JP5500387B2 - Idle stop hydraulic control device for automatic transmission - Google Patents

Description

  The present invention relates to an idle stop hydraulic control device for an automatic transmission.

  2. Description of the Related Art There is known an automatic transmission that adjusts an output generated by an internal combustion engine according to a driving condition of a vehicle and transmits the output to driving wheels of the vehicle. In an automatic transmission, a shift for adjusting the output of an engine is performed by selectively engaging or releasing a plurality of friction elements such as a clutch and a brake. The automatic transmission includes a spool valve that supplies working fluid to a plurality of friction elements and a switching valve that switches a passage connected to the spool valve. The switching valve selectively switches the path for a plurality of working fluids supplied from the outside, and switches the supply source of the working fluid applied to the friction element connected to the spool valve. Patent Document 1 describes a hydraulic control device for an automatic transmission that can drain the hydraulic pressure acting on the clutch by turning off the spool valve when the working fluid is continuously supplied to the spool valve due to a failure of the switching valve. ing.

JP 2010-175038 A

  However, in the hydraulic control device for an automatic transmission described in Patent Document 1, when the spool valve fails, the spool valve can only supply a low-pressure working fluid to the friction element, and cannot start in the low speed range of the vehicle.

  An object of the present invention is to provide an idle stop hydraulic control device for an automatic transmission which can start in a low speed range using an electric pump for idle stop when a spool valve fails.

According to the first aspect of the present invention, the spool valve provided in the automatic transmission idle stop hydraulic control device supplies the working fluid to the friction element contributing to the start of the plurality of friction elements. Mechanical and electric pumps supply pressurized working fluid to the spool valve. The first switching valve is provided between the spool valve and the electric pump, supplies the working fluid discharged from the electric pump to the spool valve, and discharges the working fluid remaining in the spool valve.
The spool valve is composed of a sleeve and a spool fitted into the sleeve. The sleeve is a supply port that supplies a working fluid from a mechanical pump, a connection port that discharges the working fluid to the outside or supplies a working fluid from an electric pump, and a friction element that contributes to starting of a plurality of friction elements. An output port for outputting a working fluid is provided. The spool fitted into the sleeve is accommodated so as to be able to reciprocate with respect to the sleeve, and selectively switches communication between the output port and the supply port or communication between the output port and the connection port according to displacement of the sleeve in the axial direction. The mechanical pump is mechanically driven by an internal combustion engine. On the other hand, the electric pump is electrically driven regardless of whether the internal combustion engine is operated or stopped. The first switching valve performs switching operation for selectively switching communication between the connection port of the spool valve and the discharge port of the electric pump or communication between the connection port and the storage tank storing the working fluid in the discharge port of the electric pump. This is done by pressure. Further, when the vehicle is in the forward range where the vehicle can move forward, the internal combustion engine is in operation, and the spool valve communicates the output port and the connection port, the electric pump is driven.

  The spool valve introduces the working fluid discharged from the mechanical pump into the inside from the supply port, and outputs the working fluid to the friction element contributing to the start of the plurality of friction elements via the output port. At this time, in order to engage or release the friction element, the spool valve adjusts the pressure of the working fluid supplied to the friction element as follows. When supplying a high-pressure working fluid, the supply port and output port of the spool valve are communicated. Thereby, the high-pressure working fluid discharged from the mechanical pump is supplied to the hydraulic chamber of the friction element, and the friction element is engaged. On the other hand, when supplying a low-pressure working fluid, the output port of the spool valve is connected to the connection port. Thereby, the working fluid staying in the hydraulic pressure chamber of the friction element is discharged via the connection port of the spool valve, and the friction element is opened. In order to achieve advancement in the low speed range of the vehicle, the supply port and the output port of the spool valve are communicated with each other in order to engage a friction element that contributes to starting. However, when the spool valve fails in a state where the output port and the connection port communicate with each other, only the low-pressure working fluid is supplied to the friction element. At this time, by driving the electric pump, the first switching valve performs a switching operation to connect the connection port of the spool valve and the discharge port of the electric pump by the pressure of the working fluid discharged from the electric pump. The friction element is supplied with high-pressure working fluid discharged from the electric pump from the connection port via the output port. Thereby, even when the spool valve is out of order, a high-pressure working fluid can be supplied to the friction element that contributes to starting.

According to the invention described in claim 2, when the idle stop hydraulic control device for an automatic transmission is in the forward range and the internal combustion engine stops, the spool valve communicates the output port and the connection port, And the electric pump is driven.
In the forward range and when the internal combustion engine is stopped, i.e., when idling is stopped, the mechanical pump mechanically driven by the internal combustion engine is stopped. At this time, the spool valve communicates the output port and the connection port to drive the electric pump. Thereby, since the discharge port of the electric pump and the hydraulic chamber of the friction element communicate with each other, the working fluid discharged from the electric pump can be supplied to the hydraulic chamber of the friction element. Therefore, when the vehicle is idling stop, high-pressure working fluid can be supplied to the friction element that contributes to starting.

According to the third aspect of the present invention, the electric pump of the idle stop hydraulic control device for an automatic transmission can be driven in reverse, and can reverse the suction and discharge of the working fluid by the reverse drive. is there. When the connection port of the spool valve and the discharge port of the electric pump remain in communication and the pressure in the communication path connecting the connection port and the discharge port is low, the electric pump is driven in reverse to Aspirate the working fluid.
The first switching valve performs a switching operation of communicating the connection port of the spool valve and the discharge port of the electric pump by applying the pressure of the working fluid discharged from the electric pump. However, when the first switching valve is in communication with the connection port of the spool valve and the discharge port of the electric pump due to a failure, the working fluid is not discharged even if the output port of the spool valve and the connection port communicate with each other. Therefore, the low-pressure working fluid cannot be supplied to the friction element. At this time, the working fluid staying in the communication path that connects the connection port of the spool valve and the discharge port of the electric pump is sucked by the electric pump that can be driven in reverse. Thereby, it is possible to adjust the pressure inside the spool valve to a pressure necessary for releasing the friction element contributing to the forward movement. Therefore, when the first switching valve fails, the working fluid can be discharged and the working fluid having a pressure required to open the friction element can be supplied. In addition, by sucking the working fluid, it is possible to remove clogging of foreign matter that causes the failure of the first switching valve.

According to the fourth aspect of the present invention, the first switching valve has one end connected to a communication path that connects the connection port of the spool valve and the electric pump, and the other end that can be connected to a storage tank that stores the working fluid. A working fluid discharge passage having An orifice is provided in the working fluid discharge passage.
The first switching valve performs a switching operation of communicating the connection port of the spool valve and the discharge port of the electric pump by applying the pressure of the working fluid discharged from the electric pump. However, when the first switching valve is in communication with the connection port of the spool valve and the discharge port of the electric pump due to a failure, the working fluid is not discharged even if the output port of the spool valve and the connection port communicate with each other. Therefore, the low-pressure working fluid cannot be supplied to the friction element. At this time, the working fluid staying in the communication passage is discharged to the storage tank by the working fluid discharge passage having one end connected to the communication passage. The working fluid discharge passage is provided with an orifice for controlling the amount of the working fluid passing through the working fluid discharge passage. Thus, when a high-pressure working fluid is supplied to the friction element by the electric pump, the amount of the working fluid discharged from the working fluid discharge passage is small, and thus does not affect the driving of the electric pump. Thereby, it is possible to adjust the pressure inside the spool valve to a pressure necessary for releasing the friction element contributing to the forward movement. Therefore, when the first switching valve fails, the working fluid can be discharged and the working fluid having a pressure required to open the friction element can be supplied.

According to the fifth aspect of the present invention, the spool valve provided in the automatic transmission idle stop hydraulic pressure control device supplies the working fluid to the plurality of friction elements for shifting the vehicle. Mechanical and electric pumps supply pressurized working fluid to the spool valve. The first switching valve provided between the spool valve and the electric pump supplies the working fluid discharged from the electric pump to the spool valve, and discharges the working fluid remaining in the spool valve. The second switching valve provided between the mechanical pump and the first switching valve is configured to switch the first switching valve in a direction in which the electric pump and the connection port are blocked by the pressure discharged from the mechanical pump. Is supplied with a working fluid.
The spool valve is composed of a sleeve and a spool fitted into the sleeve. The sleeve is a supply port that supplies a working fluid from a mechanical pump, a connection port that discharges the working fluid to the outside or supplies a working fluid from an electric pump, and a friction element that contributes to starting of a plurality of friction elements. An output port for outputting a working fluid is provided. The spool fitted into the sleeve is accommodated so as to be able to reciprocate with respect to the sleeve, and selectively switches communication between the output port and the supply port or communication between the output port and the connection port according to displacement of the sleeve in the axial direction. The mechanical pump is mechanically driven by an internal combustion engine. On the other hand, the electric pump is electrically driven regardless of whether the internal combustion engine is operated or stopped. The first switching valve performs a first switching operation for selectively switching communication between the connection port of the spool valve and the discharge port of the electric pump or communication between the connection port and the storage tank storing the working fluid. This is done by the port pressure. The second switching valve performs a second switching operation for selectively switching communication between the connection passage connected to the pressure accumulating chamber formed in the first switching valve and the mechanical pump or communication between the connection passage and the storage tank.
According to the sixth aspect of the present invention, when the vehicle is in a forward range in which the vehicle can advance, the internal combustion engine is in operation, and the spool valve communicates the output port and the connection port, the electric pump Drive.

  In the first switching valve, the connection port of the spool valve and the electric pump communicate with each other when the electric pump discharges the working fluid to the first switching valve. Thereby, the working fluid discharged from the electric pump is supplied to the friction element. However, when the electric pump is driven by a failure of the electric pump while the connection port of the spool valve and the discharge port of the electric pump are in communication, a low-pressure working fluid cannot be supplied to the friction element. At this time, the connection passage connected to the pressure accumulation chamber of the first switching valve and the mechanical pump are connected by the second switching valve, so that the working fluid discharged from the mechanical pump flows through the connection passage. The first switching valve performs the first switching operation by the pressure of the hydraulic oil discharged from the mechanical pump flowing into the connection passage, and connects the connection port of the spool valve and the storage tank. Thereby, the working fluid in the spool valve is discharged to the storage tank. Therefore, even when both the spool valve and the electric pump are out of order, the working fluid in the spool valve can be discharged and the low-pressure working fluid can be supplied to the friction element.

