EP1948938A1 - Pump with a cylindrical cooling bush - Google Patents

Abstract

A pump, particularly to a vane-cell pump for a vacuum for brake boosters in motor vehicles or for drawing blow-by gas out of the crankcase of internal combustion engines, with a casing, a rotor and with at least one vane and a liquid cooling device, which is depicted by a simple, essentially cylindrical insertion bush for inserting inside the casing.

Description

 PUMP WITH CYLINDRICAL COOLING SOCKET

The invention relates to a pump, in particular vane pump for vacuum brake booster in motor vehicles or for sucking blow-by gas from the crankcase of internal combustion engines, with a housing, with a rotor and at least one wing and a liquid cooling device.

Vacuum pumps driven directly by the internal combustion engine are operated according to the prior art as wet-running pumps. Engine oil is used for lubrication, sealing and cooling. If dry-running pumps were used, there is the problem of dissipating the heat arising from friction and compression, especially at high speeds.

Furthermore, in the prior art pumps, for example so-called scroll compressors are known, which have complex cooling means on the housing, which require a large volume of construction.

It is therefore an object of the invention to present a pump that does not have these problems.

The object is achieved by a pump, in particular vane pump for vacuum for brake booster in motor vehicles or for sucking blow-by gas from the crankcase of internal combustion engines, with a housing, with a rotor, with at least one wing and a liquid cooling device, said the cooling device is represented by means of a simple, substantially cylindrical insert sleeve by insertion inside the housing. Preferred is a pump in which the insert sleeve is both a bushing for the wing and the rotor and one of the walls of the cooling device.

Furthermore, a pump is preferred in which the insert sleeve has on its outer circumferential surface a helical groove which forms a cooling channel with the inner lateral surface of the housing. This has the advantage that the cooling channels can be produced by a simple external machining of the bush, while the smooth inner circumferential surface requires no processing. Eiπe inventive pump is characterized in that the insert bush is made in one piece of a material with good career / sliding properties, in particular wear and low friction, for the wing and the rotor. This has the advantage that only the insert bush, but not the rest of the housing of the pump is made of a high quality material.

Also preferred is a pump in which the housing is represented by a flange part, a substantially tubular intermediate part and a end cover part. This has the advantage that a simple construction of the cooling device by two pipe parts, namely that of the housing and the insert sleeve, can be produced.

Furthermore, a pump is preferred in which the cooling liquid or the lubricating oil of the internal combustion engine is used as the coolant.

Also preferred is a pump in which the pump is referred to as a so-called dry running pump, i. without lubricating oil with a wet-running, d. H. lubricated by lubricating oil and cooled vacuum pump is combined.

A pump according to the invention is characterized in that the insert bush is made of plastic. This has the advantage that the screw-shaped cooling channels arranged on the outside of the bushing can already be produced by the plastic injection process.

Also, a pump is preferred in which the wing made of plastic, optionally with caps made of a low-wear, low-friction plastic. Furthermore, a pump is preferred in which the rotor is made of plastic.

Another pump according to the invention is characterized in that the housing is made of a metallic material, for example made of sheet iron or aluminum die-cast.

The invention will now be described with reference to the figures.

FIG. 1 shows the insert bushing and the housing parts of a pump according to the invention. FIG. 2 shows a cross section through a combination of a dry-running pump according to the invention with a wet-running vacuum pump.

FIG. 1 shows the individual parts of the housing and the bush-shaped insert of the cooling device. An approximately cylindrical or pot-shaped housing 1, which is made of a metallic material such as aluminum die cast, has a smooth, cylindrical inner surface 3. However, the housing 1 can just as well be made of an iron sheet material, for example by a deep drawing process, or by a plastic material. The housing 1 further has a flange side with mounting eyes 5 and can be flanged with this side of a wet-running vacuum pump according to the prior art, for example using screws 7. In the housing 1, an insert sleeve 9 is inserted, which on its cylindrical Outside surface has helical grooves 11. After inserting the insert bushing 9 in the housing 1, the outer circumferential surface 13 of the insert bushing 9 seals hermetically against the cylindrical inner surface 3 of the housing 1, so that only the helical grooves 11 within the now double-walled housing form a circumferential channel. Through this channel, a corresponding coolant can be brought from the outside, for example from the cooling water circuit of the engine or the lubricating oil circuit of the engine. Within the insert bushing 9 is a rotor, not shown here, which is eccentrically mounted relative to the housing, and, for example, a rotatably located in this rotor within a slot wing via a drive shaft or a coupling device. The now double-walled housing is closed by means of a cover cover 15 and the cover 15 is pulled by appropriate screws 17 against the housing 1 and against the insert sleeve 9. The insert bush 9 is preferably made of a high-quality, wear-resistant material with good sliding properties, since in the socket 9, the wing with its end caps sealingly slides along the inner wall of the bushing 9 along. Preferably, a high-quality plastic is selected for the insert bushing 9, which is both wear-resistant and has good sliding properties and also can seal well against the inner wall 3 of the housing 1 by its certain elasticity to metallic materials.

