DE102018126550B4 - Hydraulic transmission actuator - Google Patents

Abstract

Hydraulic transmission actuator (10) with a carrier component (12), an attached storage container (14) for hydraulic fluid, a first hydraulic pump (16) attached to the carrier component (12) with two pressure outlets (38), each of which is assigned a proportional valve (44). , and a second hydraulic pump (18), also attached to the support component (12), which has two outputs (50) for supplying the actuating cylinders of a transmission.

Description

The invention relates to a hydraulic transmission actuator which is suitable for switching various components of a manual transmission, as used in motor vehicles.

Dual clutch transmissions are known from the prior art, which have two friction clutches, one of which is assigned to the even gears and one to the odd gears. By appropriately operating the two friction clutches, you can shift from one gear to the next without interrupting the traction.

In such transmissions, it is also known that hydraulic actuating cylinders are used to shift the individual gears in the desired manner, i.e. to connect the idler gear of a pair of gears, which forms a gear ratio, to the drive shaft in a rotationally fixed manner or to release this connection again.

To actuate the two friction clutches, a clutch actuator is usually used in the prior art, which has a hydraulic pump and at least two proportional valves as an essential component, by means of which a desired hydraulic pressure can be provided in a controlled or regulated manner. A closed hydraulic circuit, in which a pump is arranged, can be used to actuate the actuating cylinders. Depending on the direction of rotation of the pump, a specific actuating cylinder is actuated in one direction or the other.

The DE 10 2013 000 157 B3 discloses a hydraulic actuating device for actuating a friction clutch and a transmission actuator in a motor vehicle, wherein the piston of the clutch actuating cylinder is functionally assigned a locking device with a locking element as a control member, which is spring-biased into a locking position preventing movement of the piston and which by means of a via the control unit Electrically controllable actuator can be moved from the locking position against the spring preload into a release position that allows movement of the piston.

Further state of the art in this area is shown in: DE 10 2014 001 073 A1 , the EP 1 965 100 A2 , the EP 2 532 914 A1 , the WO 2004/ 072 444 A1 and the WO 2011/ 042 105 A2 .

In the DE 199 52 167 A1 A pump arrangement is shown, with a vane pump and a second hydropump driven together with this. A suction groove of the vane pump is not connected to the suction inlet, but rather to the pressure outlet of the radial piston pump.

From the DE 10 2011 105 648 A1 a hydraulic actuating device is known which includes a multi-circuit pump for supplying two pressure circuits.

The object of the invention is to reduce the effort involved in providing the hydraulic pressure or flow for the various components.

To solve this problem, according to the invention, a hydraulic transmission actuator is provided with a carrier component, an attached storage container for hydraulic fluid, a clutch hydraulic pump attached to the carrier component with two pressure outputs, each of which is assigned a proportional valve, and a switching hydraulic pump also attached to the carrier component has two outputs to supply the actuating cylinders of a transmission. The invention is based on the basic idea of combining the two different pumps into one actuator by attaching them to the support component, so that they can share a storage container and overall a very compact structure is achieved.

According to one embodiment of the invention it is provided that the two pressure outputs of the clutch hydraulic pump are symmetrical to one another. “Symmetrical to each other” means that they are designed identically so that they are supplied with the same hydraulic current when the pump is operating. This means that the two friction clutches of a dual clutch transmission can be operated independently of one another using the same hydraulic pump and the two proportional valves.

According to one embodiment of the invention it is provided that the two proportional valves are arranged in the storage container. This allows them to be cooled by the hydraulic fluid contained in the reservoir.

The proportional valves are preferably surrounded by hydraulic fluid, so that a very reproducible damping behavior for the magnetic core results.

According to one embodiment of the invention, it is provided that a check valve is arranged between a pressure outlet and a proportional valve. The check valve makes it possible to maintain a hydraulic pressure built up at a pressure connection of the transmission actuator even when the clutch hydraulic pump is switched off.

The clutch hydraulic pump draws suction from the reservoir, with the output of the proportional valves leading directly back to the reservoir. This results in a compact structure.

According to a preferred embodiment of the invention, the clutch hydraulic pump is a roller cell pump. It is characterized by a long service life with high reliability and good conveying performance.

According to the invention, a suction connection can be provided between each output of the switching hydraulic pump and a supply connection for the actuating cylinders, which is connected to the storage container and has a check valve. The hydraulic circuit, which is pressurized in one direction or the other by the switching hydraulic pump, can suck in hydraulic fluid via the suction connection as soon as the pressure on the respective suction side is below a certain value. This means that any leakage is immediately compensated for.