1 is a schematic diagram of a vehicle using an idle stop hydraulic control device for an automatic transmission according to a first embodiment of the present invention. 1 is a configuration diagram of an idle stop hydraulic control device for an automatic transmission according to a first embodiment of the present invention. FIG. It is a block diagram of the idle stop hydraulic pressure control apparatus for automatic transmissions by 1st Embodiment of this invention, and is a figure which shows the operation state different from FIG. 3 is a combination pattern table of a shift range and a clutch and a brake of an automatic transmission in the idle stop hydraulic control apparatus for an automatic transmission according to the first embodiment of the present invention. It is a table | surface which shows the relationship between the state of the linear solenoid valve in the idle stop hydraulic pressure control apparatus for automatic transmissions by 1st Embodiment of this invention, and the instruction | command to an electric pump. It is a table | surface which shows the relationship between the state of the electric pump in the idle stop hydraulic pressure control apparatus for automatic transmissions by 1st Embodiment of this invention, and the command to a linear solenoid valve. It is a table | surface which shows the influence when the 1st switching valve fails in the idle stop hydraulic pressure control apparatus for automatic transmissions by 1st Embodiment of this invention. It is a table | surface which shows the influence when the 1st switching valve in the idle stop hydraulic pressure control apparatus for automatic transmissions by 1st Embodiment of this invention fails, and is a table | surface which shows a failure state different from FIG. It is a block diagram of the idle stop hydraulic control apparatus for automatic transmissions by 2nd Embodiment of this invention. It is a block diagram of the idle stop hydraulic pressure control apparatus for automatic transmissions by 2nd Embodiment of this invention, and is a figure which shows the operation state different from FIG. It is a table | surface which shows the influence when the switching valve in the idle stop hydraulic pressure control apparatus for automatic transmissions by 2nd Embodiment of this invention fails. It is a block diagram of the idle stop hydraulic control apparatus for automatic transmissions by 3rd Embodiment of this invention. It is a block diagram of the idle stop hydraulic pressure control apparatus for automatic transmissions by 3rd Embodiment of this invention, and is a figure which shows the operation state different from FIG. It is a table | surface which shows the relationship between the state of the linear solenoid valve in the idle stop hydraulic pressure control apparatus for automatic transmissions by 3rd Embodiment of this invention, and the instruction | command to an electric pump. It is a table | surface which shows the relationship between the state of the electric pump in the idle stop hydraulic pressure control apparatus for automatic transmissions by 3rd Embodiment of this invention, and the command to a linear solenoid valve. It is a table | surface which shows the influence when the 2nd switching valve fails in the idle stop hydraulic pressure control apparatus for automatic transmissions by 3rd Embodiment of this invention. It is a table | surface which shows the influence when the 2nd switching valve in the idle stop hydraulic pressure control apparatus for automatic transmissions by 3rd Embodiment of this invention fails, and is a table | surface which shows a failure state different from FIG. It is a block diagram of the idle stop hydraulic pressure control apparatus for automatic transmissions by 4th Embodiment of this invention.

Hereinafter, an idle stop hydraulic control apparatus for an automatic transmission according to an embodiment of the present invention will be described with reference to the drawings.
(First embodiment)
1 to 8 show an idle stop hydraulic control apparatus for an automatic transmission according to a first embodiment of the present invention.
FIG. 1 shows a state where an automatic transmission 2 including an idle stop hydraulic control device for an automatic transmission is mounted on a vehicle. The automatic transmission 2 adjusts the output generated by the engine 1 from the shift range selected by the driver, which is input by the shift lever 11, and transmits the adjusted output to the drive wheels 3 of the vehicle.

  The automatic transmission idle stop hydraulic control device included in the automatic transmission 2 includes a mechanical pump unit 10, an electric pump unit 40, and a linear solenoid valve 20, and controls the clutch 30. 2 is a view showing a state in which the first switching valve 46 communicates with the connection port 21a of the linear solenoid valve 20 and the storage tank 17, and FIG. 3 shows that the first switching valve 46 is connected to the linear solenoid valve 20. It is a figure which shows the state which has connected the discharge port 41a of the electric pump 41. FIG. The linear solenoid valve 20 corresponds to a “spool valve” recited in the claims.

  The clutch 30 functions as a friction element of the automatic transmission 2. The automatic transmission 2 includes three types of clutches and two types of brakes. As shown in FIG. 4, the automatic transmission 2 realizes a predetermined shift range from a combination of a plurality of clutches and brakes. For example, when the shift range is set to the first forward range D1 in which the vehicle can advance at a low speed, it is realized by engaging the first clutch C1 and the second brake B2, respectively. The clutch 30 of the first embodiment of the present invention is a first clutch C1 that is used in a low speed range from a first forward range D1 to a fourth forward range D4. The clutch 30 corresponds to a “friction element contributing to advancing” described in the claims.

  The clutch 30 is provided inside the automatic transmission and constitutes a multi-plate clutch. The clutch 30 has a plurality of clutch disks 31 and 32 that overlap in the axial direction. An engagement state is created by the clutch disks 31 and 32.

  In the clutch 30, the shaft portion 33 is assembled so as to pass through the cylindrical base portion 34. The base portion 34 is provided with a disk-like bottom portion 34a extending outward in the radial direction, and clutch disks 31 and 32 are disposed inside an outer portion 34b that is an outer portion continuous to the bottom portion 34a. A disc-shaped clutch piston 35 is supported on the base portion 34 so as to be reciprocally movable in the axial direction. Here, a piston chamber 36 is formed between the clutch piston 35 and the bottom 34a.

  A disc-shaped locking portion 34c is formed at the end of the base portion 34 opposite to the bottom portion 34a. The locking portion 34c is located just inside the clutch disks 31 and 32 in the radial direction. A clutch spring 37 is provided between the locking portion 34 c and the clutch piston 35. As a result, the clutch piston 35 is urged toward the bottom 34a.

  The hydraulic fluid is supplied to the piston chamber 36 via an oil passage 33 a formed in the shaft portion 33. As a result, when the hydraulic pressure in the piston chamber 36 increases and the urging force of the clutch spring 37 is overcome, the clutch piston 35 moves away from the bottom 34a. When the clutch piston 35 comes into contact with the clutch disk 31 and presses the clutch disk 31, the clutch disks 31 and 32 are engaged.

  The linear solenoid valve 20 includes a sleeve 21, a spool 23, and an electromagnetic force generator 22 as shown in FIGS. 2 and 3. The sleeve 21 is formed with a connection port 21a, an output port 21b, a supply port 21c, and a self-pressure adjusting port 21d from the electromagnetic force generation unit 22 side.

The connection port 21a is connected to a first connection pipe 48 that is connected to an electric pump unit 40 described later. The first connection pipe 48 discharges the hydraulic oil to the oil pan 17 as a “reservoir” via the first switching valve 46. Further, the hydraulic oil discharged from the electric pump 41 passes through the first connection pipe 48 and enters the linear solenoid valve 20. Details will be described later.
An output pipe 29 connected to the clutch 30 is connected to the output port 21b. The output pipe 29 is connected to an oil passage 33 a formed in the shaft portion 33 of the clutch 30. As a result, the hydraulic oil is supplied from the output pipe 29 to the piston chamber 36 via the oil passage 33a. A branch pipe 291 is formed in the middle of the output pipe 29 so as to branch. The branch pipe 291 is connected to the self-pressure adjusting port 21d.
A supply pipe 18 is connected to the supply port 21c. The supply pipe 18 is a pipe that supplies hydraulic oil from the manual valve 13 to the linear solenoid valve 20.

  The sleeve 21 accommodates a spool 23 that can reciprocate in the axial direction. The spool 23 communicates with a predetermined port among the connection port 21a, the output port 21b, and the supply port 21c by displacement in the axial direction.

  Specifically, when the spool 23 is displaced in a direction away from the electromagnetic force generation unit 22 (hereinafter referred to as “high pressure setting”), the supply port 21c and the output port 21b communicate with each other. Further, when the actuator is displaced in a direction approaching the electromagnetic force generator 22 (hereinafter referred to as “low pressure setting”), the output port 21b and the connection port 21a communicate with each other. At the intermediate position, there is an overlap region where neither the supply port 21c nor the connection port 21a communicates with the output port 21b.

  A return spring 231 is provided on the front end side of the spool 23, and the spool 23 is urged to a low pressure setting by the return spring 231. Further, the hydraulic oil from the output port 21b is supplied to the self-pressure adjusting port 21d via the branch pipe 291, and the spool 23 is biased to the low pressure setting by the pressure of the hydraulic oil from the output port 21b.

  The electromagnetic force generation unit 22 includes a coil 24, a movable unit 25, a fixed unit 26, a connector 27, and the like. The movable part 25 is supported inside the cylindrical fixed part 26 so as to be movable in the axial direction. The coil 24 is disposed around the fixed portion 26. Further, the linear solenoid valve TCU 28 is electrically connected through the connector 27.

The linear solenoid valve TCU28 includes a microcomputer and a drive circuit. The linear solenoid valve TCU28 outputs a drive current based on the command signal. When the coil 24 is energized by this drive current, an electromagnetic attractive force for setting the high pressure acts on the movable portion 25. Thereby, the movable part 25 urges the spool 23 to the high pressure setting.
The microcomputer that constitutes the linear solenoid valve TCU28 executes various control programs to calculate a command signal having the target hydraulic pressure value as a command value. The drive circuit outputs a drive current for driving the electromagnetic force generator 22 based on the calculated command signal.