FIG. 2 shows the pump according to the invention in combination with a so-called wet-running vacuum pump. The same parts are provided here with the same reference numerals as in FIG. In cross section, the housing 1 is seen with the inner wall 3, in which the Ein set bush 9 is inserted with its helical grooves 11. The insert bush 9 seals with its surface 13 against the housing 1 with the inner surface 3 from. Housing 1 and insert bushing 9 are laterally sealed by the lid 15. In addition, seals 19 and 21 are respectively arranged between the cover 15, the housing 1 and the insert bush 9. The liquid-cooled vacuum pump is closed on the other side by a flange 23, which has seals 25 to the housing 1 and seals 27 to the insert bushing out. Inside the insert bushing 9, a rotor 29, shown in cross-section, is arranged eccentrically, which has two drive shaft ends 31 and 33. The shaft ends 31 and 33 are in turn mounted in two bearings 35 and 37, wherein the bearing 35 is disposed in a recess of the lid 15 and the bearing 37 in the flange 23. Furthermore, the liquid-cooled vacuum pump is sealed by a shaft seal 39 against the wet-running vacuum pump 41 , The flange 23 forms the transition to the wet-running vacuum pump 41 and is thus at the same time part of the housing of this vacuum pump 41. The vacuum pump 41 further comprises a housing 43 and a rotor 45. Within the rotor 45, a wing 47 can be seen in cross-section. The rotor 45 is driven via a drive surface 49 and a clutch 51 with a drive, for example, protruding from the engine shaft end of a camshaft. On the side opposite the coupling 51, the rotor 45 has a second coupling device 53, which constitutes the drive for the shaft section 33 of the liquid-cooled vacuum pump. While the wet-running pump 41 is lubricated and cooled by lubricating oil supply means, which are partially shown here by channels 55 in cross-section, this is not the case with the liquid-cooled vacuum pump. Therefore, for cooling the dry running vacuum pump through an inlet 57, a coolant flow is introduced into the helical annular channels 11 and guided by a corresponding outflow 59 of the coolant flow in turn into the further coolant circuit of the motor vehicle. By means of liquid cooling, therefore, the heat accumulated during rotation of the dry-running vacuum pump can be dissipated and thus overheating of the pump can be avoided. One area of application for the dry-running vacuum pump can be the extraction of blow-by gas from the crankshaft space of the internal combustion engine. As a single liquid-cooled pump, however, the vacuum pump can also, like the wet-running vacuum pump, be used for brake booster systems if oil supply from the lubricating oil circuit of the internal combustion engine is not possible for any other reason. LIST OF REFERENCES

Cup-shaped housing Cylindrical inner lateral surface Mounting eyes Screws Insert bushing Helical grooves Outer jacket surface of insert bushing End cap Screws Gasket for housing Gasket for insert bushing Flange Gasket to housing Gasket to insert bushing Rotor Drive shaft end Drive shaft end Bearing in cover 15 Bearing in flange 23 Shaft seal Wet running vacuum pump Vacuum pump housing 41 Rotor of vacuum pump 41 Wings of the vacuum pump 41 Drive surface of the rotor 45 Clutch Second clutch device Lubricating oil channels Inlet for coolant flow Outflow for coolant flow

Claims

claims 1. pump, in particular vane pump for vacuum brake booster in motor vehicles or for sucking blow-by gas from the crankcase of internal combustion engines, with a housing (1), with a rotor and at least one wing and a liquid cooling device, characterized in that the cooling device is represented by means of a simple, substantially cylindrical insert bushing (9) by insertion inside the housing (1). 2. Pump according to claim 1, characterized in that the insert bushing (9) represents both a bushing for the wing and the rotor and one of the walls of the cooling device. 3. Pump according to claim 1 or claim 2, characterized in that the insert bushing (9) on its outer circumferential surface (13) has a helical groove (11) which forms a cooling channel with the inner circumferential surface (3) of the housing (1). 4. Pump according to claim 1 or claim 2 or claim 3, characterized in that the insert bushing (9) is made in one piece from a material with good career / sliding properties (wear and low friction) for the wing and the rotor. 5. Pump according to one of the preceding claims, characterized in that the housing of a flange (23), a substantially tubular intermediate part (1) and a cover plate part (15) is shown. 6: Pump according to one of the preceding claims, characterized in that the cooling liquid or the lubricating oil of the internal combustion engine is used as the coolant. 7. Pump according to one of the preceding claims, characterized in that the pump as a so-called dry-running pump with a wet-running, ie lubricated by lubricating oil and cooled vacuum pump (41) is combined. 8. Pump according to one of the preceding claims, characterized in that the insert bushing (9) is made of plastic. 9. Pump according to one of the preceding claims, characterized in that the wing is made of plastic, optionally with caps made of a low-wear, low-friction plastic. 10. Pump according to one of the preceding claims, characterized in that the rotor is made of plastic. 11. Pump according to one of the preceding claims, characterized in that the housing is made of a metallic material, for example made of sheet iron or die-cast aluminum.