JPH10196681A - Clutch connecting/disconnecting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prohibit the operation of a clutch to a disconnecting side during the clutch is automatically connected. SOLUTION: In a clutch connecting/disconnecting device 1 having manual connecting/disconnecting means which manually connects/disconnects a clutch 8 by the operation of a clutch pedal 9, and automatic connecting/disconnecting means which automatically connects/disconnects the clutch 8 by controlling supply and exhaust of air pressure to a booster 7, two three-way solenoid valves 78, 79 arranged in series in an air pressure supply/exhaust passage 62 leading to the booster 7, and a controller 72 by which one of the three-way solenoid valves 78, 79 is changed over to a supply side after the other thereof is changed over to an exhaust side when the clutch 8 is automatically connected, are arranged.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a clutch connecting / disconnecting device, and more particularly to a clutch connecting / disconnecting device capable of automating a vehicle clutch.

[0002]

2. Description of the Related Art The present applicant has previously described a manual connection / disconnection means for performing manual connection / disconnection of a clutch by operating a clutch pedal, and an automatic connection / disconnection means for performing automatic connection / disconnection of a clutch by controlling supply / discharge of air pressure to / from a booster. Various types of clutch disconnecting devices (so-called semi-auto clutch systems) having the following have been proposed. These features include the pneumatic supply / discharge control to the master cylinder in synchronization with automatic clutch on / off,
By driving the master cylinder with pneumatic pressure, it is possible to prevent negative pressure from being generated in the hydraulic passage during automatic interruption.

[0003] Among them, the one proposed in Japanese Patent Application No. Hei 8-301698 uses two solenoid valves for air pressure supply / discharge control.
By switching these solenoid valves in an appropriate ON / OFF combination, two types of exhaust speeds can be selected, and two types of clutch connection speeds can be selected. In this way, when the clutch is automatically connected, the engagement speed is increased from the disengaged position of the clutch to the half-clutch position (sudden engagement), the engagement speed is reduced at the half-clutch position (slow engagement), and again after the clutch is completely engaged. Control close to actual manual connection, such as increasing the connection speed (rapid connection), becomes possible.

[0004]

By the way, at the time of such automatic clutch connection, conventionally, two solenoid valves are simultaneously switched to a supply side (ON) or a discharge side (OFF) to switch the connection speed. That is, the control signals are simultaneously sent to the two solenoid valves.

However, if the operation response of the solenoid valve itself fluctuates or the output timing of the control signal varies, the operation timing of the solenoid valve also becomes inconsistent, thereby increasing the air pressure during the clutch engagement operation. In some cases, the clutch was supplied to the device and the clutch was operated to the disconnected side. The shift in the operation timing of the solenoid valve is instantaneous, but still causes a sufficient high pressure backflow, and the clutch is momentarily operated from the connection direction to the disconnection direction. This reverse operation does not cause much problem during normal light-load operation, but undesirably causes slippage of the clutch during a high-load operation and, consequently, a longer shift time.

[0006]

SUMMARY OF THE INVENTION The present invention relates to a manual connecting / disconnecting means for performing manual connection / disconnection of a clutch by operating a clutch pedal, and an automatic connection / disconnecting means for executing automatic connection / disconnection of the clutch by controlling supply / discharge of air pressure to / from a booster. In a clutch disconnecting device having disconnecting means, two three-way solenoid valves provided in series in a pneumatic supply / discharge path leading to the booster, and one of the three-way solenoid valves is discharged when the clutch is automatically connected. And a controller that switches the other to the supply side after switching to the supply side.

According to this, since switching to the discharge side of the three-way solenoid valve is prioritized, even if there is a variation in the operation timing, etc., it is absorbed, and as a result, the pneumatic backflow and the power to the booster are reduced. Pneumatic supply can be prevented, and disconnection during clutch engagement can be prevented.

[0008]

Preferred embodiments of the present invention will be described below in detail with reference to the accompanying drawings.

FIG. 1 is an overall configuration diagram showing a clutch connecting / disconnecting device according to the present invention. The clutch connecting / disconnecting device 1 has pneumatic supply means 2 for supplying pneumatic pressure. The pneumatic supply means 2
A compressor 3 which is driven by an engine (not shown) to generate air pressure (air pressure); an air dryer 4 for drying air from the compressor 3; an air tank 5 for storing air sent from the air dryer 4; 5
And a check valve 6 provided on the inlet side of the valve.
The air pressure from the air pressure supply means 2 is sent to a booster (clutch booster) 7, and the booster 7 operates the friction clutch 8 to the separating side (right side) A by supplying the air pressure. ing. The booster 7 will be described in detail later,
The hydraulic pressure is also supplied from the master cylinder 10.

FIG. 2 is a longitudinal sectional view showing details of the booster 7. The booster 7 is configured in the same manner as the conventional one. As shown, the booster 7 has a cylinder shell 12 connected to a body 11 thereof.
2, a piston plate (power piston, booster piston) 13 is provided by a return spring 14 and urged toward the pneumatic pressure introduction side (left side in the figure). A pneumatic nipple 15 is attached to one end of the cylinder shell 12,
The pneumatic nipple 15 forms a pneumatic introduction port, and introduces pneumatic pressure from the air tank 5 from a pneumatic pipe 35 (FIG. 1).
When air pressure is introduced, the piston plate 13 is pushed to the right, and when this occurs, the piston plate 13 pushes the piston rod 16, the hydraulic piston 17, and the push rod 18 to move the clutch lever 8a (FIG. 1). Push to the splitting side A to split the clutch 8.

