DE102011085333A1 - hydraulic system - Google Patents

Abstract

The invention relates to a hydraulic system for controlling a dual clutch transmission with four gear actuators. The invention is characterized in that a volume flow control valve and a pressure regulating valve are connected upstream of the gear actuators in such a way that the gear actuators are moved in a volume flow-controlled and pressure-regulated manner depending on the shift position of a gear selector valve when a gear is engaged.

Description

The invention relates to a hydraulic system for driving a dual-clutch transmission with four gear actuators.

From the German patent application DE 10 2008 031 483 A1 is a dual-clutch transmission with a device for controlling a plurality of hydraulic shift cylinder known. To improve the speed when engaging a gear required for gear shift cylinders are controlled by means of at least three electromagnetically switchable directional control valves.

The object of the invention is to simplify the driving of a dual-clutch transmission with four gear actuators.

The object is achieved in a hydraulic system for driving a dual-clutch transmission with four gear actuators, that the gear actuators a flow control valve and a pressure control valve are connected upstream so that the gear selector in response to the shift position of a gear selector valve when inserting a gear volume flow controlled and pressure-controlled moves. The gear regulators include, for example, a shift cylinder in which a gear actuator piston is reciprocally movable to actuate a shift rail. The hydraulic system according to the invention makes it possible in a simple manner to control and influence both the force and the speed during shifting. In addition, almost identical valves can be used by the circuit according to the invention in the hydraulic system, whereby high quantities and thus low production costs are made possible.

A preferred embodiment of the hydraulic system is characterized in that the volume flow control valve and the pressure control valve are designed as 3/2-way valves. The 3/2-way valves each include a tank port and a pressure port to which a hydraulic pressure source is connected.

Another preferred embodiment of the hydraulic system is characterized in that the volume flow control valve and the pressure control valve are continuously adjustable and electrically actuated. The two valves are preferably designed as proportional valves.

Another preferred embodiment of the hydraulic system is characterized in that the gear selector valve is designed as a 4/2-way valve. The gear selector valve is preferably designed as a switching valve with two switching positions. The volume flow control valve is connected to a first connection of the gear selector valve. To a second connection of the gear selector valve, the pressure control valve is connected. To a third port of the gear selector valve, a B-side of a first gear pair is connected. To a fourth port of the gear selector valve, a B-side of a second gear actuator pair is connected. In a first switching position of the gear selector valve, the volume flow control valve to the B side of the second gear set pair and the pressure control valve to the B side of the first gear set pair are connected. In a second switching position of the gear selector valve, the volume flow control valve with the B side of the first gear set pair and the pressure control valve with the B side of the second gear set pair are connected.

A further preferred embodiment of the hydraulic system is characterized in that the gear plates are combined in pairs and connected to each other via a connecting line on an A-side. A first and a second gear shifter form the first gear pair. A third and a fourth gear plate form the second gear pair.

Another preferred exemplary embodiment of the hydraulic system is characterized in that the gear actuators on a B side are connected to the volume flow control valve or the pressure control valve as a function of the switching position of the gear selector valve. As a result, a simple circuit is created, which is inexpensive to produce.

Another preferred embodiment of the hydraulic system is characterized in that the A-side of a first gear set pair is connected to a branch which is arranged between the flow control valve and the gear selector valve. About the connecting line and the junction are the A-sides of all gear shifter with each other.

A further preferred embodiment of the hydraulic system is characterized in that between the gear actuators of a gear plate pair each have a locking device is arranged, which is controlled via a switching valve. The switching valve is preferably designed as a 3/2-way valve. The locking device serves to lock each one gear regulator one of the gear actuator pairs.

Another preferred embodiment of the hydraulic system is characterized in that two clutches of the dual-clutch transmission in each case a volume flow control valve is connected upstream. The two volume flow control valves are preferably also designed as 3/2-way valves. The volume flow control valves upstream of the clutches are preferably designed in the same way as the volume flow control valve arranged upstream of the gear actuators.

The invention further relates to a method for driving a dual-clutch transmission with a hydraulic system described above. The hydraulic system is subjected to a system pressure, for example, by means of a hydraulic pump. The hydraulic system further preferably comprises a hydraulic pressure accumulator which is filled with hydraulic medium by means of the hydraulic pump.

