EP0717201A2 - Protection system in a pressure installation - Google Patents

Abstract

The overflow valve for each consumer circuit is enclosed by a direction connection (29,26) which each include a shut-off device (12,19) controlled by the pressures of the two consumer circuits (10,21). When there is a higher pressure in the consumer circuits not allocated to same than in the consumer circuit (10,21) which is allocated to same the shut-off device is switched into the blocking position. At least one of the direct connections has a secondary non-return valve (30,27) which is permeable in the direction of the associated consumer circuit. At least one of the shut-off devices only switches into the shut-off position when there is a predetermined pressure difference.

Description

The invention relates to a protection system according to the preamble of patent claim 1.

Such a protection system is known from DE 34 34 884 A1. Positions I and II or 1 and 10 can be viewed there as overflow valves and consumer circuits assigned to them in the sense of the preamble of claim 1, for example in FIG. 1.

The overflow valves of a protection system of the type mentioned initially have different opening pressures when filling the pressure medium system from atmospheric pressure, which is due to inevitable manufacturing and setting tolerances. In addition to an uneven build-up of pressure when filling the consumer circuits, this can result in the fact that, in the event of a defect in the consumer circuit, whose overflow valve has the lower opening pressure when the pressure medium system is filled from atmospheric pressure, the entire delivery volume of the supply device into the defective consumer circuit and out of it into the Atmosphere flows out and the intact consumer circuit is not ready for operation.

As is explained in more detail in the already mentioned DE 34 34 884 A1, the inlet pressure to be supplied by the supply device at which an overflow valve opens, that is to say its opening pressure, also depends on the pressure on it Output, i.e. from the consumer circuit pressure of the downstream consumer circuit. An overflow valve therefore requires a lower opening pressure to open the higher the consumer circuit pressure. If the consumer circuit is empty, ie if there is atmospheric pressure in it, the assigned overflow valve has its highest opening pressure.

The known protection system evaluates this characteristic of an overflow valve by means of the direct connections with limited permeability to improve the behavior of the protection system. Chokes in the direct connections serve to limit the transmission capacity.

Via each direct connection, when the supply device is working, pressure medium is conveyed past it into the assigned consumer circuit even when the overflow valve is closed. As a result, consumer circuit pressures build up in the consumer circuits, which lower the opening pressures of the overflow valves and thus lead to a more uniform pressure build-up when filling. If only one consumer circuit is intact, a consumer circuit pressure builds up in it, which leads to the opening pressure of the assigned overflow valve being reduced below the value of the highest opening pressure and to the safe opening of the overflow valve while the atmospheric pressure is maintained in the defective consumer circuit that the assigned overflow valve maintains its highest opening pressure and does not open until the pressure of the supply device and thus also the consumer circuit pressure of the intact consumer circuit have assumed this value.

With a large delivery rate of the supply device and low permeability of the direct connections, the opening pressure of the overflow valve with the lower opening pressure builds up very quickly in front of the overflow valves. This overflow valve then opens long before the other overflow valve. This results in a very uneven pressure build-up with intact consumer circuits. This can be countered by making the direct connections as large as possible. The large permeability of the direct connections has the disadvantage, however, in the event of a defect in a consumer circuit, that the entire delivery quantity of the supply device flows into the defective consumer circuit and from there into the atmosphere and the intact consumer circuit does not become operational. This applies in particular when the supply device has a small delivery rate.

The invention has for its object to develop a protection system of the type mentioned with simple means so that it ensures a uniform pressure build-up with intact consumer circuits for both large and small delivery rates of the supply device and good filling security of the intact consumer group with a defective consumer circuit.

This object is achieved by the invention specified in claim 1. Advantageous further developments and refinements are specified in the subclaims.

The invention enables a universally applicable protection system and thereby a considerable rationalization effect.

The invention is suitable for pressure medium systems of the type mentioned at the outset for use in all technical fields and in connection with all liquid and gaseous pressure media. Compressed air is often used as a pressure medium. Vehicle pressure systems offer an important area of application in connection with compressed air.

