WO2019084585A1

WO2019084585A1 - Housing

Info

Publication number: WO2019084585A1
Application number: PCT/AT2018/060255
Authority: WO
Inventors: Herbert Wiener
Original assignee: Avl Commercial Driveline & Tractor Engineering Gmbh
Priority date: 2017-11-06
Filing date: 2018-10-23
Publication date: 2019-05-09
Also published as: AT519748B1; AT519748A4

Abstract

The invention relates to a housing (1), in particular a transmission housing, having an oil chamber (2) and at least one component (4) rotatably arranged in the oil chamber (2), wherein the component (4) is enclosed at least to some extent by a housing-mounted shield (5) which defines a cavity (7) accommodating the component (4), and the cavity (7) is separated from the oil chamber (2) by the shield (5). In order to reduce the rotational resistance of components (4) which rotate at least to some extent in oil, provision is made for the shield (5) to have at least one supply region (10), which is connected to a supply line (11) for air or gas.

Description

casing

The invention relates to a housing, in particular gear housing, with an oil chamber and at least one rotationally arranged in the oil chamber component, wherein the component is at least partially surrounded by a housing-fixed jacket, which spans a component receiving cavity, and wherein the cavity from the oil chamber separated by the mantle.

In order to prevent churning by rotating in a gear housing components, it is known to arrange housing-resistant shielding centrally to the rotating component. The shield plates facilitate the centrifuging of the excess oil entrained by the rotating components and at the same time reduce the flow of oil to the component. Shielding is effective especially at low oil level. Another positive effect when using shielding plates is that the oil is locally heated by the rotating oil in the gap area between the component and the shielding plate, as a result of which the viscosity as well as the rotational resistance and thus the churning losses decrease. Generally, however, increased oil heating also causes the aging of the oil to increase and its lubricity to decrease. The use of shielding or shielding to rotating components is for example from the publications EP 2 594 826 AI, EP 1 635 090 A2, US 2017 102 065 AI, DE 10 2013 202 594 AI, DE 10 2011 003 221 AI, EP 2 594 826 AI,

DE 10 2010 004 222 A1 or EP 1 635 090 A2.

Especially at very low below the oil level arranged rotating parts conventional devices for free-spinning of the components are no longer functional because too much oil can flow and at the same time too little oil can be displaced.

It is also known to generally reduce the churning losses between the rotating member and the shielding sheets by using a low viscosity oil and lowering the oil level in the housing.

The object of the invention is to avoid the disadvantages mentioned and to reduce the rotational resistance of at least partially rotating in oil components in a housing of the type mentioned.

According to the invention this is achieved in that the shield has at least one feed region, which is connected to a supply line for air or gas. Air or gas is conveyed into the cavity, in particular into the substantially annular circumferential gap between the rotating component and the shield, via the feed line and the feed region. Advantageously, the air or the gas is introduced exclusively into the gap between the component and the shield in order to counteract a possible inclusion of air or gas bubbles in the region of the intake of the oil pump.

The introduced into the gap between the component and the shielding air or the introduced gas, the resistance between the rotating component and the shield is reduced due to the existing oil there and achieved with very little effort, a reduction of churning losses. Thus, a similar effect as when using a less viscous oil can be achieved.

Conveniently, in one embodiment, the shield extends substantially over the entire circumference of the rotating component, wherein it is particularly advantageous if the shield is formed substantially rotationally symmetrical and preferably designed as a hollow cylinder. The shielding should also extend over the length of the component, which - without shielding - would dip into the oil sump.

The shield formed for example by a metal sheet extends at a defined distance around the rotating component. This defined distance has a significant influence on the functional effect of the "free slinging" of the rotating component. The shield is - except for any well-defined oil inlet openings and outlet openings - compared to the existing existing oil space in the oil as tight as possible to avoid too much inflow of oil and an unintentional possible air admixture in the oil sump.

The promotion of the air or the gas in the cavity can be done for example via an external or internal conveyor. An external conveyor may for example be an air pump or a compressor or other pressure source, for example compressed air tank or gas tank.

In a structurally simple embodiment of the invention with a small number of components is provided that the promotion of the air takes place in the cavity via an internal conveyor, which is formed by the rotating member and the shield, wherein preferably the rotating member is formed as a bladeless pump rotor and the shield acts as a pump housing. Such operating according to the hydrodynamic principle conveyors with paddle-less pump rotors with a cylindrical surface with defined roughness are also under the designations shear force pumps (shear force pumps), friction pumps, disk rotor pumps or Tesla pumps known, see for example DE 24 28 932 AI, DE 739 123 C, DE 720 485 C, DE 603 418 A.

