DE102023120530A1 - Level control system for vehicles and method for operating the level control system - Google Patents

Abstract

The invention relates to a level control system (10) for vehicles, the level control system comprising a compressor device (12), a gallery (14) with at least one air suspension strut connected thereto, at least indirectly, a supply line (16) and an air dryer (18) with a compressor device (18). 12) connected input side (E) and an output side (A) connected to the gallery (14), the compressor device (12) and the gallery (14) being pneumatically connected by the supply line (16) in such a way that from the compressor device ( 12) compressed air that can be generated can be supplied to the gallery (14) with the interposition of the air dryer (18), the air dryer (18) being regenerated by a regeneration device (24) by blowing out compressed air through the air dryer (18) to an atmosphere outlet (22). it is provided that a pneumatic regeneration path for regeneration of the air dryer (18) is provided in the regeneration device (24), which is designed such that the compressed air generated by the compressor device (12) is directed to the air dryer (12) in a flow direction predetermined by the compressor device (12). 18) and can then be switched to the atmosphere outlet (22).

Description

The invention relates to a level control system for vehicles, the level control system having a compressor device, a gallery with at least one air suspension strut at least indirectly connected thereto, a supply line and an air dryer with an input side connected to the compressor device and an output side connected to the gallery, the compressor device and the gallery is pneumatically connected by the supply line in such a way that compressed air generated by the compressor device can be supplied to the gallery with the interposition of the air dryer, the air dryer being regenerated by a regeneration device by blowing out compressed air through the air dryer to an atmosphere outlet.

The invention also relates to a method for operating such a level control system.

STATE OF THE ART

Level control systems of the type mentioned are basically known from the prior art.

The air dryer of such level control systems usually serves to remove as much of the air moisture contained in the compressed air sucked in from the atmosphere by the compressor device or to reduce the relative air humidity to a tolerable level. It is known that moisture can lead to corrosion-related wear in pneumatic systems, especially in metal components, but also in plastic components. In this respect, without the air dryer, the moisture introduced into the system could cause damage to the system and thus negatively affect its operability.

The air dryer is usually filled with at least one moisture-storing material, usually silica gel, which, when the compressed air is passed through it, automatically removes and absorbs or stores at least part of the moisture it contains. However, the moisture storage capacity of the material is always limited, so that above a certain throughput of dried air, moisture can no longer be stored and the air would pass through the air dryer undried.

In order to permanently maintain the moisture storage capacity or drying capacity of the air dryer, it is known to regenerate the air dryer at regular intervals. For physical reasons, the moisture-storing material always strives to always create a state of equilibrium with the ambient moisture in terms of its moisture content. In known corresponding regeneration processes, comparatively dry air is usually blown out through the air dryer into the atmosphere, whereby the air absorbs the stored moisture and transports it away into the atmosphere. This reduces the load on the material so that the drying capacity is maintained or restored and the air dryer is regenerated.

In this regard, for example, the DE 100 16 917 C1 a generic level control system for a vehicle, in which compressed air can be supplied to an air spring gallery by means of a compressor through an air dryer. The gallery and the air dryer are pneumatically decoupled by a check valve and can be pneumatically coupled if necessary using at least one magnetically or pneumatically controllable valve. If the air dryer and the gallery are pneumatically coupled, compressed air stored in the system in the gallery or in a compressed air reservoir can be fed through the air dryer to an atmosphere outlet. This blowing out of compressed air through the air dryer enables regeneration of the air dryer, so that at least one valve forms a regeneration device.

The EP 3 436 295 B1 discloses a generic level control system with a gallery that can be filled with compressed air by a compressor with the interposition of a dryer. The dryer is decoupled from the gallery by a check valve. This check valve is part of a controllable solenoid valve, which can pneumatically couple or decouple the gallery and dryer depending on the switching status. Furthermore, a bridging valve is provided, by means of which the check valve can be bridged via a decoupling line. When the solenoid valve is switched, the gallery is pneumatically connected to an atmosphere outlet. In addition, another line to the outlet is provided via the bridging valve, so that the gallery can be vented, i.e. the compressed air stored in the gallery can be released particularly quickly. Since the compressed air flowing from the gallery is passed through the dryer, the regeneration of the dryer is also ensured, so that a regeneration device is also formed by the valves.

The currently known level control systems all always have in common that the air dryer can only be regenerated with compressed air that is already in the system, which in this respect results in one introduced into the system at an earlier point in time and already dried by the air dryer. Regeneration also takes place passively as standard when the gallery or system is vented, i.e. when compressed air is released from the system anyway and not specifically when necessary for the primary purpose of regeneration.

