DE102013213678A1 - Device for actuating a locking mechanism, in particular for actuating a parking brake device of a drive train designed with an automatic transmission - Google Patents

Abstract

The invention relates to a device (1) for actuating a locking mechanism (2) with a piston unit (4), a latching device (5) and an actuating device (6) for actuating a release element (7), which is used to switch over the latching device (5) a preferably provided by an electromagnet (10) provided actuating force of the actuating device (6) can be acted upon. According to the invention, a hydraulic actuating region (15) of the piston unit (4) is formed with a leakage point (14) which can be switched between open and closed states whose flow cross-section is dimensioned such that a pressure build-up for actuating the piston unit (4) starts from one to the closed one Operating state of the locking mechanism (2) equivalent axial position in the direction of the open state of the locking mechanism (2) equivalent axial position in the open operating state of the leakage point (14) is prevented.

Description

The invention relates to a device for actuating a locking mechanism, in particular for actuating a parking brake device of a running with an automatic transmission drive train according to the closer defined in the preamble of claim 1. Art.

In known from practice devices for actuating locking mechanisms, such as parking brake devices each executed with an automatic transmission vehicle drive trains, it is usually provided to transfer the locking mechanism via a spring to its closed operating state and by pressurizing a cooperating with the parking brake device piston unit against the spring accumulator from the closed operating state in the open operating state to transfer. In this case, the piston unit is held in its open operating state of the parking brake device equivalent axial position against the spring force of the spring accumulator in the activated state of a latching device even with no more applied hydraulic pressure of this.

Disadvantageously, the piston unit in the case of erroneous application of actuating pressure from its axial closed position to the closed operating state of the parking brake device in the direction of their open operating state of the parking brake device equivalent axial position feasible, with which the parking brake device is undesirably interpretable in case of failure.

From the unpublished DE 10 2012 210 571.9 The Applicant is a device for actuating a locking mechanism, in particular for actuating a parking brake device of a running with an automatic transmission drive train of a vehicle known. The device comprises a piston unit slidably disposed in the axial direction, a latching device automatically activating in an axial position of the piston unit equivalent to an open state of the latching mechanism, for holding the piston unit in the axial position equivalent to the open state of the latching mechanism, and an actuator for actuating a release element on, which is provided for deactivating the latching device. The latching means is designed to activate the piston unit in an axial position equivalent to a closed state of the latching mechanism and to release movement of the piston unit from the axial position equivalent to the closed state of the latching mechanism toward the axial position equivalent to the open state of the latching mechanism deactivated.

The device is part of an electro-hydraulic parking lock operation and is also referred to as a parking lock actuator, by means of which the parking brake of a vehicle without hydraulic pressure supply in the designed position is stable. The engagement of the parking brake is effected via a hydraulic pressure, which adjusts the piston unit or a cylinder from a first end position, to which the parking brake is engaged, in a second end position in which the parking brake is designed. The disengagement of the parking brake is performed via a spring return mechanism, wherein the electromagnetic locking mechanism of the device in the unpressurized state prevents unwanted engagement of the parking brake against the force of the return mechanism. In addition, the interpretation of the parking brake is also in case of failure, such as an undesirable hydraulic control of the piston unit, prevented by the locking device mechanically locks the parking lock engaged with active parking of an electromagnet by laying out the parking brake. Thus, a vehicle is also secured during a so-called remote start of a vehicle against unwanted starting.

The problem with this is, however, that the interpretation of the parking brake in case of failure of the power supply of the device and simultaneous undesired pressurization of the piston unit is not ensured to the extent required.

The present invention is therefore an object of the invention to provide a device for actuating a locking mechanism, in particular for actuating a parking brake device available, by means of an undesirable design of a parking brake is safely avoided.

According to the invention this object is achieved with a device having the features of claim 1.

In the device according to the invention for actuating a locking mechanism, in particular for actuating a parking lock device of a vehicle equipped with an automatic transmission drive train, the at least one in the closing direction of the locking mechanism spring-loaded and in the opening direction of the locking mechanism hydraulically actuated piston unit, a latching device for holding the piston unit in the open Operating state of the locking mechanism equivalent axial position and an actuating device for actuating a release element, which is used to switch the latching device between a piston unit and one holding the A hydraulic actuation range of the piston unit is formed with a switchable between an open and a closed state leakage point, the flow cross-section is dimensioned so that a pressure build-up for actuating the piston unit is prevented from an equivalent to the closed operating state of the locking mechanism axial position in the direction of the open state of the locking mechanism equivalent axial position in the open operating state of the leakage point.

About the inventive device is an undesirable opening of the locking mechanism or an undesirable opening the parking brake device in a structurally simple and cost-effective manner even in case of failure to which the piston unit is acted upon without corresponding request to open the locking mechanism with actuating pressure, since the in Direction of the piston unit guided actuation pressure is reduced via the then present in the open operating state leakage point and an undesired adjustment of the piston unit in the direction of its closed operating state of the locking mechanism or the inserted operating state of the parking brake device safely omitted.

The locking mechanism or the parking brake device is not opened or designed even in the event of a power failure if the leakage point is in the current operating state of an electromagnet of the actuating device with the locking mechanism closed or with the parking brake device engaged.

