree θ is feedback-controlled so as to coincide with each other, and is specifically executed according to the flowchart of FIG. In step R1 of FIG. 9, it is determined whether or not the flag F4 is "0". If the flag F4 = 0, the actual throttle valve opening degree θ represented by the throttle valve opening degree signal Sθ is predetermined in step R2. It is determined whether it is smaller than the determined determination value θ1. The determination value θ1 is a small value of about 5% or less, and can be determined using an idle signal or the like indicating that the throttle valve opening θ is substantially fully closed.
When θ ≧ θ1, that is, the throttle valve opening θ
When it is possible to increase the engine braking force by closing, the step R3 is executed and the vehicle speed V is made to substantially match the target vehicle speed Vm according to the deviation between the target vehicle speed Vm and the current vehicle speed V. Throttle valve opening TH3
(%) Is calculated according to the feedback control calculation formula.

In the next step R4, based on the current gear position and the target vehicle speed Vm, the throttle valve opening that can maintain the target vehicle speed Vm in flatland traveling, that is, the driving force considering the running resistance becomes zero. Throttle valve opening THm
(%) Is calculated from the data map of FIG. 11 by map interpolation, and it is determined whether the throttle valve opening TH3 is smaller than the throttle valve opening THm. And T
If H3 <THm, in step R5, the throttle valve opening TH3 is set to the target throttle valve opening TH,
By outputting a throttle command signal SQ indicating the target throttle valve opening TH to the throttle control computer 35, the actual throttle valve opening θ of the throttle valve 20 is controlled to be the throttle valve opening TH3.
By repeatedly executing these steps R3, R4, R5, the throttle valve opening θ is rapidly controlled so that the vehicle speed V substantially matches the target vehicle speed Vm, and the accelerator O
The engine braking force for driving the vehicle at the target vehicle speed Vm at the time of FF or the target vehicle speed Vm changed with the decrease in the vehicle speed V due to the brake depression operation can be obtained. In this embodiment, the throttle valve opening θ is feedback-controlled so that the vehicle speed V substantially matches the target vehicle speed Vm, so that the engine speed is substantially matched with the target vehicle speed Vm regardless of the change in the road surface gradient. When the braking force is increased / decreased and the gradient changes from a steep gradient to a gentle gradient, the vehicle speed V is prevented from being lowered against the driver's intention due to excessive engine braking.

On the other hand, when TH3 ≧ THm, the determination in step R4 is NO, and in step R6 the throttle valve opening THm is set to the target throttle valve opening TH and the throttle command indicating the target throttle valve opening TH is set. By outputting the signal SQ to the throttle control computer 35, the actual throttle valve opening θ of the throttle valve 20 is controlled to be the throttle valve opening THm. This is because the engine braking force is increased or decreased so that the vehicle speed V substantially matches the target vehicle speed Vm regardless of the change in the road surface gradient as described above, and therefore the throttle valve opening θ Is opened and the vehicle speed V is maintained at the target vehicle speed Vm. However, with such engine braking control, the driver usually thinks that the vehicle speed V will decrease on an uphill road, and even if traveling on a flat surface. Target vehicle speed Vm
The throttle valve opening THm that can maintain the above is set as the upper limit of the throttle valve opening TH3 by the feedback control. As a result, the target vehicle speed Vm is maintained on the downhill and the flat ground, but the vehicle speed V becomes lower than the target vehicle speed Vm according to the gradient on the uphill, and the traveling control as intended by the driver is performed. Will be done.

When the throttle valve 20 is almost fully closed and the engine braking force cannot be increased by the throttle control, the determination at step R2 becomes YES, and steps R7 and thereafter are executed. In step R7, the flag F4 instructing the downshift to increase the engine braking force is set to "1", and the flag F6 instructing the throttle change standby is set to "1".
As a result, step S43 of FIG. 5 is executed, and step SS24 and subsequent steps of FIG. 8 are executed. Further, in step R8, based on the gear position after the downshift and the current vehicle speed V, the throttle valve opening that can maintain the current vehicle speed V in flat ground traveling, that is, the driving force in consideration of running resistance is zero. The throttle valve opening TH4 (%) is calculated from the data map of FIG. 11 by map interpolation,
In step R9, the throttle valve opening change timing time T2 is set and the timer Tb is reset.
In the throttle valve opening change timing time T2, the gear shift output is actually performed in accordance with the setting of the downshift in step S43, and the engine speed is set to the above-mentioned throttle in accordance with the timing when the clutch C and the brake B start to slip. The type of shift, the vehicle speed V, the oil temperature of the hydraulic control circuit 150, and the like are predetermined as parameters based on the shift timing T1 so as to increase corresponding to the valve opening TH4.