The disadvantage of the known level control systems is that, due to the aforementioned equilibrium condition, this compressed air can only absorb as much moisture as it previously introduced into the system or released to the air dryer. The stored compressed air is also comparatively cool and therefore only has a relatively low moisture storage capacity. Another disadvantage is that regeneration is only possible if compressed air has previously been introduced into the system and stored; there is no possibility of regeneration independent of the previous introduction of compressed air.

The object of the invention is therefore to provide an improved level control system in which the regeneration of the air dryer can be carried out at any time when necessary and independently of compressed air stored in the system and, moreover, takes place with improved efficiency due to an increased moisture storage capacity.

This task is solved by a level control system and a method according to the independent claims. Advantageous embodiments of the invention are the subject of the subclaims.

DISCLOSURE OF INVENTION

The invention is based on a level control system for vehicles, the level control system having a compressor device, a gallery with at least one air suspension strut connected to it at least indirectly, a supply line and an air dryer with an input side connected to the compressor device and an output side connected to the gallery, the Compressor device and the gallery are pneumatically connected by the supply line in such a way that compressed air generated by the compressor device can be supplied to the gallery with the interposition of the air dryer, the air dryer being regenerated by a regeneration device by blowing out compressed air through the air dryer to an atmosphere outlet.

According to the invention, it is provided that a pneumatic regeneration path for regeneration of the air dryer is provided in the regeneration device, which is designed such that the compressed air generated by the compressor device can be fed to the air dryer in a flow direction predetermined by the compressor device and then switchably to the atmosphere outlet.

The compressor device can be designed in one stage or in two stages with a pre-compression and a post-compression stage, and can be designed as a reciprocating piston compressor, a rotary compressor, a scroll or screw compressor.

In the context of the present invention, the regeneration device is to be understood as meaning a combination of at least one controllable valve, in particular several valves of different types that are at least operatively connected to one another (but possibly structurally separate), as well as at least one compressed air line, through which a pneumatic direct connection between the air dryer and the Atmosphere outlet can be produced. The pneumatic regeneration path is understood to mean the flow path of the compressed air predetermined by the mechanical design of the regeneration device, which in this respect results from the specific arrangement of lines and valves of the regeneration device.

The specified flow direction is the pumping direction of the compressor device, i.e. the direction in which it delivers the compressed air when operating as intended. In the present case, the flow direction runs from the compressor device to the inlet side of the air dryer and from the outlet side of the air dryer in the direction of the gallery. As is known to those skilled in the art, this flow direction results from the excess pressure generated by the compressor device and therefore always leads away from the compressor device. A corresponding return flow direction opposite to the flow direction leads to the compressor device and thus acts counter to the pumping direction.

The solution according to the invention advantageously enables active regeneration of the air dryer - in contrast to solutions known from the prior art. In the context of the present invention, active regeneration means a regeneration of the dryer that can be carried out at any time when necessary and is independent of the compressed air already in the system, i.e. a procedure in which at least components of the level control system are operated primarily for the purpose of operating the air dryer to regenerate.

In the present case, the active regeneration takes place through targeted operation of the compressor device and directing the compressed air generated through the air dryer to the atmosphere outlet. As a result of the operation of the compressor device, the air sucked in is heated or heated, in particular due to friction processes occurring in the compressor device, so that its capacity to absorb moisture is increased for physical reasons. The sucked in and heated air can then be specifically conveyed through the air dryer using the regeneration path, whereby it can absorb an increased amount of moisture stored in the air dryer. The compressed air generated primarily for the purpose of regeneration can then essentially be released directly into the atmosphere, so that the moisture can be removed from the air dryer in a targeted and controlled manner.

The solution according to the invention offers the advantage that targeted regeneration of the dryer is always possible when necessary. Because the air heated during this procedure simultaneously has an increased moisture storage capacity, the efficiency of the regeneration process is also advantageously increased. Advantageously, the active regeneration can also be carried out independently of compressed air stored in the level control system.

According to a preferred development, it is provided that the regeneration path comprises at least one first outlet valve arranged on the outlet side of the air dryer, through which a connection of the outlet side of the air dryer to the atmosphere outlet can be switched, wherein preferably the first outlet valve from the direction of the outlet side to the gallery in front of a decoupling valve is arranged, through which the output side can be decoupled from the gallery at least in a return flow direction opposite to the flow direction. Advantageously, the atmosphere outlet can be pneumatically separated from the level control system by the first outlet valve, so that a flow of air back into the system and, in particular, the entry of dirt and/or moisture can be safely avoided. The decoupling valve offers the further advantage that the air volume of the gallery is separated from the air volume of the air dryer, so that less compressed air is required to fill the gallery to a sufficient or desired pressure level.

According to a preferred development, it is provided that the decoupling valve is designed as an actively switchable valve or as a check valve. In particular, in the case of a switchable valve, a pneumatic valve or solenoid valve is provided. These embodiments of the decoupling valve are advantageously cost-effective, easy-to-operate and relatively wear-resistant solutions.