The protection system mentioned at the outset can be supplemented by one or more additional overflow valves for one or more additional consumer groups which are subordinate to the original consumer groups mentioned in the preamble of claim 1. This is dealt with in more detail below using the example of an additional overflow valve and an additional consumer circuit. These explanations apply in full to one or more additional overflow valves and the associated consumer circuits.

There are two options for arranging the additional consumer group. In the first possibility, the overflow valve of the subordinate consumer circuit is arranged parallel to the overflow valves of the original consumer circuit. In the second possibility, the overflow valve of the additional consumer circuit is arranged downstream of the overflow valves and the associated direct connections of the original consumer circuits via a check valve which is permeable in the direction of the additional consumer circuit.

In a protection system of the known type which has been supplemented in this way, if the pressure build-up in the original consumer circuits is uneven, the overflow valve of the additional consumer circuit may occur an overflow valve or the overflow valves of the original consumer circuits opens. The invention eliminates this possibility in the universally applicable embodiment mentioned above.

A case of such a pressure medium system is given, for example, by a vehicle pressure medium system, the original (and priority) consumer circuits of the service brake circuits and the additional (and subordinate) consumer circuit of which is a spring-loaded parking brake circuit if a certain performance of the service brake circuits is required to fill the pressure medium system with atmospheric pressure before the spring-loaded parking brake circuit has sufficient pressure to release the spring-loaded brake.

Fig. 1

schematisch ein Schutzsystem für eine Druckmittelanlage,

Fig. 2

ausschnittsweise Einzelheiten einer Ausgestaltung,

Fig. 3

eine Fortbildung der Ausgestaltung nach Fig. 2,

Fig. 4

eine Fortbildung der Ausgestaltung nach Fig. 3.

Further advantages of the invention will become apparent from the explanation which now follows with reference to drawings. Show with consistent use of reference numerals for elements with the same functions

Fig. 1

schematically a protection system for a pressure medium system,

Fig. 2

details of a configuration,

Fig. 3

a further development of the embodiment according to FIG. 2,

Fig. 4

a further development of the configuration according to FIG. 3.

Fig. 1 shows in solid lines the basic design of a protection system for a pressure medium system with two consumer circuits (10, 21), which are symbolized by storage containers.

The protection system contains an overflow valve (4), a direct connection (29) and a shut-off device (12) for one consumer circuit (10). The overflow valve (4) is arranged between a supply device (1) and the consumer circuit (10).

The supply device (1) contains, in a known manner, a pressure generator and any necessary pressure medium preparation devices, pressure regulating and pressure limiting devices.

The direct connection (29) is arranged bypassing the protective valve (4), that is to say parallel to it, also between the supply device (1) and the consumer circuit (10). The overflow valve (4) and the direct connection (29) are connected to the supply device (1) via a supply line (2, 28).

The shut-off device (12) is arranged in the direct connection (29) in such a way that it masters its passage. The shut-off device (12) can be controlled by two pressures by means of two pressure-dependent control devices (not described in more detail). Your one control device is connected to the one consumer circuit (10) via a control line (11), and your other control device is connected to the other consumer circuit (21) via a control line (20). The shut-off device (12) is designed such that, in the case of pressure equality, that is to say also at atmospheric pressure, the passage of the Direct connection (29) opens and closes this passage at a higher pressure in the control line (20) than in the control line (11). In other words, the shut-off device (12) is switched into a blocking position closing the passage of the direct connection (29) in favor of the consumer circuit (21) not assigned to it.

For the other consumer circuit (21), the protection system contains an overflow valve (23), a direct connection (26) and a shut-off device (19) with associated control lines (22, 32). The same applies to these components for the corresponding components for the one consumer circuit (10).

The transmission capacity of the direct connections (26, 29) is limited in such a way that in the event of a defect in a consumer circuit (10 or 21), the supply quantity (1) flowing into the defective consumer circuit (10 or 21) in every possible delivery quantity is the supply device (1) the assigned direct connection (29 or 26) generates a dynamic pressure which produces the effect described below. This limitation of the transmission capacity can be achieved by suitable dimensioning of the direct connections, but also by throttling in the direct connections, as indicated by the reference numerals (31 or 24). Throttles provided, as shown, can be arranged upstream of the shut-off devices (12 or 19), but also downstream thereof.