Further advantages, features and details of the invention will become apparent from the following description in which, with reference to the drawings, various embodiments are described in detail. Show it:

1 an inventive hydraulic system in the form of a hydraulic circuit diagram;

2 an enlarged section 1 with an arranged between two gear actuators locking device and

3 an enlarged and detailed view of the locking device 2 ,

1 shows a hydraulic diagram of a hydraulic system 1 with a hydraulic medium reservoir 2 , The hydraulic medium is, for example, hydraulic oil which is provided with a hydraulic pressure source, which is preferably designed as a hydraulic pump 3 pressurized with hydraulic pressure. At the hydraulic pump 3 it is preferably an electrically driven pump in Verdrängerbauweise.

Excess hydraulic medium, especially oil, is used to fill a hydraulic accumulator 5 used until a target pressure level is reached and the hydraulic pump 3 is switched off. A check valve 4 prevents unwanted emptying of the hydraulic accumulator 5 over the hydraulic pump 3 in the hydraulic medium reservoir 2 , Switching the hydraulic pump on and off 3 is via a pressure sensor 6 in a system pressure area 7 monitored, which is subjected to a system pressure. A pressure relief valve 8th prevents an undesirable exceeding of the system pressure.

The hydraulic system 1 includes four gear shifters 11 . 12 . 13 . 14 and two clutches 41 . 42 , A first gearshift 11 and a second gear knob 12 are interconnected to a first gear pair. A third gear plate 13 and a fourth gear knob 14 are connected together to form a second gear pair.

Pressing the gear plates 11 to 14 is achieved by means of a volume flow control valve 21 , a pressure control valve 22 and a gear selector valve 25 controlled. The volume flow control valve 21 and the pressure control valve 22 are designed as infinitely variable 3/2-way valves. The valves 21 . 22 . 25 are each biased by a spring in their illustrated switch positions and are electrically operated. The volume flow control valve 21 and the pressure control valve 22 are designed as proportional valves. The gear selector valve 25 is designed as a switching valve.

A first connection of the two valves 21 . 22 Used to connect the system pressure. A second connection of the two valves 21 . 22 is connected to the hydraulic medium reservoir, which is also referred to as a tank. A third connection of the volume flow control valve 21 is over a branch 26 with a first connection of the gear selector valve 25 in connection. A third connection of the pressure control valve 22 stands with a second connection of the gear selector valve 25 in connection.

A third connection of the gear selector valve 25 is with a B side of the first gear pair 11 . 12 connected. An A side of the first gear pair 11 . 12 is with the branching 26 connected. The A side of the first gear pair 11 . 12 is about a connection 28 with an A-side of the second Gear actuator pair 13 . 14 connected. A B side of the second gear pair 13 . 14 is with a fourth connection of the gear selector valve 25 connected.

The first gear pair 11 . 12 is a first locking device 31 assigned. The second gear pair 13 . 14 is a second locking device 32 assigned. The two locking devices 31 . 32 are via a switching valve 35 controlled or pre-controlled. The switching valve 35 is designed as a 3/2-way valve and biased by a spring in its illustrated switching position. The switching valve 35 is electrically operated. In the illustrated shift position, the gear shifter 11 and 13 locked. When the switching valve 35 is switched, then the gear shifter 11 and 13 released and the gear plates 12 and 14 locked.

When the switching valve 35 is de-energized, so the switching valve 35 is located in a switching position shown, then are in de-energized gear selector valve 25 following switching movements possible: second gear 12 Direction A, supply control 22 , Flow control 21 ; second gear knob 12 Direction B, supply control 21 , Process control 22 , All switching movements with the hydraulic system according to the invention 1 possible are shown in the following table: Engage gear 35 lock 25 21 22 11 Direction A energized 12 + 14 energized flow control Fill control 11 Direction B energized 12 + 14 energized feed control Discharge control 12 Direction A energized 11 + 13 energized flow control Fill control 12 Direction B energized 11 + 13 energized feed control Discharge control 13 Direction A energized 12 + 14 energized flow control Fill control 13 Direction B energized 12 + 14 energized feed control Discharge control 14 Direction A energized 11 + 13 energized flow control Fill control 14 Direction B energized 11 + 13 energized feed control Discharge control

Via the volume flow control valve 21 and the pressure control valve 22 can, depending on the position of the gear selector valve 25 , the inlet and the expiration of the gear plate 11 to 14 pressure-controlled and volume flow controlled "to be moved". It is either the inlet of the respective gear selector pressure-controlled and the flow volume flow controlled, or vice versa, depending on the gear plate. This can with every gear plate 11 to 14 at the same time the pressure and the volume flow are influenced. Thus, the speed and the force during the switching operations can be controlled or influenced.

