EP2173987A1

EP2173987A1 - Compressed-air system

Info

Publication number: EP2173987A1
Application number: EP08785079A
Authority: EP
Inventors: Eduard Gerum; Mathias Mayr; Huba NÉMETH; Michael Herges
Original assignee: Knorr Bremse Systeme fuer Nutzfahrzeuge GmbH
Current assignee: Knorr Bremse Systeme fuer Nutzfahrzeuge GmbH
Priority date: 2007-07-25
Filing date: 2008-07-25
Publication date: 2010-04-14
Also published as: KR101419096B1; BRPI0814596A2; RU2467182C2; US20100147271A1; WO2009013006A1; US8371275B2; JP2010534305A; KR20100045951A; DE102007035163B4; CN101680357A; CA2692613C; JP5473910B2; CN101680357B; DE102007035163A1; RU2010106648A; CA2692613A1

Abstract

A compressed-air system for supplying a compressed-air injection module (9) of a turbocharged internal combustion engine and the pneumatic systems of the vehicle comprises a compressor (1), which is connected via a line (20) to a pressure accumulator (7) for the supply of a compressed-air injection module (9), and a device (10) for compressed-air preparation having an air dryer and a pressure regulator for supplying pressure circuits (11 to 14) for compressed-air-actuated consumers, wherein the line (20) for supplying the compressed-air injection module (9) branches off upstream of the device (10) for compressed-air preparation.

Description

Compressed air system

The present invention relates to a compressed air system according to the preamble of claim 1.

DE 10 2006 008 783 discloses a fresh gas supply device for a turbocharged turbocharged engine. In this case, a compressor is operated, behind which an air dryer is arranged to supply the dried air to a pressure chamber. The air dryer is in operation of the compressor constantly in operation, which means a relatively high cost, especially because the air to be dried about 10% of the air volume in turn to regenerate the

Desiccant needs. With regard to the installation space, the weight and the consumption, such a compressed air system can therefore be optimized.

Although air drying is only partially necessary for a compressed air injection module for a turbo-charged brake engine, but if with the

Compressed air and other compressed air consumers, such as a brake system, air suspension and auxiliary consumers to be operated, air drying is important to avoid filling the pressure vessel and lines with water, especially because this can cause problems due to ice formation and corrosion. It is therefore an object of the present invention to provide a compressed air system for supplying a turbocharged reciprocating internal combustion engine whose operation is optimized and flexible.

This object is achieved with a compressed air system with the features of claim 1.

According to the invention in the compressed air system, the line for filling the reservoir for supplying a compressed air injection module in the flow direction of the air is branched off in front of the device for compressed air preparation. As a result, the compressor supplies both the reservoir for supplying a compressed air injection module and the device for compressed air treatment, but via separate lines, so that a variable operation of the compressed air system is made possible. In particular, the entire amount of air is no longer supplied to the device for compressed air preparation.

The compressor is connected via a first line to the pressure vessel for supplying a compressed air injection module and via a second line to the pressure vessels for compressed air consumers. By splitting the compressed air from the compressor in two lines, either a supply of compressed air to the compressed air injection module and / or the pressure vessel for compressed air actuated consumers can be provided. The duration of the compressed air supply can be adjusted individually.

According to a preferred embodiment of the invention, at least one switchable valve is provided in a line between the compressor and the device for compressed air preparation to shut off the compressed air supply with sufficient filling of the pressure vessel for compressed air consumers. As a result, the compressed air preparation can always be carried out if the corresponding pressure vessels are to be filled up. If the pressure vessels are filled, the device for compressed air treatment can be switched off with the air dryer, so that the air dryer can go through a regeneration phase. This procedure is particularly efficient because the high energy consumption for the air drying only in certain phases of the operation of the compressed air system. must be done and a regeneration of an air dryer cartridge is made possible.

In order to avoid a backflow in the line to the compressed air injection module, a check valve may be arranged in front of the pressure limiting valve. In particular, when the vent valve is switched, so a return flow is avoided.