The basic mode of operation of overflow valves and direct connections that circumvent them in a protection system is detailed in the aforementioned DE 34 34 884 A1 described and is therefore assumed to be known in the present case.

It is assumed that one consumer circuit (10) is so badly defective that when the pressure medium system is filled with atmospheric pressure in this consumer circuit (10), despite the inflow of pressure medium through the associated direct connection (29), the atmospheric pressure is maintained. In the assigned direct connection (29), on the other hand, a dynamic pressure builds up even with a high permeability due to the flow resistance caused by the inflow. This propagates into the direct connection (26) assigned to the other consumer group (21) and through this into the other consumer group (21), which is indeed intact. The pressure propagation also takes place in the control line (20) of the shut-off device (12) assigned to the consumer circuit (21). This is switched into its blocking position by the pressure difference between the control lines (20) and (11). Now the entire delivery quantity of the supply device can flow via the direct connection (26) into the other, intact, consumer circuit (21). As a result, a consumer circuit pressure builds up in the other consumer circuit (21), which reduces the opening pressure of the associated overflow valve (23) and contributes to the safe opening of the same. By blocking the direct connection (29), a further escape of pressure medium via the now closed direct connection (26) and the defective consumer circuit (10) is prevented until the assigned overflow valve (4) opens, with the result that the intact consumer circuit ( 21) is filled up at least up to the (undiminished) opening pressure of the overflow valve (4) assigned to the defective consumer circuit (10). This opening pressure is called Safety pressure of the consumer circuit (21) is also maintained if the defect in the consumer circuit (10) occurs when the pressure medium system is full.

Switching the shut-off device (12) assigned to the defective consumer circuit (10) just described with practically every - however small - pressure difference can be disadvantageous if both consumer circuits (10, 21) are intact. A certain unevenness in the build-up of consumer pressure when topping up atmospheric pressure is inevitable, for example as a result of unequal volumes of consumer groups (10, 21). Switching a shut-off device (12 or 19) at practically any pressure difference would interrupt the filling of the consumer circuit (10 or 21) with the respective lower consumer circuit pressure until the pressure in the supply line (2, 28) and thus the consumer circuit pressure of the other consumer circuit (10 or 21) reaches the opening pressure of the overflow valve (4 or 23) of the consumer circuit (10 or 21) with the lower consumer circuit pressure. The unavoidable unevenness of pressure build-up in consumer circles would therefore be increased. This can be countered by further training of the shut-off devices (12, 19) in such a way that they are switched into the blocking position only at a predetermined value of the pressure difference. This training allows pressure differences up to the predetermined value, the switching of the shut-off device (12 or 19) is delayed accordingly, the described increase in the unevenness of the pressure build-up is avoided.

However, the shut-off devices (12, 19) must be specially designed for this training. Your switching must already start in the blocking position at the pressure difference caused by the dynamic pressure which, as described above, occurs in the case of a defective consumer circuit (10 or 21) in its direct connection (29 or 26) and in the intact consumer circuit (26 or 29) builds up. As the pressure difference increases, the shut-off devices must continuously approach the blocking position until they reach this at the predetermined value of the pressure difference. In other words, the shut-off devices (12, 19) in this development for pressure differences below the predetermined value must be designed as continuously narrowing throttles which reach the (complete) blocking position at the predetermined value of the pressure difference. With this design, the consumer circuit pressure leading to the safe opening of the associated overflow valve (23 or 4) also builds up in the intact consumer circuit (26 or 29).

Of course, with a correspondingly limited result, only one of the shut-off devices (12 or 19) can be designed in this way.

The broken line shows the figure further developments of the embodiment.

Secondary check valves (30 or 27) can be arranged in the direct connection assigned to a consumer circuit or in the direct connections (29 or 26) assigned to the two consumer circuits (10, 21). This secondary check valve or these secondary check valves prevent pressure medium from being supplied to the supply device (1) via the respectively assigned direct connection from the respectively assigned consumer circuit (10 or 21). or can flow into the other consumer group (21 or 10). The - albeit very low - flow resistance of the secondary check valve (s) (30 or 27) causes an increase in the above-mentioned dynamic pressure and therefore has an advantageous effect on the behavior of the protection system in the event of a defective consumer circuit pressure.