According to a preferred development, it is provided that a second outlet valve is arranged on the inlet side of the air dryer, through which a connection of the inlet side of the air dryer to the atmosphere outlet can be switched. Advantageously, in addition to the active regeneration already described above, the second outlet valve also enables passive regeneration (already discussed at the beginning), i.e. the regeneration of the air dryer by blowing out compressed air that is already in the level control system, in particular in the gallery. Depending on your needs, you can advantageously choose between active and passive regeneration.

According to a preferred development, it is provided that the regeneration device has a bridging path as part of the regeneration path with at least one bridging valve, in particular a pneumatic valve or solenoid valve, the bridging valve being arranged and designed in such a way that the decoupling valve can be bridged by the bridging valve.

In this respect, it is provided that the bridging valve can be switched between at least two switching states. In a first switching state, the bridging path is blocked so that the decoupling valve fulfills its intended function of pneumatic decoupling of the air dryer and gallery. In a second switching state, however, the bridging path is opened and the decoupling valve is thus bridged, so that the air dryer and the gallery are pneumatically coupled. The check valve and the bridging valve are therefore arranged in the bridging path in such a way that an automatic backflow of the compressed air to the air dryer is prevented by the check valve (and the bridging valve in the first switching state), and the backflow is possible if necessary by switching the bridging valve (second switching state). . The bridging valve is therefore arranged between the air dryer and the gallery. This advantageously further improves the operating efficiency of the level control system.

According to a preferred development, it is provided that the regeneration device has a check valve, which is arranged in the bridging path between the outlet side of the air dryer and an outlet side of the bridging valve in such a way that a Automatic backflow of compressed air from the gallery via the open bridging valve to the outlet side of the air dryer can be blocked during operation of the compressor device. During operation of the compressor device, there is always excess pressure on the opening side of the check valve (compared to the closing side), so that the check valve cannot be opened. However, if the compressor device is not in operation, no pressure is applied to the opening side of the check valve, so that when excess pressure occurs on the other side, it opens and the compressed air can flow through the check valve accordingly. This advantageously ensures that the compressed air is always passed through the air dryer during operation of the compressor device for the purpose of active regeneration.

According to a preferred development, it is provided that in the regeneration device the second outlet valve (in particular the second outlet valve (which is coupled in terms of switching technology to the bridging valve, preferably pneumatically controllable) is connected to the output side of the bridging valve.

In this respect, in a first switching state of the second outlet valve, the atmosphere outlet can be at least indirectly connected to the gallery. In a second switching state, however, the atmosphere outlet and the gallery are pneumatically decoupled by the second outlet valve. The second outlet valve is thus arranged between the air dryer and the outlet. The second outlet valve is preferably switched depending on the bridging valve, so that when the bridging valve is bridged and allows the compressed air to flow back to the air dryer, the compressed air can be released directly through the second outlet valve after passing through the air dryer.

Advantageously, this embodiment also enables passive regeneration of the air dryer in addition to active regeneration. Advantageously, with passive regeneration no energy expenditure is necessary to generate a flow or conveying direction of the compressed air.

According to a preferred development, it is provided that the bridging valve is designed as a 2/2-way valve and the second outlet valve is designed as a 3/2-way valve. These are embodiments of the valves that are particularly suitable for the present application, through which the structure of the level control system is structurally simplified and operation can be carried out particularly efficiently.

According to a preferred development, it is provided that the regeneration path is designed such that the gallery can be pneumatically connected to the atmosphere outlet in a return flow direction via the bridging valve, the air dryer and the second outlet valve, in particular in the idle state of the compressor device with the second check valve open. As already mentioned at the beginning, the return flow direction is opposite to the flow direction. This advantageously also enables the passive regeneration of the air dryer, with the level control system, in particular the regeneration path, having a particularly simple design.

According to a preferred development, it is provided that the second outlet valve is arranged and designed in such a way that, depending on a respective switching state of the second outlet valve, the output side of the bypass valve can be connected to the atmosphere outlet either directly or indirectly with the interposition of the air dryer. In other words, the second exhaust valve couples either the regeneration path or the bypass path to the atmosphere exhaust. The second outlet valve is therefore arranged in both paths or is part of them. This advantageously further improves the design and efficiency of the level control system.

According to a preferred development, it is provided that the second outlet valve can be switched independently of the bypass valve or is designed and coupled to the bypass valve in such a way that when a definable, preferably pneumatic, switching threshold, in particular a defined air pressure or control signal, is reached, it switches in such a way that it the bridging valve indirectly connects to the atmosphere outlet with the interposition of the air dryer.