  The mechanical pump unit 10 includes a shift lever 11, a spool 12, a manual valve 13, a mechanical pump 15, and the like. The mechanical pump unit 10 supplies hydraulic oil to the supply port 21 c of the linear solenoid valve 20.

  The shift lever 11 is used when the driver selects a shift range. The shift lever 11 and the manual valve spool 14 inserted in the manual valve 13 are connected, and the manual valve spool 14 moves according to the shift range selected by the shift lever 11.

  The manual valve sleeve 14 has a substantially bottomed tubular shape, and the spool 12 is inserted into the manual valve 13 through an opening at one end of the manual valve sleeve 14 and slides with the inner wall of the manual valve sleeve 14. In the manual valve sleeve 14, a D range pressure port 14a, a line pressure port 14b, and an R range pressure port 14c are formed in this order from the bottomed side. The D range pressure port 14 a and the supply port 21 c of the linear solenoid valve 20 are connected by a supply pipe 18, and hydraulic oil staying inside the manual valve 13 is sent to the linear solenoid valve 20. The line pressure port 14b is connected to a mechanical pump 15, which will be described later, and hydraulic oil discharged from the mechanical pump 15 enters the manual valve 13 through the line pressure port 14b. The R range pressure port 14 c is connected to another linear solenoid valve different from the linear solenoid valve 20 that sends hydraulic oil to another clutch different from the clutch 30. When the driver selects the R range with the shift lever 11, the hydraulic oil staying in the manual valve 13 is sent to the other linear solenoid valve.

  The mechanical pump 15 pumps up the hydraulic oil stored in the oil pan 17 and discharges it to the manual valve 13. The mechanical pump 15 is driven in conjunction with the vehicle engine. For this reason, the mechanical pump 15 is not driven when the engine is not in operation, such as when idling is stopped. The mechanical pump 15 is provided with a pressure regulator 16 for adjusting the pressure of the hydraulic oil discharged to the manual valve 13.

  The electric pump unit 40 includes an electric pump 41, a first switching valve 46, and the like. The electric pump unit 40 is connected to the connection port 21 a of the linear solenoid valve 20. The electric pump unit 40 discharges hydraulic oil discharged from the connection port 21 a to the oil pan 17 via the first switching valve 46, and discharges hydraulic oil discharged from the electric pump 41 via the first switching valve 46. To the inside of the linear solenoid valve 20 from the connection port 21a.

  The first switching valve 46 is in a position where the electric pump 41 and the linear solenoid valve 20 are connected. The first switching valve 46 includes a first output port 46a, a first supply port 46b, a first connection port 46c, and a first discharge port 46d. Among these, the first output port 46 a and the first supply port 46 b communicate with each other inside the first switching valve 46. The first connection port 46 c and the first discharge port 46 d communicate with each other inside the first switching valve 46. The 1st switching valve 46 is installed so that a movement in the left-right direction of FIG. 2 is possible. FIG. 3 shows a state when the first switching valve 46 in FIG. 2 is moved leftward. A first spring 47 is in contact with the left side wall of the first switching valve 46 as urging means. The first spring 47 biases the first switching valve 46 in the right direction in FIG.

  The electric pump 41 is a gear pump that can reverse the pumping direction by the electric motor 42. The electric motor 42 is connected to an electric pump TCU 42 a that outputs a driving current to the electric motor 42. The electric pump TCU 42a includes a microcomputer, a drive circuit, and the like. The electric pump TCU 42 a outputs the drive current described above to the electric motor 42 based on the command signal.

  The electric pump 41 sucks the hydraulic oil stored in the oil pan 17 and discharges it from the discharge port 41a. One end of a first supply pipe 44 is connected to the discharge port 41a. The other end of the first supply pipe 44 can be connected to the first supply port 46 b of the first switching valve 46. A first switching passage 43 is connected in the middle of the first supply pipe 44. The other end of the first switching passage 43 that is different from the one connected to the first supply pipe 44 is connected to a first pressure accumulating chamber 46 g formed in the first switching valve 46. The hydraulic oil discharged from the first switching passage 43 flows into the first pressure accumulation chamber 46g. The end of the first switching passage 43 connected to the first switching valve 46 is in a state where the other end is connected to the first switching valve 46 as the first switching valve 46 moves in the left-right direction in FIG. To maintain. When the electric pump 41 is driven, the pressure of the hydraulic oil discharged from the electric pump 41 is applied to the first pressure accumulating chamber 46g, thereby applying a biasing force to the first switching valve 46 in the left direction of FIG. At this time, if the urging force is greater than the urging force of the first spring 47 in the right direction, the first switching valve 46 moves in the left direction to the position shown in FIG. At this time, the other end of the first supply pipe 44 is connected to the first supply port 46 b of the first switching valve 46. Thereby, the hydraulic oil discharged from the electric pump 41 enters the linear solenoid valve 20 from the connection port 21a via the first switching valve 46.

  The first supply pipe 44 is provided with a relief valve 45. When the internal pressure of the first supply pipe 44 becomes equal to or higher than a predetermined pressure, the relief valve 45 is opened to release the internal pressure of the first supply pipe 44.

(Function)
Next, the operation of the automatic transmission idle stop hydraulic control apparatus according to the first embodiment will be described with reference to FIGS.
First, the command content to the electric pump 41 according to the state of the linear solenoid valve 20 shown in FIG. 5 and the clutch pressure which is the pressure in the piston chamber 36 of the clutch 30 secured at that time will be described.

  As shown in FIG. 5a, any one of the first forward range D1 to the fourth forward range D4 capable of traveling at low speed is selected, the engine is operating, and the linear solenoid valve 20 Is normally operated and set to a high pressure, a command to “not drive” is input to the electric pump 41. At this time, the pressure of the hydraulic oil discharged from the mechanical pump 15 is transmitted to the piston chamber 36 of the clutch 30 via the linear solenoid valve 20, and the clutch pressure becomes high.

  As shown in FIG. 5b, any one of the first forward range D1 to the fourth forward range D4 capable of traveling at low speed is selected and the engine is operating, but the linear solenoid valve 20 Is set to low pressure due to a failure, a command to “drive” is input to the electric pump 41. At this time, when the pressure of the hydraulic oil discharged from the electric pump 41 is applied to the first pressure accumulating chamber 46g, the first switching valve 20 is switched to the left as shown in FIG. Thereby, the electric pump 41 and the connection port 21a of the linear solenoid valve 20 communicate with each other via the first switching valve 46. At this time, the pressure of the hydraulic oil discharged from the mechanical pump 15 is transmitted to the piston chamber 36 of the clutch 30 via the linear solenoid valve 20, and the clutch pressure becomes high.

  As shown in FIG. 5c, the fifth forward range D5 or the sixth forward range D6 capable of moving forward at high speed is selected, the engine is operating, and the linear solenoid valve 20 is operating normally. When the low pressure is set, a command to “not drive” is input to the electric pump 41. At this time, a part of the pressure of the hydraulic oil inside the linear solenoid valve 20 flows out from the connection port 21a to the oil pan 17 via the first switching valve 46, so that the clutch pressure becomes low.

  As shown in FIG. 5d, the fifth forward range D5 or the sixth forward range D6 capable of moving forward at high speed is selected, and the engine is operating, but the linear solenoid valve 20 is set to a high pressure level due to a failure. If so, a command to “not drive” is input to the electric pump 41. At this time, since the clutch pressure becomes high, the gear position is changed from any one of the first forward range D1 capable of moving forward at a low speed to any one of the fourth forward range D4. Start is possible.

  As shown in FIG. 5e, the first forward range D1 capable of moving forward at a low speed is selected, the engine is stopped, that is, idling stop, and the linear solenoid valve 20 is normally operated. When the low pressure is set, a command to “drive” is input to the electric pump 41. When the engine is stopped, the mechanical pump 15 is stopped and the hydraulic oil pressure from the mechanical pump 15 is not applied to the clutch 30. Therefore, when the electric pump 41 is driven, the hydraulic oil pressure is applied to the linear solenoid valve 20, and the clutch pressure becomes high.

  As shown in FIG. 5f, when the first forward range D1 capable of moving forward at low speed is selected and the engine is stopped, but the linear solenoid valve 20 is set to high pressure, the electric pump 41 A command to “not drive” is input to. At this time, the vehicle stops idling stop and starts the engine. As a result, the mechanical pump 15 is driven, the pressure of the hydraulic oil discharged from the mechanical pump 15 is transmitted to the piston chamber 36 of the clutch 30 via the linear solenoid valve 20, and the clutch pressure becomes high.

  As shown in FIGS. 5g and h, when the shift range of the vehicle is the neutral range N or the parking range P, the mechanical pump 15 and the linear solenoid valve 20 are not in communication. At this time, a command to “not drive” is input to the electric pump 41 regardless of whether the linear solenoid valve 20 is set to low pressure or high pressure. Thereby, since the pressure of the hydraulic fluid from the mechanical pump 15 and the electric pump 41 is not applied to the linear solenoid valve 20, the clutch pressure becomes low.

  As shown in FIGS. 5 i and j, when the vehicle is in the reverse range R in which the vehicle can reverse, the mechanical pump 15 and the clutch 30 are not in communication. At this time, a command to “not drive” is input to the electric pump 41 regardless of whether the linear solenoid valve 20 is set to low pressure or high pressure. As a result, the hydraulic pressure from the mechanical pump 15 and the electric pump 41 is not applied to the solenoid valve 20, so the clutch pressure is low.

Next, the command content to the linear solenoid valve 20 corresponding to the state of the electric pump 41 shown in FIG. 6 and the clutch pressure secured at that time will be described.
As shown in FIG. 6a, any one of the first forward range D1 to the fourth forward range D4 capable of traveling at low speed is selected, the engine is operating, and the electric pump 41 is In a normal state and not driven, a command to “move the spool 23 to the high pressure setting” is input to the linear solenoid valve 20. Thereby, the pressure of the hydraulic oil discharged from the mechanical pump 15 is transmitted to the piston chamber 36 of the clutch 30 via the linear solenoid valve 20, and the clutch pressure becomes high.