As further developments, the exemplary embodiment shows two arrangements of additional overflow valves and additional consumer circuits assigned to them. Alternatively, but also simultaneously, these arrangements can be present.

In the first arrangement, the relevant additional overflow valve (8) is arranged via an additional branch (5) of the supply line to be designated in this case with (2, 5, 28) between the supply device (1) and the associated additional consumer circuit (9). The additional overflow valve (8) and the associated additional consumer circuit (9) are subordinate to the original overflow valves (4, 23) and the assigned consumer circuit (10, 21) by suitable measures, for example by one compared to the opening pressures of the overflow valves (4, 23 ) of the original consumer groups (10, 21) increased opening pressure.

In the second arrangement of the additional overflow valve (15), the one original overflow valve (4) and the assigned direct connection (29) are a check valve (14) and the other original overflow valve (23) and the assigned direct connection (26) are a check valve (18). subordinate. The additional overflow valve (15) is connected to the outputs of the Check valves (14, 18) connected, and consequently arranged between each check valve (14, 18) and the additional consumer circuit (17). The check valves (14, 18) are arranged so that they are permeable in the direction of the additional overflow valve (15) or the additional consumer circuit (17). In this arrangement, the additional consumer circuit (17) receives pressure medium which has previously passed one of the original overflow valves (4, 23) or one of the direct connections (29, 26) assigned to it. As a result, the additional overflow valve (15) and the associated additional consumer circuit (17) are also subordinate to the original overflow valves (4, 23) and the associated consumer circuits (10, 21) in this arrangement. In this arrangement, the opening pressure of the additional overflow valve (15) can always be arbitrary between the pressure which can occur at its inlet when filling up atmospheric pressure only via the direct connections up to the full or nominal pressure. In this arrangement it is determined by aspects that are of no interest in the present context.

The check valves (14, 18) arranged between the original overflow valves (4, 23) and the associated direct connections (29, 26) are responsible for a (back) flow from the additional consumer circuit (17) into the original consumer circuits (10, 21 ), but also to prevent a (cross) flow between the original consumer groups (10, 21).

In both arrangements of additional overflow valves (8, 15) and associated additional consumer circuits (9, 17), the overflow valves (8, 15) are immediate direct connections not provided. However, such direct connections are possible in a manner not shown and can be used to design subordinate values by suitably designing their flow capacity.

In each arrangement, the additional overflow valve (8 or 15) and the associated consumer circuit (9 or 17) can stand for several additional consumer circuits. This is indicated by broken lines and labeled (7) or (13). In this case, it may be expedient to prevent a cross flow between the additional consumer circuits through the check valves upstream or downstream. Such check valves are shown with the reference numerals (6 and 16). In the case of the arrangement of the additional overflow valve (s) mentioned first, which is a parallel arrangement to the original overflow valve (4, 23), the check valve (6) connected upstream or downstream of the additional overflow valve (8) or the additional overflow valves is also used Prevention of a backflow to the supply device (1) and prevention of a cross flow between the additional consumer circuit (9) or the additional consumer circuits and the original consumer circuits (10, 21).

Check valves (3, 25) can also be connected upstream or downstream of the original overflow valves (4, 23), which prevent backflow to the supply device (1) and crossflow between the consumer circuits, including any additional ones arranged in parallel.

The illustration shows the protection system in a resolved design. This means that the existing overflow valves, the shutdown devices and the existing check valves are independent units and the associated pressure medium lines as well as the existing direct connections, including the throttles, form an open line system. Any known suitable type comes into consideration as an overflow valve in this design, e.g. B. according to the WABCO Westinghouse publication "Überströmventil 434 100", August 1973 edition. The version shown there "without backflow" includes an approximately assigned check valve. Any suitable pressure difference controlled 2/2-way valve can be used as a shut-off device. The shut-off devices must be linked so that one remains continuous when the other is in the locked position.

However, all components of the protection system can also be combined in a compact design to form a "multi-circuit protection valve" and then form an assembly similar to that which is shown in FIG. 3 of the already mentioned DE 34 34 884 A1.

Fig. 2 shows an embodiment of the shut-off devices (12 and 19).