Depending on the switching threshold, the second outlet valve connects either the regeneration path or the bridging path to the atmosphere outlet. It is basically provided that in an initial state, i.e. before the switching threshold is reached, the regeneration path (direct connection between the bridging valve and the atmosphere outlet) is connected to the atmosphere outlet as standard and only when the switching threshold is reached is the regeneration path (indirect connection with the interposition of the air dryer) connected to the atmosphere outlet is connected. The construction and operation of the level control system are thereby further simplified in an advantageous manner.

The invention also relates to a method for operating the level control system described above. It is provided here that, in order to regenerate the air dryer, compressed air generated or sucked in by the compressor device is actively supplied to the air dryer in the flow direction specified by the compressor device and is then released essentially directly into the environment via the regeneration path and the atmosphere outlet. In this respect, it is provided that the air dryer is actively regenerated in the manner described above by specifically supplying heated compressed air. This results in the advantages already mentioned in this regard.

According to a preferred development, it is provided that compressed air, which flows through the air dryer in the flow direction specified during operation of the compressor device, is discharged via the atmosphere outlet through a first outlet valve, which is arranged on the outlet side of the air dryer. This results in the advantages already mentioned in this regard.

According to a preferred development, it is provided that compressed air is actively conveyed one after the other through the air dryer, the decoupling valve, then through the bridging valve and finally through the second outlet valve to the atmosphere outlet in the course of the regeneration path. This is a structurally simple and efficient solution for creating the regeneration path so that the air dryer can be actively regenerated with maximum efficiency. The advantages already mentioned above arise.

• - der Regenerationspfad entweder durch das Überbrückungsventil, eine das Überbrückungsventil direkt mit dem zweiten Auslassventil verbindende Ablassleitung und das in einer ersten Schaltstellung befindliche zweite Auslassventil gebildet wird, sodass der Lufttrockner in Strömungsrichtung mit dem Atmosphärenauslass verbunden wird, oder
• - der Regenerationspfad durch das Überbrückungsventil, das Rückschlagventil, den Lufttrockner und das in einer zweiten Schaltstellung befindliche zweite Auslassventil gebildet wird, sodass der Lufttrockner in einer der Strömungsrichtung entgegengesetzten Rückströmrichtung mit dem Atmosphärenauslass verbunden wird.

According to a preferred further development it is provided that

• - the regeneration path is formed either by the bridging valve, a drain line connecting the bridging valve directly to the second outlet valve and the second outlet valve located in a first switching position, so that the air dryer is connected to the atmosphere outlet in the direction of flow, or
• - the regeneration path is formed by the bridging valve, the check valve, the air dryer and the second outlet valve located in a second switching position, so that the air dryer is connected to the atmosphere outlet in a return flow direction opposite to the flow direction.

In other words, if the air dryer is connected to the atmosphere outlet in the flow direction, the regeneration path is connected to it, whereas if there is a connection in the return flow direction, then the bridging path is connected to the atmosphere outlet. Advantageously, as already discussed in advance, this enables both active and passive regeneration of the air dryer.

According to a preferred development, it is provided that depending on a definable switching threshold, in particular a control signal or a defined pressure, the drain or bridging path is connected to the atmosphere outlet by means of the second outlet valve. In this respect, the second exhaust valve is switched depending on the switching threshold. This results in the advantages already mentioned in this regard.

• - dann, wenn der Regenerationspfad zur aktiven Regeneration Druckluft durch den Lufttrockner in der durch die Kompressorvorrichtung vorgegebene Strömungsrichtung durchführt, erwärmte Druckluft durch den Lufttrockner hindurch aktiv gefördert und über den Atmosphärenauslass abgelassen wird, und
• - dann, wenn der Regenerationspfad zur passiven Regeneration Druckluft in Rückstromrichtung von der Galerie durch den Lufttrockner durchführt, kühle Druckluft aus der Galerie über den durch den Lufttrockner hindurch passiv/selbsttätig strömt und über den Atmosphärenauslass abgelassen wird.

According to a preferred further development it is provided that

• - when the regeneration path for active regeneration carries compressed air through the air dryer in the flow direction specified by the compressor device, heated compressed air is actively conveyed through the air dryer and discharged via the atmosphere outlet, and
• - when the regeneration path for passive regeneration carries compressed air in the reverse flow direction from the gallery through the air dryer, cool compressed air from the gallery flows passively/automatically through the air dryer and is discharged via the atmosphere outlet.

Advantageously, the regeneration process of the air dryer is designed with maximum efficiency. The choice between active and passive regeneration is preferably made depending on the moisture load in the air dryer. For example, if the air dryer is only lightly loaded, passive regeneration is sufficient or this is carried out automatically in parallel with the standard venting of the gallery. If, on the other hand, there is a high moisture load in the air dryer, especially when the maximum moisture storage capacity has been reached, active regeneration takes place in a targeted and therefore needs-based manner, so that the functionality of the air dryer is always guaranteed or maintained.