In a further embodiment of the invention, it is provided that the shield is arranged eccentrically with respect to the rotating component, wherein preferably a gap dimension defined between the shield and the component is smaller in the entry region than in the exit region. The eccentric arrangement of the shield causes different ratios of the flow velocities over the circumference. The small radial gap between the component and the shield in the inlet area causes high flow velocities in the gap and a negative pressure difference and thus a good suction. For sucking in the air, the inlet opening of the supply line should preferably be arranged above the maximum oil level of the oil chamber - protected from spray oil.

The shield has, in one embodiment of the invention, at least one discharge area, which is connected to a discharge line. This allows a defined outlet of the supplied air or the supplied gas. In order to avoid foaming of the oil by the exiting air or the escaping gas, it is advantageous if the discharge line has at least one outlet opening into the housing at a defined location, which is preferably arranged above the maximum oil level of the oil space. Additionally or instead, it can also be provided that at least one further outlet opening is arranged just below the maximum oil level of the oil chamber. In any case, the suction position of the oil pump should be provided at an oil-soiled point of the housing.

A variant embodiment provides that the shielding in the feed region has a feed part, preferably widening in a funnel shape in the flow direction, the feed part preferably having at least one first oil inlet opening communicating with the oil space.

Alternatively or additionally, it can be provided in a further embodiment variant of the invention that the supply line has at least one second oil inlet opening communicating with the oil space.

The oil inlet openings serve to deliver metered oil to the cavity. The oil inlet openings have a well-defined cross-section.

By preferably funnel-shaped in the flow direction expanding supply part can air and oil or an oil-air mixture below the oil level in Oil space are sucked down into the gap between the component and the shield. Depending on the set oil-air ratio of the sucked oil-air mixture, a high oil exchange in the gap can be achieved.

In a further embodiment of the invention it is provided that the shield in the discharge region has a - preferably conically narrowing - discharge part. The discharge part may have at least one outlet opening for the oil or the oil / air mixture which communicates with the oil space.

In one exemplary embodiment of the invention, provision is made for the feed region and the discharge region-preferably approximately diametrically-to be arranged opposite one another with respect to the rotational axis of the component, the delivery region and the discharge region being particularly preferably arranged in the region of a horizontal plane which includes the axis of rotation of the component. But it is also a different arrangement of the feeding and Abführbereiche possible.

In a development of the invention, it can be provided that the shield has at least one ventilation opening in its geodetically highest area. Air can escape upwards out of the cavity via the vent opening and obstruction of the pumping action due to trapped air can be avoided.

The invention will be explained in more detail below with reference to the embodiment shown in the non-limiting figures. Show:

1 shows an inventive housing including rotating component and shield in a cross section.

FIG. 2 shows the component together with the shield from FIG. 1 in cross section; FIG. and

Fig. 3 shows the component including shield in an oblique view.

The housing 1, for example a transmission housing, has an oil chamber 2 (oil sump), which receives oil, in particular lubricating oil, up to a defined maximum oil level 3.

In the oil chamber 2 of the housing 1, a rotating component 4, for example, a shaft with at least one clutch and / or at least one gear, rotatably mounted. The component 4 is surrounded by a substantially cylindrical shield 5 - for example, sheet metal - which is fixedly connected via a fixing 6 to the housing 1 and a cavity 7 spans, in which the component 4 is arranged to rotate. Between the substantially cylindrical component 4 and the shield 5 is a substantially annular narrow Gap 8 is formed. The shield 5 is formed substantially rotationally symmetrical and formed, for example, as a hollow cylinder.

The existing example of sheet steel or aluminum sheet shielding 5 has in the embodiment shown in a feed region 10 a funnel-shaped in the flow direction P of the incoming air or the incoming gas expanding supply part 9. The preferably funnel-shaped feed part 9 is connected in the region of its constricted funnel neck 9a with a feed line 11 for air or gas, wherein the feed line 11 opens into the feed part 9. The supply line 11 is formed as a riser and has in the region of the feed part 9 facing away from an inlet opening 12 for air or gas, which is arranged above the maximum oil level 3 of the oil chamber 2. In the region of the constricted funnel neck 9a facing away from the component 4, the feed part 9 has a first oil inlet opening 13 which communicates with the oil space 2. Furthermore, in the exemplary embodiment shown, the supply line 11 has at least one second oil inlet opening 14 communicating with the oil chamber 2.

With respect to the axis of rotation 4a of the component approximately diametrically opposite to the feed region 10, the shield 5 has a discharge region 15, which is connected to a discharge line 16 likewise designed as a riser. The feed region 10 and the discharge region 15 are arranged, for example, in the region of a horizontal plane ε containing the rotation axis 4a of the component 4.