  As shown in FIG. 6b, any one of the first forward range D1 to the fourth forward range D4 capable of traveling at low speed is selected and the engine is operating, but the electric pump 41 is In the case of driving due to failure, the linear solenoid valve 20 is input with a command “move the spool 23 to either the high pressure setting or the low pressure setting”. At this time, when the spool 23 is moved to the high pressure setting, the pressure of the hydraulic oil discharged from the mechanical pump 15 is changed. When the spool 23 is moved to the low pressure setting, the pressure of the hydraulic oil discharged from the electric pump 41 is changed. The pressure is transmitted to the piston chamber 36 of the clutch 30 and the clutch pressure becomes high.

  As shown in FIG. 6c, the fifth forward range D5 or the sixth forward range D6 capable of high speed advance is selected, the engine is operating, and the electric pump 41 is in a normal state. If not, a command to “move the spool 23 to the low pressure setting” is input to the linear solenoid valve 20. Thereby, a part of the hydraulic oil inside the linear solenoid valve 20 flows out from the connection port 21a to the oil pan 17 via the first switching valve 46, so that the clutch pressure becomes low.

  As shown in FIG. 6d, the fifth forward range D5 or the sixth forward range D6 capable of moving forward at high speed is selected and the engine is running, but the electric pump 41 is broken and driven. If so, a command to “move the spool 23 to either the high pressure setting or the low pressure setting” is input to the linear solenoid valve 20. At this time, since the clutch pressure becomes high, the gear position is changed from any one of the first forward range D1 capable of moving forward at a low speed to any one of the fourth forward range D4. Start is possible.

  As shown in FIG. 6e, the first forward range D1 capable of moving forward at a low speed is selected, the engine is stopped, that is, idling stop, and the electric pump 41 is normal and driven. In this state, a command to “move the spool 23 to the low pressure setting” is input to the linear solenoid valve 20. As a result, the pressure of the hydraulic oil discharged from the electric pump 41 is applied to the piston chamber 36 of the clutch 30 via the connection port 21a of the linear solenoid valve 20, so that the clutch pressure becomes high.

  As shown in FIG. 6f, when the first forward range D1 capable of moving forward at a low speed is selected and the engine is stopped, but the electric pump 41 has failed and is not driven, the linear solenoid valve A command “Move spool 23 to high pressure setting” is input to 20. At this time, the vehicle stops idling stop and starts the engine. As a result, the mechanical pump 15 is driven, the pressure of the hydraulic oil discharged from the mechanical pump 15 is transmitted to the piston chamber 36 of the clutch 30 via the linear solenoid valve 20, and the clutch pressure becomes high.

  In the case of the neutral range N or the parking range P as shown in FIG. 6g, the mechanical pump 15 and the linear solenoid valve 20 are not in communication. At this time, if the electric pump 41 is normal and not driven, a command to “move the spool 23 to either the high pressure setting or the low pressure setting” is input to the linear solenoid valve 20. Thereby, since the pressure of the hydraulic fluid from the mechanical pump 15 and the electric pump 41 is not applied to the linear solenoid valve 20, the clutch pressure becomes low.

  As shown in FIG. 6h, in the neutral range N or the parking range P, the mechanical pump 15 and the linear solenoid valve 20 are not in communication. However, when the electric pump 41 is driven due to a failure, a command to “move the spool 23 to the high pressure setting” is input to the linear solenoid valve 20. As a result, the pressure of the hydraulic oil discharged from the mechanical pump 15 and the electric pump 41 is not applied to the linear solenoid valve 20, so that the clutch pressure is low.

  As shown in FIG. 6i, in the reverse range R in which the vehicle can reverse, the mechanical pump 15 and the linear solenoid valve 20 are not in communication. At this time, if the electric pump 41 is normal and not driven, a command to “move the spool 23 to either the high pressure setting or the low pressure setting” is input to the linear solenoid valve 20. Since the mechanical pump 15 does not communicate with the linear solenoid valve 20 and the electric pump 41 is not driven, no hydraulic oil pressure is applied to the linear solenoid valve 20. As a result, the clutch pressure becomes low.

  As shown in FIG. 6j, the mechanical pump 15 and the linear solenoid valve 20 are not in communication in the reverse range R in which the vehicle can reverse. However, when the electric pump 41 is driven due to a failure, a command to “move the spool 23 to the high pressure setting” is input to the linear solenoid valve 20. As a result, the pressure of the hydraulic oil discharged from the driving electric pump 41 is not applied to the clutch 30, so that the clutch pressure is low.

Next, the influence when the first switching valve 46 fails will be described with reference to FIGS.
FIG. 7 shows the effect of the failure of the first switching valve 46 while the first connection port 46c of the first switching valve 46 and the connection port 21a of the linear solenoid valve 20 are in communication as shown in FIG. .

  As shown in FIG. 7a, when any one of the first forward range D1 to the fourth forward range D4 capable of traveling at a low speed is selected and the engine is operating, the linear solenoid valve 20 Is a high pressure setting, and the electric pump 41 is not driven. At this time, the clutch pressure becomes a high pressure required for engaging the clutch 30, so that there is no influence of the failure of the first switching valve 46.

  As shown in FIG. 7b, when the fifth forward range D5 or the sixth forward range D6 capable of high speed advance is selected and the engine is operating, the linear solenoid valve 20 is set to a low pressure. The electric pump 41 is not driven. At this time, since the clutch pressure becomes a low pressure required to open the clutch 30, there is no influence of the failure of the first switching valve 46.

  As shown in FIG. 7c, when the first forward range D1 capable of moving forward at a low speed is selected and the engine is stopped, that is, idling stop, the linear solenoid valve 20 is set to a low pressure. The electric pump 41 is driven. At this time, since the first switching valve 46 fails while the first connection port 46c and the connection port 21a of the linear solenoid valve 20 are in communication, the pressure of the hydraulic oil discharged from the electric pump 41 is the linear solenoid valve 20. Not communicated to. As a result, the clutch pressure does not become a high pressure required for engaging the clutch 30, but a low pressure. At this time, the vehicle stops idling stop, starts the engine, and sets the linear solenoid valve 20 to a high pressure setting. Thereby, since the pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the linear solenoid valve 20, the clutch pressure becomes high.

  As shown in FIG. 7d, in the neutral range N or the parking range P, the linear solenoid valve 20 is set to a low pressure, and the electric pump 41 is not driven. At this time, since the clutch pressure becomes a low pressure required to open the clutch 30, there is no influence of the failure of the first switching valve 46.

  As shown in FIG. 7e, in the reverse range R in which the vehicle can reverse, the linear solenoid valve 20 is set to a low pressure, and the electric pump 41 is not driven. At this time, since the clutch pressure becomes a low pressure required to open the clutch 30, there is no influence of the failure of the first switching valve 46.

  FIG. 8 shows the effect of failure of the first switching valve 46 while the first output port 46a of the first switching valve 46 and the connection port 21a of the linear solenoid valve 20 are in communication with each other as shown in FIG. .

  As shown in FIG. 8a, when one of the first forward range D1 to the fourth forward range D4 capable of moving forward at a low speed is selected and the engine is operating, the linear solenoid valve 20 Is a high pressure setting, and the electric pump 41 is not driven. At this time, the clutch pressure becomes a high pressure necessary for engaging the clutch 30 regardless of the state of the first switching valve 46, and therefore, there is no influence of the failure of the first switching valve 46.

  As shown in FIG. 8b, when the fifth forward range D5 or the sixth forward range D6 capable of high speed advance is selected and the engine is operating, the linear solenoid valve 20 is set to a low pressure. The electric pump 41 is not driven. At this time, the pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the linear solenoid valve 20, and the first switching valve 46 is broken while the first output port 46a and the connection port 21a remain in communication. Therefore, the communication path 46h that communicates the first output port 46a and the connection port 21a of the linear solenoid valve 20 has a high pressure. Thereby, since the clutch pressure becomes high, the clutch 30 cannot be released. At this time, the gear position is changed to any one of the first forward range D1 to the fourth forward range D4, which can advance at a low speed, and the low speed advance is enabled.

  As shown in FIG. 8c, when the first forward range D1 capable of moving forward at a low speed is selected and the engine is stopped, that is, idling stop, the linear solenoid valve 20 is set to a low pressure. The electric pump 41 is driven. At this time, the pressure of the hydraulic oil discharged from the electric pump 41 acts on the clutch 30, and the clutch pressure becomes a high pressure necessary to engage the clutch 30, so there is no influence of the failure of the first switching valve 46.

  As shown in FIG. 8d, in the neutral range N or the parking range P, the spool 23 of the linear solenoid valve 20 is moved to the low pressure setting, and the electric pump 41 is not driven. At this time, the pressure of the hydraulic oil from the mechanical pump 15 is not applied to the linear solenoid valve 20, but the first switching valve 46 is broken while the first output port 46a and the connection port 21a remain in communication. The communication path 46h that communicates the first output port 46a and the connection port 21a of the linear solenoid valve 20 has a pressure at which the clutch 30 cannot be released. At this time, the electric pump 41 capable of reversing the pressure feeding direction is driven, and the internal pressure is lowered by sucking the hydraulic oil in the communication passage 46h, so that the clutch pressure becomes a low pressure necessary for opening the clutch 30.

  As shown in FIG. 8e, in the reverse range R in which the vehicle can reverse, the spool 23 of the linear solenoid valve 20 is moved to the low pressure setting, and the electric pump 41 is not driven. At this time, the pressure of the hydraulic oil from the mechanical pump 15 is not applied to the linear solenoid valve 20, but the first switching valve 46 remains in communication with the first output port 46a and the connection port 21a of the linear solenoid valve 20. Due to the failure, the communication passage 46h that connects the first output port 46a and the connection port 21a of the linear solenoid valve 20 has a pressure at which the clutch 30 cannot be released. At this time, the electric pump 41 capable of reversing the pressure feeding direction is driven, and the internal pressure is lowered by sucking the hydraulic oil in the communication passage 46h, so that the clutch pressure becomes a low pressure necessary for opening the clutch 30.

