JP5701315B2 - Master cylinder - Google Patents

Description

  The present invention relates to a hydraulic cylinder, in particular a master cylinder for a clutch release device in an automotive powertrain, comprising a casing and movable in the axial direction in the casing and can be filled with a pressure medium on the primary side of the master cylinder The pressure chamber can be connected to the rear supply tank on the secondary side of the master cylinder via a connection opening for compensating the pressure medium, and the connection to the rear supply tank is connected to the piston. Can be opened and closed by movement in the axial direction.

  In the hydraulic clutch release system, the hydraulic section is exposed to external influences that are adapted to change the volume of the pressure medium, such as the temperature or wear of the friction lining. Therefore, the master cylinder is provided with a so-called sniffer hole for compensating for the pressure medium, which is a connection opening to the supply tank after normal pressure.

  In a friction clutch that is pushed open by the pressure of the slave cylinder piston and the friction clutch is closed, the connection opening can be opened by the movement of the master cylinder piston to the stationary state, and pressure compensation is performed. Can do.

  In a friction clutch that is pushed and closed, pressure compensation can be performed when the friction clutch is fully open. The reason is that in this state, the master cylinder piston is in a stationary state and the connection opening is opened.

  Normally, the connection opening is controlled by a master cylinder piston that opens the opening when the seal portion is exceeded. For this purpose, the master cylinder piston has an axial groove or so-called sniffer groove at the bottom of the piston on the side opposite the piston rod. This sniffer groove exposes the connection opening when it exceeds the seal.

  In order to avoid damage to the hydraulic system due to heating and the expansion of the fluid in the hydraulic line due to heating or the pressure increase due to the expansion of the fluid, further regular time intervals are provided. It is common to completely return the master cylinder piston. In this configuration, the master cylinder piston releases the connection or sniffer opening in the master cylinder. Through this connection or sniffer opening, fluid can escape to or flow out of the reserve tank or rear supply tank. Pressure compensation with the surroundings is performed.

  In a clutch that is open in an unoperated state (a clutch that is pushed closed), it can happen that the fluid expands significantly during a relatively long run without gear changes. Control therefore returns the master cylinder until the sniffer opening is released. With this arrangement, a rapid pressure drop occurs in the line and the clutch is inconveniently released.

  In the prior art, methods and devices are proposed in the prior art that suggest improvements to the opening and closing of the sniffer opening or the sniffer characteristics of the master cylinder to minimize wear or damage to the clutch system. In this configuration, the control of the system is troublesome (for example, German Patent Application No. 102005027066 or German Patent Application No. 102009009145). However, the above-mentioned problem of unintentional release of the clutch is not touched and has not been solved.

  An object of the present invention is to provide a master cylinder in which the above-mentioned problems can be solved with a small amount of labor. In the present invention, it is desirable that there is no excessive pressure rise and therefore no unintentional release of the clutch.

  This object is achieved by a master cylinder with the features of the first claim. Advantageous configurations result from the dependent claims.

  In a hydraulic cylinder, in particular a master cylinder for a clutch release device in an automobile power train, a pressure chamber is provided which has a casing and is movable in the axial direction in the casing and can be filled with a pressure medium on the primary side of the master cylinder. A pressure chamber, which can be connected to the rear supply tank on the secondary side of the master cylinder via a connection opening for compensating the pressure medium, the connection to the rear supply tank being in the axial direction of the piston It can be opened and closed by movement, and according to the invention, the following means can be adjusted in the casing / into the casing so that the following means can be adjusted: Means for cooperating corresponding to the means in are provided.

  The configuration according to the present invention includes a valve device in / in the piston. This valve device can contact the casing wall when the piston moves in the axial direction toward the secondary side, thereby opening an axial through-opening in the piston that connects the primary side to the secondary side. is there. The valve device has a highly rigid slide portion that houses the closing member so as to protrude through the through hole on the primary side and accommodates the spring element on the secondary side. One end of the spring element is supported on the piston and the other end of the spring element is supported on the bottom of the slide portion.