On the other hand, a hydraulic path 20 is formed inside the body 11, and a hydraulic pressure inlet of the hydraulic path 20 is formed by a hydraulic nipple 19. One end of a hydraulic pipe 54 is connected to the hydraulic nipple 19. The hydraulic passage 20 includes a hole 21 formed at one end (lower end) of the body flange portion 11a, a hydraulic cylinder (hydraulic cylinder) 22 that accommodates the hydraulic piston 17 (formed on the body cylinder portion 11b), and a hydraulic cylinder. It is mainly formed by the control hole 23 on the other end (upper end) side communicating with the lick cylinder 22 via the small hole 23a. When the hydraulic pressure is introduced from the hydraulic nipple 19, the hydraulic pressure reaches the control hole 23 through the above passage, and pushes the control piston 24 rightward along the control cylinder 25. As described in detail later, the control valve portion 7a (hydraulic valve) for controlling the pneumatic supply to the booster 7 is provided on the upper end side of the body flange portion 11a.
Is formed.

The control valve portion 7a is defined by a control body portion 26 projecting rightward. A control chamber 27 and a pneumatic port 28 are formed in the control body 26 so as to communicate coaxially with the control cylinder 25 described above. The control section 27 of the control piston 24 is provided in the control chamber 27.
However, a poppet valve 30 is slidably accommodated in the pneumatic port 28. Nipple 3 in pneumatic port 28
The nipple 31 is provided with a pneumatic piping 67.
(FIG. 1) is connected and air pressure is always supplied.

Normally, the poppet valve 30 is urged to the left by pneumatic pressure and a poppet spring 32, and closes a communication port 33 that connects the control chamber 27 and the pneumatic port 28. Therefore, the air pressure from the nipple 31 is cut off at the position of the poppet valve 30. However, when hydraulic pressure is supplied from the hydraulic piping 54, the control unit 29 of the control piston 24 pushes the poppet valve 30 to the right to open the communication port 33. When this happens, the air pressure that has entered the control chamber 27 from the communication port 33 is
As will be described in detail later, the cylinder shell 12 enters the above-described cylinder shell 12 through pneumatic pipes 34 and 35 (FIG. 1) communicating with the control chamber 27, and acts on the pneumatic action surface 13a on the left side of the piston plate 13 to move it to the right side. The clutch 8 is pushed and the clutch 8 is operated to the disconnection side.

Here, the booster 7 can operate the clutch 8 for a predetermined stroke according to the magnitude of the supplied hydraulic pressure. That is, for example, when the hydraulic pressure is increased by a relatively small value, the piston plate 13 is pushed rightward by the above-described pneumatic action, and in conjunction with this, the hydraulic piston 17 is pushed rightward by a predetermined stroke. . Then, the volume of the hydraulic passage 20 increases and the hydraulic pressure in the control hole 23 decreases. When this happens, a balance state occurs in which the poppet valve 30 closes the communication port 33 while the control unit 29 of the control piston 24 presses the poppet valve 30. The control room 27 and the pneumatic piping 3
4, 35, and the pneumatic surface 13 of the piston plate 13
A predetermined air pressure is held in the air pressure introduction chamber 12b on the a side, the piston plate 13 is held at a predetermined stroke position, and the clutch 8 is held at a predetermined half-clutch position.

When the hydraulic pressure is completely released, the control holes 2
3, the control piston 24 is returned to the leftmost home position as shown. In this case, the control unit 29 is separated from the poppet valve 30, and the open port 36 provided inside the control unit 29 communicates with the control room 27 and the like. Then, the held air pressure is partially released from the open port 36 through the atmospheric pressure port 39 to the atmosphere chamber 12 on the opposite side of the air pressure introduction chamber 12b.
a, which in turn pushed the piston plate 13 to the right, which in turn cooperated with the return spring 14 to push it to the opposite left and actuated the clutch 8 to the connection side (left) B. The remaining air pressure is released to the atmosphere through the breather 37.

In particular, since the breather 37 has a built-in check valve capable of exhausting only, when the clutch is connected, the atmosphere chamber 12a becomes negative pressure, and a connection failure of the clutch 8 occurs. To prevent this, a part of the air pressure is released to the atmosphere chamber 12a.
And the rest must be discharged from the breather 37.

In the booster 7, reference numeral 38 denotes a seal member for partitioning the cylinder chamber 12a and the hydraulic cylinder 22 in an oil-tight manner, reference numeral 40 denotes an atmospheric pressure port, and reference numeral 41 denotes an air vent for the hydraulic oil when loosened. Breeder.

As described above, the control valve section 7a controls the supply / discharge of pneumatic pressure to / from the booster 7 based on the signal oil pressure from the master cylinder 10 interlocked with the operation of the clutch pedal 9, and Perform manual intermittent.