The operation of the device according to the invention provides a redundant protection of a locking mechanism or a parking brake device against unintentional opening or laying in case of failure, to which the piston unit is undesirably acted upon by actuating pressure available. This functionality is particularly required for vehicles that are designed with a so-called remote start function or with a so-called engine start-stop system, in which a prime mover of a vehicle can pass without a corresponding driver request in a switched operating state or from a parent Operating strategy and a shutdown of the prime mover in the closed operating state of the locking mechanism or in the engaged operating state of the parking brake device may be provided.

In the present case, a remote start of a vehicle means a start of the engine of a vehicle by remote control without a driver being in the vehicle. Such a remote start is performed, for example, by an operator to warm a vehicle or to cool the interior by means of air conditioning.

The background is that a hydraulic supply of an automatic transmission and also a device for actuating a parking brake device is carried out by a transmission oil pump, which provides only in switched-on operating state of the prime mover of a vehicle drive train a hydraulic fluid volume flow required for this purpose.

In an embodiment of the device according to the invention which can be actuated with little effort, the leakage point can be opened and closed via a valve device.

If the valve device is provided in the region of a line via which the piston unit can be acted upon by actuating pressure, a pressure buildup in the region of the piston unit without additional space requirement in the area of conventionally designed devices can be avoided.

In structurally simple and cost-producible developments of the devices according to the invention, the valve device via a voltage applied in the region of the piston unit hydraulic pressure and / or via a pressure medium source can be applied to the piston unit hydraulic pressure in a closing position closing the operating state and / or preserved by the hydraulic pressure in this operating condition ,

If the valve device comprises a valve tappet cooperating with the piston unit, which releases or closes the leakage point as a function of an operating state of the actuating device and / or the operating state of the piston unit, existing devices can be executed with little effort with the switchable leakage point.

The valve stem is coupled in a particularly space-saving and easy operable embodiment of the device according to the invention with the release element, which is in operative connection with an anchor element of the electromagnet of the actuator, wherein the valve stem in energized operating state of the electromagnet sealingly in the preferably as in the Piston unit extending line formed leakage point engages, which connects in a released from the valve tappet operating state acted upon by an actuating pressure region of the piston unit with a low pressure region.

If the release element is designed to be displaceable in relation to the anchor element and a spring device is provided between the anchor element and the release element, via which the actuating force of the electromagnet can be forwarded from the anchor element to the release element, movements of the release element are possible without the anchor element from a pole face of the electromagnet having to lift off the energized operating state of the electromagnet. Thus, in the energized operating state of the electromagnet high holding forces at the same time low power consumption of the solenoid can be displayed and the electromagnet cost and space interpreted interpretable.

If a spring device is provided between the release element and the piston unit via which a force can be imparted to the release element from the piston unit, which is opposite to the actuating force of the electromagnet, the release element is displaceable, for example, during activation of the latching device with respect to the piston unit, at least in the short term the armature element of the electromagnet in turn can be applied to the pole face of the electromagnet when activating the latching device.

In order to avoid unwanted operating noise in the region of the device according to the invention, the piston unit is formed in a further advantageous embodiment with a range in a matched to the area of the piston unit before reaching an end position of the piston unit to which the locking mechanism is in the closed operating condition a housing-fixed component surrounding the piston unit dips for damping an actuating speed of the piston unit. About this so-called end position damping unwanted noise, which are caused by a strong impact of the piston unit to a housing-fixed stop, avoided with little effort.

Are a travel of the piston unit and a length of the valve stem coordinated so that the locking mechanism passes before immersing the area of the piston unit in the region of the housing-fixed component in its closed operating state and the leakage point before immersing the area of the piston unit in the region of the housing-fixed component from Valve tappet is locked, is ensured with little effort that the closed operating state of the locking mechanism by the Endlagendämpfung can be produced without delay to the desired extent and on the other hand driving noise affecting operating comfort are reliably avoided.

During fault-free driving operations of vehicle drive trains, a parking brake device is usually designed. In case of an error case in which the power supply of a vehicle drive train and thus the device according to the invention may not be guaranteed, in particular an automatic transmission associated with the device goes into a so-called mechanical emergency, to which a so-called predefined emergency gear is engaged in the automatic transmission. Due to the circuit in the automatic transmission, which may have to be carried out for this purpose, there is the possibility that the actuating pressure holding the parking brake device in a disengaged operating state will strongly collapse and the parking brake device will be engaged with high dynamics.

By the above-described end position damping is now avoided that the axial position of the piston unit, to which the leakage point is in the open operating state, is reached too quickly. This is a renewed pressurization of the piston unit with actuating pressure after completion of the pressure drop is possible and the parking brake device can be converted by the applied pressure in emergency operation again in its designed operating condition.

Characterized in that the leakage point is blocked before immersion of the region of the piston unit in the region of the housing-fixed component of the valve lifter, the parking brake device is also in the occurrence of an emergency mode with renewed timely pressure build-up in its designed operating state can be transferred.

In the open operating state of the leakage point, the piston unit is no longer adjustable even when re-printing in emergency in its open to the operating state of the locking mechanism or in their designed for the operating state of the parking brake device axial position. Therefore, the parking brake device is at open leakage point while driving the vehicle in a so-called ratcheting operating state to which a parking lock pawl of the parking brake device is in contact with a parking lock gear, but does not go into the closed mode. This results from the fact that the parking pawl is rejected at higher speeds of the teeth of the parking lock gear, which is associated with a strong noise and high wear.