According to an alternative embodiment of the invention, it is provided that a supply connection for a further clutch is connected to an output of the switching hydraulic pump. The further clutch can be a clutch with which, for example, the internal combustion engine of a hybrid drive can be decoupled from the transmission and reconnected. This clutch can then be actuated without much additional effort using the transmission actuator according to the invention.

It is preferably provided that a switching valve, a check valve and a proportional valve are arranged between the output and the supply connection. With the switching valve, the supply connection for the additional clutch can be isolated from the circuit of the switching hydraulic pump, so that the clutch is not unintentionally pressurized when the actuating cylinder is actuated. The switching valve and check valve can also be combined into one component. In order to put the supply connection for the additional pump into operation, the switching valve is switched to a continuous position so that the pressure generated by the switching hydraulic pump can then be controlled or regulated using the proportional valve.

• - 1 in einer perspektivischen Ansicht einen erfindungsgemäßen Getriebeaktuator;
• - 2 eine Draufsicht auf den Getriebeaktuator von 1;
• - 3 eine Seitenansicht des Getriebeaktuators von 1;
• - 4 einen Schnitt entlang der Ebene IV-IV von 2;
• - 5 einen hydraulischen Schaltplan des Getriebeaktuators der 1 bis 4; und
• - 6 einen hydraulischen Schaltplan eines Getriebeaktuators gemäß einer zweiten Ausführungsform.

The invention is described below using two embodiments, which are shown in the accompanying drawings. Show in these:

• - 1 a perspective view of a transmission actuator according to the invention;
• - 2 a top view of the transmission actuator of 1 ;
• - 3 a side view of the transmission actuator from 1 ;
• - 4 a section along plane IV-IV of 2 ;
• - 5 a hydraulic circuit diagram of the transmission actuator 1 to 4 ; and
• - 6 a hydraulic circuit diagram of a transmission actuator according to a second embodiment.

In the 1 to 4 A hydraulic transmission actuator can be seen, which has a central support component 12, on one side (here on the upper side) a reservoir 14 for hydraulic fluid is attached.

On the side opposite the storage container, a first and a second hydraulic pump are attached to the carrier component, which are referred to below as a clutch hydraulic pump 16 and a switching hydraulic pump 18 for better differentiation.

The clutch hydraulic pump 16 is intended to supply two pressure connections 20, 22 with hydraulic pressure and current (see also 5 ). One of the pressure ports 20, 22 is connected to an actuating cylinder of a first friction clutch, and the other of the pressure ports 20, 22 is connected to a further actuating cylinder for a second friction clutch. The two friction clutches are part of a dual clutch transmission and serve to transmit drive torque to a first and a second transmission shaft.

The switching hydraulic pump is arranged in a fluid circuit which has two connections 24, 26 to which various switching cylinders S1 to S5 (see 5 ) are connected. Details of this switching cylinder can be found on the DE 10 2013 000 157 B3 to get expelled.

The clutch hydraulic pump is a roller cell pump and includes an electric motor 30 that drives a rotor 32 that rotates in a stator 34. The stator has a (in 4 (not visible) fluid inlet 36, through which fluid is sucked out of the storage container 14, as well as two pressure outlets 38.

The pressure outputs 38 are connected to output chambers 40 arranged on both sides of the stator 34, so that the axial flow The communication paths out of the individual chambers of the roller cell pump are very short.

A check valve 42 and a proportional valve 44 are arranged between the pressure outputs 38 of the clutch hydraulic pump 16 and the corresponding pressure connections 20, 22. The proportional valves 44 can be used to control (or, if a pressure sensor is present, also regulate) the hydraulic pressure and the hydraulic flow at the pressure connections 20, 22. The check valves 42 serve to maintain pressure at the pressure connections 20, 22 even when the clutch hydraulic pump 16 is switched off.

A special feature of the proportional valves 44 is that they are arranged in the pre-locking container 14 (see in particular 2 ). Not only are they surrounded by hydraulic fluid on the outside, but the hydraulic fluid is also in the gap between the coil and the armature of the proportional valve. This results in very constant damping.