FIG. 3 is a longitudinal sectional view showing details of the master cylinder 10. As shown in FIG. As shown, the master cylinder 10
Has a cylinder body 45 extending in the longitudinal direction. The cylinder body 45 has a cylinder bore 46 having a predetermined diameter inside the cylinder body 45. In the cylinder bore 46, in particular, two pistons 47 and 48 are independently slidably mounted. A distal end of a push rod 49 that is inserted and withdrawn when the clutch pedal 9 is depressed or returned is inserted into one end (left end) of the cylinder bore 46, and the opening is closed by a dust boot 50. The first and second pistons 47, 4 are provided on the other end side (right side) in the cylinder bore 46.
A return spring 52 is provided for urging the piston 8 toward one end via the piston cup 51. The other end of the cylinder bore 46 communicates with a hydraulic supply port 53 formed in the cylinder body 45, and a hydraulic pipe 54 shown in FIG. 1 is connected to the hydraulic supply port 53. 53a is a check valve.

In the illustrated state, the clutch pedal 9 has not been depressed and the first and second pistons 47,
48 is located at the original position on one end side. In particular, the cylinder body 45 is provided with a pneumatic pressure introduction port 55 located between the pistons 47 and 48 at this time. In the master cylinder 10, when the clutch pedal 9 is operated manually, both pistons 47 and 48 are pushed to supply hydraulic pressure. On the other hand, in the case of automatic operation, as will be described in detail later, air pressure is supplied from the air pressure introduction port 55, and only the second piston 48 is appropriately pushed. At this time, the movement of the first piston 47 is restricted by the snap ring 56. At this time, the clutch piston 9 does not move because the first piston 47 does not move. 57 is a hydraulic oil reservoir tank 58
An oil supply nipple connected to an oil supply pipe 59 from FIG.
Reference numerals 60 and 61 denote small- and large-diameter ports for refueling the right side of the piston cup 51 and the position of the second piston 48, respectively.

As shown in FIG. 1, a pneumatic pipe 62 extends from the air tank 5, a pneumatic pipe 67 branches from a branch 63 of the pneumatic pipe 62, and the pneumatic pipe 67 is a booster. 7 is connected to the nipple 31. On the other hand, pneumatic piping 6
Numeral 2 is connected to a shuttle valve 69. In particular, two 2-way three-way solenoid valves 78 and 79 (first and second three-way solenoid valves) are provided in series on the upstream and downstream sides in the middle thereof. I have. Here, the pneumatic pipe 62 includes an upstream portion 62 a connecting the air tank 5 and the upstream three-way solenoid valve 78, and a three-way solenoid valve 78,
The intermediate portion 62b that connects the portions 79 and the downstream portion 62c that connects the downstream three-way solenoid valve 79 and the shuttle valve 69 are divided.
A pneumatic pipe 64 is connected to the exhaust side of the upstream three-way solenoid valve 78, a pneumatic pipe 74 (first pneumatic discharge path) is connected to the intermediate portion 62 b, and an exhaust side of the downstream three-way solenoid valve 79. Is connected to a pneumatic pipe 68 (second pneumatic discharge passage).

The three-way solenoid valves 78 and 79 are switch-controlled based on an ON / OFF signal (control signal) from a control device (controller) 72 built in the computer. When the three-way solenoid valve 78 on the upstream side is ON, the upstream portion 62a and the intermediate portion 62
b and the pneumatic piping 64 is closed, and when OFF, the intermediate part 62b and the pneumatic piping 64 are connected to form the upstream part 62a.
Is closed. The downstream three-way solenoid valve 79 connects the intermediate portion 62b and the downstream portion 62c to close the pneumatic piping 68 when ON, and connects the downstream portion 62c and the pneumatic piping 68 when OFF to connect the intermediate portion 62b to the pneumatic piping 68. The part 62b is closed.

As will be described in detail later, both solenoid valves 78 and 79
Is ON, the upstream portion 62a, the intermediate portion 62b, and the downstream portion 6
2c are all communicated and the air pressure of the air tank 5 is increased by the booster 7
Supplied to Thus, when the solenoid valves 78 and 79 are ON, they are switched to the supply side. Also, the solenoid valve 78,
79 indicates that the pneumatic pressure of the booster 7 is
4 and 68 to discharge to breather 37.
Is a state in which the state is switched to the discharge side.

Shuttle valve (double check valve) 69
Is a mechanical three-way valve, and connects only one of the pneumatic pipes 62 or 34 to the pneumatic pipe 35 based on a difference in pneumatic pressure between them.

On the other hand, the pneumatic pipe 68 extending from the three-way solenoid valve 79 is connected to the breather 37 of the booster 7 described above. In the middle of the pneumatic piping 68, an intermediate portion 62b
The end of a pneumatic pipe 74 extending from the end is connected. Further, the end of a pneumatic pipe 64 extending from the three-way solenoid valve 78 is connected to the pneumatic pipe 68 downstream of the connection portion (on the breather 37 side).

The pneumatic pipe 74 is provided with a restrictor 66 (first restrictor) for restricting the flow path and a check valve 75 for restricting the moving direction of pneumatic pressure in one direction. ing. The throttle portion 66 is provided on the intermediate portion 62b side, and the check valve 75 is provided on the pneumatic piping 68 side. As will be described later in detail, when the air pressure is discharged due to the automatic clutch connection, the air is exhausted from the air pressure pipe 68 toward the intermediate portion 62b.
Is located downstream, and the check valve 75 is located upstream. Further, the check valve 75 allows only the movement of the air pressure or the air from the pneumatic piping 68 side to the intermediate portion 62b side, and restricts or prohibits the movement in the reverse direction.