DRAWINGS

Further advantages result from the present drawing description. Exemplary embodiments of the invention are shown in the drawings. The drawing, description and claims contain numerous features in Kombi nation. The person skilled in the art will also expediently consider the features individually and combine them into further sensible combinations.

• 1 Eine stark vereinfachte schematische Darstellung eines vorteilhaften Niveauregesystems gemäß einem ersten Ausführungsbeispiel,
• 2 eine stark vereinfachte schematische Darstellung des Niveauregesystems gemäß einem zweiten Ausführungsbeispiel,
• 3 eine stark vereinfachte schematische Darstellung des Niveauregesystems gemäß einem dritten Ausführungsbeispiel,
• 4 eine stark vereinfachte schematische Darstellung des Niveauregesystems gemäß einem vierten Ausführungsbeispiel.

Show it:

• 1 A greatly simplified schematic representation of an advantageous level control system according to a first exemplary embodiment,
• 2 a greatly simplified schematic representation of the level control system according to a second exemplary embodiment,
• 3 a greatly simplified schematic representation of the level control system according to a third exemplary embodiment,
• 4 a greatly simplified schematic representation of the level control system according to a fourth exemplary embodiment.

In the figures, similar elements are numbered with the same reference numbers. The figures only show examples and are not to be understood as limiting.

1 shows a simplified schematic representation of an advantageous level control system 10. The level control system 10 is designed for use in a motor vehicle and has a compressor device 12 and a gallery 14 with at least one air suspension strut.

In the present case, the compressor device 12 has various components, in particular check valves, compressors and motors, which are not provided with a reference number for reasons of clarity. The gallery 14 also has several components, in particular four air suspension struts, a compressed air reservoir, several controllable solenoid valves for pneumatic coupling or decoupling of the air suspension struts and at least one compressed air sensor. For reasons of clarity, the components of the gallery 14 are not provided with reference numbers.

The compressor device 12 is designed to supply compressed air to the gallery 14 by means of a supply line 16 or to convey it in the direction of the gallery 14. The conveying or flow direction of the compressed air is shown in the figures using dashed arrows. In this and the following embodiments, the compressor device 12 is designed in two stages, but can also be designed as a single-stage compressor device.

The level control system 10 also has an air dryer 18, which serves or is designed to bind or absorb and store air moisture contained in the compressed air. For this purpose, the air dryer 18 is arranged between the compressor device 12 and the gallery 14 with respect to the flow direction of the compressed air, as in 1 is easy to see. The air dryer 18 in this respect has an input side E connected to or assigned to the compressor device 12 by means of the supply line 16 and an output side A connected to or assigned to the gallery 14 by means of the supply line 16.

When the level control system 10 is operated as intended, air is sucked in from the atmosphere at regular intervals by the compressor device 12 via an air inlet 20, compressed and fed to the gallery 14 for compressed air supply with the interposition of the air dryer 18 by means of the supply line 16. By interposing the air dryer 18, the moisture contained in the compressed air is bound and stored by a moisture-storing material, for example silica gel, which is arranged in the air dryer 18.

However, the air dryer 18 only has a limited moisture storage capacity. In other words, the air dryer 18 can no longer store moisture after a certain period of operation and can therefore no longer fulfill its drying function. It is therefore necessary to regenerate the air dryer 18 at regular intervals, with the moisture stored in the air dryer 18 being supplied to the environment or transported away into the atmosphere via an atmosphere outlet 22 using compressed air.

For the purpose of regeneration of the air dryer 18, the level control system 10 has a regeneration device 24. In the present level control system 10 it is advantageously provided that a pneumatic regeneration path for regeneration of the air dryer 18 is provided in the regeneration device 24, which is designed such that the compressed air generated by the compressor device 12 is directed in the predetermined flow direction to the air dryer 18 and then switchably to the atmosphere outlet 22 can be supplied. In other words, an active regeneration of the air dryer 18 is advantageously made possible, in which compressed air is specifically conveyed through the air dryer 18 for the purpose of regeneration, thereby absorbing the moisture stored in the air dryer 18 and dissipating it via the atmosphere outlet 22.

The regeneration device 24 is, depending on the specific exemplary embodiment, essentially made up of one or preferably several ren valves of various designs and corresponding compressed air lines.

At the in 1 In the first exemplary embodiment shown, the regeneration device 24 has a decoupling valve 26 designed as a check valve and a first outlet valve 28. As in 1 can be clearly seen, the decoupling valve 26 is arranged between the air dryer 18 and the gallery 14 in such a way that the gallery 14 is pneumatically decoupled from the air dryer 18 in a return flow direction opposite to the flow direction. This ensures that compressed air in the gallery 14 does not automatically flow out of it. The first outlet valve 28 in turn is arranged in front of the decoupling valve 26 from the direction of the outlet side A of the air dryer 14 and is designed such that the outlet side A of the air dryer 18 is switchably connected to the atmosphere outlet 22.

