EP0245539A2 - Apparatus provided with a vane pump - Google Patents

Abstract

The object of the invention is an apparatus fitted with a vane pump (10) which has a rotor (14) eccentrically supported in a housing (12) forming a chamber (16). The rotor (14) contains recesses (42) in which vanes are arranged in a radially displaceable manner, interacting with the inside wall of the housing. The wall of the chamber (16) contains two passages (24, 26) each for connection to at least one consuming unit and to a chamber containing a medium to be conveyed. The rotor (14) together with the housing (12) forms a second chamber (32), in the wall of which two passages (38, 40) are provided. Each passage (38, 40) is connected by means of a first and a second non-return valve (54, 56; 58, 60) on the one hand to a common chamber for the medium to be conveyed and on the other to a common duct (64) for the control pressure. The rotor (14) may be driven in either of the opposing directions of rotation. <IMAGE>

Description

The invention relates to a device with a vane pump, which has a rotor eccentrically mounted in a housing to form a chamber, which contains recesses in which vanes interacting with the inner wall of the housing are arranged radially displaceable, two in the wall of the chamber Passages are provided for connection to at least one consumer and to a room containing a medium to be conveyed.

Vane pumps of the construction described above, which are also called vane pumps, are often used for over- or. Vacuum generation used in motor vehicles to supply and operate central locking systems, child safety devices or locking aids to the required extent with pressure or vacuum. The individual consumers that can be actuated with pressure or vacuum are connected to the vane pump via lines.

The invention is based on the object of further developing a device of the type described in the introduction, that it is optionally suitable for generating positive and negative pressure and at the same time a control pressure which is made available as positive pressure.

The object is achieved in that the rotor forms a second chamber with the housing, in the wall of which two passages are provided, each via a first and a second check valve on the one hand with a common space for the medium to be conveyed and on the other hand with a common one Channel for the control pressure are connected and that the rotor is optionally driven in opposite directions of rotation. Depending on the direction of rotation of the rotor, an overpressure occurs at one or the other passage of the first chamber. A corresponding negative pressure then prevails at the second passage of the first chamber. Regardless of the direction of rotation of the rotor, the control pressure is created as overpressure in the common channel. The control pressure can be used for various control elements of a motor vehicle. The device explained above can be used for consumers that are operated only with positive pressure or only with negative pressure. In this case, the consumers must be connected to the passage of the first chamber where the desired type of pressure occurs, coordinating the direction of rotation of the rotor. However, it is also possible to connect consumers which react to both overpressure and underpressure in a predetermined manner to the one passage of the first chamber. The type of actuation of the consumer depends on the direction of rotation of the rotor. The device described above can thus be used in many ways. The wide range of uses results in higher quantities, so that economical production is also guaranteed.

The check valves are so in the lines between the room with the medium to be pumped and the channel for the Control pressure arranged that they block in the direction of the space for the medium to be conveyed. The medium to be pumped can be a liquid, eg oil, which is in a tank. With a liquid, a pressure or vacuum sufficient for the actuation of consumers to be controlled can be generated relatively quickly, ie with a few revolutions of the rotor. The device is therefore particularly suitable for generating pressure or vacuum using liquids.

The second chamber preferably has a smaller volume than the first chamber. The second chamber is only required for the generation of the control pressure with which no large-volume parts are moved. Therefore, a relatively small second chamber is also sufficient for the generation of a high control pressure. A relatively large volume of the first chamber r is thus available for conveying the medium from or to the consumers, so that despite the second chamber, a large volume of the medium can be conveyed with a corresponding overpressure or underpressure.

In a preferred embodiment, a further passage is provided in the wall of the first chamber and is connected to the channel for the control pressure via a check valve which is permeable in the direction of the chamber. This device has the advantage that pressure medium can be fed into the first chamber from the control pressure side when the control pressure has reached a correspondingly high value.

It is advantageous if the two chambers each have subspaces with crescent-shaped cross sections with respect to a plane of symmetry. This has a favorable effect on the stress of the vanes which are displaced against the housing wall under centrifugal force.

Further details, advantages and features of the invention result not only from the claims and those for them features and / or in combination, but also from the following description of an embodiment shown in a drawing.

• Fig. 1 eine Vorrichtung mit einer Flügelzellenpumpe schematisch im Schnitt und
• Fig. 2 den gegenüber der Vorrichtung gemäß Fig. 1 geänderten Teil einer Vorrichtung mit einer Flügelzellenpumpe schematisch im Schnitt.