In the pneumatic piping 68, another restricting portion 76 (second restrictor) is provided at a position between the connecting portions of the pneumatic pipings 74 and 64. The throttle unit 76 has a larger throttle amount than the previous throttle unit 22 and further reduces the flow channel area. Here, as will be described in detail later, when the pneumatic pressure is released due to the automatic clutch connection, the exhaust is performed from the three-way solenoid valve 79 side to the breather 37 side. Piping 74
Will be located downstream of the connection part.

Further, as will be described in detail later, pneumatic pipes 62, 3 connecting the air tank 5 to the three-way solenoid valves 78, 79, the shuttle valve 69, and the pneumatic nipple 15 of the booster 7 in this order.
5 forms a first pneumatic supply path a for supplying pneumatic pressure to the booster 7 when the clutch 8 is automatically disconnected. In particular, the intermediate portion 62b and the downstream portion 62c of the pneumatic pipe 62 and the pneumatic pipe 35 are also used for pneumatic discharge from the booster 7 to form a pneumatic supply / discharge passage.

Pneumatic pipes 62, 67, 34, and 3 sequentially connecting the air tank 5 to the branch 63, the control valve section 7a, the shuttle valve 69, and the pneumatic nipple 15 of the booster 7.
5 forms a second pneumatic supply path b for supplying pneumatic pressure to the booster 7 when the clutch 8 is manually disconnected.

In particular, a pneumatic pipe 70 is connected to an intermediate portion 62b of the pneumatic pipe 62. The pneumatic pipe 70 is used for supplying pneumatic pressure to the master cylinder 10 when the clutch 8 is automatically disconnected. A third air pressure supply path c is formed.

The pneumatic pipe 70 is connected to the pneumatic introduction port 55 of the master cylinder 10 and supplies pneumatic pressure to the back side of the second piston 48. A two-way three-way solenoid valve 80 (third three-way solenoid valve) is provided in the middle of the pipe 70.
The three-way solenoid valve 80 controls supply and discharge of air pressure to and from the master cylinder 10. A pneumatic pipe 73 is connected to the exhaust side of the three-way solenoid valve 80, and an end of the pneumatic pipe 73 is connected to a downstream portion 62 c of the pneumatic pipe 62. A check valve 43 is provided in the middle of the pneumatic pipe 73. The check valve 43 allows only the movement of the pneumatic pressure from the three-way solenoid valve 80 to the downstream portion 62c, and restricts or prohibits the movement in the reverse direction. I do. By the action of the internal spring, the air pressure is allowed to move only when the air pressure on the three-way solenoid valve 80 side is higher than the air pressure on the downstream portion 62c side.

The three-way solenoid valve 80 is controlled by the controller 72.
ON / OFF control is performed, and when ON, the upstream side (the air tank 5 side) and the downstream side (the master cylinder 10 side) of the pneumatic piping 70
Are connected or communicated, and the pneumatic pipe 73 is closed. Also
When it is OFF, the downstream side of the pneumatic piping 70 and the pneumatic piping 73
And the upstream side of the pneumatic pipe 70 is closed. Thus, when ON, air pressure supply to the master cylinder 10 is permitted, and when OFF, air pressure is discharged from the master cylinder 10 and the air pressure is discharged through the air pressure pipe 73 to the pneumatic pipe 62.
To be sent. Thus, the downstream side of the pneumatic pipe 70 and the pneumatic pipe 73 constitute a pneumatic discharge passage for the master cylinder.

The clutch connecting / disconnecting device 1 is interlocked with a transmission 71 provided separately. The transmission 71 is configured to perform automatic shifting,
That is, when a gearshift position is selected by the manual shift lever, a gearshift signal by an electric switch is sent to the controller 72, and an actuator (not shown) is operated to perform a substantial gearshift operation instead of the driver's operation. Has become.

The controller 72 is provided with a stroke sensor 82 and an idle switch 83 provided on an accelerator pedal 75, an emergency switch 84 provided near a shift lever of the transmission 71, and near an output shaft of the transmission 71. Vehicle speed sensor 85, pressure switch 86 provided on air tank 5, pedal switch 87 provided on clutch pedal 9, and clutch pedal stroke sensor 8
9 and a clutch stroke sensor 88 provided on the clutch 8 and the like.

Next, the operation of the above device will be described. FIG. 4 shows each solenoid valve 78, 7 in each clutch mode.
Since 9, 80 energization patterns (ON / OFF patterns) are shown, refer to them as appropriate. In this case, the normal time is a time of manual operation, and at this time, all the solenoid valves 78, 79, 80 are turned off.

First, the manual disconnection operation of the clutch 8 is performed as follows. When the clutch pedal 9 is depressed, hydraulic pressure is supplied from the master cylinder 10, and this hydraulic pressure operates the control valve portion 7a to connect or communicate the pneumatic pipings 67 and 34 as described above. In this case, the pneumatic pressure of the pipe 34 switches the shuttle valve 69 to reach the pipe 35, and moves to the pneumatic pressure introducing chamber 12b of the booster 7. Then, the piston plate 13 is pushed and the clutch 8 is disconnected. At this time, the clutch 8 can be separated by an appropriate amount according to the operation of the clutch pedal 9.
At this time, the controller 72 determines that manual operation is performed based on a signal input (ON signal) from the pedal switch 87, and turns off the three-way solenoid valves 78, 79, and 80.
Leave as F.