When the flag F6 is set to "1" in step R7, step S in FIG.
The determination in S16 is NO, and step SS24 is executed. In step SS24, it is determined whether or not the content of the timer Tb is longer than the throttle valve opening change timing time T2. When the timing time T2 is reached, step S24 is executed.
In S25, the throttle valve opening TH4 is set to the target throttle valve opening TH, and the target throttle valve opening TH is set.
By outputting the throttle command signal SQ indicating
The actual throttle valve opening θ is the throttle valve opening TH4
Control so that. Then, the next step SS26
In, the flag F6 is set to "0". The change timing of the throttle valve opening degree during the downshift is set so that the engine is blown up in accordance with the timing when the clutch C and the brake B start to slip with the shift output as described above. Is step S3
If it is before the change output of 0, the determination in step SS18 becomes YES in the subsequent cycle and step S
Although S21 is executed, since the flag F4 is "1" until the shift output is made in step S30, the throttle control after step R2 in FIG. 9 is not executed. Further, when the shift output is executed in step S30,
Since the determination in step SS18 is NO, the throttle control in step SS21 is not executed until the shift is completed. On the other hand, if the timing of changing the throttle valve opening is later than the shift output of step S30, the determination of step SS18 becomes NO in the subsequent cycles, and thus step SS2 is similarly performed until the shift is completed.
Throttle control of 1 is never executed.

Here, in the automatic engine braking control of the present embodiment, when it is determined in step SS5 that the accelerator is in the OFF state, the vehicle speed V when the accelerator is OFF is set to the target vehicle speed Vm. , The engine braking force is controlled by performing feedback control of the throttle valve opening θ in steps R3 and R5 or performing a downshift in steps R7 and below so that the vehicle speed V substantially matches the target vehicle speed Vm. When the driver releases the accelerator on the downhill and dislikes the further acceleration, the vehicle speed V at the time of releasing the accelerator is set as the target vehicle speed Vm, and the vehicle speed is controlled by the engine brake as intended by the driver. To be done. On the other hand, if the brake pedal is depressed during such automatic engine braking control, the throttle valve 20 is fully closed in step SS22 or steps S45, S46, S48 without performing the throttle control in steps R3 and R5. As the engine braking force is increased by downshifting in the engine, engine braking control that matches the driver's desire to decelerate is performed, and the pedal effort can be small. Burden is reduced.

In the present embodiment, in the series of signal processing by the transmission control computer 34, the part that executes step SS5 in FIG. 7 corresponds to the accelerator OFF judging means, and steps SS11 and SS in FIG.
22, SS23, and steps S41 and S4 of FIG.
5, S46 and S48 correspond to the second control means, and steps R3, R5 and R7 of FIG. 9, steps S42 and S43 of FIG. 5, and step S30 of FIG. The computer 35 and the throttle valve 20 constitute a first control means. The rotation speed sensor 82 that detects the output shaft rotation speed N _O corresponding to the vehicle speed V corresponds to a vehicle speed sensor, and the brake lamp switch 72 that outputs the brake signal SB corresponds to brake detection means.

On the other hand, in this embodiment, when the accelerator is turned off and the automatic engine braking control is started, first, at step SS20, the throttle valve opening θ is opened up to the throttle valve opening TH2 at which the driving force = 0. afterwards,
In steps R3 and R5, the vehicle speed V is accelerator OF
Since the throttle valve opening θ is controlled so as to be substantially equal to the target vehicle speed Vm at F, the engine braking force does not become excessive, and an appropriate engine braking force is obtained even when the road gradient is relatively gentle. There are advantages. Even when a downshift is performed to increase the engine braking force, the throttle valve opening degree θ is opened to the throttle valve opening degrees TH4 and TH2 where the driving force becomes 0 in steps SS25 and SS20, and the step R3 is performed after the shift is completed.
Since the throttle control is performed by R5 and R5, the engine braking force does not suddenly increase due to the downshift and a shock or the like does not occur.

In steps R3 and R5, the throttle valve opening θ is controlled so that the vehicle speed V matches the target vehicle speed Vm. Therefore, the vehicle speed V is the target vehicle speed Vm regardless of the change in the road surface gradient. The engine braking force is increased / decreased so as to substantially match with, and when the gradient changes from a steep gradient to a gentle gradient, the vehicle speed V is prevented from decreasing against the driver's will due to excessive engine braking. Particularly, in this embodiment, the throttle valve opening θ is feedback-controlled so that the vehicle speed V substantially matches the target vehicle speed Vm.
There is an advantage that the vehicle speed V can be quickly brought close to the target vehicle speed Vm, and an appropriate engine braking force can be quickly obtained.