Show it:

• Fig. 1 shows a device with a vane pump schematically in section and
• Fig. 2 schematically in section the part of a device with a vane pump which has been modified compared to the device according to Fig. 1.

A device for selectively generating a negative or positive pressure and a control pressure contains a vane pump (10) which has a housing (12) in which a rotor (14) which can be driven by a motor (not shown in detail) is rotatably mounted. In the housing (12) there is a cylindrical cavity with a larger cross section than the cross section of the rotor (14). The rotor (14) is arranged eccentrically to this cavity, which forms a first chamber (16). A plane of symmetry (18), which runs through the longitudinal axes (not shown) of the chamber (16) and the rotor (14), divides the chamber (16) into two subspaces (20, 22) that are crescent-shaped. The subspaces (20, 22) each contain a passage (24, 26) for connection to consumers (not shown) or to the space of a medium to be conveyed. In the device shown in the drawing, for example, consumers (not shown) are connected to the passage (26) via a pipe (28), while the passage (24) is connected to the space for the medium to be conveyed via a pipe (30). The medium to be pumped can be a gas, for example air. However, the medium is preferably a liquid, for example oil. This liquid is located in a tank (not shown in more detail) which is at atmospheric air pressure and to which the pipeline (30) runs, the end of which is not shown and which dips into the liquid level in all operating positions of the consumers.

There is also a second cavity in the housing (12), which is cylindrical and partially overlaps with the first cavity. The rotor (14) is also arranged eccentrically to this cavity, which is not described in any more detail and has a larger diameter than the rotor (14). As a result, a second chamber (32) is formed, which is enclosed by the inner wall of the housing (12), the outside of the rotor (14) and the end walls of the vane pump (10), not shown. The chamber (32), like the chamber (16), has two subspaces (34, 36) with respect to the plane of symmetry (18). Each subspace (34, 36) contains a passage (38) or (40).

The rotor (14) contains radially extending recesses (42) which are arranged at equal distances from one another. Wings (44) are mounted radially displaceably in the cutouts (42). The blades (44) come into contact or interaction with the rotation of the rotor (14) with the inner wall of the housing (12), with their ends sliding along the inner wall and forming separate compartments into which during the rotation of the Rotors (14) the medium to be conveyed is sucked in and then pressurized. The pressurized medium is discharged through a passage.

The passages (38) and (40) are each connected via pipes (46, 48) to further pipes (50, 52). The pipes (46, 48) open into the longitudinal walls of the pipes (50, 52). Each pipe (50, 52) is on Both ends are each connected to a check valve (54, 56) or (58, 60). The check valves (54) and (58) open in the direction of connecting the pipes (46) and (48) and block in the opposite direction. The check valves (56) and (60) block in the direction of the connection of the pipes (46) and (48) and open in the opposite direction. At their connections facing away from the pipes (50) and (52), the check valves (54) and (58) are each connected together with a pipe (62) which projects at one end into the tank, not shown, in which the medium to be funded. The check valves (56) and (60) are connected at their connections facing away from the pipes (50, 52) to a common channel (64) which is intended for the transmission of a control pressure. The rotor (14) can optionally be driven with the motor in two opposite directions of rotation. In Fig. 1 arrows indicate the two opposite directions of rotation (66, 68).

When the rotor (14) rotates in the direction of rotation (66), the medium is sucked in via the pipe (30) and the passage (24), compressed in the chamber (16) and under pressure through the passage (26) into the pipe (28) to which the consumers are connected. A negative pressure occurs at the passage (24). The consumers, for example central locking devices, locking aids and similar devices in motor vehicles, are actuated in such a way that they assume a certain operating position or pass into this operating position. When the rotor (14) rotates in the direction of rotation (66), a negative pressure is created in the partial space (36), which propagates through the passage (40) and causes the open check valve (58) and the pipe (48, 52) Pipeline (62) the medium is sucked out of the tank, while the check valve (60) locks. This medium is compressed in the second chamber (32) and fed into the pipeline (46) and the pipeline (50) under excess pressure via the passage (38). Via the open non-return valve (56), the medium under pressure passes into the channel (64) to which parts of the motor vehicle which require control pressure are connected. The check valve (54) is blocked.