  In this configuration, when the slide portion is provided away from the casing wall, the through hole in the piston is closed. The spring element has a relaxed state in this configuration. On the other hand, when the slide portion is in contact with the casing wall, the through hole in the piston is opened. In this configuration, the spring element has a tensioned state. Similarly, when the through hole in the casing is open, the connection opening in the casing is closed by the piston. In this configuration, the connection to the post-feed tank can be made via an additional connection opening.

  According to another configuration of the present invention, a sniffer groove that can contact the connection opening is arranged on the piston bottom and / or the peripheral surface of the piston. In this configuration, at least one auxiliary sniffer groove is provided, which is an auxiliary sniffer groove when the piston moves axially toward the secondary side and before the connection opening can be opened by the sniffer groove. The sniffer groove is additionally dimensioned so that it can contact a connection opening additionally arranged in the casing. In this configuration, the auxiliary sniffer groove has a larger axial length than the sniffer groove, but has a smaller width and / or depth than the sniffer groove.

1 is a basic view showing a first embodiment of a master cylinder according to the present invention in a first position. FIG. It is a basic view showing a first embodiment of a master cylinder according to the present invention in a second position. It is a basic view showing a second embodiment of a master cylinder according to the present invention in a first position. It is a basic view showing a second embodiment of a master cylinder according to the present invention in a second position.

  Hereinafter, the present invention will be described in detail with reference to the embodiments and the accompanying drawings.

  In order to achieve the above objective, it was necessary to find a possible embodiment that requires as little structural effort as possible. This possible embodiment results in a change in the sniffer characteristics in a hydrostatically actuable clutch that is open in a non-operated state (push-closed clutch). The important thing is that if the beginning of sniffing, i.e. opening the sniffer passage (connection opening to the afterfeed tank) begins, the master cannot be leaked very quickly from the pressure chamber into the afterfeed tank. Forming a cylinder. Instead, it is desired to leak slowly, so the master cylinder position control has sufficient time to react to the pressure drop.

  In the very schematic FIGS. 1a, 1b and 2a, 2b, two different possible embodiments are shown in which a slow and metered leakage of the pressure medium can be achieved.

  1a and 1b show a first possible embodiment of a master cylinder 1 according to the invention. The master cylinder 1 has a casing 2 in which the piston 3 can move in the axial direction. In this embodiment, the piston 3 is operated by the piston rod 4 on the secondary side 1B of the master cylinder 1. On the primary side 1A of the master cylinder 1, the piston bottom 3.1 of the piston 3 defines a pressure chamber 5 (only suggestion) filled with a pressure medium. On the piston bottom side, the piston 3 has one or more known sniffer grooves 6 extending in the axial direction on its peripheral surface. These sniffer grooves 6 correspond to the connection openings 7 arranged on the secondary side 1 </ b> B in the casing 2 of the master cylinder 1. A connection between the pressure chamber 5 and a pressure medium tank or a rear supply tank (not shown) can be formed through the connection opening 7. In addition to the existing sniffer groove 6, another axial auxiliary sniffer groove S according to the invention is arranged on the circumferential surface of the piston 3. The auxiliary sniffer groove S is smaller in width and / or smaller in depth than the other sniffer grooves 6 and has a larger axial length I than the other sniffer grooves 6, and thus the other sniffer grooves 6. Is different in dimension setting. In addition, a connection opening 7.0 corresponding to the auxiliary sniffer groove S, preferably dimensioned smaller than the connection opening 7, is arranged in the casing 2. In this embodiment, the connection opening 7.0 is provided at substantially the same height in the axial direction as the connection opening 7 corresponding to the single / plurality of sniffer grooves 6.

  At the position in the axial direction of the piston 3 shown in FIG. 1a, the circumferential surface of the piston 3 is in contact with both the connection opening 7 and the connection opening 7.0. As a result, the two connection openings 7, 7.0 are closed. The sniffer groove 6 and the auxiliary sniffer groove S are provided on the outer side in the axial direction of the region of the connection opening 7 or 7.0. Compensation of the pressure medium between the pressure chamber 5 on the primary side 1A and the secondary supply tank is not performed.