At the in 1 In the first exemplary embodiment shown, a vent valve EV arranged between the gallery 14 and the decoupling valve 26 is also provided, by means of which, if necessary, the gallery 14 can be vented or compressed air located in the gallery 14 can be released via the atmosphere outlet 22. The release of compressed air from the gallery 14 or its venting is regularly necessary for the intended operation of the level control system 10 and is ensured by the venting valve EV.

2 shows a simplified schematic representation of a second embodiment of the previously described level control system 10. The same elements are provided with the same reference numerals, with reference to what was described above. In the following, only the differences will be explained.

This in 2 The second exemplary embodiment shown differs from that in 1 shown first embodiment in that the decoupling valve 26 is no longer designed as a simple check valve, but as a switchable, for example magnetically or pneumatically switchable, valve. The decoupling valve 26 thus fulfills the function of a check valve in a first switching position by preventing or blocking the compressed air from automatically flowing back from the gallery 14 in the direction of the air dryer 18. In a second switching position, however, the gallery 14 and the air dryer 18 are pneumatically coupled, so that compressed air can flow from the gallery 14 in the direction of the air dryer 18 or for the purpose of venting the gallery 14 to the first outlet valve 28, so that it can be fed to the atmosphere outlet 22.

The second exemplary embodiment therefore has the advantage that for the purpose of venting the gallery 14, no specially provided venting valve EV is necessary, but its function is taken over by the first outlet valve 28.

3 shows a simplified schematic representation of the level control system 10 described above according to a third exemplary embodiment. The same elements are provided with the same reference numerals, with reference to what has been described above and only the differences will be explained below.

This in 3 The third exemplary embodiment shown differs from the previous exemplary embodiments in that a second outlet valve 30 is also provided as part of the regeneration device 24 or the regeneration path.

The second exhaust valve 30 is as in 3 can be clearly seen, arranged on the input side E of the air dryer 18 and designed or arranged in such a way that a connection of the input side E of the air dryer 18 to the atmosphere outlet 22 can be switched. In this respect, in the third exemplary embodiment, the pneumatic circuit of the level control system 10 can be connected to the atmosphere outlet 22 or the atmosphere both via the first outlet valve 28 and via the second outlet valve 30.

As already discussed above, the active regeneration of the air dryer 18 can be carried out by means of the first outlet valve 28 by conveying compressed air in the predetermined flow direction through the air dryer 18 to the atmosphere outlet 22.

By means of the second outlet valve 30, a passive regeneration of the air dryer 18 is now also possible in that compressed air already in the level control system 10, specifically stored in the gallery 14, can be fed in the return flow direction through the air dryer 18 to the atmosphere outlet 22. In other words, during passive regeneration when the gallery 14 is vented, i.e. the compressed air stored there is released into the atmosphere, the air dryer 18 can be regenerated in parallel. During passive regeneration, the compressed air flows automatically from the gallery 14 through the air dryer 18, not via the first outlet valve 28, but via the second outlet valve 30 Atmosphere outlet 22 is supplied or released into the atmosphere.

Even with passive regeneration, moisture stored in the air dryer 18 is absorbed by the compressed air flowing through and discharged into the environment. In this respect, in the third exemplary embodiment, the gallery can be vented via the first outlet valve 28 or the second outlet valve 30, with the air dryer 18 being passively regenerated at the same time when venting via the second outlet valve 30. Nevertheless, there is also the possibility of active regeneration at the same time, so that the air dryer can be regenerated particularly efficiently.

4 shows the previously described level control system 10 according to a fourth exemplary embodiment. The same elements are provided with the same reference numerals, with reference being made in this regard to what has been described above. In the following, only the differences will be explained.

This in 4 The fourth exemplary embodiment shown differs from the previous exemplary embodiments with regard to the specific design of the regeneration device 24 or the regeneration path and therefore with regard to the individual components of the regeneration device 24.

In the fourth exemplary embodiment, on the one hand, a bridging path is provided as part of the regeneration path, the bridging path having at least one bridging valve 32. The bridging valve 32 is preferably designed as a pneumatic valve or solenoid valve and is arranged in such a way that the decoupling valve 26 can be bridged by the bridging valve 32 in order to enable a backflow in the return flow direction of compressed air from the gallery 14 to the air dryer 18 if necessary.

Furthermore, the in 4 In the fourth exemplary embodiment shown, the regeneration device 24 has a check valve 34, which is arranged in the bridging path between the output side A of the air dryer 18 and an output side AÜ of the bridging valve 32 in such a way that an automatic backflow of compressed air from the gallery 14 via the opened bridging valve 32 to the output side A of the air dryer 18 can be locked during operation of the compressor device 12. The check valve 34 thus ensures that when the compressor device 12 is in operation for the purpose of active regeneration of the air dryer 18, no compressed air can flow back to the outlet side A of the air dryer 18 and thereby impair the active regeneration in terms of its efficiency. In other words, the check valve 34 ensures that the compressed air always takes or can take the intended flow path via the regeneration path during active regeneration.