The two clutches 41 . 42 are each via a flow control valve 43 . 44 actuated. The two volume flow control valves 43 . 44 are, as well as the flow control valve 21 designed as infinitely variable and electrically operated 3/2-way valves. The two volume flow control valves 43 . 44 control the two path-controlled clutches 41 . 42 , Alternatively, a position-controlled and a pressure-controlled clutch or two pressure-controlled couplings could be used. It would have one or both valves 43 . 44 but then run as a pressure regulator.

In the 2 and 3 is the locking device 32 between the two gear actuators 13 and 14 enlarged and detailed. The gear plates 11 to 14 are each executed the same and are described below by means of the gear selector 13 in 2 described in detail. The gear plate 13 includes a shift cylinder 50 in which a piston with two piston surfaces 51 . 52 is movable back and forth. The piston surface 51 is commissioned on page A with pressure. The piston surface 52 is pressurized on side B. Between the two piston surfaces 51 . 52 is a shift rail 54 arranged. The gear plate 14 includes a shift rail 55 ,

In 3 you can see that the locking device 32 a locking piston 60 comprises, which is movable in a locking cylinder back and forth. The locking piston 60 is by a spring 61 down, so to the shift rail 55 down, biased. On his pen 61 opposite side, the locking piston 60 in a pressure room 62 via the switching valve ( 35 in 1 ) are applied to the system pressure or with a pilot pressure to the locking piston 60 up, that is to the shift rail 54 to move.

On the locking piston 60 are two locking members 64 . 65 attached, which are designed as piston rods and extend in opposite directions. The locking member 65 engages with its free end in a Arretierausnehmung 67 one on the shift rail 55 is provided. This will cause the shift rail 55 locked. At the shift rail 54 is a corresponding locking recess 66 provided, in which the locking member 64 engages with its free end when the locking device 32 via the switching valve 35 is pressed.

LIST OF REFERENCE NUMBERS

1

hydraulic system

2

Hydraulic fluid reservoir

3

Hydraulic pressure source

4

check valve

5

Hydraulic accumulator

6

pressure sensor

7

System pressure range

8th

Pressure relief valve

11

gear actuator

12

gear actuator

13

gear actuator

14

gear actuator

21

Flow control valve

22

Pressure control valve

25

Gear actuator selector valve

26

branch

28

connection

31

locking

32

locking

35

switching valve

41

clutch

42

clutch

43

Flow control valve

44

Flow control valve

50

switching cylinder

51

piston area

52

piston area

54

shift rail

55

shift rail

60

lock piston

61

feather

62

pressure chamber

64

locking member

65

locking member

66

locking recess

67

locking recess

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102008031483 A1 [0002]

Claims (10)

Hydraulic system for driving a dual-clutch transmission with four gear actuators ( 11 - 14 ), characterized in that the gear actuators ( 11 - 14 ) a volume flow control valve ( 21 ) and a pressure control valve ( 22 ) are connected upstream so that the gear plate ( 11 - 14 ) in dependence on the switching position of a gear selector valve ( 25 ) are moved volume-controlled and pressure-controlled when inserting a gear. Hydraulic system according to claim 1, characterized in that the volume flow control valve ( 21 ) and the pressure control valve ( 22 ) are designed as a 3/2-way valve. Hydraulic system according to one of the preceding claims, characterized in that the volume flow control valve ( 21 ) and the pressure control valve ( 22 ) are infinitely adjustable and electrically operated. Hydraulic system according to one of the preceding claims, characterized in that the gear selector valve ( 25 ) is designed as a 4/2-way valve. Hydraulic system according to one of the preceding claims, characterized in that the gear plates ( 11 - 14 ) in pairs and via a connecting line ( 28 ) are connected together on an A-side. Hydraulic system according to claim 5, characterized in that the gear plate ( 11 - 14 ) on a B side in dependence on the switching position of the gear selector valve ( 25 ) with the volume flow control valve ( 21 ) or the pressure regulating valve ( 22 ) are connected. Hydraulic system according to claim 5 or 6, characterized in that the A side of a first gear pair ( 11 . 12 ) with a branch ( 26 ) connected between the volume flow control valve ( 21 ) and the gear selector valve ( 25 ) is arranged. Hydraulic system according to one of claims 5 to 7, characterized in that between the gear actuators of a gear actuator pair ( 11 . 12 ; 13 . 14 ) each have a locking device ( 31 . 32 ) is arranged, which via a switching valve ( 35 ) is controllable. Hydraulic system according to claim 8, characterized in that two clutches ( 41 . 42 ) of the dual-clutch transmission in each case a volume flow control valve ( 43 . 44 ) is connected upstream. Method for controlling a dual-clutch transmission with a hydraulic system ( 1 ) according to any one of the preceding claims.

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