  FIG. 1 b shows a state in which the connection opening 7.0 corresponding to the auxiliary sniffer groove S is opened. In FIG. 1 b, the piston 3 of the master cylinder 1 performs an axial movement toward the secondary side 1 </ b> B of the master cylinder 1. It can be seen that the sniffer groove 6 has not yet reached the connection opening 7 and thus the connection opening 7 is still closed. The auxiliary sniffer groove S is already in contact with the connection opening 7.0 based on the relatively large axial length l of the auxiliary sniffer groove S. As a result, the connection opening 7.0 is opened. The auxiliary sniffer groove S is based on a small extension to the width or depth and has only a small receiving volume for the pressure medium, so that a slow exchange of the pressure medium, in this embodiment the post supply from the pressure chamber 5 Only a slow leak of pressure medium towards the tank begins. Since the associated connection opening 7.0 is similarly sized relatively small, only a small volume flow reaches the afterfeed tank in the sniffer stage.

  The volumetric flow metered into the rear supply tank (or in the opposite direction) via the auxiliary sniffer groove S and the connection opening 7.0 is also suitable for the auxiliary sniffer groove S and the additional connection opening 7.0. It can be adjusted by configuration and arrangement. The opening of the connection opening 7.0 can therefore be adjusted.

  Due to the slow and metered leakage of the fluid, the position control of the master cylinder 1 reacts to the pressure drop and moves the master cylinder 1 or the piston 3 again in the opposite direction, ie the connection opening 7.0. There is enough time to close again. On the other hand, since there is no reaction from the control unit side, the piston 3 can further move toward the secondary side 1B of the master cylinder 1. In this embodiment, after reaching the connection opening 7, the pressure medium exchange between the pressure chamber 5 and the rear supply tank is also performed through the remaining sniffer groove 6. This exchange takes place very rapidly on the basis of the relatively large dimensions of the sniffer groove 6 and the connection opening 7 corresponding to this sniffer groove 6.

  Another possible embodiment of the master cylinder 1 according to the invention, in which a slow and metered exchange of fluid takes place between the pressure chamber 5 and a post supply tank (also not shown), 2a and 2b. In this embodiment, the same reference numerals are used for components used in the same manner as in the first embodiment.

  A master cylinder 1 according to the present invention has a casing 2 and a piston 3. The piston 3 is movable in the axial direction inside the casing 2. The piston rod 4 engages with the piston 3 on the secondary side 1 </ b> B of the master cylinder 1. On the primary side 1A of the master cylinder 1, the piston bottom 3.1 of the piston 3 defines a pressure chamber 5 filled with a pressure medium. On the secondary side 1B, the casing 2 is provided with a connection opening 7 for connecting the rear supply chamber 8 to a rear supply tank (not shown).

  Instead of one or more sniffer grooves, the valve device V is provided in the piston 3 in the embodiment according to the present invention. The valve device V has a closing member VT arranged on the piston bottom 3.1 of the piston 3 on the pressure chamber side. This closing member VT corresponds to the axial through hole 3.2 arranged in the piston 3. This through hole 3.2 connects the pressure chamber 5 (simply suggested) on the primary side 1 </ b> A to the rear supply chamber 8 on the secondary side 1 </ b> B of the master cylinder 1. On the secondary side 1B, a spring element VF that functions as an energy storage, in this embodiment, a compression spring is provided. This compression spring is accommodated by a slide part VS that passes through the through-hole 3.2 and is firmly connected to the closing member VT of the valve device V. The slide portion VS enters the rear supply chamber 8 in the axial direction. In this embodiment, the compression spring VF is supported by the piston 3 with one end thereof, and is supported by the bottom VS1 of the slide portion VS with the other end.