The flow path over the regeneration path specified during active regeneration is in 4 shown by dashed arrows.

The fourth exemplary embodiment further differs from the previous exemplary embodiments in that the second outlet valve 30 is designed and arranged in such a way that, depending on a respective switching state of the second outlet valve 30, the output side AÜ of the bridging valve 32 either directly or indirectly with the interposition of the air dryer 18 with the Atmosphere outlet 22 can be connected. The second bridging valve 30 is therefore both part of the regeneration path and part of the bridging path. Depending on the switching position of the second outlet valve 30, the air dryer 18 is regenerated either actively or passively.

In the fourth exemplary embodiment, the regeneration path is designed such that the gallery 14 can be pneumatically connected to the atmosphere outlet 22 in the return flow direction via the bridging valve 32, the air dryer 18 and the second outlet valve 30 (passive regeneration) and at the same time the outlet side A of the air dryer 18 via the Bridging valve 32 can be connected directly to the atmosphere outlet 22 in the flow direction (active regeneration).

In the present case, the bridging valve 32 is designed as a 2/2-way valve and the second outlet valve 30 as a 3/2-way valve. By designing it as a 3/2-way valve, either the bridging path or the regeneration path can be connected to the atmosphere outlet 22 in an advantageous manner through the second outlet valve 30 by simply switching the switching state.

It is also preferably provided that the second outlet valve 30 is coupled to the bridging valve 32 in terms of switching technology, in particular pneumatically. It is provided here that the second outlet valve 30 is designed or coupled to the bridging valve 32 in such a way that it switches when a definable switching threshold, in particular a defined air pressure or control signal, is reached. The second outlet valve 30 preferably switches in such a way that it indirectly connects the bypass valve 32 to the atmosphere outlet 22 with the interposition of the air dryer 18. The coupling is advantageous This enables automated switching between active and passive regeneration.

In all previously described exemplary embodiments of the advantageous level control system 10, a specifically controllable and particularly efficient regeneration of the air dryer 18 in the form of the active regeneration described is made possible in a structurally simple manner. Advantageously, with active regeneration it is not necessary that compressed air has previously been stored in the level control system 10, but the regeneration of the air dryer 18 can be carried out at any time as required by simply operating the compressor device 12. Since the compressed air generated by the compressor device 12 is heated by the operation of the compressor device 12, it has an increased moisture storage capacity, so that the active regeneration has a higher efficiency compared to the passive regeneration.

Advantageously, in some exemplary embodiments, passive regeneration of the air dryer 18 is also possible at the same time, so that the level control system 10 is designed to be particularly efficient with regard to the regeneration of the air dryer 18, with the fourth exemplary embodiment in particular being a structurally easy to implement and therefore particularly advantageous embodiment.

Reference symbol list

10

Level control system

12

Compressor device

14

gallery

16

supply line

18

Air dryer

20

Air intake

22

Atmosphere outlet

24

Regeneration device

26

Decoupling valve

28

First exhaust valve

30

Second exhaust valve

32

Bypass valve

34

check valve

E

Entrance page

A

Home page

EÜ

Inlet side bypass valve

EV

vent valve

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was 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 10016917 C1 [0007]
• EP 3436295 B1 [0008]

Claims (17)