On the other hand, during the manual connection operation of the clutch 8, when the hydraulic pressure is released by the return operation of the clutch pedal 9, the pneumatic piping 34 is operated by the operation of the control valve portion 7a.
And the atmospheric pressure port 39 are communicated. In this case, the air pressure in the air pressure introduction chamber 12b is introduced into the atmosphere chamber 12a via the pipes 35 and 34, and thereby the clutch 8
Connection is achieved. During this connection, the controller 72
Since the pedal switch 87 remains ON, the three-way solenoid valves 78, 79 and 80 are all kept OFF.

As can be seen, the control valve section 7a
Functions as a three-way valve that receives a hydraulic pressure signal (pilot hydraulic pressure) from the master cylinder 10 and connects the pneumatic pipe 34 to either the pneumatic pipe 67 or the atmospheric pressure port 39. Pneumatic supply means 2, a second pneumatic supply path b,
The booster 7, the control valve unit 7a, the master cylinder 10, and the hydraulic passages 54, 20 constitute a manual connection / disconnection unit that performs manual connection / disconnection of the clutch by operating the clutch pedal.

Next, the automatic on / off operation of the clutch 8 will be described. First, the contents will be briefly described including the outline of the automatic transmission.

When the driver performs a shift operation, a shift signal is input to the controller 72, and the controller 72 turns on the three-way solenoid valves 78 and 80 and subsequently turns on the three-way solenoid valve 79. In this case, the pneumatic pressure is supplied to the pneumatic pressure introduction chamber 12b of the booster 7 at a relatively high speed (in a short time) through the first pneumatic pressure supply path a, whereby the clutch 8 is immediately disconnected. (Clutch suddenly stopped). After this,
The shifting operation of the transmission 71 is completed by an actuator (not shown). After being introduced, the rest is discharged from the breather 37 and the clutch 8 is connected at a relatively high speed (high-speed connection or rapid connection of the clutch) to complete the shift.

As described in detail later, the pneumatic supply means 2, the first pneumatic supply path a, the booster 7, the three-way solenoid valves 78 and 79, and the pneumatic discharge path (pneumatic pipe 35) , 62, 64,
68, 74) and the control device 72 constitute an automatic connection / disconnection means for executing automatic connection / disconnection of the clutch 8 by controlling supply / discharge of air pressure to / from the booster 7.

Referring to FIG. 2, especially when the clutch 8 is automatically disconnected, the hydraulic piston 17 moves to the right, thereby increasing the volume of the hydraulic cylinder 22 filled with hydraulic oil. Hydraulic path 2
0 and inside the hydraulic piping 54 (collectively inside the hydraulic passage)
, A negative pressure may be generated, and air bubbles may be mixed into the hydraulic oil.

Therefore, in the present apparatus 1, at the time of the automatic disconnection operation of the clutch 8, the three-way solenoid valves 78 and 80 are turned on to supply air pressure to the master cylinder 10 through the air pressure pipes 62 and 70, and the second piston 48 is appropriately operated. By pushing, the inside of the hydraulic passage is appropriately pressurized. In this case, the negative pressure in the hydraulic passage can be prevented from occurring. At this time, unlike the case of Japanese Patent Application No. Hei 8-14536, since the gas does not pass through the check valve, there is no pressure difference between the upstream side and the downstream side, and a sufficient high pressure can be supplied to the master cylinder 10 immediately. It is possible to prevent a delay in hydraulic pressure generation and a shortage of hydraulic pressure.

In particular, in the present apparatus 1, since the pneumatic pipe 70 is connected to the pneumatic pipe 62 at a position between the three-way solenoid valves 78 and 79, the booster 7 is more capable of supplying air than the pneumatic supply to the master cylinder 10.
Pneumatic supply can be delayed. That is, at the time of the automatic disconnection operation of the clutch 8, first, the three-way solenoid valves 78 and 80 are turned on.
When the three-way solenoid valve 79 is turned on with a predetermined time difference (for example, 50 ms), the operation of the booster 7 (the piston plate 13) is performed after a sufficient hydraulic pressure is generated from the master cylinder 10 (that is, after the preload is performed). Movement) can be started. As a result, the generation of the hydraulic pressure by the master cylinder 10 is hastened, and the negative pressure in the hydraulic passage can be completely prevented. At extremely low temperatures (for example, -20 ° C. or lower), the oil pressure generation tends to be delayed, and such a configuration is very advantageous at this time.

On the other hand, at the time of the automatic connection operation of the clutch 8, in such a device, three types of clutch connection speeds can be particularly selected by a combination of ON / OFF of the three-way solenoid valves 78 and 79.

That is, the three-way solenoid valve 78 is
When the three-way solenoid valve 79 is ON, the pneumatic pressure in the pneumatic introduction chamber 12 b of the booster 7 is reduced by the pneumatic piping 35 and the shuttle valve 6.
9, the downstream part 62c, the three-way solenoid valve 79, the intermediate part 62b, the three-way solenoid valve 78, the pneumatic pipe 64, the pneumatic pipe 68, and the breather 37 move sequentially. Since there is no throttle on this route, the movement is performed promptly, and the movement of the pneumatic pressure entering the pneumatic pipe 74 from the intermediate portion 62b is regulated by the check valve 75. Most of the air pressure reaching the breather 37 is introduced into the atmosphere chamber 12a of the booster 7. Thereby, the piston plate 13 of the booster 7 is
In addition to the biasing force of the return spring 14 and the return spring (not shown) of the clutch 8, the clutch returns to the original position at a relatively high speed by the action of pneumatic pressure and operates the clutch 8 at a relatively high speed. (Clutch high-speed connection).
Then, the excess air pressure is released from the breather 37 to the atmosphere.