Further, in the present embodiment, when the throttle valve opening TH3 obtained in step R3 becomes equal to or larger than the throttle valve opening THm capable of maintaining the target vehicle speed Vm in the case of traveling on a flat surface, step R6. Since the throttle valve opening THm is set to the target throttle valve opening TH, the vehicle speed V is lowered below the target vehicle speed Vm according to the gradient when there is an uphill after the downhill. The traveling control is performed as intended by the driver who thinks that the vehicle speed V will decrease.

Further, if the brake pedal is operated while the automatic engine braking is being controlled, step SS10 is executed every time the judgment in step SS9 becomes NO due to the decrease in vehicle speed V.
Is executed and the target vehicle speed Vm is sequentially changed according to the vehicle speed V at that time. Therefore, when the depression of the brake is released after the vehicle speed has decreased to the desired vehicle speed, the vehicle speed V when the brake is released is set to the target vehicle speed Vm, and thereafter, based on the new target vehicle speed Vm when the brake is released. The engine braking force is controlled by throttle control and downshift. As a result, it is possible to avoid insufficient engine braking force after releasing the brakes.For example, even if you decelerate by depressing the brake before the end of the straight line on the downhill and then release the brake and travel on the curve, accelerate while running the curve. The driving operation is further facilitated.

In the above embodiment, even if the next gear is changed to 3rd in step S27 of FIG. 6, if the accelerator is depressed before the shift timing time T1, the next gear is changed in step S28. Although it is returned to O / D, as shown in FIG. 14, for example, when the next gear is changed to 3rd in step S27, step S30 may be immediately executed to output gears.

Further, in the above-described embodiment, step SS9 is executed every time the judgment in step SS9 becomes NO as the vehicle speed V decreases.
10 was executed and the target vehicle speed Vm was sequentially changed according to the vehicle speed V at that time. However, as shown in FIG. 15 and FIG. 16, for example, the step SS9 is omitted and the step SS11 and the step SS12 are performed. Alternatively, steps SS27 and SS28 may be provided to change the target vehicle speed Vm according to the vehicle speed V when the brake is released. Also in this case, there is no fear of sudden acceleration due to insufficient engine braking force after releasing the brake, and the same effect as that of the above-described embodiment that the driving operation becomes easier can be obtained.

Although the embodiments of the present invention have been described in detail with reference to the drawings, the present invention can be implemented in other modes.

For example, although the engine braking force is controlled by the throttle control and the downshift in the above-mentioned embodiment, the engine auxiliary equipment such as the alternator or the idle speed control valve 38 is opened or closed. The engine braking force can be controlled, or in a vehicle equipped with a belt type continuously variable transmission, the engine braking force can be controlled by changing the groove width of the variable pulley, that is, the gear ratio.

Further, in the above embodiment, the throttle valve opening θ
However, the present invention can be applied to a vehicle in which the throttle valve 20 is mechanically connected to an accelerator pedal to open and close. Ac
Alternatively, the throttle valve opening θ may be used instead of.

Further, in the above embodiment, the automatic engine braking control of step SS8 and the subsequent steps is executed on condition that the automatic engine braking pattern is selected by the pattern select switch 70. When the driving pattern of is selected, automatic engine braking control is performed,
The automatic engine braking control may be executed regardless of the type of driving pattern. It is of course possible to dispose the engine brake control switch separately from the pattern select switch 70.

Further, although the vehicle speed limitation of steps SS3 and SS4 is provided as a condition for performing the automatic engine braking control in the above-mentioned embodiment, such vehicle speed limitation is not always necessary and the range of the vehicle speed limitation is appropriately determined. Other conditions may be added as conditions for performing automatic engine braking control.

Further, in the above embodiment, the vehicle speed V when the accelerator is off or when the brake is released is set to be the target vehicle speed Vm as it is, but the target vehicle speed Vm does not need to be completely matched with the vehicle speed V and is measured. The target vehicle speed Vm may be set by adding or subtracting a predetermined value to the vehicle speed V in consideration of an error or the like.

In the above embodiment, the vehicle speed V is set to the target vehicle speed V
Although the throttle valve opening θ is feedback-controlled so as to match m, the throttle valve opening θ may be increased or decreased by a predetermined constant amount ΔTH, or the vehicle speed V
It is also possible to use other control methods, such as decreasing the throttle valve opening θ by a fixed amount ΔTH so that does not exceed the target vehicle speed Vm. Step S
The constant vehicle speed Vf in S9 is determined in consideration of the fluctuation of the vehicle speed V accompanying the control of the throttle valve opening θ.

