EP3516235A1

EP3516235A1 - Screw compressor for a utility vehicle

Info

Publication number: EP3516235A1
Application number: EP17772657.7A
Authority: EP
Inventors: Gilles Hebrard; Jean-Baptiste Marescot; Jörg MELLAR; Thomas Weinhold
Original assignee: Knorr Bremse Systeme fuer Nutzfahrzeuge GmbH
Current assignee: Knorr Bremse Systeme fuer Nutzfahrzeuge GmbH
Priority date: 2016-09-21
Filing date: 2017-09-19
Publication date: 2019-07-31
Also published as: CN109923314A; JP2019529804A; DE102016011506A1; WO2018054875A1; US20190309747A1; BR112019005071A2; KR20190047064A

Abstract

The invention relates to a screw compressor (10) for a utility vehicle, comprising a rotor housing (20b), in which screw rotors (16, 18) of said screw compressor (10) are arranged, and a housing cover (20a), an air outlet pipe (34) arranged on an output side of the housing cover (20a) and comprising a riser (36), the air outlet pipe (34) having at least one oil separation means.

Description

DESCRIPTION

Screw compressor for a commercial vehicle The present invention relates to a screw compressor for a commercial vehicle,

Screw compressors for commercial vehicles are already known from the prior art. Such screw compressors are used to provide the necessary

Provide compressed air for, for example, the braking system of the commercial vehicle,

In this context, in particular oil-filled compressors, especially screw compressors are known in which the task is to regulate the oil temperature. This is usually accomplished by having an external oil cooler, the compressor filled with the oil and the

Oil circuit is connected via a thermostatic valve. The oil cooler is here

Heat exchanger having two separate circuits, wherein the first circuit for the hot liquid, so the compressor oil is provided and the second for the cooling liquid. As a coolant, for example, air,

Water mixtures can be used with an antifreeze or other oil.

This oil cooler must then be connected to the compressor oil circuit via pipes or hoses and the oil circuit must be secured against leakage.

This external volume must also be filled with oil, so that the total amount of oil is increased. This increases the system inertia. In addition, the oil cooler must be mechanically housed and secured, either by surrounding brackets or by a separate bracket, which requires additional means of improvement, but also space.

From US 4,780,061 a screw compressor with an integrated oil cooling is already known. Furthermore, DE 37 17 493 A1 discloses a arranged in a compact housing screw compressor system having an oil cooler on the electric motor of the screw compressor.

A generic screw compressor is already known, for example, from DE 10 2004 060 417 B4.

It is therefore an object of the present invention to develop a screw compressor for a commercial vehicle of the type mentioned in an advantageous manner, in particular to the effect that a first oil separation can already take place before the compressed by the screw compressor fluid, especially air reaches the oil separator, this task is achieved by a screw compressor for a commercial vehicle with the features of claim 1. After that it is envisaged that a

Screw compressor for a commercial vehicle with a rotor housing in which the screws of the screw compressor are arranged, and is provided with an outlet side of the housing cover arranged air outlet pipe with a riser, wherein the air outlet pipe has at least one ölabscheidemittel.

The invention is based on the idea of carrying out a first oil separation in the case of a screw compressor already on the output side of the housing cover and the screws which serve to compress, for example, the air or an other fluid. This first oil separation is not carried out by a conventional oil separator but already through the air outlet pipe, through which the compressed fluid, in particular the compressed air from the rotor housing or after the compression by the screws is further derived in the screw compressor. This oil separation already taking place there in the air outlet pipe makes it possible to significantly improve the efficiency of the oil separation. As a result, it is also achieved that the oil separator can optionally be dimensioned and designed differently, since a first oil separation already takes place beforehand. Furthermore, it can be provided that the oil separation means a

Has oil return opening. Such an oil return opening may, for example, be an opening in a wall of the air outlet pipe, through which oil precipitating on the walls of the air outlet pipe can drain.

In particular, it can be provided that the oil return opening connects the interior of the air outlet pipe with the oil sump. As a result, a simple oil return is already achieved.

In addition, it can be provided that the air outlet pipe has a neck, with which the air outlet pipe is connected to the housing cover, wherein the

Oil return opening in the region of the approach or adjacent to the approach is arranged. This makes it possible that the oil return port comparatively directly after the outlet of the housing cover, i. at the Steile, where the

Attaches air outlet pipe is arranged. Any oil which has already been deposited there can thus be discharged there directly from the air outlet pipe.

The oil return opening may be formed by a simple bore. This allows easy installation and at the same time easy positioning of the oil return opening.

Furthermore, it can be provided that the air outlet tube is at least partially conical. By a conical design of the air outlet pipe, it is possible to weed out of the air due to the effect of gravity oil particles and to prevent them from leaving the Luftauslassrohres.