If the piston unit is held by the latching device in its equivalent to the open state of the locking mechanism in energized operating state of the electromagnet, the latching device can be deactivated by interrupting the energization of the electromagnet with little effort and the piston unit from the associated spring accumulator in the closed operating state of the locking mechanism equivalent axial Position without initiation of further measures with little tax and regulatory effort convertible.

In a space-and cost-effective embodiment of the device according to the invention, the locking device is designed with at least one operatively connected to the piston unit spring arm, by means of which the piston unit in the equivalent to the open state of the locking mechanism axial position is durable, the spring arm operable at a low effort Development of the device according to the invention is preferably carried out with a spring force bias, which pivots the spring arm in its the piston unit releasing position, and wherein the spring arm is preferably fixedly connected to the piston unit, so that the spring force bias of the spring arm can be supported on this.

If the spring arm is held against the spring bias of the release element in engagement with a housing-fixed component to the operating state of the spring arm to which the piston unit is held by the spring arm in the axial position corresponding to the open state of the locking mechanism, an opening of the locking mechanism with structurally small Expenditure in energized operating state of the electromagnet avoided.

In an equally space-saving and operable with little effort alternative embodiment, the device according to the invention is designed with a latching device having at least one preferably spherical locking element, which held between the housing-fixed component and the release element in the radial direction and displaceable in the radial direction of this relative to the piston unit and held in the axial direction of the piston unit and designed to be displaceable with the piston unit, wherein the blocking element in energized operating state of the electromagnet from the release element in the radial direction in a blocking region of the housing-fixed component is feasible and an axial actuating movement of the piston unit, starting from the to the open operating state of the locking mechanism is locked in the direction of the closed operating state of the locking mechanism equivalent axial position.

Both the features specified in the claims and the features specified in the subsequent embodiments of the device according to the invention are each suitable alone or in any combination with each other to further develop the subject invention. The respective feature combinations represent no limitation with respect to the development of the subject matter according to the invention, but essentially have only an exemplary character.

Further advantages and advantageous embodiments of the device according to the invention will become apparent from the claims and the embodiments described in principle below with reference to the drawings, wherein the same reference numerals are used in the description of the various embodiments in favor of clarity for construction and functionally identical components.

It shows:

1a to 1f a schematic longitudinal sectional view of a first embodiment of the device according to the invention for actuating a locking mechanism during various operating conditions; and

2a to 2f a 1a corresponding representation of a second embodiment of the device according to the invention for actuating a locking mechanism during different operating conditions.

1a to 1f each show a schematic partial longitudinal sectional view of a first embodiment of a device 1 for actuating a locking mechanism designed in the present case as a parking brake device of a drive train of a vehicle designed with an automatic transmission 2 , The device 1 In a manner known per se, a fluid which can be acted upon by a fluid and in dependence on a fluid pressure p is opposite to a direction of closing S of the locking mechanism 2 acting spring device 17 in the opening direction of the locking mechanism 2 operable and in the axial direction in a cylinder 3 executed housing-fixed component displaceably arranged piston unit 4 on, in the manner described in more detail later with the locking mechanism 2 connected is.

The piston unit 4 is presently a so-called parking lock valve 13 from a system pressure p_sys leading portion of a hydraulic system of an automatic transmission with an actuating pressure p applied when the parking brake device 2 should be interpreted. The device 1 is with one in an open state of the locking mechanism 2 equivalent axial position of the piston unit 4 , in the 1d and 1e shown closer activatable locking device 5 for holding the piston unit 4 in the to the open state of the locking mechanism 2 equivalent axial position executed.

Furthermore, the device 1 also an electromagnetic actuator 6 for actuating a release element 7 on, about the locking device 5 can be activated and deactivated in the manner described later. The release element 7 is present with an anchor rod 8th connected and together with the anchor rod 8th and an anchor element operatively connected thereto 9 longitudinally movable inside the cylinder 3 arranged. Furthermore, the release element 7 , the anchor rod 8th and the anchor element 9 in each case with a direction towards the activated operating state of the latching device 5 equivalent position acting actuator force acted upon.

The piston unit 4 is connected in a manner not shown with a detent disc which is rotatably mounted in the region of a bolt and a leg spring against a stop of the piston unit 4 is pressed. The detent disc is rotatably mounted in the region of a bolt and a non-illustrated leg spring against a stop of the piston unit 4 pressed. A parking lock rod is fixedly connected to the detent disk, via which a rotational movement of the detent disk is transferable to a parking lock cone. The Park Sperrenkonus interacts with a parking pawl, in a conventional manner with inserted parking brake device 2 engages with a portion in a toothing of a parking lock gear. The parking lock gear is in turn connected to the output of a vehicle, which with inserted parking brake device 2 the output of the vehicle by the engaging in the parking lock gear parking pawl is held against rotation. The parking lock cone is arranged longitudinally displaceable on the parking brake rod and pressed by a compression spring against a stop.