Further, in the above-mentioned embodiment, at the time of downshifting for increasing the engine braking force, step SS
In 20 and SS25, the throttle valve opening degree θ is opened so that the driving force becomes 0 at the gear after the gear shift, and after the gear shift is finished, it is gradually closed by step R3 and the like.
After the shift is completed, the throttle valve opening θ can be controlled so that a braking torque substantially the same as or slightly larger than the braking torque before the shift is obtained. A data map for obtaining the throttle valve opening in this case can be created in advance using the data in FIG. 12 and the like with the gear position and the vehicle speed V as parameters, as in the data map in FIG.

Further, in the above-described embodiment, only the upshift to the O / D gear is prohibited in step S27. However, if the engine brake is applied even in the first gear or the second gear, " It is also possible to prohibit the 2 → 3 ”shift and the“ 1 → 2 ”shift. The number of gears of the automatic transmission 78 is also changed as appropriate.

Further, although the engine control computer 32, the transmission control computer 34, and the throttle control computer 35 are separately configured in the above embodiment, they may be configured by a single computer. It is possible.

In the above embodiment, the engine braking force control is performed by the throttle control so that the vehicle speed V matches the target vehicle speed Vm by the first control means, but the acceleration of the vehicle becomes negative. It does not matter if the engine braking force control is performed.

Further, in the above embodiment, the throttle valve 20 is fully closed or downshifted by the second control means to increase the engine braking force, but the throttle valve 20 is fully closed. It may be closed or only downshifted.

Although not illustrated one by one, the present invention can be carried out in various modified and improved modes based on the knowledge of those skilled in the art.

[Brief description of drawings]

FIG. 1 is a diagram corresponding to a claim of the present invention.

FIG. 2 is a diagram illustrating a configuration of an automatic transmission, an engine, and the like including an engine braking force control device that is an embodiment of the present invention.

FIG. 3 is a diagram illustrating a configuration of the automatic transmission of FIG.

FIG. 4 is a diagram showing a shift stage of the automatic transmission of FIG. 3, excitation of a solenoid for establishing the shift stage, and engagement operation of a clutch and a brake.

FIG. 5 is a flowchart illustrating an operation of gear shift determination as to whether or not to shift a gear stage of the automatic transmission of FIG.

FIG. 6 is a flowchart illustrating an operation of shift control for switching a shift stage of the automatic transmission of FIG.

7 is a flowchart illustrating an operation of controlling the throttle valve opening of the engine of FIG. 2 together with FIG.

8 is a flowchart illustrating an operation for controlling the throttle valve opening of the engine of FIG. 2 together with FIG. 7.

9 is a flowchart illustrating the contents of an automatic engine brake throttle processing routine of FIG.

10 is an example of a shift map for switching the shift speed of the automatic transmission of FIG.

11 is an example of a data map used to obtain a throttle valve opening degree at which the driving force in consideration of running resistance is approximately zero from the gear position and the vehicle speed in the throttle control of FIG.

12 is basic data for creating the data map of FIG.

13 is data showing the output characteristics of the engine used to obtain the basic data of FIG.

FIG. 14 is a flowchart illustrating another aspect of the shift control for switching the shift stage of the automatic transmission, corresponding to FIG. 6.

FIG. 15 is a flowchart illustrating another aspect regarding control of the throttle valve opening with FIG. 16.

16 is a flowchart illustrating another aspect of controlling the throttle valve opening with FIG.

[Explanation of symbols]

20: Throttle valve 34: Transmission control computer 35: Throttle control computer 72: Brake lamp switch (brake detection means) 76: Accelerator operation amount sensor 78: Automatic transmission 82: Rotation speed sensor (vehicle speed sensor) V: Vehicle speed step SS5: Accelerator OFF determination means Steps S30, S42, S43, R3, R5, R7:
First control means Steps SS11, SS22, SS23, S41, S4
5, S46, S48: Second control means

Claims (1)

[Claims] 1. An engine braking force control device for controlling an engine braking force when an accelerator is in an OFF state in a vehicle provided with an automatic transmission for changing a gear ratio according to a predetermined gear shifting condition. An accelerator operation amount sensor for detecting an amount, a vehicle speed sensor for detecting a vehicle speed, and whether or not the accelerator operation amount is substantially equal to or less than a predetermined value equal to or less than a predetermined value based on an output signal of the accelerator operation amount sensor. When the accelerator off determination means for determining whether or not the accelerator off state is determined by the accelerator off determination means, the engine braking force is increased as the actual vehicle speed detected by the vehicle speed sensor increases. First control means for increasing and brake detection means for detecting whether or not the brake is depressed , When it is determined that the brake based on the output signal of the brake detecting means during the control of the engine braking force by the first control means is depressed, the first
An engine braking force control device comprising: a second control unit that gives priority to the control of the control unit and increases the engine braking force more than when the brake pedal is not operated.