In particular, it can be provided that the riser end conical

Such a conical widening of the riser makes it possible to eliminate the effect of separating oil particles and droplets from the air by means of gravity. The separated by this oil particles fall back into the air outlet pipe and accumulate in the area adjacent to the approach of Air outlet pipe and can flow there via the oil return opening back into the oil sump.

Further details and advantages of the invention will now be described with reference to a

Drawings illustrated embodiment will be explained in more detail schematic schematic sectional view through a screw compressor according to the invention; Fig. 2 is a detailed perspective view of the rotor housing of

Screw compressor with air outlet of the screw compressor of FIG. 1, and

Fig. 3 is a perspective sectional view through the air outlet pipe according to

Fig. 2.

Fig. 1 shows a schematic sectional view of a screw compressor 10 in the sense of an embodiment of the present invention. The screw compressor 10 has a mounting flange 12 for mechanical attachment of the screw compressor 10 to a not shown here

Electric motor on.

Shown, however, is the input shaft 14, via which the torque from the electric motor is transmitted to one of the two screws 16 and 13, namely the screw 16.

The screw 18 meshes with the screw 16 and is driven by this.

The screw compressor 10 has a housing 20 in which the essential components of the screw compressor 10 are housed.

The housing 20 is filled with oil 22. Air inlet side is on the housing 20 of the screw compressor i 0 a

Inlet port 24 is provided. The inlet nozzle 24 is designed such that an air filter 26 is arranged on it. In addition, an air inlet 28 is provided radially on the air inlet pipe 24.

In the area between inlet port 24 and the point at which the inlet port 24 attaches to the housing 20, a spring-loaded valve core 30 is provided, designed here as an axial seal. This valve insert 30 serves as a check valve.

Downstream of the valve core 30, an air supply duct 32 is provided, which supplies the air to the two screws 16, 18. On the output side of the two screws 16, 18 is an air outlet pipe 34 with a

Riser 36 provided.

In the region of the end of the riser 36, a temperature sensor 38 is provided, by means of which the oil temperature can be monitored.

Furthermore, a holder 40 for an air de-oiling element 42 is provided in the air outlet area.

The holder 40 for the air de-oiling element has in the assembled state in the area facing the bottom (as shown in Fig. 1), the air de-oiling element 42.

Provided further inside the air de-oiling element 42 is a corresponding filter screen or known filter and oil-separating devices 44, which are not specified in greater detail. In the central upper area, relative to the assembled and ready-to-use state (ie as shown in FIG. 1), the holder for the air de-oiling element 40 has a

Air outlet opening 46, leading to a check valve 48 and a Minimum pressure valve 50 lead. The check valve 48 and the minimum pressure valve 50 may also be formed in a common, combined valve.

Following the check valve 48, the air outlet 51 is provided,

The air outlet 51 is connected to correspondingly known compressed air consumers in the rule.

In order to return the oil 22 located and separated in the air de-oiling element 42 back into the housing 20, a riser 52 is provided, the outlet of the holder 40 for the Luftentöfelement 42 when passing into the housing 20 a filter and

Check valve 54 has.

Downstream of the filter and check valve 54, a nozzle 56 is provided in a housing bore. The oil return line 58 leads back approximately in the middle

Area of the screw 16 or the screw 18 to supply this again oil 22.

In the assembled state of the bottom portion of the housing 20, an oil drain plug 59 is provided. About the oil drain plug 59, a

corresponding oil drain opening are opened, via which the oil 22 can be drained.

In the lower region of the housing 20 and the neck 60 is present at which the

Oil filter 62 is attached. Above a Öffiltereinlasskanal 64, which is arranged in the housing 20, the oil 22 is first passed to a thermostatic valve 86.

Instead of the thermostatic valve 66, a control and / or

Regulation means may be provided, by means of which the oil temperature of the oil 22 located in the housing 20 can be monitored and adjusted to a desired value.

Downstream of the thermostatic valve 66 is then the oil inlet of the oil filter 62, the oil 22 via a central return line 68 back to the screw 18 or screw 16, but also to the oil-lubricated bearing 70 of the shaft 14 leads. in the Area of the bearing 70 and a nozzle 72 is provided, which is provided in the housing 20 in connection with the return line 68.

The cooler 74 is connected to the projection 60, as will be explained in more detail below in FIGS. 2 to 4.

In the upper region of the housing 20 (relative to the mounted state) there is a safety valve 76, via which an excessive pressure in the housing 20 can be reduced.

Before the minimum pressure valve 50 is a bypass line 78, which leads to a

Relief valve 80 leads. Above this relief valve 80 by means of a

Air can be recirculated to the area of the air inlet 28 in this connection. In this area, a vent valve (not shown in greater detail) and also a nozzle (diameter reduction of the feed line) can be provided.