Preferably, a first control signal is generated via corresponding pressure sensors if a maximum pressure is reached behind the check valve, and a second control signal is generated when a predetermined maximum pressure is reached in the line for supplying the device for compressed air preparation. Furthermore, a logical switching device can be provided which generates a third control signal when the first and the second control signal are present. As a result, preferably via the third control signal, a venting valve can be actuated, which is arranged in a delivery line of the compressor, in particular before the branching of the lines. Alternatively, it is possible to control a valve of a power saving system via the third control signal, by means of which the compressor can be switched off.

Preferably, a pressure relief valve is arranged in the line between the compressor and the pressure vessel for supplying a compressed air injection module. This ensures that switching off the compressor and / or a venting valve is possible when a predetermined pressure is exceeded, in particular when the compressed air injection module no longer requires compressed air.

According to a further embodiment of the invention, the venting valve in a delivery line of the compressor in front of a branch of the lines to the compressed air injection module and the pressure vessels for compressed air actuated

Consumers arranged and formed switchable. Preferably, the switching takes place via control signals that are generated by the pressure relief valve and the switchable valve before the device for compressed air preparation. In particular, the vent valve can be turned off automatically when the Pressure relief valve closes and the device for compressed air treatment no longer requires compressed air. For this purpose, for example, be provided a logical valve for switching the vent valve.

Preferably, in the line to the compressed air injection module behind the

Pressure relief valve, an overflow valve provided which has a higher opening pressure than at least one pressure vessel for compressed air-operated consumers. As a result, the filling purity of the pressure vessels can be specified.

The invention will be explained in more detail using an exemplary embodiment with reference to the accompanying drawings. It shows:

Figure 1 is a circuit diagram of a compressed air system according to the invention.

The compressed air system comprises a compressor 1, which sucks in fresh air and is driven, for example, by an internal combustion engine. The compressor 1 is connected via a feed line 22 with a vent valve 2, behind which a branch is provided, which performs a subdivision into a first line 20 and a second line 21.

The first line 20 serves to supply a storage container 7 for supplying a compressed air injection module 9, in particular for an internal combustion engine. In this case, a return valve 4 is provided in the line 20 behind the vent valve 2, which is arranged in front of a pressure relief valve 5. Behind the

Pressure relief valve 5, an overflow valve 6 is provided. At the pressure vessel 7, an automatic drain valve 8 is connected to allow a certain moisture removal.

The second line 21 is connected via a switchable valve 15 with a device 10 for compressed air processing, which has an air dryer and a pressure regulator for supplying individual pressure vessels 1 1 to 14. In this case, the pressure vessel 11 and 12 can be used for a service brake circuit having compressed air consumers. The pressure vessel 13 may, for example to operate a parking brake or a trailer. The pressure vessel 14 can be used to operate other auxiliary consumers, such as a clutch. The pressure vessels 11 to 14 can be used in particular on a commercial vehicle for a brake system.

In operation, the compressor 1 promotes compressed air via the vent valve 2 to the lines 20 and 21. When the air pressure requirement on the first line 20 is no longer present and behind the pressure relief valve 5, a predetermined maximum pressure is reached, the pressure relief valve 5 turns off and it ers - tes control signal via a control line 23 to a logic valve 3, preferably with AND function, issued. The return valve 4 prevents a backflow of the compressed air.

If on the second line 21, the device 10 for compressed air treatment with the pressure regulator determines that the pressure vessels 11 to 14 no longer require compressed air and a predetermined maximum pressure is reached, the switchable valve 15 is turned off via a control signal and a control line 24 is a second Control signal to the logical valve 3 given.

Thus, when a second control signal is generated both by the pressure limiting valve 5, a first control signal and by the device 10 for compressed air treatment, then a third control signal is generated via the logic valve 3, which then also turns off the vent valve 2. As a result, a compressed air decrease takes place only in cases in which the utilities also require appropriate compressed air. The logic valve 3 as a switching device can process control signals in the form of pneumatic pressures. It is also possible to use control signals in the form of electrical signals.