Further, the three-way solenoid valves 78 and 79 are both OF
In the case of F 2, the pneumatic pressure discharged from the booster 7 is supplied to the pneumatic pipe 35, the shuttle valve 69, the downstream portion 62 c, the three-way solenoid valve 7.
9, pneumatic piping 68, pneumatic piping 74, intermediate portion 62b, three-way solenoid valve 78, pneumatic piping 64, pneumatic piping 68, breather 3
It will mainly move along the route 7. Here, the air pushes and opens the check valve 75 in the pneumatic pipe 74, and then passes through the throttle section 66. At this time, the aperture 66
Is relatively small (large flow path area), the air is only slightly decelerated. A part of the air in the pneumatic piping 68 does not branch to the pneumatic piping 74 and reaches the throttle portion 76 as it is. However, since the throttle amount is relatively large (the flow passage area is small), the air in the throttle portion 76 is reduced. The passing speed of
6 slower than that at 6. Thus, the throttle unit 7
The air that has passed through 6 merges with the air that has flowed through the pneumatic piping 64, and as a result, the pneumatic discharge speed passes through a restrictor having a flow area that is equal to the flow area of the restrictors 76 and 66. It is almost equal to the speed at the time. Then, the air pressure is moved to the breather 37 at a medium speed, and the return speed of the piston plate 13 and the connection speed of the clutch 8 also become the medium speed (medium clutch engagement).

When the three-way solenoid valve 78 is ON and the three-way solenoid valve 79 is OFF, the pneumatic pressure discharged from the booster 7 is reduced by the pneumatic piping 35, the shuttle valve 69, the downstream portion 62c, the three-way solenoid valve 79, It moves along the path of the pneumatic piping 68 and the breather 37. Here, the pneumatic piping 68 to the pneumatic piping 74
However, the movement of the flow is restricted by the check valve 75 for the following reason. That is, since the three-way solenoid valve 78 is ON, the pneumatic pressure of the air tank 5 is moved through the route of the upstream portion 62a, the three-way solenoid valve 78, the intermediate portion 62b, and the pneumatic piping 74. Then, the air pressure holds the check valve 75 in the closed state, whereby the flow in the backward flow direction is prohibited. On the other hand, since the pneumatic piping 68 has a throttle portion 76 with a large throttle amount, the piping 68
The inside flow is greatly decelerated by the throttle section 76 and the breather 37
Will be reached. Eventually, the pneumatic discharge speed is reduced
The air pressure is moved to the breather 37 at a low speed, and the return speed of the piston plate 13 and the connection speed of the clutch 8 are also low (the clutch is in the low-speed engagement).

In this manner, three types of clutch connection speeds can be selected by the two three-way solenoid valves 78 and 79. In particular, two types of slow connection speeds such as medium speed and low speed can be selected, and the degree of freedom of control can be increased. become. As a result, the optimum connection speed can be switched in all driving modes, the clutch connection shock can be reduced, and it is possible to cope with the aging of clutch wear and the like, and tuning becomes easy.

Further, since this is achieved by the same number of two solenoid valves as in the prior art, an increase in cost due to an increase in the number of solenoid valves can be avoided. Here, there are 2 × 2 = 4 combinations of ON / OFF of the two solenoid valves, and in Japanese Patent Application No. 7-337023, only three of them are used, but this device 1 uses all of them. As a result, the above effect is achieved. Since the number of solenoid valves does not change, it is not necessary to newly provide an output port of the controller 72 and a space for installing the solenoid valves, and it is possible to prevent an increase in failure modes and maintain reliability. Furthermore, since only the pneumatic circuit is changed by adding the pneumatic piping, the throttle, and the check valve, the cost increase accompanying the change is small and the space is not increased.

By the way, in the present apparatus 1, when switching from the other clutch mode to the clutch high-speed connection or the low-speed connection, one of the three-way solenoid valves 78 and 79 is turned off by outputting a control signal with a predetermined time difference. Later, the other is turned on.

That is, as shown in FIG. 5, for example, the three-way solenoid valves 78 and 79 are turned OFF and ON from the ON and OFF states (low speed connection).
In the case of switching to the state (high-speed connection), when the control signal is simultaneously output at time t ₀ and switching is started as in the conventional case, the electromagnetic valve 78 is turned off due to a variation in the operation timing of the electromagnetic valves 78 and 79. Then, the solenoid valve 79 may be turned on. That is, from time t ₀ , the solenoid valve 79
The time Δt ₁ before turning on may be shorter than the time Δt ₂ from time t ₀ until the solenoid valve 78 turns off.