The longitudinally movable design of the parking lock cone on the parking brake rod and the corresponding springing of the parking lock cone on the compression spring is provided so that the presence of a request to insert the parking brake device to be executed rotational movement of the detent disc and thus a substantially translational adjustment of the parking lock bar despite the presence of a so-called tooth -On-tooth position between the parking lock pawl and the parking lock gear is feasible, in which the parking pawl initially not incident in the desired extent in the parking lock gear. By the time the parking pawl engages the parking lock gear, the compression spring is biased due to park lock detent not locked by the parking lock bar. If the parking pawl falls into the parking lock wheel to the desired extent, the parking lock cone can change into its equivalent position, whereby the compression spring relaxes during this adjusting movement of the parking lock cone.

In the 1a to 1f illustrated device 1 indicates in the normal operating mode during which the piston unit 4 in the range of an effective area 14 can be acted upon by the fluid pressure p and the electromagnetic actuator 6 can be energized, the following functionality:
To the in 1a illustrated operating state of the device 1 the piston unit is in the closed operating state of the locking mechanism 2 or in the operating state of the parking brake device equivalent position or in a first end position in which the piston unit 4 not from the deactivated locking device 5 is held. In this operating state of the device 1 is the energization of an electromagnet 10 the actuator 6 interrupted and the release element 7 , is in common with the anchor element 9 and the anchor rod 8th in the in 1a shown axial position shifted.

The release element 7 , the anchor rod 8th and the anchor element 9 are in the cylinder 3 or to the electromagnet 10 in the de-energized operating state of the electromagnet 10 designed to be freely movable in the axial direction. Is there a corresponding requirement for laying the parking brake device 2 before, becomes the electromagnet 10 energized and the release element 7 together with the anchor element 9 and the anchor rod 8th from the in 1a represented axial position in the in 1b shown axial position shifted. This is one with the release element 7 firmly connected valve tappet 11 a valve device 12 in one in the piston unit 4 running line 14 inserted and closes this sealing. The administration 14 thus provides a switchable leakage point of a hydraulic operating range 15 the piston unit 4 whose flow cross-section is dimensioned so that a pressure build-up for actuating the piston unit 4 in the range of an effective area 16 the piston unit 4 starting from a closed operating state of the locking mechanism 2 equivalent axial position in the direction of the open state of the locking mechanism 2 equivalent axial position in the open operating state of the leakage point 14 is prevented.

Since the leakage point or the line 14 by the energization of the electromagnets 10 from tappet 11 to the in 1b illustrated operating state of the device 1 is sealed, causes a corresponding actuation of the parking brake valve 13 and a pressure supply of actuating pressure p in the direction of the effective surface 16 the piston unit 4 in that the piston unit 4 against the spring force of the spring device 17 from the in 1a and 1b shown axial position increasingly in the direction of in 1e shown axial position, the open operating state of the locking mechanism 2 or the designed operating state of the parking brake device 2 is equivalent.

With increasing axial travel of the piston unit 4 are also about the scope of the release element 7 arranged distributed and present as spring arms 18 . 19 executed locking elements, the one end fixed to the piston element 4 are connected and their opposite ends in the axial direction is carried out freely, also displaced in the axial direction and increasingly overlap in the radial direction, the release element 7 , The spring arms 18 and 19 are in this case designed with a spring force bias, the spring arms or locking elements 18 and 19 in the in 1a . 1b and 1f holds position shown or pivoted in this position. Here are the spring arms 18 and 19 with the piston unit 4 firmly connected so that the spring force bias of the spring arms 18 and 19 can be supported on this.

With increasing axial displacement of the piston unit 4 and the spring arms 18 and 19 reduces an axial distance between an at least approximately conical diameter range 20 of the release element 7 and a radially outwardly bent portion 21 respectively. 22 of the spring arm 18 or of the spring arm 19 , To the in 1c illustrated operating state of the device 1 come the spring arms 18 and 19 with their areas 21 and 22 in contact with the conical diameter range 20 of the release element 7 , An increasing axial adjustment of the piston unit 4 with respect to the release element 7 leads to the plant one between the piston unit 4 and the release element 7 provided further spring means 23 on the release element 7 , which then one end in a hollow cylindrical area 24 the piston unit 4 engages and there is shouldered while the other spring device 23 in contact with the release element 7 in the area of one of the piston unit 4 facing end face 25 of the release element 7 is also shouldered and with increasing adjustment of the piston unit 4 in the in 1c to 1e illustrated manner is increasingly compressed.

From the moment when the spring arms 18 and 19 with their areas 21 and 22 at the conical area 20 of the release element 7 abut, be the spring arms 18 and 19 initially pivoted radially outward in the region of their free ends until they are in each case to the areas 21 and 22 subsequent areas 26 . 27 on an inside 28 of the cylinder 3 abuts and a further radially outwardly directed pivoting movement of the spring arms is locked. This causes the release element 7 against the electromagnetic force of the electromagnet 10 together with the piston unit 4 and the spring arms 18 and 19 is adjusted in the axial direction, wherein a distance between a the electromagnet 10 facing the end of the release element 7 and the electromagnet 10 it is reduced in size.

Between the fixed with the release element 7 connected anchor rod 8th and the anchor element 9 is present an additional spring device 29 provided, which is designed as a compression spring and one end on the anchor element 9 and at the other end to the anchor rod 8th is shouldered and thus the anchor rod 8th from the anchor element 9 away in the direction of the piston unit 4 shifts. The anchor rod 8th is in the in 1a shown axial position of a stop 30 against a further axial relative displacement relative to the anchor element 9 secured.