In addition, approximately at the level of the conduit 34 in the outer wall of the

Housing 20 an oil level sensor 82 may be provided. This oil level sensor 82 may, for example, be an optical sensor and designed and set up so that it can be determined from the sensor signal whether the oil level is above the oil level sensor 82 during operation or if the oil level sensor 82 is free and the oil level has fallen accordingly. In connection with this monitoring, an alarm unit can also be provided which outputs or forwards an appropriate error message or warning message to the user of the system.

The function of the screw compressor 10 shown in FIG. 1 is as follows:

Air is supplied via the air inlet 28 and passes through the check valve 30 to the screws 16, 18, where the air is compressed. The compressed air-oil mixture, with a factor between 5 to 16 times compression after the Screws 18 and 18 rising through the outlet conduit 34 via the riser 36 is blown directly onto the temperature sensor 38.

The air, which still partially carries oil particles, is then guided via the holder 40 into the air de-oiling element 42 and, provided that the corresponding minimum pressure is reached, enters the air outlet line 51.

The oil 22 located in the housing 20 is via the oil filter 62 and possibly over the

Heat exchanger 74 maintained at operating temperature.

If no cooling is necessary, the heat exchanger 74 is not used and is not switched on

The corresponding connection is made via the thermostatic valve 88. After the purification in the oil filter 64 is via the line 88 oil of the screw 18 or the

Screw 16, but also fed to the bearing 72. The screw 16 or the screw

18 is supplied via the return line 52, 58 with oil 22, here is the purification of the oil 22 in Luftentölelement 42. About the electric motor not shown in detail, which transmits its torque via the shaft 14 to the screw 16, which in turn with the shaft 18th combs, the

Screws 16 and 18 of the screw compressor 10 driven.

About the relief valve 80 is not shown in detail ensures that in the supply line 32 is not the high pressure prevailing in the operating state, for example, the output side of the screws 16, 18, can be locked, but that in particular at the start of the compressor in the supply line 32 always a low inlet pressure, in particular atmospheric pressure exists. Otherwise, with a start-up of the compressor, a very high pressure would initially arise on the output side of the screws 16 and 18, which would overload the drive motor. Fig. 2 shows a perspective view of the housing cover 20 a of the

Screw compressor 10, as shown in Fig. 1.

The housing cover 20a has an outlet, on which the air outlet pipe 34 attaches.

The air outlet pipe 34 in this case has a projection 34a, with which the air outlet pipe 34 is connected to the housing cover 20a. The air outlet pipe 34 further has a riser 36.

The riser 38 is widened conically, in the end region 38 a,

The air outlet pipe 34 has a further in the region of its projection 34 a

Oil return opening 100 on.

The oil return opening 100 is formed as a bore.

The oil return port 100 connects the interior of the air outlet pipe 34 with the oil sump 22a.

Due to the conical widening and the oil return opening 100 has the

Air outlet 34 total oil separating, which serve for the first oil separation, even before the compressed air through the screw compressor 10 is passed through the oil separator.

The oil separation takes place in such a way that due to the conical expansion and thus achieved reduction of the flow velocity in this area located in the air flow oil particles can fall back due to gravity, reflected on the walls inside the air outlet pipe 34 and then through the oil return port 100 in the Oil sump 22a can flow back. 3 shows a perspective sectional view through the air outlet pipe according to FIG. 2, FIG.

LIST OF REFERENCE NUMBERS

Claims

A screw compressor (10) for a utility vehicle having a housing cover (20a) in which screws (16, 18) of the screw compressor (10) are arranged and arranged with an output side of the housing cover (20b)

Air outlet pipe (34) having a riser (36), wherein the Luftausiassrohr (34) aulweist at least one öiabscheidemittel.

2. screw compressor (10) according to claim 1,

characterized in that

the Öiabscheidemittel an Olrückführöffnung (100).

3. screw compressor (10) according to claim 2,

characterized in that

the Olrückführöffnung (100) the interior of the Luftausiassrohres (34) with the oil sump

(22a) connects.

4. screw compressor (10) according to claim 2 or claim 3,

characterized in that

the Luftausiassrohr (34) has a projection (34 a), with which the Luftausiassrohr (34) is connected to the housing cover (20 a), wherein the Olrückführöffnung (100) in

Area of the approach (34 a) or adjacent to the projection (34 a) is arranged

5. screw compressor (10) according to one of claims 2 to 4,

characterized in that

the Olrückführöffnung (100) is a bore.

6. screw compressor (10) according to one of the preceding claims, characterized in that

the Luftausiassrohr (34) is at least partially conical,

7. screw compressor (10) according to claim 6,

characterized in that the riser (38) is end conical.