(effect)
Next, the effect of the idle stop hydraulic control apparatus for an automatic transmission according to the first embodiment will be described.
(1) The first switching valve 46 switches the connection path of the connection port 21 a of the linear solenoid valve 20 according to the state of the linear solenoid valve 20. When the linear solenoid valve 20 is set to a low pressure due to a failure, a command to “drive” is input to the electric pump 41. When the electric pump 41 is driven, the pressure of hydraulic oil from the electric pump 41 acts on the first pressure accumulating chamber 46g provided in the first switching valve 46, and the first switching valve 46 is as shown in FIG. Move left. At this time, the electric pump 41 and the connection port 21 a of the linear solenoid valve 20 communicate with each other via the first switching valve 46. Thereby, the pressure of the hydraulic oil discharged from the electric pump 41 is transmitted to the piston chamber 36 of the clutch 30 via the linear solenoid valve 20, and the clutch pressure becomes high. Thereby, even when the linear solenoid valve 20 is out of order, high pressure hydraulic oil can be supplied to the clutch 30.

  (2) The first forward range D1 capable of traveling at low speed is selected, the engine is stopped, that is, idling stop, and the linear solenoid valve 20 operates normally and moves to the low pressure setting. If so, a command to “drive” is input to the electric pump 41. As described above, when the electric pump 41 is driven, the first switching valve 46 moves to the left as shown in FIG. At this time, the electric pump 41 and the connection port 21 a of the linear solenoid valve 20 communicate with each other via the first switching valve 46. Thereby, the pressure of the hydraulic oil discharged from the electric pump 41 is transmitted to the piston chamber 36 of the clutch 30 via the linear solenoid valve 20, and the clutch pressure becomes high. Therefore, it is possible to supply high-pressure hydraulic oil to the clutch 30 that contributes to starting during idling stop.

(3) When the engine is in operation and the spool 23 of the linear solenoid valve 20 is moved to the low pressure setting and the electric pump 41 is not driven, the connection port 21a and the first connection port 46c communicate with each other. If the first switching valve 46 fails, the working fluid is not discharged from the communication passage 46h of the first switching valve 46, so that the pressure becomes high. At this time, the hydraulic oil is sucked from the communication passage 46h by the electric pump 41 that can reverse the pumping direction of the working fluid. Thereby, the pressure in the linear solenoid valve 20 can be adjusted to a low pressure. Therefore, even when the first switching valve 46 fails, the working fluid can be discharged and low pressure hydraulic oil can be supplied to the clutch 30.

  (4) When the first switching valve 46 fails while the connection port 21a of the linear solenoid valve 20 and the first connection port 46c of the first switching valve 46 are in communication, the electric pump 41 is connected from the communication path 46h as described above. Aspirate the hydraulic fluid. At this time, the clogging of the foreign matter that causes the failure of the first switching valve 46 can be removed from the communication path 46h.

(Second Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIGS. The second embodiment is different from the first embodiment in that the first switching valve has a working fluid discharge passage having an orifice. In addition, the same code | symbol is attached | subjected to the site | part substantially the same as 1st Embodiment, and description is abbreviate | omitted.

  In the second embodiment, as shown in FIG. 9, a hydraulic oil discharge passage 46e having one end connected to a communication passage 46h that connects the first output port 46a and the first supply port 46b of the first switching valve 46 is provided. The other end of the hydraulic oil discharge passage 46e is connected to the oil pan 17 when the first switching valve 46 moves leftward as shown in FIG. An orifice 46f is provided in the middle of the hydraulic oil discharge passage 46e. The orifice 46f limits the amount of hydraulic oil that passes through the hydraulic oil discharge passage 46e. The hydraulic oil discharge passage 46e corresponds to a “working fluid discharge passage” recited in the claims.

(Function)
Next, the operation of the automatic transmission idle stop hydraulic control apparatus according to the second embodiment will be described with reference to FIG.
FIG. 11 shows the effect of failure of the first switching valve 46 with the first output port 46a of the first switching valve 46 and the connection port 21a of the linear solenoid valve 20 communicating with each other as shown in FIG. .

  As shown in FIG. 11b, when the fifth forward range D5 or the sixth forward range D6 capable of high speed advance is selected and the engine is operating, the linear solenoid valve 20 is set to a low pressure. The electric pump 41 is not driven. At this time, the pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the linear solenoid valve 20, and the first switching valve 46 is kept in communication with the first output port 46a and the connection port 21a of the linear solenoid valve 20. , The communication path 46h that connects the first output port 46a and the connection port 21a has a high pressure. Thereby, since the clutch pressure becomes high, the clutch 30 cannot be released. At this time, the gear position is changed to any one of the first forward range D1 to the fourth forward range D4, which can advance at a low speed, and the low speed advance is enabled.

  As shown in FIG. 11d, in the neutral range N or the parking range P, the linear solenoid valve 20 is set to a low pressure, and the electric pump 41 is not driven. At this time, the pressure of the hydraulic oil from the mechanical pump 15 is not applied to the linear solenoid valve 20, but the first switching valve 46 remains in communication with the first output port 46a and the connection port 21a of the linear solenoid valve 20. Due to the failure, the communication passage 46h that connects the first output port 46a and the connection port 21a of the linear solenoid valve 20 has a pressure at which the clutch 30 cannot be released. At this time, the hydraulic oil stopped in the communication passage 46h is discharged to the oil pan 17 via the hydraulic oil discharge passage 46e. As a result, the internal pressure of the communication passage 46h decreases and the internal pressure of the piston chamber 36 of the clutch 30 communicating with the communication passage 46h decreases, so that the clutch pressure becomes a low pressure necessary for opening the clutch 30.

  As shown in FIG. 11e, in the reverse range R in which the vehicle can reverse, the linear solenoid valve 20 is moved to the low pressure setting, and the electric pump 41 is not driven. At this time, the pressure of the hydraulic oil from the mechanical pump 15 is not applied to the linear solenoid valve 20, but the first switching valve 46 remains in communication with the first output port 46a and the connection port 21a of the linear solenoid valve 20. Due to the failure, the communication path 46h that connects the first output port 46a and the connection port 21a has a pressure that does not allow the clutch 30 to be released. At this time, the hydraulic oil staying in the communication passage 46h is discharged to the oil pan 17 via the hydraulic oil discharge passage 46e. As a result, the internal pressure of the communication passage 46 h decreases and the internal pressure of the piston chamber 36 of the clutch 30 communicating with the communication passage 46 h decreases, so that the clutch pressure becomes a low pressure necessary for opening the clutch 30.

(effect)
A hydraulic oil discharge passage 46e having an orifice 46f is provided in the communication passage 46h of the first switching valve 46 that communicates the connection port 21a with the electric pump 41. When the linear solenoid valve 20 is set to a low pressure and the electric pump 41 is not driven, if the first switching valve 46 communicates with the connection port 21a and the electric pump 41 due to a failure, the hydraulic fluid is placed in the communication passage 46h. Stops. At this time, the hydraulic oil that stops is gradually discharged from the hydraulic oil discharge passage 46e connected to the communication passage 46h. On the other hand, when the electric pump 41 is driven and the hydraulic oil is discharged to the linear solenoid valve 20, the amount of the hydraulic oil discharged by the orifice 46f provided in the hydraulic oil discharge passage 46e is limited. There is no effect on hydraulic pumping. Therefore, in addition to the effects (1) to (4) of the first embodiment, even when the first switching valve 46 fails, the hydraulic oil can be discharged and the low pressure working fluid can be supplied to the clutch 30.

(Third embodiment)
Next, a third embodiment of the present invention will be described with reference to FIGS. 3rd Embodiment is provided with the 2nd switching valve with respect to 1st Embodiment. In addition, the same code | symbol is attached | subjected to the site | part substantially the same as 1st Embodiment, and description is abbreviate | omitted.

  In 3rd Embodiment, it has the 2nd switching valve 56 which can move to the left-right direction of FIG. 11 with the pressure of the hydraulic fluid which the mechanical pump 15 discharges, and the urging | biasing force of the 2nd spring 57. In FIG. A second spring 57 is in contact with the right side wall of the second switching valve 57 as a biasing means for the second switching valve 56. The second spring 57 urges the second switching valve 56 in the left direction in FIG. 12, so that the second switching valve 56 moves in the left direction as compared with FIG. A third pressure accumulation chamber 56e is formed on the outer wall of the second switching valve 56 on the side opposite to the side on which the second spring 57 is in contact. The third pressure accumulation chamber 56e is connected to the second switching passage 53 having one end connected to the middle of the supply pipe 18. The other end of the second switching passage 53 maintains a state in which the other end is connected when the second switching valve 56 moves to the right in FIG. As a result, the second switching valve 56 is urged leftward by the second spring 57 as shown in FIG. 12, while the hydraulic pressure discharged from the mechanical pump 15 is applied to the third pressure accumulation chamber 56e. As shown in FIG. 13, the second switching valve 56 is moved rightward against the urging force of the second switching valve spring 57.

The second switching valve 56 includes a second output port 56a, a second supply port 56b, a second connection port 56c, and a first discharge port 56d. Among these, the second output port 56 a and the second supply port 56 b communicate with each other inside the second switching valve 56. Further, the second connection port 56 c and the second discharge port 56 d communicate with each other inside the second switching valve 46.
The second output port 56 a is formed to be connectable to one end of the second connection pipe 58. The other end of the second connection pipe 58 is connected to a second pressure accumulation chamber 46 i provided on the opposite side of the first switching valve 46 from the first pressure accumulation chamber 46 g. The second supply port 56 b is connected to the mechanical pump 15 by the second supply pipe 54. The second connection port 56c is formed to be connectable to the second connection pipe 58. The second discharge port 56d is formed to be connectable to the oil pan 17.