Due to the last-described embodiment of the device 1 with the spring device 29 in the area of the anchor rod 8th , the anchor element 9 and the release element 7 and the spring device 23 there is a simple way the release element 7 together with the spring arms 18 and 19 and the piston unit 4 in energized state of the electromagnet 10 to adjust in the axial direction, without the anchor element 9 from a pole surface 31 of the electromagnet 10 to have to take off. This is the electromagnet 10 in a simple way smaller dimensionable, because the anchor element 9 is at plant of the pole face 31 with a high adhesive force at the same time low current values in the desired axial position durable.

The further axial adjustment of the piston unit 4 together with the spring arms 18 and 19 and the release element 7 causes the spring arms 18 and 19 with their areas 26 and 27 in overlap with an enlarged inner diameter range 32 of the cylinder 3 come and from the dissolution element 7 and at the release element 7 adjacent spring force of the additional spring device 29 starting from the in 1c illustrated pivoting position radially outward in the in 1d shown pivot position can be transferred. The additional spring device 29 and the other spring device 23 are to be coordinated accordingly to the release element 7 from the additional spring device 29 and against the spring force of the other spring device 23 in the direction of piston unit 4 further between the spring arms 18 and 19 to be able to push.

To the in 1e illustrated operating state of the device 1 is the locking device 5 fully activated and the piston unit 4 from the spring arms 18 and 19 positively in their designed for the operating state of the parking brake device 2 equivalent axial position held securely, even if the actuation pressure p falls to a level to which the piston unit 4 from the actuating pressure p no longer counter to the spring force of the spring device 17 in the designed for operating the parking brake device 2 equivalent axial position is durable.

Lies starting from the in 1e illustrated operating state of the device 1 a corresponding request for inserting the parking brake device 2 before, the energization of the electromagnet 10 interrupted. This causes the release element 7 by moving the release element 7 axially in the direction of the electromagnet 10 from the other spring device 23 out of engagement with the spring arms 18 and 19 to be led. Due to the above-described spring force bias of the spring arms 18 and 19 fall from the release element 7 released spring arms 18 and 19 radially inward, whereby the positive connection between the spring arms 18 and 19 and the cylinder 3 is canceled. As in the presence of a request to engage the parking brake device 2 in the area of the parking lock valve 13 the actuating pressure p is lowered to a pressure level required for this purpose, the piston unit 4 from the spring device 17 in the in 1a and 1b shown displaced axial position, wherein the leakage 14 in the in 1a shown axial position of the release element 7 and the valve lifter 11 opened and in the 1b illustrated axial position of the release element 7 and the valve lifter 11 to which the electromagnet 10 energized, is closed.

Because the release element 7 and the piston rod operatively connected thereto 8th and the anchor element 9 in non-energized operating state of the electromagnet 10 freely movable with respect to the cylinder 3 the piston unit 4 are executed, lies the release element 7 together with the valve lifter 11 in pickled operating condition of the parking brake device 2 in the axial direction in one between the in 1b shown axial end position and in 1a initially shown in an undefined position. Is due to a fault in the area of the effective area 16 the piston unit 4 undesirably applied an actuation pressure p, the piston unit 4 against the spring force of the spring device 17 from their engaged to the operating state of the parking brake device 2 equivalent axial position in the direction of the electromagnet 10 would adjust, this operating pressure at the in 1a to 1f illustrated first embodiment of the device 1 over radial bores 33 in the piston unit 4 in the direction of the leak 14 forwarded. The actuating pressure p comes in the line 14 engaging valve lifter 11 at the end face 34 to concerns and pushes the valve lifter 11 to the desired extent from the line 14 the piston unit 4 , with which the line 14 or the leakage goes into the open operating state.

As in the open operating state of the leakage 14 in the area of the effective area 16 the piston unit 4 no the parking brake device 2 interpretive actuation pressure p can be applied, the parking brake device remains 2 even in the event of a fault in the desired extent in the engaged operating state. The one by the line 14 guided hydraulic fluid flow reaches the area of the interior of the cylinder 3 in which the spring arms 18 and 19 as well as the release element 7 are arranged. From there, the hydraulic fluid in a manner not shown in the direction of a low pressure region 35 dissipated, bringing in this interior of the cylinder 3 and thus also in the area of effective area 16 no the functioning of the device 1 can build up disabling pressure.

In turn, there is a corresponding requirement for laying out the parking brake device 2 with open leakage 14 before, first the electromagnet 10 energized and the valve lifter 11 in the in 1b illustrated manner sealing in the line 14 inserted. With appropriate pressurization of the effective surface 16 the piston unit 4 can the piston unit 4 starting from the in 1a shown axial position in the direction of the electromagnet 10 be moved.

To the dynamics of the device 1 when inserting the parking brake device 2 or when closing the locking mechanism 2 over a defined range of the travel of the piston unit 4 defined to be able to adjust is the device 1 with a damping device 36 or a dipping step. This is the piston unit 4 on the release element 7 opposite side with an area 37 formed from a defined axial position of the piston unit with respect to the cylinder 3 in one on the area 37 the piston unit 4 coordinated area of the piston unit 4 surrounding cylinder 3 or a housing-fixed component for damping an actuating speed of the piston unit 4 in the direction of the engaged operating state of the parking brake device 2 dips.