The switching hydraulic pump 18 is basically constructed identically to the clutch hydraulic pump 16. It is also a roller cell pump that has two symmetrically constructed outputs 50. The difference to the clutch hydraulic pump 16 is that the switching hydraulic pump 18 can be operated in two directions of rotation, while the clutch hydraulic pump is always operated in the same direction of delivery. The switching hydraulic pump 18 also does not suck primarily from the storage container 14, but depending on the direction of rotation from one or the other output 50, which accordingly becomes the input. In other words, the switching hydraulic pump 18 “shifts” the hydraulic fluid either to one connection 24 or to the other connection 26, so that one side of the switching valves S1 to S5 is pressurized or the other side.

Between each output 50 of the switching hydraulic pump 18 and the corresponding connection 24, 26, a suction connection 52 is provided, which is provided with a check valve 54 and via which hydraulic fluid can be sucked out of the storage container 14 when the pressure on the "suction side" of the Switching hydraulic pump 18 falls below a certain value.

With the transmission actuator described, two friction clutches of a dual clutch transmission can be switched simultaneously via the pressure connections 20, 22, while at the same time the actuating cylinders of the transmission can be actuated via the connections 24, 26.

In 6 a second embodiment of the transmission actuator 10 is shown. The same reference numbers are used for the components known from the first embodiment, and reference is made to the above explanations.

The difference between the first and second embodiments is that in the second embodiment an additional supply connection 27 is provided for another actuator.

The further actuator can be a parking brake. It is also possible that the additional actuator is another clutch. The additional clutch can be used, for example, to disconnect or reconnect an internal combustion engine of a hybrid drive from the transmission. Regardless of the fact that the second hydraulic pump 18 in the second embodiment no longer serves exclusively to actuate the actuating cylinders, it is still referred to as a switching hydraulic pump.

The supply connection 27 branches off from one of the outputs 50 of the switching hydraulic pump 18. Between the output 50 and the supply connection 27, a switching valve 60 is provided, which can be adjusted between a continuous and a closed position, a check valve 62 and a proportional valve 64.

The switching valve 60 serves to isolate the supply connection 27 from the hydraulic circuit that can supply the actuating cylinders. In the shut-off state, the presence of the supply connection 27 has no effect on the functioning of the switching hydraulic pump and the supply to the actuating cylinders.

If the supply port 27 is to be operated, the switching valve 60 is switched to a continuous position and the output 50 to which the supply port 27 is connected is pressurized (in 6 the right exit 50). Then, by activating the proportional valve, the pressure at the supply connection 27 can be controlled in the desired manner (and also regulated if a pressure sensor is present).

Claims (11)

Hydraulic transmission actuator (10) with a carrier component (12), an attached storage container (14) for hydraulic fluid, a first hydraulic pump (16) attached to the carrier component (12) with two pressure outlets (38), each of which is assigned a proportional valve (44). , and one also attached to the support component (12). th hydraulic pump (18), which has two outputs (50) for supplying the actuating cylinders of a transmission. Hydraulic transmission actuator (10) after Claim 1 , characterized in that the two pressure outputs (38) of the first hydraulic pump (16) are symmetrical to one another. Hydraulic transmission actuator (10) after Claim 1 or Claim 2 , characterized in that the two proportional valves (44) are arranged in the storage container (14). Hydraulic transmission actuator (10) after Claim 3 , characterized in that the proportional valves (44) are surrounded by hydraulic fluid. Hydraulic transmission actuator (10) according to one of the preceding claims, characterized in that a check valve (42) is arranged between a pressure outlet (38) and a proportional valve (44). Hydraulic transmission actuator (10) according to one of the preceding claims, characterized in that the first hydraulic pump (16) sucks from the storage container (14). Hydraulic transmission actuator (10) according to one of the preceding claims, characterized in that the first hydraulic pump (16) is a roller cell pump. Hydraulic transmission actuator (10) according to one of the preceding claims, characterized in that a suction connection (52) is provided between each output (50) of the second hydraulic pump (18) and a connection (24, 26) for the actuating cylinders, which is connected to the storage container (14) is connected and has a check valve (54). Hydraulic transmission actuator (10) according to one of the preceding claims, characterized in that a supply connection (27) for a further clutch is connected to an output (50) of the second hydraulic pump (18). Hydraulic transmission actuator (10) after Claim 9 , characterized in that a switching valve (60), a check valve (62) and a proportional valve (64) are arranged between the output (50) and the supply connection (27). Hydraulic transmission actuator after Claim 10 , characterized in that the check valve (62) and the switching valve (60) are combined into one component.

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