  When the second switching valve 56 moves leftward as shown in FIG. 12, the second connection pipe 58 and the second output port 56a communicate with each other. At this time, the second supply pipe 54 connected to the mechanical pump 15 and the second supply port 56b communicate with each other. As a result, the hydraulic oil discharged from the mechanical pump 15 flows into the second connection pipe 58 through the second switching valve 56. The hydraulic oil that has flowed into the second connection pipe 58 maintains the pressure of the hydraulic oil discharged from the mechanical pump 15, and the discharge pressure is applied to the second pressure accumulation chamber 46 i of the first switching valve 46. As a result, the first switching valve 46 is urged to the right as shown in FIG. Further, when the second switching valve 56 moves to the right as shown in FIG. 12, the second connection pipe 58 and the second connection port 56 c communicate with each other, and the first discharge port 56 d communicates with the oil pan 17. As a result, the working fluid in the second connection pipe 58 is discharged, so that the internal pressure becomes low, and the first switching valve 46 has the urging force of the first spring 47 and the pressure of the working fluid in the first switching passage 43. Switching operation is performed according to the magnitude relationship.

(Function)
Next, the operation of the idle stop hydraulic control device for an automatic transmission according to the present embodiment will be described with reference to FIGS.
First, the command contents to the electric pump 41 according to the state of the linear solenoid valve 20 shown in FIG. 14 and the clutch pressure secured at that time will be described.

  As shown in FIG. 14a, any one of the first forward range D1 to the fourth forward range D4 capable of traveling at low speed is selected, the engine is operating, and the linear solenoid valve 20 Is normally operated and set to a high pressure, a command to “not drive” is input to the electric pump 41. Further, in the second switching valve 56, the pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the third pressure accumulating chamber 56e. Therefore, the second switching valve 56 moves to the right as shown in FIG. The internal pressure of the pipe 58 is lowered. Accordingly, the first switching valve 46 is not switched by the second switching valve 56. At this time, the pressure of the hydraulic oil discharged from the mechanical pump 15 is transmitted to the piston chamber 36 of the clutch 30 via the linear solenoid valve 20, and the clutch pressure becomes high.

  As shown in FIG. 14b, any one of the first forward range D1 to the fourth forward range D4 capable of traveling at low speed is selected and the engine is operating, but the linear solenoid valve 20 Is set to low pressure due to a failure, a command to “drive” is input to the electric pump 41. At this time, when the pressure of the hydraulic oil discharged from the electric pump 41 is applied to the first pressure accumulation chamber 46g, the first switching valve 20 moves to the left. Further, in the second switching valve 56, the pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the third pressure accumulating chamber 56e. Therefore, the second switching valve 56 moves to the right as shown in FIG. The internal pressure of the pipe 58 is lowered. Accordingly, the first switching valve 46 is not switched by the second switching valve 56. Thereby, the electric pump 41 and the connection port 21a of the linear solenoid valve 20 communicate with each other via the first switching valve 46. At this time, the pressure of the hydraulic oil discharged from the mechanical pump 15 is transmitted to the piston chamber 36 of the clutch 30 via the linear solenoid valve 20, and the clutch pressure becomes high.

  As shown in FIG. 14c, the fifth forward range D5 or the sixth forward range D6 capable of moving forward at high speed is selected, the engine is operating, and the linear solenoid valve 20 operates normally. When the low pressure is set, a command to “not drive” is input to the electric pump 41. Further, in the second switching valve 56, the pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the third pressure accumulating chamber 56e. Therefore, the second switching valve 56 moves to the right as shown in FIG. The internal pressure of the pipe 58 is lowered. Accordingly, the first switching valve 46 is not switched by the second switching valve 56. At this time, part of the hydraulic oil in the linear solenoid valve 20 flows out from the connection port 21a to the oil pan 17 via the first switching valve 46, so that the clutch pressure becomes low.

  As shown in FIG. 14d, the fifth forward range D5 or the sixth forward range D6 capable of advancing at high speed is selected, and the engine is operating, but the linear solenoid valve 20 is set to a high pressure due to a failure. If so, a command to “not drive” is input to the electric pump 41. Further, in the second switching valve 56, the pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the third pressure accumulating chamber 56e. Therefore, the second switching valve 56 moves to the right as shown in FIG. The internal pressure of the pipe 58 is lowered. Accordingly, the first switching valve 46 is not switched by the second switching valve 56. At this time, since the clutch pressure becomes high, the gear position is changed from any one of the first forward range D1 capable of moving forward at a low speed to any one of the fourth forward range D4. Start is possible.

  As shown in FIG. 14e, the first forward range D1 capable of moving forward at a low speed is selected, the engine is stopped, that is, idling stop, and the linear solenoid valve 20 is normally operated. When the low pressure is set, a command to “drive” is input to the electric pump 41. At this time, the second switching valve 56 moves to the left as shown in FIG. 12, but since the mechanical pump 15 is stopped by stopping the engine, the hydraulic pressure is not applied to the second connection pipe 58. Accordingly, the first switching valve 46 is not switched by the second switching valve 56. Further, since the mechanical pump 15 is stopped, no hydraulic oil pressure is applied to the clutch 30. Therefore, when the electric pump 41 is driven, the hydraulic oil pressure is applied to the linear solenoid valve 20, and the clutch pressure is set high.

  As shown in FIG. 14f, when the first forward range D1 capable of moving at low speed is selected and the engine is stopped, but the linear solenoid valve 20 is set to high pressure, the electric pump 41 A command to “not drive” is input to. Further, the second switching valve 56 moves to the left as shown in FIG. 12, but since the mechanical pump 15 is stopped when the engine is stopped, the hydraulic pressure is not applied to the second connection pipe 58. Accordingly, the first switching valve 46 is not switched by the second switching valve 56. At this time, the vehicle stops the idling stop being executed and starts the engine. As a result, the mechanical pump 15 is driven, the pressure of the hydraulic oil discharged from the mechanical pump 15 is transmitted to the piston chamber 36 of the clutch 30 via the linear solenoid valve 20, and the clutch pressure becomes high.

  As shown in FIGS. 14g and h, when the shift range of the vehicle is the neutral range N or the parking range P, the mechanical pump 15 and the linear solenoid valve 20 are not in communication. Moreover, in the 2nd switching valve 56, the pressure of the hydraulic fluid which the mechanical pump 15 discharges according to the position of the sleeve 12 of the manual valve 13 does not apply to the 3rd pressure accumulation chamber 56e. The second switching valve 56 moves leftward as shown in FIG. 12, and hydraulic oil discharged from the mechanical pump 15 flows into the second connection pipe 58. The pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the second pressure accumulation chamber 46 i connected to the second connection pipe 58. Accordingly, the first switching valve 46 moves to the right by the second switching valve 56. At this time, a command to “not drive” is input to the electric pump 41 regardless of whether the linear solenoid valve 20 is at a low pressure setting or a high pressure setting. Thereby, since the pressure of the hydraulic fluid from the mechanical pump 15 and the electric pump 41 is not applied to the linear solenoid valve 20, the clutch pressure becomes low. Further, when the electric pump 41 is driven due to a failure, the connection port 21a and the first connection port 46a are not connected, so the pressure of the hydraulic oil discharged by the electric pump 41 does not apply to the linear solenoid valve 20. Therefore, the clutch pressure is low.

  As shown in FIGS. 14i and j, the mechanical pump 15 and the clutch 30 are not in communication in the reverse range R in which the vehicle can reverse. Moreover, in the 2nd switching valve 56, the pressure of the hydraulic fluid which the mechanical pump 15 discharges according to the position of the sleeve 12 of the manual valve 13 does not apply to the 3rd pressure accumulation chamber 56e. The second switching valve 56 moves leftward as shown in FIG. 12, and hydraulic oil discharged from the mechanical pump 15 flows into the second connection pipe 58. The pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the second pressure accumulation chamber 46 i connected to the second connection pipe 58. Accordingly, the first switching valve 46 moves to the right by the second switching valve 56. At this time, a command to “not drive” is input to the electric pump 41 regardless of whether the linear solenoid valve 20 is at a low pressure setting or a high pressure setting. As a result, the solenoid valve 20 is not subjected to the pressure of the hydraulic oil discharged from the mechanical pump 15 and the electric pump 41, so the clutch pressure is low. Further, when the electric pump 41 is driven due to a failure, the connection port 21a and the first connection port 46a are not connected, so the pressure of the hydraulic oil discharged by the electric pump 41 does not apply to the linear solenoid valve 20. Therefore, the clutch pressure is low.

Next, the command content to the linear solenoid valve 20 according to the state of the electric pump 41 shown in FIG. 15 and the clutch pressure secured at that time will be described.
As shown in FIG. 15a, any one of the first forward range D1 to the fourth forward range D4 capable of traveling at low speed is selected, the engine is operating, and the electric pump 41 is In a normal state and not driven, a command to “move the spool 23 to the high pressure setting” is input to the linear solenoid valve 20. Further, in the second switching valve 56, the pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the third pressure accumulating chamber 56e. Therefore, the second switching valve 56 moves to the right as shown in FIG. The internal pressure of the pipe 58 is lowered. Accordingly, the first switching valve 46 is not switched by the second switching valve 56. At this time, the pressure of the hydraulic oil discharged from the mechanical pump 15 is transmitted to the piston chamber 36 of the clutch 30 via the linear solenoid valve 20, and the clutch pressure becomes high.

  As shown in FIG. 15b, any one of the first forward range D1 to the fourth forward range D4 capable of traveling at a low speed is selected and the engine is operating, but the electric pump 41 is In the case of driving due to failure, the linear solenoid valve 20 is input with a command “move the spool 23 to either the high pressure setting or the low pressure setting”. Further, in the second switching valve 56, the pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the third pressure accumulating chamber 56e. Therefore, the second switching valve 56 moves to the right as shown in FIG. The internal pressure of the pipe 58 is lowered. Accordingly, the first switching valve 46 is not switched by the second switching valve 56. Thereby, the electric pump 41 and the connection port 21a of the linear solenoid valve 20 communicate with each other via the first switching valve 46. At this time, the pressure of the hydraulic oil discharged from the mechanical pump 15 is transmitted to the piston chamber 36 of the clutch 30 via the linear solenoid valve 20, and the clutch pressure becomes high.