Here are the areas 36 and 37 as well as the piston unit 4 and the parking lock facility 2 coordinated so that a desired rapid insertion of the parking brake device 2 through the damping device 36 is not affected. For this reason, the parking lock device 2 already at the time or to the axial position of the piston unit 4 inserted before the area 37 the piston unit 4 in the area 38 of the cylinder 3 dips. In addition, the switchable leakage point 14 in this axial position of the piston unit 4 both in energized and de-energized operating state of the electromagnet 10 from the valve lifter 11 sealed. This is done by appropriate interpretation of the length dimensions of the components of the device 1 secured to each other. In addition, it is provided that the switchable leakage point 14 even in de-energized operating state of the electromagnet 10 just before reaching the in 1a shown end position of the piston unit 4 goes into open operating state.

The last-described design of the device 1 based on the knowledge that while driving, usually the parking brake device 2 is present in designed operating state, a transition to a so-called emergency program, to which an energization of the electromagnet 10 and further actuators of an automatic transmission is no longer possible, the parking brake device without corresponding pressurization of the effective surface 16 the piston unit 4 can no longer be kept in their designed operating condition and the device 1 from her in 1e shown operating state in the in 1f goes over shown operating state. Occurs in the mechanical emergency operation of an automatic transmission, a correspondingly strong pressure drop, which is triggered for example by the circuit, starting from the currently engaged translation in the direction of a defined emergency gear is in the range of hydraulic actuation range 15 Under certain circumstances, a very strong pressure drop caused that leads to a more or less high insertion dynamics of the parking brake device.

By the damping device 36 or the end position damping of the device 1 is avoided in a structurally simple manner that during the operating state change of the device 1 in the direction of the engaged operating state of the parking brake device 2 the leakage point 14 already present at an instant in the open operating state, to which in emergency operation, preferably after completion of the switching operation in the direction of the emergency, again a corresponding pressure in the region of the effective area 16 the piston unit 4 can be applied, over which the parking brake device 2 is durable even in emergency operation in designed operating condition or can be converted into the designed operating state. Will the leak point 14 Released too soon is the parking brake device 2 even with renewed printing of the effective area 16 the piston unit 4 no longer interpretable. The parking brake device is then in driving operation of a vehicle in the ratcheting operating state.

Alternatively to the above-described embodiment of the device 1 in which the valve device 12 inside the cylinder 3 is provided, depending on the particular application, the possibility, the switchable leakage point via a valve system downstream of the parking brake valve 13 in the supply line in the direction of the effective surface 16 the piston unit 4 to realize a correspondingly suitable valve system. It is possible to apply a holding pressure to the valve system, which converts the valve system into an operating state equivalent to the closed operating state of the leakage point. Such a holding pressure or hydraulic pressure can be in the area of the effective area 16 adjacent hydraulic pressure, ie a back pressure in the hydraulic operating range 15 the device 1 during a quick loading operation of the parking brake device 2 or be diverted from the Endlagendämpfungsraum the damping device of the device or by a further pressure source of a hydraulic switching device, which continues to provide pressure in the case of emergency, are provided.

2a to 2f also show a schematic partial longitudinal sectional view of a second embodiment of the device 1 in different operating states, which are essentially in the area of the latching device 5 and the actuator 6 from the in 1a to 1f illustrated first embodiment of the device 1 differs, which is why in the description below 2a to 2f each to the differences from the first embodiment of the device 1 according to 1a to 1f will be discussed in more detail and with respect to the further operation of the device 1 according to 2a to 2f to the above description 1a to 1f is referenced.

In the device 1 according to 2a to 2f are the blocking elements 18 and 19 formed as balls between the housing-fixed component 3 or the cylinder and the release element 7 held in the radial direction and in addition in the radial direction of these opposite the piston unit 4 slidable and in the axial direction of the piston unit 4 held and with the piston unit 4 are designed to be displaceable. In energized operating state of the electromagnet 10 are the blocking elements 18 and 19 from the release element 7 in the radial direction in a blocking area 39 of the housing-fixed component 3 feasible, wherein an axial adjusting movement of the piston unit 4 starting from the to the open operating state of locking mechanism 2 or the parking brake device in the direction of the closed operating state of the locking mechanism 2 equivalent axial position is then locked. In addition, the locking elements 18 and 19 from the release element 7 in the in 2a shown manner in de-energized operating state of the electromagnet 10 in another restricted area 40 of the housing-fixed component 3 feasible, wherein an axial adjusting movement of the piston unit 4 starting from the closed operating state of the parking brake device 2 equivalent axial position in the direction of in 2f shown axial position, the interpreted operating state of the parking brake device 2 is equivalent, is locked.

Lies starting from the in 2a illustrated operating state of the device 1 a request to lay out the parking lock device 2 before, becomes the electromagnet 10 energized and the release element 7 together with the anchor rod 8th and the anchor element, not shown 9 against a spring force of a spring device 41 from the in 2a represented axial position in the in 2 B moved shown axial position. Here, the designed as a compression spring spring device 41 compressed. The axial adjustment of the release element 7 from the electromagnet 10 away in the direction of the piston unit 4 causes the locking elements 18 and 19 no longer from a larger diameter diameter area 7A of the release element 7 in the in 2a illustrated radial outer position are held, but along a ramp area 7B , which is in axial extension of the release element 7 to the diameter range 7A connects, radially inward out of engagement with the blocking area 40 be guided. This in turn causes the piston unit 4 from that in the area of the effective area 16 applied actuating pressure p against the spring force of the spring device 17 in the in 2c illustrated manner increasingly in the direction of the electromagnet 10 is adjusted.