When this happens, all the pneumatic pipes 62 are in communication with each other, and the pneumatic supply to the booster 7 is executed for a moment, and the clutch 8 is operated to the disengaged side even though the clutch is connected. Will be done. This is also true when the ON / OFF relationship is reversed, that is, as shown in FIG.
Even when 79 is switched from the OFF / ON state (high-speed connection) to the ON / OFF state (low-speed connection), an operation to the disconnection side as indicated by a broken line is executed for a moment.

[0054] Therefore, in the present apparatus 1, as shown in FIG. 6, firstly outputs the OFF control signal at time T ₁ to the solenoid valve 78 to be (OFF signal), after the lapse of a predetermined time [Delta] T, ON the solenoid valve 79 to be a, and outputs a control signal (oN signal) at time T _2. As a result, after the solenoid valve 78 is actually turned off, the solenoid valve 79 can be switched on, and after the pneumatic supply is shut off, the exhaust is performed to completely prevent the clutch 8 from being operated to the disengaged side. Can be. Also, in the case where the ON / OFF relationship is reversed as in the example of FIG. 7, by giving priority to the OFF of the solenoid valve 79, the operation of disengaging the clutch 8 is prevented as shown by the solid line, and as designed. Can reliably be achieved.

After all, in the case of high-speed clutch engagement, the three-way solenoid valve 78 may be turned off and then the three-way solenoid valve 79 may be turned on.
In the case of low-speed clutch engagement, the three-way solenoid valve 79 may be turned off and then the three-way solenoid valve 78 may be turned on. It is preferable that the time difference ΔT is a time capable of absorbing a variation in the operation timing of the solenoid valves 78 and 79 and a variation in the output timing of the control signal, for example, 50 ms. When one of the solenoid valves 78 and 79 is kept OFF, for example, when shifting from medium-speed connection to high-speed connection, operation of the clutch 8 to the disengaged side is prevented without intentionally executing such control. You.

By the way, when the clutch 8 is automatically connected, there is substantially no air flow flowing into the pneumatic pipe 70 from the intermediate portion 62b of the pneumatic pipe 62. This is because the three-way solenoid valve 8 is simultaneously switched with the solenoid valves 78 and 79 as described above.
This is because 0 is turned off.

That is, when the three-way solenoid valve 80 is turned off,
The movement of the air pressure toward the master cylinder 10 is prohibited, and the air pressure is simultaneously discharged from the master cylinder 10. Then, the air pressure passes through the check valve 43 through the air pressure pipe 73, and then joins with the discharge air pressure from the booster 7 in the downstream portion 62 c of the air pressure pipe 62. After the merging, the same route as the pneumatic discharge route is followed.

In this manner, the air pressure discharged from the master cylinder 10 (master cylinder discharge pressure) is made equal to the air pressure discharged from the booster 7 (power booster discharge pressure). That is, the exhaust pressures can be synchronized, and the air exhaust speeds can be adjusted automatically. In particular, the check valve 43 can maintain the master cylinder discharge pressure always higher than the booster discharge pressure, and the discharge speed of the master cylinder 10 can always be slower than the discharge speed of the booster 7. As a result, the second piston 48 of the master cylinder 10 can be constantly pressurized while the clutch is engaged without any special adjustment or the like for adjusting the discharge speed, thereby completely preventing negative pressure in the hydraulic passage. become able to.

On the other hand, such a configuration is characterized in that two three-way solenoid valves 78 and 79 are provided in series with the pneumatic piping 62. That is, for example, if the upstream three-way solenoid valve 78
Is kept ON due to a trouble such as a short circuit. In this case, if the three-way solenoid valve 79 on the downstream side is turned off, the pneumatic pressure from the three-way solenoid valve 78 on the upstream side can be cut off, and the pneumatic pressure can be discharged from the booster 7, whereby the clutch 8 is automatically connected. After that, the clutch can be manually engaged / disengaged.

It is assumed that the downstream three-way solenoid valve 7 is
It is assumed that 9 keeps on due to a trouble such as a short circuit. Similarly, in this case, if the three-way solenoid valve 78 on the upstream side is turned off, the air pressure from the air tank 5 is shut off at that position, and the air pressure from the booster 7 is discharged through the pipes 64 and 68. The clutch 8 can be automatically connected. Thereafter, manual clutch operation can be performed. The three-way solenoid valve 80 is synchronized with the exhaust of the booster 7.
Must also be turned OFF, and the exhaust on the master cylinder side must be executed.

As described above, when the three-way solenoid valves 78 and 79 are provided in series, even if a trouble occurs in one, the pneumatic supply control is stopped in the other, and the clutch 8 is shifted to the connected state by performing exhaust. Can be. As a result, the clutch can be switched on and off by manual operation, and a reliable fail-safe can be achieved. In addition, traveling can be performed, and the reliability of the device can be reliably improved. In particular, since both of them are three-way solenoid valves, it is advantageous in that the exhaust passage (pneumatic piping 64 or 68) can be switched as compared with the case where a two-way solenoid valve is employed. The above-mentioned fail-safe, switching of the exhaust speed (clutch connection speed), and further, pneumatic supply / discharge control of the master cylinder 10 can be covered by the two solenoid valves. And it is very advantageous in terms of cost. The three-way solenoid valve 80
Keeps ON, turns off the upstream three-way solenoid valve 78
You can do it.

Next, another embodiment will be described.

As shown in FIG. 8, a part of the pneumatic circuit is changed in this embodiment. That is, here, the pneumatic pipes 73 and 74, the check valve 75, the throttle section 76, and the three-way solenoid valve 80 according to the above embodiment are removed,
A relatively simple configuration is employed.