Two consumer circuit chambers (41, 46) are arranged within a housing (42). The housing (42) can be a housing specially provided for the shut-off devices (12 and 19), but in the case of the compact construction of the protection system it can also be the housing common to all components.

From the viewer's point of view, one of the direct connections (29 or 26) opens into each consumer circuit chamber (41 or 46) from the right or left. Valve seats are arranged in the housing in a known manner surrounding the orifices. In the following, for the sake of simplicity, these valve seats are referred to as "mouth (s)". The orifices (47 or 40) of the direct connections (29 or 26) to be understood in this way are coaxial to one another.

The consumer circuit chambers (41, 46) are connected to one another by a housing opening (43) running coaxially to the orifices (40, 47). In addition, the consumer circuit chambers (41, 46) are each connected to one of the original consumer circuits (10 or 21) and to the outlet of the respectively assigned overflow valve (4 or 23).

A sealing body (44) is sealed in the housing opening (43) and axially displaceable between two end positions. In the exemplary embodiment, a separate, unspecified, sealing element of conventional design is provided for sealing against each consumer circuit chamber (41 or 46). This type of sealing secures the consumer circuits (10, 21) against each other, since a leakage amount that may pass through one sealing element cannot pass into the other consumer circuit, but via an unidentified breathing opening of the housing opening (43) to the atmosphere, or, depending on Type of pressure medium that can escape into a collecting container with atmospheric pressure. Without this advantage, the sealing of the closing body (44) can also be carried out with only one sealing element.

The right end position of the closing body (44) from the viewpoint of the viewer is determined by its striking against the mouth (47) of the direct connection (29). The left end position of the closing body (44) from the viewer's point of view is determined accordingly. The stop surfaces or stop lines of the closing body (44) are dimensionally and of material so that the closing body (44) over these surfaces or lines with the respectively assigned mouth (47 or 40) of the direct connections (29 or 26) each form a valve (44, 47 or 44, 40) which controls the passage between the respective direct connection (29 or 26) and the respective consumer circuit chamber (46 or 41) and thus the respective consumer circuit (10 or 21) . It is obvious that the orifices (47 or 40) must also be suitable in terms of the material used to form these valves (44, 47 or 44, 40).

As a result of the sealing of the closing body (44) described, two piston surfaces are formed on it, each of which is subjected to the consumer circuit pressure prevailing in a consumer circuit chamber (46 or 41).

If the consumer circuit pressure in one consumer circuit chamber (46 or 41) outweighs the consumer circuit pressure in the other consumer circuit chamber (41 or 46), the higher consumer circuit pressure shifts the closing body (44) into the end position, which through the mouth (40 or 47) the direct connection (29 or 26) assigned to the respective other consumer group (10 or 21). In the case of pressure equality in the consumer circuit chambers (41, 46), that is to say also at atmospheric pressure in the same, the shooting body (44) assumes a central position which releases both valves, but which is not necessarily the geometric one Must be middle position. Due to the mode of operation described above, the closing body (44) and the orifices (47 and 40) represent shut-off devices (12 and 19) according to FIG. 1. In a general form, these shut-off devices can be referred to as two pressure-difference-controlled 2/2-way valves, which are linked so that one is in its open position when the other is in its locked position.

If the embodiment according to FIG. 2 is to be developed in such a way that at least one shut-off device (12 or 19) does not move into its blocking position until the valve (44, 47 or 44, 40) concerned has reached a predetermined value of the pressure difference between the consumer circuit pressures. is closed, is switched, this can be done, for example, by a switching spring (45). The switching spring (45) is supported on the one hand on the closing body (44) and on the other hand on the housing (42) and, by means of its force in the assigned end position of the closing body (44), determines the pressure difference at which the higher consumer circuit pressure presses the closing body against the force of the switching spring (45) has moved to this end position. The switching spring (45) must be designed in order to achieve the above-mentioned characteristic of the continuously narrowing throttle in its spring characteristic.

Switch springs (45) are shown on both sides in the embodiment described, but if the application requires this, a switch spring (45) can also be provided on only one side.

FIG. 3 shows, on the example of the right-hand side from the viewpoint of the beholder, a further development of the configuration with switching spring (45) according to FIG. 2.