With further increasing adjustment of the piston unit 4 become the blocking elements 18 and 19 against another ramp area 7C of the release element 7 guided, in whose area the diameter of the release element 7 of the reduced diameter of a central area 7C increases with a defined gradient, until a turn to the ramp area 7D subsequent diameter range or end diameter range 7E in contact with the locking elements 18 and 19 located. The blocking elements 18 and 19 be of the diameter range 7E in the in 2f shown radial position held in the locking elements 18 and 19 in the rest area 40 are arranged and an axial adjusting movement of the piston element 4 lock. During the last-described activation of the latch 5 becomes the release element 7 from the date from which the locking elements 18 and 19 at the ramp area 7D abutment of the piston unit 4 as long as in the direction of the electromagnet 10 moved until the locking elements 18 and 19 from the ramp area 7D radially outward into the further blocking area 40 are feasible. Subsequently, the blocking element 7 from the spring device 41 from the in 2e represented axial position in the in 2f shown axial position of the electromagnet 10 pushed away and in the axial movement of the piston unit 4 locking axial position adjusted.

This for the activation of the locking device 5 required adjusting movement of the release element 7 is in the execution of the device 1 according to 2a to 2f only guaranteed if the anchor element 9 from the pole face of the electromagnet 10 takes off. Because of this, the electromagnet is 10 the device 1 To size larger than this in the execution of the device 1 according to 1a to 1f the case is.

Should the device 1 also with a smallest possible sized electromagnet 10 are executed, the device 1 according to 2a to 2f in the area of the actuating device corresponding to the actuating device 6 the device 1 according to 1a to 1f perform a relative movement between the anchor rod 8th and the anchor element 9 to enable.

In the device 1 according to 2a to 2f is the same extent as in the device 1 according to 1a to 1f ensures that the switchable leakage 14 in de-energized operating state of the electromagnet 10 and with engaged parking brake device 2 is present in the open operating state, an undesirable interpretation of the parking brake device 2 in the event of a fault, that means if the piston unit is faulty 4 in the area of the effective area 16 , sure to avoid.

At the same time is the switchable leakage 14 in energized operating state of the electromagnet 10 and with engaged parking brake device 2 in in 2 B illustrated extent closed to the laying out the parking brake device 2 required pressure build-up in the area of the effective area 16 the piston unit 4 to ensure safe.

The device 1 according to 2a to 2f is present without the damping device 36 the device 1 according to 1a to 1f executed. It is, of course, at the discretion of the skilled person, the device 1 according to 2a to 2f to the same extent as the device 1 according to 1a to 1f with a damping device to perform the above-described functionality the damping device 36 to make available.

LIST OF REFERENCE NUMBERS

1

contraption

2

Locking mechanism, parking lock device

3

Cylinder, housing-fixed component

4

piston unit

5

locking device

6

actuator

7

release element

7A

Diameter range

7B

ramp area

7C

mid-range

7D

ramp area

7E

Diameter range, end diameter range

8th

anchor rod

9

anchor member

10

electromagnet

11

tappet

12

valve means

13

Parking lock valve

14

Line, switchable leakage

15

hydraulic actuation area

16

effective area

17

spring means

18

Locking element, spring arm

19

Locking element, spring arm

20

conical diameter range of the release element

21

Area of the spring arm 18

22

Area of the spring arm 19

23

further spring device

24

hollow cylindrical area

25

face

26

Area of the spring arm 18

27

Area of the spring arm 19

28

Inside of the cylinder

29

additional spring device

30

attack

31

Pole face of the electromagnet

32

Inner diameter area

33

radial bore

34

face

35

Low pressure area

36

attenuator

37

Area of the piston unit

38

Area of the cylinder

39

stopband

40

further restricted area

41

spring means

p

actuating pressure

p_sys

system pressure

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 102012210571 [0004]

Claims (14)