The pneumatic pipe 70 is located downstream of the pneumatic pipe 62.
c, a branch section 42 is provided in the middle of the pipe 70, and the branch pipes 42a, 42b of the branch section 42 are provided.
Are provided in parallel with check valves 43a and 43b for restricting the moving direction of the air pressure to one side. One check valve 43a inhibits pneumatic movement from the downstream portion 62c to the master cylinder 10, and the other check valve 43b inhibits pneumatic movement from the master cylinder 10 to the downstream portion 62c. And, for example, for one check valve 43a,
Due to the action of the internal spring, the movement of the air pressure is permitted only when the air pressure on the master cylinder 10 side becomes higher than the air pressure on the downstream portion 62c side. The check valve 43b allows pneumatic supply to the master cylinder 10.

The throttle section 66 is provided in the pneumatic pipe 64. With the pneumatic pipe 74 and the throttle section 76 being eliminated, two types of clutch connection speeds can be selected here. The throttle amount of the throttle section 66 here is appropriately changed because the clutch loose connection speed is one type.

In this case, the clutch mode and the energization pattern of each of the three-way solenoid valves 78 and 79 are as shown in FIG. The same applies to normal (manual) operation and sudden clutch disconnection.

When the clutch is suddenly connected, the three-way solenoid valve 78 is turned on.
9 is OFF, and at this time, the booster exhaust pressure is
After merging with the master cylinder exhaust pressure at 2c, the air moves to the breather 37 via the three-way solenoid valve 79 and the pneumatic piping 68. At this time, since it does not pass through the throttle section 66, the moving speed is high and the clutch connection speed is also high. At this time, the three-way solenoid valve 78 may be off.

When the clutch is loosely connected, the three-way solenoid valve 78
OFF and 79 are ON. At this time, after the booster exhaust pressure merges with the master cylinder exhaust pressure at the downstream portion 62c, the three-way solenoid valve 79, the intermediate portion 62b, the three-way solenoid valve 78, the pneumatic piping 64 , And moves to the breather 37 via the pneumatic piping 68. In order to pass through the throttle section 66 in the pneumatic pipe 64,
The moving speed is reduced, and the clutch connection speed becomes low.

Even in such a case, the three-way solenoid valves 78, 7
After turning off one of the nine, the other with a predetermined time difference
If it is set to ON, disconnection operation during clutch connection due to variation in operation is prevented, whereby unexpected clutch operation, prolonged shift time, clutch slippage, and the like can be prevented, and smooth clutch connection can be achieved.

Note that the present invention can naturally adopt other embodiments. Such a configuration can also be applied to a control device for a hydraulic actuator. At this time, the working fluid is not limited to air or oil, but may be another gas or liquid. The pressure may be a positive pressure or a negative pressure, and the time difference between the operation of the solenoid valves is not limited to the above-described value.

[0071]

In summary, the present invention has an excellent effect that the clutch can be prevented from being operated to the disengaged side during the automatic clutch connection, and the clutch can be prevented from slipping and the shift time can be lengthened.

[Brief description of the drawings]

FIG. 1 is an overall configuration diagram showing a clutch connecting / disconnecting device according to the present invention.

FIG. 2 is a longitudinal sectional view showing a booster.

FIG. 3 is a longitudinal sectional view showing a master cylinder.

FIG. 4 is a table showing a relationship between a clutch mode and an energization pattern of a solenoid valve according to the clutch connecting / disconnecting device of FIG. 1;

FIG. 5 is a time chart showing a conventional method of controlling an electromagnetic valve.

FIG. 6 is a time chart showing a control method of the solenoid valve of the present invention.

FIG. 7 is a diagram showing a state of automatic clutch connection.

FIG. 8 is an overall configuration diagram showing another embodiment of the clutch connecting / disconnecting device according to the present invention.

FIG. 9 is a table showing a relationship between a clutch mode and an energization pattern of a solenoid valve according to the clutch connecting / disconnecting device of FIG. 8;

[Explanation of symbols]

 DESCRIPTION OF REFERENCE NUMERALS 1 clutch intermittent device 2 pneumatic pressure supply means 7 booster device 7a control valve unit 8 clutch 9 clutch pedal 10 master cylinder 20 hydraulic path 34, 35, 62, 64, 67, 68 pneumatic pipe 54 hydraulic path 72 controller 78, 79 Three-way solenoid valve a First pneumatic supply path b Second pneumatic supply path

 ──────────────────────────────────────────────────の Continuing from the front page (72) Inventor Masaaki Nishigami 8 Tsuchiya, Fujisawa City, Kanagawa Prefecture Isuzu Central Research Institute Co., Ltd.

Claims (1)

[Claims] 1. A clutch connecting / disconnecting means having manual connecting / disconnecting means for performing manual connection / disconnection of a clutch by operating a clutch pedal, and automatic connecting / disconnecting means for performing automatic connection / disconnection of the clutch by controlling supply / discharge of air pressure to / from a booster. In the device, two three-way solenoid valves provided in series in a pneumatic supply / discharge path leading to the booster, and at the time of automatic connection of the clutch,
And a controller that switches one of the three-way solenoid valves to the discharge side and then switches the other to the supply side.