If the rotor (14) rotates in the direction of rotation (68), then a partial vacuum is created in the subspace (22), which propagates to the consumers via the passage (26) and the pipeline (28) and at least partially sucks the medium out of them . The medium is pressurized via the partial chamber (22) and conveyed back into the tank through the passage (24) and the pipeline (30). The consumers can therefore be relieved of the negative pressure or put into another operating position or transferred into this. When the rotor (14) rotates in the direction of rotation (68), partial pressure (34) arises, which is propagated via the passage (38) and the pipes (46) and (50). The check valve (54) is opened by the negative pressure, so that medium is sucked out of the tank via the pipeline (62). The medium is compressed in the subspace (36) and passes under pressure through the passage (40) and the pipes (48, 52) to the check valves (58, 60). While the check valve (58) blocks, the check valve (60) opens and clears the way for the medium under pressure to the channel (64). Regardless of the direction of rotation of the rotor (14), a control pressure is therefore always generated in the channel (64) as overpressure k, so that the control elements working only with overpressure can be actuated. If necessary, the channel (64) and the control elements connected to it, for example pressure-consuming parts which belong to the control elements or can form them, and channels which are not shown connected to the tank so that the control pressure is reduced by itself when the rotor (14) is at a standstill.

With the device described above, after the elements of a central locking system, child locks or locking aids have been actuated, the pressure can be reduced immediately by reversing the direction of rotation of the rotor (14). This reversal is e.g. automatically specified for a short period of time. This means that the system is ready to be operated again after a short time.

In the device shown in FIG. 2, the chamber (16) of the vane pump (10) is connected via a line (70) to a check valve (72) which is connected to the channel (64) via a further line (74) . The check valve (72) is arranged to block in the direction of the channel (64).

When the rotor (14) rotates, a control pressure quickly builds up in the channel (64). If this control pressure exceeds the force of the spring preload of the check valve (72) and the pressure prevailing in the chamber (16) at the mouth of the line (70), pressure medium is fed into the chamber (16) from the channel (64). The second chamber (32) is therefore additionally used in the device according to FIG. 2 for charging the chamber (16) with the medium to be conveyed. The efficiency of the vane pump (10) is therefore improved.

The channel (64) for the control pressure is expediently connected to actuating elements of a central locking system of a motor vehicle. The actuators require overpressure to switch them on and off. The passage (26) of the first chamber (16) intended for consumers is preferably connected to the seals of a sealing system in a motor vehicle.

The seals can be pressurized to e.g. to seal windows or doors of the motor vehicle well while driving and to exert a certain holding force on them. The holding force is particularly important for motor vehicle doors that have a certain type of frame for the panes. When the panes are opened, the seals are subjected to negative pressure.

Claims (9)

1. Device with a vane pump (10), which has a rotor (14) eccentrically mounted in a housing (12) to form a chamber (16), which contains recesses (42) in which vanes interacting with the inner wall of the housing ( 44) are arranged to be radially displaceable, two passages (24, 26) being provided in the wall of the chamber (16) for connection to at least one consumer and to a space containing a medium to be conveyed,
characterized by
that the rotor (14) forms a second chamber (32) with the housing (12), in the wall of which two passages (38, 40) are provided, each having a first and a second check valve (54, 56; 58, 60 ) are connected on the one hand to a common space for the medium to be conveyed and on the other hand to a common channel (64) for the control pressure and that the rotor (14) can optionally be driven in opposite directions of rotation (66, 68). 2. Device according to claim 1,
characterized by
that the check valves (54, 56; 58, 60) are each arranged at the ends of pipes (50, 52) connected to a partial space (34, 36) of the second chamber (32) in such a way that they are in the direction of the space block the medium to be funded. 3. Device according to claim 1 or 2,
characterized by
that the medium is a liquid. 4th Device according to claim 1 or 2,
characterized by
that the second chamber (32) has a smaller volume than the first chamber (16). 5. Device according to one of the preceding claims,
characterized by
that a further passage is provided in the wall of the first chamber (16) and is connected to the channel for the control pressure via a check valve which is permeable in the direction of the chamber (16). 6. Device according to one of the preceding claims,
characterized by
that both chambers (16, 32) have partial spaces (20, 22; 34, 36) with crescent-shaped cross sections with respect to a plane of symmetry (18). 7. The device according to claim 5,
characterized by
that the rotor (14) after switching from one direction of rotation to the other direction of rotation (68) for a predetermined short period of time with this direction of rotation can be driven and automatically switched off. 8. Device according to one of the preceding claims,
characterized by
that the channel (64) for the control pressure is connected to the actuating elements of a central locking system of a motor vehicle. 9. Device according to one of the preceding claims 1 to 7,
characterized by
that the one passage (26) of the first chamber (16) is connected to a pressurizable sealing system for the windows or doors of a motor vehicle.

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