  In FIG. 2a, the compression spring VF is provided in a relaxed state. The bottom part VS1 of the slide part VS is provided at a predetermined interval with respect to the casing wall 2.1 provided with a receiving hole for the piston rod 4, which is arranged transversely to the direction of movement of the piston 3. It has been. The through hole 3.2 in the axial direction of the piston 3 is closed by a closing member VT in this embodiment. Since the piston 3 is provided in front of the connection opening 7 when viewed from the primary side 1 </ b> A, the connection opening 7 is open to the rear supply chamber 8. No fluid is exchanged between the pressure chamber 5 on the primary side 1A and the post supply tank.

  In FIG. 2 b, the piston 3 is moving towards the rear supply chamber 8. As a result, the bottom VS1 of the slide part VS, and thus the end of the compression spring VF attached to the slide part VS, abuts on the casing wall 2.1. At the same time, the outer periphery of the piston 3 was moved in front of the connection opening 7. The connection opening 7 is thereby closed. At the moment when the bottom part VS1 of the slide part VS comes into contact with the casing wall 2.1, the closing member VT starts to open the axial through hole 3.2 in the piston 3, so that the fluid flows from the primary pressure chamber 5 to the secondary side. Starts to flow into the rear supply chamber 8. Further movement of the piston 3 in the axial direction is damped by the compression spring VF which is clamped between the piston 3 and the casing wall 2.1, so that only a small amount of the compressed medium is metered. Flows in. In this embodiment, another connection with the post supply tank is additionally ensured via a connection opening 7.1 provided in the casing 2 on the secondary side 1B. This connection opening 7.1 is preferably arranged axially spaced from the connection opening 7 and close to the casing wall 2.1.

  Therefore, the valve device V operating as a control valve can be controlled via the position of the piston 3. Also in the above-described embodiment of the master cylinder 1 according to the present invention, a slow and metered replacement of the pressure medium is guaranteed. Based on the configuration of the slide part VS and the compression spring VF of the valve device V and taking into account the dimensions of the piston 3, the amount of leaking volume flow can be adjusted.

  Metered sniffing can be achieved in the master cylinder 1 according to the invention shown by the two embodiments. In this embodiment, it is not only the “sniffer (connection) opening is closed” position or the “sniffer (connection) opening is open” position. Rather, any position between the two extreme positions is adjustable.

  A long and narrow auxiliary sniffer groove S associated with the additional connection opening 7.0 and a spring-loaded valve device V associated with the additional connection opening 7.1. Such means acts like a control valve and thus allows the sniffer characteristics of the master cylinder 1 to be controlled.

  If the fluid in the master cylinder of the hydrostatically operated clutch, which is open in the unoperated state, expands significantly, the means S or V according to the invention provided on the piston (VT, VS, VF) ) On the basis of the open sniffer groove in cooperation with the means 7.0 or 7.1, 2.1 provided in the casing 2 corresponding to this means S or V. Rather than providing rapid pressure compensation (as is the case with technology), metered slow leakage of fluid from the pressure chamber takes place, so that the master cylinder position control is performed before unintentional clutch release occurs. In response to the pressure drop, the piston can be returned again.

DESCRIPTION OF SYMBOLS 1 Master cylinder 1A Primary side 1B Secondary side 2 Casing 2.1 Casing wall 3 Piston 3.1 Piston bottom 3.2 Through hole 4 Piston rod 5 Pressure chamber 6 Sniffer groove 7 Connection opening 7.0 Connection opening 7.1 Connection opening 8 Rear supply chamber l Length S Auxiliary sniffer groove V Valve device VF Energy reservoir / spring element / compression spring VS slide part VS1 bottom part of slide part VT

Claims (10)