  As shown in FIG. 15c, the fifth forward range D5 or the sixth forward range D6 capable of high speed advance is selected, the engine is operating, and the electric pump 41 is in a normal state. If not, a command to “move the spool 23 to the low pressure setting” is input to the linear solenoid valve 20. Further, in the second switching valve 56, the pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the third pressure accumulating chamber 56e. Therefore, the second switching valve 56 moves to the right as shown in FIG. The internal pressure of the pipe 58 is lowered. Accordingly, the first switching valve 46 is not switched by the second switching valve 56. At this time, a part of the hydraulic oil inside the linear solenoid valve 20 flows out from the connection port 21a to the oil pan 17 via the first switching valve 46, so that the clutch pressure becomes low.

  As shown in FIG. 15d, the fifth forward range D5 or the sixth forward range D6 capable of moving forward at high speed is selected, and the engine is running, but the electric pump 41 fails and is driven. If so, a command to “move the spool 23 to either the high pressure setting or the low pressure setting” is input to the linear solenoid valve 20. Further, in the second switching valve 56, the pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the third pressure accumulating chamber 56e. Therefore, the second switching valve 56 moves to the right as shown in FIG. The internal pressure of the pipe 58 is lowered. Accordingly, the first switching valve 46 is not switched by the second switching valve 56. At this time, since the clutch pressure becomes high, the gear position is changed from any one of the first forward range D1 capable of moving forward at a low speed to any one of the fourth forward range D4. Start is possible.

  As shown in FIG. 15e, the first forward range D1 capable of moving forward at a low speed is selected, the engine is stopped, that is, idling stop, and the electric pump 41 is normal and driven. If so, a command to “move the spool 23 to the low pressure setting” is input to the linear solenoid valve 20. Further, the second switching valve 56 moves to the left as shown in FIG. 12, but since the mechanical pump 15 is stopped when the engine is stopped, the hydraulic pressure is not applied to the second connection pipe 58. Accordingly, the first switching valve 46 is not switched by the second switching valve 56. Further, since the mechanical pump 15 is stopped, no hydraulic oil pressure is applied to the clutch 30. Therefore, when the electric pump 41 is driven, the hydraulic oil pressure is applied to the linear solenoid valve 20, and the clutch pressure is set high.

  As shown in FIG. 15f, when the first forward range D1 capable of moving forward at a low speed is selected and the engine is stopped, but the electric pump 41 has failed and is not driven, the linear solenoid valve 20, a command to “move the spool 23 to either the high pressure setting or the low pressure setting” is input. Further, the second switching valve 56 moves to the left as shown in FIG. 12, but since the mechanical pump 15 is stopped when the engine is stopped, the hydraulic pressure is not applied to the second connection pipe 58. Accordingly, the first switching valve 46 is not switched by the second switching valve 56. At this time, the vehicle stops the idling stop being executed and starts the engine. As a result, the mechanical pump 15 is driven, the pressure of the hydraulic oil discharged from the mechanical pump 15 is transmitted to the piston chamber 36 of the clutch 30 via the linear solenoid valve 20, and the clutch pressure becomes high.

  In the case of the neutral range N or the parking range P as shown in FIG. 15g, the mechanical pump 15 and the linear solenoid valve 20 are not in communication. At this time, if the electric pump 41 is normal and not driven, a command to “move the spool 23 to either the high pressure setting or the low pressure setting” is input to the linear solenoid valve 20. Further, since the discharge pressure from the mechanical pump 15 is not applied to the third pressure accumulation chamber 56e in the second switching valve 56, the second switching valve 56 moves to the left as shown in FIG. The pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the second pressure accumulation chamber 46 i via the second connection pipe 58. Accordingly, the first switching valve 46 moves to the right as shown in FIG. As a result, the hydraulic oil retained in the linear solenoid valve 20 is discharged to the oil pan 17. Further, since the mechanical pump 15 does not communicate with the linear solenoid valve 20, no hydraulic oil pressure is applied to the linear solenoid valve 20. As a result, the clutch pressure becomes low.

  As shown in FIG. 15h, in the case of the neutral range N or the parking range P, the mechanical pump 15 and the linear solenoid valve 20 are not in communication. However, when the electric pump 41 is driven due to a failure, a command to “move the spool 23 to either the high pressure setting or the low pressure setting” is input to the linear solenoid valve 20. In the second switching valve 56, the pressure of the hydraulic oil discharged from the mechanical pump 15 is not applied to the third pressure accumulating chamber 56e, so the second switching valve 56 moves to the left as shown in FIG. Thereby, the pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the second pressure accumulating chamber 46 i via the second connection pipe 58. Accordingly, the first switching valve 46 moves to the right as shown in FIG. As a result, the hydraulic oil retained in the linear solenoid valve 20 is discharged to the oil pan 17. Further, since the mechanical pump 15 does not communicate with the linear solenoid valve 20, no hydraulic oil pressure is applied to the linear solenoid valve 20. As a result, the clutch pressure becomes low.

  As shown in FIG. 15i, in the case of the reverse range R in which the vehicle can reverse, the mechanical pump 15 and the linear solenoid valve 20 are not in communication. At this time, if the electric pump 41 is normal and not driven, a command to “move the spool 23 to either the high pressure setting or the low pressure setting” is input to the linear solenoid valve 20. In the second switching valve 56, the pressure of the hydraulic oil discharged from the mechanical pump 15 is not applied to the third pressure accumulation chamber 56e, so the second switching valve 56 moves to the left as shown in FIG. Thereby, the pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the second pressure accumulating chamber 46 i via the second connection pipe 58. Accordingly, the first switching valve 46 moves to the right as shown in FIG. As a result, the hydraulic oil retained in the linear solenoid valve 20 is discharged to the oil pan 17. Further, since the mechanical pump 15 does not communicate with the linear solenoid valve 20, no hydraulic oil pressure is applied to the linear solenoid valve 20. As a result, the clutch pressure becomes low.

  As shown in FIG. 15j, the mechanical pump 15 and the linear solenoid valve 20 are not in communication in the reverse range R in which the vehicle can reverse. However, when the electric pump 41 is driven due to a failure, a command to “move the spool 23 to the high pressure setting” is input to the linear solenoid valve 20. In the second switching valve 56, the pressure of the hydraulic oil discharged from the mechanical pump 15 is not applied to the third pressure accumulation chamber 56e, so the second switching valve 56 moves to the left as shown in FIG. Thereby, the pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the second pressure accumulating chamber 46 i via the second connection pipe 58. Accordingly, the first switching valve 46 moves to the right as shown in FIG. As a result, the hydraulic oil retained in the linear solenoid valve 20 is discharged to the oil pan 17. Further, since the mechanical pump 15 does not communicate with the linear solenoid valve 20, no hydraulic oil pressure is applied to the linear solenoid valve 20. As a result, the clutch pressure becomes low.

  Next, the influence when the second switching valve 56 fails will be described based on FIGS. 16 and 17 in accordance with the state of the first switching valve 46.

  FIG. 16 shows the effect when the second switching valve 56 fails while the second connection port 56c and the second connection pipe 58 are in communication as shown in FIG. 16A shows the case where the first switching valve 46 is operating normally, and FIG. 16B shows that the first switching valve 46 communicates the first connection port 46c with the connection port 21a of the linear solenoid valve 20. FIG. 16C shows a case where the first switching valve 46 fails while the first output port 46a and the connection port 21a of the linear solenoid valve 20 are in communication with each other.

  In FIG. 16, the second switching valve 56 communicates with the second connection port 56 c and the second connection pipe 58. Thereby, the pressure of the hydraulic fluid discharged from the mechanical pump 15 is not applied to the second pressure accumulating chamber 46i of the first switching valve 46 connected to the second switching valve 56. Accordingly, the first switching valve 46 is not switched by the second switching valve 56. That is, in the state where the second connection port 56c and the second connection pipe 58 are in communication, the influence of the failure of the second switching valve 56 is the same as in FIGS. 7 and 8 described in the first embodiment.

  FIG. 17 shows the influence of failure when the second switching valve 56 fails while the second output port 56a and the second connection pipe 58 are in communication as shown in FIG. 17A shows a case where the first switching valve 46 is operating normally. FIG. 17B shows a case where the first switching valve 46 communicates the first connection port 46c with the connection port 21a of the linear solenoid valve 20. FIG. 17C shows a case where the first switching valve 46 fails while the first output port 46a and the connection port 21a of the linear solenoid valve 20 are in communication with each other.

  In FIG. 17, the second switching valve 56 communicates with the second output port 56 a and the second connection pipe 58. When the mechanical pump 15 is driven in this state, the pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the second pressure accumulating chamber 46i via the second switching valve 56. Thereby, the 1st switching valve 46 moves to the right direction of FIG. When the first switching valve 46 moves to the right, the connection port 21a of the linear solenoid valve 20 and the first connection port 46c are connected. Therefore, the hydraulic oil that remains in the linear solenoid valve 20 is discharged to the oil pan 17 through the connection port 21a.

  When the electric pump 41 is driven in FIG. 17B, since the electric pump 41 and the connection port 21a are not connected, the piston chamber 36 of the clutch 30 communicating with the inside of the linear solenoid valve 20 has a low pressure. Become. At this time, the idling stop is stopped and the engine is started to increase the clutch pressure.

  In FIG. 17C, the linear solenoid valve 20 is set to a low pressure, and the electric pump 41 is not driven. At this time, the pressure of the hydraulic oil discharged from the mechanical pump 15 is applied to the linear solenoid valve 20, and the hydraulic oil is not discharged from the inside of the linear solenoid valve 20, so that the clutch pressure becomes high. Thereby, the clutch 30 cannot be released. At this time, the gear position is changed to any one of the first forward range D1 to the fourth forward range D4, which can advance at a low speed, and the low speed advance is enabled.