Contraption ( 1 ) for actuating a locking mechanism ( 2 ), in particular for actuating a parking brake device of a drive train of a vehicle which is designed with an automatic transmission and which has at least one in the closing direction of the locking mechanism ( 2 ) spring-loaded and in the opening direction of the locking mechanism ( 2 ) hydraulically actuated piston unit ( 4 ), a latching device ( 5 ) for holding the piston unit ( 4 ) in the open operating state of the locking mechanism ( 2 ) equivalent axial position and an actuator ( 6 ) for actuating a release element ( 7 ), which is used for switching the latching device ( 5 ) between a piston unit ( 4 ) holding one and the piston unit ( 4 ) releasing operating state with a preferably of an electromagnet ( 10 ) provided actuating force of the actuator ( 6 ) is acted upon, characterized in that a hydraulic actuation area ( 15 ) of the piston unit ( 4 ) with a switchable between an open and a closed state leakage point ( 14 ) is formed whose flow cross-section is dimensioned so that a pressure build-up for actuating the piston unit ( 4 ) starting from a closed operating state of the locking mechanism ( 2 ) equivalent axial position in the direction of the open state of the locking mechanism ( 2 ) equivalent axial position in the open operating state of the leakage point ( 14 ) is prevented. Apparatus according to claim 1, characterized in that the leakage point ( 14 ) via a valve device ( 12 ) is openable and closable. Apparatus according to claim 1, characterized in that the valve device is provided in the region of a line via which the piston unit can be acted upon by actuating pressure. Device according to one of claims 1 to 3, characterized in that the valve device ( 12 ) over one in the region of the piston unit ( 4 ) applied hydraulic pressure and / or one of a pressure medium source to the piston unit ( 4 ) applicable hydraulic pressure in a the leakage point ( 14 ) Closing operating state can be transferred and / or preserved by the hydraulic pressure in this operating condition. Device according to claim 2 or 4, characterized in that the valve device ( 12 ) one with the piston unit ( 4 ) cooperating valve tappets ( 11 ), which depends on an operating state of the actuating device ( 6 ) and / or the operating state of the piston unit ( 4 ) the leakage point ( 14 ) releases or closes. Apparatus according to claim 5, characterized in that the valve stem ( 11 ) with the release element ( 7 ) coupled to an anchor element ( 9 ) of the electromagnet ( 10 ) of the actuating device ( 6 ) is in operative connection, wherein the valve stem ( 11 ) in energized operating state of the electromagnet ( 10 ) sealingly in the preferably as one in the piston unit ( 4 ) running line ( 14 ) trained leakage point, which in from the valve stem ( 11 ) enabled operating state to an actuating pressure (p) acted upon area ( 16 ) of the piston unit ( 4 ) with a low pressure area ( 35 ) connects. Apparatus according to claim 6, characterized in that the release element ( 7 ) with respect to the anchor element ( 9 ) is displaceable and between the anchor element ( 9 ) and the release element ( 7 ) a spring device ( 29 ) is provided, via which the actuating force of the electromagnet ( 10 ) from the anchor element ( 9 ) on the release element ( 7 ) is forwarded. Device according to one of claims 1 to 7, characterized in that between the release element ( 7 ) and the piston unit ( 4 ) a spring device ( 23 ) is provided, via which of the piston unit ( 4 ) on the release element ( 7 ) a force can be imposed, the force of the electromagnet ( 10 ) is directed opposite. Device according to one of claims 1 to 8, characterized in that the piston unit ( 4 ) with an area ( 37 ) is formed, which before reaching an end position of the piston unit ( 4 ), to which the locking mechanism ( 2 ) is in the closed operating state, in one on the area of the piston unit ( 4 ) coordinated area ( 38 ) one of the piston unit ( 4 ) surrounding housing-fixed component ( 3 ) for damping an actuating speed of the piston unit ( 4 immersed). Apparatus according to claim 9, characterized in that a travel of the piston unit ( 4 ) and a length of the valve stem ( 11 ), that the locking mechanism ( 2 ) before immersing the area ( 37 ) of the piston unit ( 4 ) in the area ( 38 ) of the housing-fixed component ( 3 ) goes into its closed operating state and the leakage point ( 14 ) before immersing the area ( 37 ) of the piston unit ( 4 ) in the area ( 38 ) of the housing-fixed component ( 3 ) from the valve tappet ( 11 ) Is blocked. Device according to one of claims 1 to 10, characterized in that the piston unit ( 4 ) of the latching device ( 6 ) in their open state of the locking mechanism ( 2 ) equivalent position in energized operating state of the electromagnet ( 10 ) is held. Device according to one of claims 1 to 11, characterized in that the latching device ( 5 ) with at least one with the piston unit ( 4 ) Actively connected spring arm ( 18 . 19 ) is carried out, by means of which the piston unit ( 4 ) in the to the open state of the locking mechanism ( 2 ) equivalent axial position, wherein the spring arm ( 18 . 19 ) is preferably designed with a spring force bias, the spring arm ( 18 . 19 ) in its the piston unit ( 4 ) releasing position pivoted, and wherein the spring arm ( 18 . 19 ) preferably fixed to the piston unit ( 4 ), so that the spring force bias of the spring arm ( 18 . 19 ) Is supported on this. Device according to claim 12, characterized in that the spring arm ( 18 . 19 ) to the operating state of the spring arm ( 18 . 19 ) to which the piston unit ( 4 ) of the spring arm ( 18 . 19 ) in the to the open state of the locking mechanism ( 2 ) equivalent axial position, against the spring bias of the release element ( 7 ) in engagement with a housing-fixed component ( 3 ) is held. Device according to one of claims 1 to 11, characterized in that the latching device ( 5 ) at least one preferably spherical blocking element ( 18 . 19 ), which between the housing-fixed component ( 3 ) and the release element ( 7 ) held in the radial direction and in the radial direction of these opposite the piston unit ( 4 ) displaceable and in the axial direction of the piston unit ( 4 ) and with the piston unit ( 4 ) is displaceable, wherein the blocking element ( 18 . 19 ) in energized operating state of the electromagnet ( 10 ) from the release element ( 7 ) in the radial direction in a blocking region of the housing-fixed component ( 3 ) is feasible and an axial adjusting movement of the piston unit ( 4 ) starting from the to the opened operating state of the locking mechanism ( 2 ) in the direction of the closed operating state of the locking mechanism ( 2 ) equivalent axial position is then locked.

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