Level control system (10) for vehicles, the level control system comprising a compressor device (12), a gallery (14) with at least one air suspension strut connected thereto, at least indirectly, a supply line (16) and an air dryer (18) with one connected to the compressor device (12). Input side (E) and an output side (A) connected to the gallery (14), the compressor device (12) and the gallery (14) being pneumatically connected by the supply line (16) in such a way that the compressor device (12) can be generated Compressed air can be supplied to the gallery (14) with the interposition of the air dryer (18), the air dryer (18) being regenerated by a regeneration device (24) by blowing out compressed air through the air dryer (18) to an atmosphere outlet (22), characterized in that in that a pneumatic regeneration path for regeneration of the air dryer (18) is provided in the regeneration device (24), which is designed such that the compressed air generated by the compressor device (12) flows to the air dryer (18) in a flow direction predetermined by the compressor device (12). and can then be switchably fed to the atmosphere outlet (22). Level control system Claim 1 , characterized in that the regeneration path comprises at least one first outlet valve (28) arranged on the outlet side (A) of the air dryer (18), through which a connection of the outlet side (A) of the air dryer (18) to the atmosphere outlet (22) can be switched , wherein preferably the first outlet valve (28) from the direction of the outlet side (A) to the gallery (14) is arranged in front of a decoupling valve (26), through which the outlet side (A) from the gallery (14) at least in a return flow direction opposite to the flow direction can be decoupled. Level control system Claim 2 , characterized in that the decoupling valve (26) is designed as an actively switchable valve, in particular a pneumatic valve or solenoid valve, or as a check valve. Level control system according to one of the Claims 2 or 3 , characterized in that a second outlet valve (30) arranged on the inlet side (E) of the air dryer (18) is provided, through which a connection of the inlet side (E) of the air dryer (18) to the atmosphere outlet (22) can be switched. Level control system according to one of the Claims 2 until 4 , characterized in that the regeneration device (24) has a bridging path as part of the regeneration path with at least one bridging valve (32), in particular a pneumatic valve or solenoid valve, the bridging valve (32) being arranged and designed in such a way that the decoupling valve (26) passes through the bridging valve (32) can be bridged. Level control system Claim 5 , characterized in that the regeneration device (24) has a check valve (34) which is arranged in the bridging path between the output side (A) of the air dryer (18) and an output side (AÜ) of the bridging valve (32) in such a way that an automatic Backflow of compressed air from the gallery (14) via the open bridging valve (32) to the outlet side (A) of the air dryer (18) can be blocked during operation of the compressor device (12). Level control system Claim 5 or 6 , characterized in that in the regeneration device (24) the, preferably pneumatically controllable, second outlet valve (30), in particular pneumatic valve, which is coupled in particular to the bridging valve (32) in terms of switching technology, is connected to the output side (AÜ) of the bridging valve (32). Level control system Claim 7 , characterized in that the bridging valve (32) is designed as a 2/2-way valve, and the second outlet valve (30) is designed as a 3/2-way valve. Level control system according to one of the Claims 7 or 8th , characterized in that the regeneration path is designed such that the gallery (14) can be pneumatically connected in a return flow direction via the bridging valve (32), the air dryer (18) and the second outlet valve (30) to the atmosphere outlet (22), in particular in the idle state of the compressor device (12) with the second check valve (34) open. Level control system according to one of the Claims 7 until 9 , characterized in that the second outlet valve (30) is designed and arranged such that, depending on a respective switching state of the second outlet valve (30), the output side (AÜ) of the bridging valve (32) either directly or indirectly with the interposition of the air dryer (18) can be connected to the atmosphere outlet (22). Level control system according to one of the Claims 7 until 10 , characterized in that the second outlet valve (30) can be switched independently of the bypass valve (32) or such designed and coupled to the bridging valve (32) so that when a definable, preferably pneumatic, switching threshold, in particular defined air pressure or signal, is reached, it switches in such a way that it switches the bridging valve (32) indirectly with the interposition of the air dryer (18) with the atmosphere outlet (22) connects. Method for operating a level control system (10) according to one of Claims 1 until 11 , characterized in that for the regeneration of the air dryer (18), compressed air generated by the compressor device (12) is actively supplied to the air dryer (18) in the flow direction specified by the compressor device (12) and then essentially via the regeneration path and the atmosphere outlet (22). is released directly into the environment. Procedure according to Claim 12 , characterized in that compressed air, which flows through the air dryer (18) in the flow direction specified during operation of the compressor device (12), flows through a first outlet valve (28), which is arranged on the outlet side (A) of the air dryer (18). the atmosphere outlet (22) is omitted. Procedure according to Claim 12 or 13 , characterized in that compressed air is actively conveyed in the course of the regeneration path one after the other through the air dryer (18), the decoupling valve (26), then through the bypass valve (32) and finally through the second outlet valve (30) to the atmosphere outlet (22). . Procedure according to one of the Claims 12 until 14 , characterized in that - the regeneration path is formed either by the bridging valve (32), a drain line connecting the bridging valve (32) directly to the second outlet valve (30) and the second outlet valve (30) located in a first switching position, so that the air dryer (18) is connected in the direction of flow to the atmosphere outlet (22), or - the regeneration path is formed by the bridging valve (32), the check valve (34), the air dryer (18) and the second outlet valve (30) located in a second switching position , so that the air dryer (18) is connected to the atmosphere outlet (22) in a return flow direction opposite to the flow direction. Procedure according to Claim 15 , characterized in that depending on a defined switching threshold, in particular a control signal or a defined pressure, the drain or bridging path is connected to the atmosphere outlet (22) by means of the second outlet valve (30). Procedure according to Claim 15 or 16 , characterized in that - when the regeneration path for active regeneration passes compressed air through the air dryer (18) in the flow direction specified by the compressor device (12), heated compressed air is actively conveyed through the air dryer (18) and via the atmosphere outlet (22 ) is drained, and - when the regeneration path for passive regeneration passes compressed air in the reverse flow direction from the gallery (14) through the air dryer (18), cool compressed air from the gallery (14) passes through the air dryer (18). flows automatically and is discharged via the atmosphere outlet (22).

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