  17C and 17E, the spool 23 of the linear solenoid valve 20 is set to a low pressure, and the electric pump 41 is not driven. At this time, the pressure of the hydraulic oil from the mechanical pump 15 is not applied to the linear solenoid valve 20, but the first switching valve 46 is broken while the first output port 46a and the connection port 21a remain in communication. The communication path 46h that communicates the first output port 46a and the connection port 21a of the linear solenoid valve 20 has a pressure at which the clutch 30 cannot be released. At this time, the electric pump 41 capable of reversing the pressure feeding direction is driven, and the internal pressure is lowered by sucking the hydraulic oil in the communication passage 46h, so that the clutch pressure becomes a low pressure necessary for opening the clutch 30.

(effect)
In 3rd Embodiment, the 2nd switching valve 56 which switches by the pressure of the hydraulic fluid which the mechanical pump 15 discharges is provided. When the mechanical pump 15 and the second pressure accumulating chamber 46i of the first switching valve 46 are communicated with each other, the first switching valve 46 has a hydraulic fluid discharged from the electric pump 41 by the pressure of the hydraulic oil discharged from the second switching valve 56. It moves to the right in FIG. 12 against the pressure. As a result, when the neutral range N, the parking range P, or the reverse range R and the electric pump 41 is driven due to a failure, the clutch pressure is reduced regardless of the position of the spool 23 of the linear solenoid valve 20. can do. Therefore, in addition to the effects (1) to (4) of the first embodiment, even when the linear solenoid valve 20 and the electric pump 41 fail at the same time, the hydraulic oil in the linear solenoid valve 20 is discharged and the clutch 30 has a low pressure. The hydraulic oil can be supplied.

(Fourth embodiment)
Next, a fourth embodiment of the present invention will be described with reference to FIG. 4th Embodiment provides the working-fluid discharge channel | path which has a 1st switching valve orifice with respect to 3rd Embodiment. In addition, the same code | symbol is attached | subjected to the site | part substantially the same as 3rd Embodiment, and description is abbreviate | omitted.

    In the fourth embodiment, a hydraulic oil discharge passage 46e having one end connected to the communication passage 46h that connects the first output port 46a and the first supply port 46b of the first switching valve 46 is provided. The other end of the hydraulic oil discharge passage 46e is connected to the first supply pipe 44 when the first switching valve 46 moves leftward. An orifice 46f is provided in the middle of the hydraulic oil discharge passage 46e. The orifice 46f limits the amount of hydraulic oil that passes through the hydraulic oil discharge passage 46e. The hydraulic oil discharge passage 46e corresponds to a “working fluid discharge passage” recited in the claims.

  When the first switching valve 46 is broken with the connection port 21a and the first output port 46a being connected due to a failure, the pressure in the linear solenoid valve 20 cannot be adjusted. In the fourth embodiment, the hydraulic oil staying in the communication passage 46h is gradually discharged by the hydraulic oil discharge passage 46e having one end connected to the communication passage 46h that connects the connection port 21a and the first output port 46a. On the other hand, when the electric pump 41 is driven and the hydraulic oil is discharged to the linear solenoid valve 20, the amount of the hydraulic oil discharged by the orifice 46f provided in the hydraulic oil discharge passage 46e is limited. There is no effect on hydraulic pumping. Therefore, in addition to the effects (1) to (4) of the first embodiment, even when the first switching valve 46 fails, the hydraulic oil can be discharged and the low pressure working fluid can be supplied to the clutch 30.

(Other embodiments)
(A) In the above-described embodiment, the type of the electric pump connected to the first switching valve is the gear pump. However, the type of electric pump does not have to be limited to this. An electric motor drive volume pump, a solenoid drive pump, a piezoelectric drive pump, or the like may be used.

  (A) In the above-described embodiment, the spool valve that controls the pressure of the working fluid is a linear solenoid valve. However, the spool valve need not be limited to this.

  As mentioned above, this invention is not limited to such embodiment, It can implement with a various form in the range which does not deviate from the summary.

15 ... mechanical pump,
17 ... oil pan (storage tank),
21a ... connection port,
21b... Output port,
21c ... supply port,
20 ... Linear solenoid valve (spool valve),
21 ... Sleeve,
23 ・ ・ ・ Spool,
28 ... Linear solenoid valve TCU (spool valve drive control means),
30 ・ ・ ・ Clutch (friction element contributing to starting),
41 ... Electric pump (electric pump),
42a ... Electric pump TCU (electric pump control means),
46 ・ ・ ・ first switching valve,
46e ... hydraulic oil discharge passage (working fluid discharge passage),
46f ... Orifice,
46h ・ ・ ・ Communication passage,
46i ... 2nd pressure accumulation chamber (pressure accumulation chamber),
56 ・ ・ ・ second switching valve,
58 ... 2nd connection pipe (connection channel).

Claims (9)

An idle stop hydraulic control device for an automatic transmission for use in a vehicle equipped with an automatic transmission that shifts by controlling engagement and release of a plurality of friction elements and an idle stop device that stops an internal combustion engine when the vehicle stops. ,
A mechanical pump mechanically driven by the internal combustion engine;
An electric pump that is electrically driven regardless of whether the internal combustion engine is operated or stopped; and
An electric pump drive control means for controlling the drive of the electric pump;
To a supply port that supplies a working fluid from the mechanical pump, a connection port that discharges the working fluid to the outside or supplies a working fluid from the electric pump, and a friction element that contributes to starting of the plurality of friction elements A sleeve having an output port for outputting a working fluid; and a sleeve inserted into the sleeve so as to be reciprocally movable; and communication between the output port and the supply port or displacement of the output port by axial displacement of the sleeve And a spool valve that provides a spool for selectively switching communication with the connection port;
Spool valve drive control means for controlling the drive of the spool with respect to the sleeve;
A switching operation for selectively switching communication between the connection port of the spool valve and the electric pump or communication between the connection port and a storage tank storing the working fluid according to the pressure of the working fluid discharged from the electric pump. A first switching valve that
With
The electric pump is driven when the vehicle is in a forward driving range, the internal combustion engine is in operation, and the spool valve communicates the output port and the connection port. An idle stop hydraulic control device for an automatic transmission. The idle stop hydraulic control apparatus for an automatic transmission according to claim 1 ,
When in the forward range and when the internal combustion engine stops, the spool valve communicates the output port and the connection port to drive the electric pump. Stop hydraulic control device. The idle stop hydraulic control apparatus for an automatic transmission according to claim 1 or 2 ,
The electric pump is a pump capable of reversing the suction and discharge of the working fluid,
When the first switching valve remains in communication between the connection port of the spool valve and the electric pump, and the communication path connecting the connection port and the electric pump is at a low pressure, the electric pump Is an idle stop hydraulic control device for an automatic transmission, which sucks the working fluid in the communication passage. In the idle stop hydraulic control device for an automatic transmission according to any one of claims 1 to 3 ,
The first switching valve includes a working fluid discharge passage that has one end connected to the communication passage and the other end connected to the storage tank, and an orifice is provided in the working fluid discharge passage. Idle stop hydraulic control device. An idle stop hydraulic control device for an automatic transmission for use in a vehicle equipped with an automatic transmission that shifts by controlling engagement and release of a plurality of friction elements and an idle stop device that stops an internal combustion engine when the vehicle stops. ,
A mechanical pump mechanically driven by the internal combustion engine;
An electric pump that is electrically driven regardless of whether the internal combustion engine is operated or stopped; and
An electric pump drive control means for controlling the drive of the electric pump;
To a supply port that supplies a working fluid from the mechanical pump, a connection port that discharges the working fluid to the outside or supplies a working fluid from the electric pump, and a friction element that contributes to starting of the plurality of friction elements A sleeve having an output port for outputting a working fluid; and a sleeve inserted into the sleeve so as to be reciprocally movable; and communication between the output port and the supply port or displacement of the output port by axial displacement of the sleeve And a spool valve that provides a spool for selectively switching communication with the connection port;
Spool valve drive control means for controlling the drive of the spool with respect to the sleeve;
A first switching valve that performs a first switching operation that selectively switches communication between the connection port of the spool valve and the electric pump or communication between the connection port and a storage tank that stores a working fluid;
A second switching valve for performing a second switching operation for selectively switching the communication between the connection passage formed in the first switching valve with the pressure accumulating chamber and the mechanical pump or the communication between the connection passage and the storage tank. When,
With
The second switching valve performs the second switching operation by the pressure of the working fluid of the mechanical pump,
The automatic switching idle stop hydraulic control device according to claim 1, wherein the first switching valve performs the first switching operation by the pressure of the working fluid in the connection passage and the pressure of the working fluid of the electric pump. In the idle stop hydraulic control device for an automatic transmission according to claim 5 ,
The electric pump is driven when the vehicle is in a forward driving range, the internal combustion engine is in operation, and the spool valve communicates the output port and the connection port. An idle stop hydraulic control device for an automatic transmission. The idle stop hydraulic control device for an automatic transmission according to claim 5 or 6 ,
When in the forward range and when the internal combustion engine stops, the spool valve communicates the output port and the connection port to drive the electric pump. Stop hydraulic control device. The idle stop hydraulic control apparatus for an automatic transmission according to claim 1 or 2 ,
The electric pump is a pump capable of reversing the suction and discharge of the working fluid,
When the first switching valve remains in communication between the connection port of the spool valve and the electric pump, and the communication path connecting the connection port and the electric pump is at a low pressure, the electric pump Is an idle stop hydraulic control device for an automatic transmission, which sucks the working fluid in the communication passage. In the idle stop hydraulic control device for an automatic transmission according to any one of claims 1 to 3 ,
The first switching valve includes a working fluid discharge passage that has one end connected to the communication passage and the other end connected to the storage tank, and an orifice is provided in the working fluid discharge passage. Idle stop hydraulic control device.

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