In this development, the secondary check valve (30) according to FIG. 1 is integrated in the shut-off device (12). For this purpose, a secondary valve member (54) is arranged between the closing body (52) here and the mouth (47) of the direct connection (29). Together with the mouth (47), this forms the secondary check valve (30).

If the pressures in the consumer circuit chamber (46) and in the direct connection (29) are the same, the secondary valve member (54) is pressed against the mouth (47) by a closing spring (51) while closing the secondary check valve (30). Only if the pressure in the direct connection (29) outweighs the consumer circuit pressure and the force of the closing spring (51), does the pressure in the direct connection (29) lift the auxiliary valve member (54) from the mouth (47) while opening the auxiliary check valve (30) ). The secondary check valve (30) is consequently (only) permeable in the direction of the consumer circuit chamber (46) and thus in the direction of the associated consumer circuit (10). The force of the closing spring (51) was mentioned above for the sake of completeness. It is so small by appropriate design of the closing spring (51) that its effect in practice is negligible with the exception of the above-mentioned increase in dynamic pressure in the event of a defective consumer circuit.

If the closing body (52) is shifted to the right from the perspective of the viewer by a pressure difference in favor of the consumer circuit pressure in the consumer circuit chamber (41), which is not shown but is connected to the other consumer circuit (21), its end facing the secondary valve member (54) shifts towards the secondary valve member (54) presses it against the mouth (47), thereby closes the auxiliary check valve (30) and keeps it closed, regardless of the pressures in the direct connection (29) and in the consumer circuit chamber (46).

The closing spring (51) can be supported directly on the housing (42) in a manner not shown. In the illustration, however, a spring plate (50) is arranged between the closing spring (51) and the housing (42). The spring plate (50) is due to the switching spring (45). It offers a simple solution for the simultaneous arrangement of the closing spring (51) and the switching spring (45). If, as shown, the closing body (52) is in a central position, both springs (45) and (51) are supported on the housing (42) via the spring plate (50). If the closing body (52) is shifted to the right from the viewpoint of the beholder, a driving shoulder (53) arranged on the closing body (52) grips the spring plate (50), so that both springs (45) and (51) support on the closing body (52) and determine the characteristics of the shut-off device (12).

From the participation of the closing spring (51) in determining the characteristic of the shut-off device (12), the advantage follows that the switching spring (45) can be made correspondingly weaker and therefore cheaper and smaller.

The aforementioned gripping of the spring plate (50) by the driving shoulder (53) of the valve body (52) takes place after the latter has covered an empty displacement (x). The empty displacement (x) serves to compensate for any manufacturing tolerances between the closing body (52) and the housing (42).

The statements made above for the right-hand side from the viewpoint of the viewer apply in a corresponding manner to the left-hand side, which is not shown, from the viewpoint of the viewer.

In FIG. 4, the embodiment according to FIG. 3 is developed into an embodiment in which the check valves (14, 18) required for the reordering of the additional overflow valve (15) and the associated additional consumer circuit (17) are integrated.

With regard to components and functions that appear identically on both sides, the description is again based on the viewer's right-hand side of the illustration.

In this case, the housing opening (43) in FIGS. 2 and 3 is developed into an additional consumer circuit chamber (64). For the purpose of forming the additional consumer circuit chamber (64), a housing-fixed valve seat (62) facing the interior of the housing opening is arranged between the consumer circuit chamber (46) and the interior of the housing opening in the housing designated here (65), namely coaxially to the mouth (47 ) of the direct connection (29) and thus also coaxial to the mouth (40) on the left, from the perspective of the viewer.

The additional consumer circuit chamber (64) is connected to the additional overflow valve (15) associated with the additional consumer circuit (17) via a connection (not described in more detail), specifically to the inlet thereof.

An axially displaceable valve body (60) is arranged within the additional consumer circuit chamber (64). With the valve seat (62) fixed to the housing, this forms the check valve (14) of FIG. 1, to the outlet of which - via the additional consumer circuit chamber (64) - the additional overflow valve (15), namely its inlet, is connected.

The valve body (60) has an unspecified cavity, which extends axially through the valve body (60) and extends coaxially to the mouth (47) of the direct connection (29) and to the valve seat (62). The closing body (52) is sealed and axially displaceable in this cavity.