A master cylinder (1) for a hydraulic system, in particular a clutch release device in an automobile powertrain, comprising a casing (2) and movable in the axial direction in the casing (2) with the pressure chamber which can be filled with pressure medium in (1) the primary side of the (1A) to (5) piston (3) defining the said pressure chamber (5) for compensating for the pressure medium, said casing It can be connected to the rear supply tank on the secondary side (1B) of the master cylinder (1) through the first connection opening (7) provided in (2), and the connection to the rear supply tank is In the master cylinder, which can be opened and closed by movement in the axial direction of the piston (3),
The casing (2) is further provided with a second connection opening (7.0),
Means ( S) cooperating correspondingly with the second connection opening (7.0 ) so that the volumetric flow rate of the pressure medium from the pressure chamber (5) to the post supply tank is adjustable. , it has been eclipsed set to the piston (3),
A sniffer groove (6) connectable to the first connection opening (7) is provided in a piston bottom (3.1) and / or a peripheral surface of the piston (3),
In the case where the piston (3) moves in the axial direction toward the secondary side (1B) on the piston bottom (3.1) and / or the circumferential surface of the piston (3), the first connection opening ( Dimensioned so that it can be connected to the second connection opening (7.0) additionally arranged in the casing (2) before it can be opened through the sniffer groove (6) A master cylinder, characterized in that at least one auxiliary sniffer groove (S) is provided as said means . The auxiliary sniffer groove (S) has a larger axial length (l) than the sniffer groove (6), but has a smaller width and / or depth than the sniffer groove (6). The master cylinder according to claim 1, wherein the master cylinder is provided. A master cylinder (1) for a hydraulic system, in particular a clutch release device in an automobile powertrain, comprising a casing (2) and movable in the axial direction in the casing (2) The casing (1) includes a piston (3) that defines a pressure chamber (5) that can be filled with a pressure medium on a primary side (1A) of the (1), the pressure chamber (5) compensating for the pressure medium It can be connected to the rear supply tank on the secondary side (1B) of the master cylinder (1) through the first connection opening (7) provided in (2). In the master cylinder, which can be opened and closed by the axial movement of the piston (3),
The casing (2) is further provided with a second connection opening (7.1),
The second connection opening (7.1) and the casing (2) in the casing (2) so that the volumetric flow rate of the pressure medium from the pressure chamber (5) to the post supply tank is adjustable. Through-holes in the axial direction of the piston (3) connecting the primary side (1A) to the secondary side (1B). Provided in (3.2),
When the piston (3) moves axially towards the secondary side (1B), the valve device before the first connection opening (7) can still be opened to the rear supply tank (V) opens the through hole (3.2), and the pressure chamber (5) is post-supplied through the through hole (3.2) through the second connection opening (7.1). A master cylinder that can be connected to a tank. Before Kiben device (V), the piston (3) when the movement in the axial direction toward the secondary side (1B), is capable of contacting the casing wall (2.1), whereby said primary side characterized in that said through hole for connecting the (1A) to the secondary side (1B) (3.2) can be opened, according to claim 3 wherein the master cylinder. The valve device (V) has a highly rigid slide portion (VS), and the slide portion (VS) protrudes through the through hole (3.2), and a closing member (VT) is provided on the primary side. Yes, and accommodates the spring element (VF) at the secondary side, one end of the spring element (VF) is supported by the piston (3), the other end of the spring element (VF) is The master cylinder according to claim 4 , wherein the master cylinder is supported by a bottom portion (VS1) of the slide portion (VS). The through hole (3.2) in the piston (3) is closed when the slide part (VS) is spaced apart from the casing wall (2.1). Item 6. The master cylinder according to item 5 . The master according to claim 5 or 6 , characterized in that when the sliding part (VS) is spaced apart from the casing wall (2.1), the spring element (VF) has a relaxed state. Cylinder. The master cylinder according to claim 5 , characterized in that when the sliding part (VS) contacts the casing wall (2.1), the through hole (3.2) in the piston (3) starts to open. The master cylinder according to claim 5 or 8 , characterized in that the spring element (VF) has a tensioned state when the sliding part (VS) is in contact with the casing wall (2.1). When the through hole (3.2) in the piston (3) is open, the first connection opening (7) in the casing (2) is closed by the piston (3), and the post supply tank 10. A master cylinder according to any one of claims 4 to 9 , characterized in that the connection to can be made via a second connection opening (7.1).

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