Optionally, then the compressor 1 or a drive or power supply of the compressor 1 can be switched off. This is due to the compressor 1 a

Valve 16 or a clutch 17 is provided as a switching device, by means of which or the compressor 1 in the presence of the third control signal can be switched off. In order to carry out the filling of the pressure vessel 1 1 to 14 in a particular order, the overflow valve 6 may be set to a certain opening pressure on the first line 20. The opening pressure may be greater than the pressure for filling the pressure vessels 11 and 12 for the service brake circuits, so that first the pressure vessels 1 1 and 12 are filled and then on further increase in pressure, the overflow valve 6 opens and only then a supply of the reservoir 7 takes place ,

By switching off the Drucklufitversorgung it is possible in the device for compressed air treatment to regenerate the air dryer, in particular, this is turned on only in certain intervals, which increases the efficiency of the compressed air system.

It is possible to integrate in the compressed air system according to the invention, the valves 2, 4, 5, 6 and 15 in a common module, which may also be coupled to a controller. Furthermore, it is possible to provide a heating cartridge on the compressed air injection module 9, in particular in order to avoid a freezing in this area.

Instead of the illustrated logical valve 3, the function of the control of the

Venting valve, and the switchable valve 15 are also made by an external control, receives and outputs the appropriate switching signals.

Claims

claims

Compressed air system for supplying a turbocharged internal combustion engine, comprising a compressor (1), which is connected via a line (20) with a reservoir (7) for supplying a compressed air injection module (9), and a device (10) for compressed air treatment an air dryer and a pressure control for supplying pressure vessel (11 to 14) for compressed air actuated consumers, characterized in that the line (20) for filling the reservoir (7) for supplying a compressed air injection module (9) in the flow direction of the air before the device

(10) is diverted to the compressed air treatment.

2. Compressed air system according to claim 1, characterized in that in a line (21) between the compressor (1) and the device for Druckluftauf- preparation (10) at least one switchable valve (15) is provided in order to sufficiently fill the pressure vessel (11 to 14) for compressed air operated consumers switch off the compressed air supply.

3. Compressed air system according to claim 1 or 2, characterized in that in the line (20) for filling the storage container (7) for supplying a

Compressed air injection module (9) a check valve (4) is provided.

4. Compressed air system according to claim 3, characterized in that a first control signal is generated when behind the check valve (4) or another valve (5) a maximum pressure is reached and a second control signal is generated when in the line (21) for Supply of the device (20) for compressed air treatment a predetermined maximum pressure is reached.

5. Compressed air system according to claim 4, characterized in that a logical switching device (3) is provided which generates a third control signal when the first and the second control signal are present.

6. compressed air system according to claim 4 or 5, characterized in that the

Control signals are generated as pneumatic pressures.

7. Compressed air system according to claim 4 or 5, characterized in that the control signals are electrical signals.

8. Compressed air system according to one of the preceding claims, characterized in that a switchable vent valve (2) in a feed line (22) of the compressor (1) is arranged.

9. compressed air system according to one of claims 8, characterized in that the switchable vent valve (2) before splitting into the first line

(20) and the second line (21) is provided.

10. Compressed air system according to one of claims 5 to 9, characterized in that a valve (16) or a coupling (17) is provided, by means of which or the compressor (1) in the presence of the third control signal is switched off.

1 1. Compressed air system according to one of the preceding claims, characterized in that in the line (20) between the compressor (1) and the reservoir (7) for supplying a compressed air injection module (9)

Valve (5) is arranged, which interrupts the promotion to the reservoir (7) upon reaching a defined pressure.

12. Compressed air system according to one of the preceding claims, characterized marked, that in the line (20) to the reservoir (7) for supplying a

Compressed air injection module (9) an overflow valve (6) is provided which has a higher opening pressure than at least a portion of the pressure vessel (11 to 14) for compressed air actuated consumers.

13. Compressed air system according to one of the preceding claims, characterized in that the storage container (7) for supplying a compressed air injection module (9) with a drain valve (8) is equipped.