The valve body (60) is biased by a closing spring (63) arranged in the additional consumer circuit chamber (64) against the valve seat (62) and thus in the closing direction of the check valve (14). The closing spring (63), on the other hand, is supported on the corresponding valve body on the left-hand side from the perspective of the viewer and therefore also serves as the closing spring of the check valve (18) which can be seen on the left.

Only if the consumer circuit pressure in the consumer circuit chamber (46) outweighs the pressure prevailing in the additional consumer circuit chamber (64) and the force of the closing spring (63), does the consumer circuit pressure mentioned lift the valve body (60) from the valve seat () by opening the check valve (14). 62). Otherwise, the closing spring (63), possibly in connection with an excess pressure in the additional consumer pressure chamber (64), presses the valve body (60) against the valve seat (62) while closing the check valve (14). The check valve (14) is therefore (only) in Permeable direction of the additional consumer circuit (17).

If the auxiliary check valve (30) and the switching spring (45) are also provided in this embodiment, as shown, it is expedient, as shown, to support the spring plate (61) assigned to the valve body (60). Supporting the valve plate, as in FIG. 3, on the housing could have an adverse effect on the flow or flow through the check valve (14). However, with this arrangement of the spring plate (61), the closing spring (63) must be designed so strong that it also counteracts the forces of the closing spring (51) and the switching spring (45) at atmospheric pressure or a low pressure in the additional consumer circuit chamber (64). sufficient closing force is required to securely close the check valve (14).

If the empty displacement (x) of the closing body (52) is also to be possible in this embodiment, it must, as shown, be provided within the cavity of the valve body (60).

When the pressure medium system is filled from atmospheric pressure, the overflow valve (14) opens when, via the direct connection (29) in the consumer circuit chamber (46) and thus in the associated consumer circuit (10), a consumer circuit pressure has built up, which the pressure from the closing spring (63) overcomes the closing force exerted on the valve body (62). Due to the now possible pressure medium flow through the check valve (14), a pressure builds up via the additional consumer circuit chamber (64) up to the entrance of the additional overflow valve (15). However, this pressure is not sufficient to open the additional overflow valve (15).

Only when the overflow valve (4) assigned to the consumer circuit (10) has opened can pressure build up in the consumer circuit (10) and thus in the assigned consumer circuit chamber (46), which pressure can be exerted via the overflow valve (14) and the additional consumer circuit chamber (64 ) enables the opening pressure to be built up when atmospheric pressure is filled at the inlet of the additional overflow valve (15) and thus opens it. This ensures the priority of the consumer circuit (10) and the overflow valve (4) assigned to it over the additional consumer circuit (17) and the overflow valve (15) assigned to it.

In a further development, the closing spring (63) can be designed so strongly that it exerts a force on the valve body (60) that goes beyond the closing force required to close the check valve (14) properly. As a result, when the pressure medium system is filled from atmospheric pressure, the value of the consumer circuit pressure in the consumer circuit (10) and in the associated consumer circuit chamber (46), which is required to open the overflow valve (14), is increased. The consequence of this is that the priority of the consumer circuit (10) over the additional consumer circuit (17) and the associated additional overflow valve (15), measured in pressure units, is increased.

The participation of the parts of the pressure medium system shown on the left from the viewpoint of the viewer is not necessary to achieve the effects described above. This means that this functional description also applies in the event that the other consumer group (21) is defective. However, if, as is normal, both consumer groups (10) and (21) are intact, they apply above for the explanations given on the right-hand side from the point of view of the viewer for the left-hand side in a corresponding manner from the point of view of the viewer.

In the case of the parallel arrangement of the additional consumer circuit (9) according to FIG. 1, further devices, such as, for example, a pressure limiting device, can be arranged between the assigned overflow valve (8) and the supply device (1), in the event that the additional consumer circuit (17) is arranged. Such further devices can be arranged between the check valves (14) and (18) and the associated additional overflow valve (15) without the above statements being influenced thereby.

For the rest, unless otherwise stated in the foregoing, the statements made for one figure apply to the other figures directly or in a corresponding application.

Those skilled in the art recognize that the scope of protection of the invention is not limited to the above exemplary embodiments or configurations, but rather that it encompasses all configurations whose characteristics are subordinate to the patent claims.