In the region of the upper end facing away from the shield 5, the discharge line 16 is provided with a first outlet opening 17, which is positioned above the maximum oil level 3 of the oil space 2. In the example, the discharge line 16 furthermore has at least one second outlet opening 18, which lies below the maximum oil level 3.

The shield 5 has a discharge part 19 in the discharge region 15, which narrows in a funnel shape in the flow direction P of the air flowing therein or of the oil-air mixture flowing therein. The discharge part 19 is provided with at least one communicating with the oil chamber 2 third outlet opening 20. Furthermore, in the embodiment at the highest point of the shield 5, a vent opening 22 is provided.

In the exemplary embodiment, the shield 5 is arranged eccentrically with respect to the rotating component 4, with a gap dimension S of the gap 8 defined between the shield 5 and component 4 being smaller in the feed region 10 than in the region When the component 4 rotates, the surface roughness of the component 4 results in a pressure difference between the supply region 10 and the discharge region 15, as a result of which the component 4 functions as an internal delivery device 21. The pumping effect can be increased by targeted surface design of the outer shell of the component 4, for example by slits 23 arranged in the axial direction, projections or the like.

Claims

PATENT APPLICATIONS

1. Housing (1), in particular gear housing, with an oil chamber (2) and at least one in the oil chamber (2) rotatably arranged component (4), wherein the component (4) is at least partially surrounded by a housing-fixed shield (5), which clamps a cavity (7) receiving the component (4), and wherein the cavity (7) is separated from the oil chamber (2) by the shield (5), characterized in that the shield (5) comprises at least one feed region (10). having, which is connected to a supply line (11) for air or gas.

2. Housing (1) according to claim 1, characterized in that the supply line (11) has at least one inlet opening (12) for air or gas, which is preferably arranged above a maximum oil level (3) of the oil space (2).

3. housing (1) according to claim 1 or 2, characterized in that the shield (5) has at least one discharge area (22, 15) which is preferably connected to a discharge line (16).

4. Housing according to claim 3, characterized in that the discharge line (16) has at least one outlet opening (17, 18).

5. Housing according to claim 4, characterized in that at least one outlet opening (17) above the maximum oil level (3) of the oil chamber (2) is arranged.

6. Housing (1) according to claim 4 or 5, characterized in that at least one outlet opening (18) below the maximum oil level (3) of the oil chamber (2) is arranged.

7. Housing (1) according to one of claims 1 to 6, characterized in that the shield (5) in the feed region (10) has a - preferably flared funnel-shaped - supply part (9), wherein preferably the feed part (9) at least one Having with the oil chamber (2) communicating first oil inlet opening (13).

8. Housing (1) according to one of claims 1 to 7, characterized in that the supply line (11) has at least one with the oil chamber (2) communicating second oil inlet opening (14).

9. Housing (1) according to one of claims 4 to 8, characterized in that the shield (5) in the discharge area (15) has a - preferably funnel-shaped narrowing - discharge part (18), wherein preferably the discharge part (18) has at least one outlet opening (20) which communicates with the oil space (2).

10. Housing (1) according to one of claims 1 to 9, characterized in that the shield (5) is formed by a metal sheet.

11. Housing (1) according to one of claims 1 to 10, characterized in that the feed region (10) and the discharge region (15) of the shield (5) - preferably approximately diametrically - with respect to the axis of rotation (4a) of the component (4). The feed region (10) and the discharge region (15) are preferably arranged in the region of a horizontal plane (ε) containing the axis of rotation (4a) of the component (4).

12. Housing (1) according to one of claims 1 to 11, characterized in that between the component (4) and the shield (5) at least in sections, preferably around the entire circumference of the component (4), a substantially annular gap ( 8) is formed.

13. Housing (1) according to one of claims 1 to 12, characterized in that the conveying of the air or gas into the cavity (7) via an internal conveyor (21), which by the rotating member (4) and the Shield (5) is formed, wherein preferably the rotating member (4) is formed as a blade-less pump rotor.

14. Housing (4) according to one of claims 1 to 13, characterized in that the shield (5) is arranged eccentrically with respect to the rotating component (4), wherein preferably between a shield (5) and component (4) defined gap dimension ( S) is less in the feed region (10) than in the discharge region (15).

15. Housing (1) according to one of claims 1 to 14, characterized in that the shield (5) in its geodetically highest region has at least one vent opening (22).

16. Housing (1) according to one of claims 1 to 15, characterized in that the shield (5) is formed substantially rotationally symmetrical and is preferably formed as a hollow cylinder.

17. Housing (1) according to one of claims 1 to 16, characterized in that the shield (5) over the entire circumference of the component (4).

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