Claims (10)

Protection system for a pressure medium system having two consumer circuits (10, 21), with an overflow valve (4 or 23) for each consumer circuit (10 or 21), which is arranged between a supply device (1) and the respectively assigned consumer circuit (10 or 21) is provided for each consumer circuit (10 or 21) a direct connection (29 or 26) bypassing the respective overflow valve (4 or 23) with limited permeability, characterized in that in each of the direct connections (29 or 26) a shut-off device (12 or 19) controlled by the pressures of both consumer circuits (10, 21) is arranged, which at a higher pressure in the consumer circuits (21 or 10) not assigned to it than in the consumer circuit (10 or 21 ) is switched to a locked position. Protection system according to claim 1,
characterized by
in that at least one of the direct connections (29 or 26) has a secondary check valve (30 or 27) which is permeable in the direction of the respectively assigned consumer circuit (10 or 21). Protection system according to one of the preceding claims,
characterized by
that at least one of the shut-off devices (12, 19) is switched into the blocking position only at a predetermined value of the pressure difference. Protection system according to one of claims 1 or 2,
characterized by
that it has the following features for forming the shut-off devices (12, 19): a) within a housing (42) each direct connection (29 or 26) opens coaxially to the respective other direct connection (26 or 29) in each case in a consumer circuit chamber (46) connected at least to the outlet of the respectively assigned overflow valve (4 or 23) or 41); b) the consumer circuit chambers (46, 41) are connected by a housing opening (43) arranged coaxially to the orifices (47 or 40) of the direct connections (29 or 26); c) in the housing opening (43) is sealed and axially displaceably guided a closing body (44) which closes the mouth (47 or 40) of a direct connection (29 or 26) in an end position. Protection system according to one of the preceding claims,
characterized by
that it has at least one additional overflow valve (8) arranged between the supply device (1) and an additional consumer circuit (9) with an increased opening pressure compared to the opening pressures of the first-mentioned overflow valves (4, 23). Protection system according to one of the preceding claims,
characterized by
that each direct connection (29 or 26) and the associated overflow valve (4 or 23) is followed by a check valve (14 or 18) and the protection system has at least one additional, between the check valves (14, 18) and an additional consumer circuit ( 17), in the direction of which the check valves (14, 18) are permeable, has an overflow valve (15). Protection system according to one of Claims 1 to 3 and 6 or 5 and 6,
characterized by
that it has the following features for forming the shut-off devices (12, 19): a) within a housing (65) each direct connection (29 or 26) coaxially to the respective other direct connection (26 or 29) opens into a consumer circuit chamber (46 or at least) connected to the outlet of the respectively assigned overflow valve (4 or 23) . 41), b) coaxial to the orifices (47 or 40) are direct connections (29 or 26) to the housing-fixed valve seats (62), each having a consumer circuit chamber (46 or 41) from an additional consumer circuit chamber connected to the additional overflow valve (15) Delimit (64); c) each of a direct connection (29 or 26) and the associated overflow valve (4 or 23) downstream check valves (14, 18) are each formed by one of the valve seats (62) and a valve body (60); d) the valve bodies (60) have coaxial cavities to the orifices (47 or 40) of the direct connections (29 or 26); e) in the cavities of the valve body (60) is sealed and axially displaceably guided a closing body (52) penetrating the additional consumer circuit chamber (64), which in its end positions has the mouth (47 or 40) of a direct connection (29 or 26) closes. Protection system according to claims 2 and 4 or 2 and 7,
characterized by
that to form the secondary check valve (30 or 27) between the mouth (47 or 40) of the associated direct connection (29 or 26) and the closing member (44; 52) coaxial with this mouth (47 or 40) and the closing member (52) is arranged an axially displaceable secondary valve member (54). Protection system according to claims 3 and 4 or 3 and one of claims 7 or 8,
characterized by
that the closing body (44; 52) is biased at least in one direction of displacement relative to the housing (42; 65). Protection system according to claim 9,
characterized by
that a switch spring (45), which is provided on the one hand on the closing member (44; 52) and on the other hand on the housing (42; 65), is provided for producing the pretension, seen in the direction of displacement of the closing member (44; 52).

Images