This application is a 35 U.S.C. ยง371 National Stage Application of PCT/EP2010/001163, filed Feb. 25, 2010, which claims the benefit of priority to application Ser. No. DE 10 2009 012 853.0, filed Mar. 12, 2009 in Germany, the disclosures of which are incorporated herein by reference in their entirety.
The disclosure relates to a hydraulic toothed wheel machine.
EP 1 291 526 A2 shows a toothed wheel machine having a housing in which two intermeshing toothed wheels supported in bearing bushes or bearing bodies are arranged, the housing being closed at the ends by a first and a second housing cover respectively. The helically toothed wheels are each supported in a sliding manner axially by two axial surfaces between the bearing bodies and radially by respective bearing shafts accommodated in the bearing bodies. During the operation of the toothed wheel machine, hydraulic and mechanical forces act on the toothed wheels along the same toothed wheel longitudinal axis in each case. To ensure that the first bearing body, which lies in the direction of action of the forces, is not pushed beyond the axial surfaces of the toothed wheels, between the toothed wheels and the first housing cover, and that only a small sliding gap occurs between the toothed wheels and the second bearing body, a counter-force is applied to the toothed wheels and to the first bearing body. This counter-force is larger than the hydraulic and mechanical forces, with the result that the first bearing body is pressed against the toothed wheels, the toothed wheels are pressed against the second bearing body, and the second bearing body is pressed against the second housing cover. All the resultant forces on the bearing bodies and the toothed wheels thus act in the direction of the second housing cover.
The counter-force on the toothed wheels is applied via pistons acting on the bearing shafts. The pistons are accommodated in a sliding manner, approximately coaxially with respect to the toothed wheel longitudinal axis, in an intermediate cover arranged between the first housing cover and the housing and rest by means of a first piston end face against a shaft end face of the bearing shafts which faces in the direction of the first housing cover and are each subjected to pressure by way of a second piston end face. The counter-force is applied to the first bearing body by way of a pressure field formed between the bearing body and the intermediate cover.
The disadvantage with this solution is that the entire assembly of bearing bodies and toothed wheels is pressed onto the second housing cover of the toothed wheel machine, with the result that the second housing cover and the housing are subjected to very high and uneven loads. Moreover, the pressing together of the toothed wheels and the bearing bodies results in very high wear between the axial surfaces of the toothed wheels and the bearing bodies.
It is the object of the present disclosure to provide a hydraulic toothed wheel machine in which machine elements, in particular housing covers and housings, are subjected to little force and which is subject to minimal wear.
This object is achieved by a hydraulic toothed wheel machine in accordance with the features set forth below.
According to the disclosure, a toothed wheel machine has a housing for accommodating two intermeshing toothed wheels, in particular helically toothed wheels, which are supported in a sliding manner axially by axial surfaces between bearing bodies accommodated in the housing and radially by respective bearing shafts accommodated in the bearing bodies. During the operation of the toothed wheel machine, an axial force component of a force resulting from hydraulic and mechanical forces acts on each toothed wheel in the same axial direction. A counter-force against the respective axial force component is then applied to the toothed wheels and/or bearing shafts, the magnitude of said counter-force being equal to or less than that of the respective axial force component.
This solution has the advantage that the toothed wheels of the toothed wheel machine are each pressed against the bearing body lying in the direction of action of the axial force component by an axial force component reduced by the counter-force, with the result that there is a reduction in the sliding friction between the toothed wheels and the bearing body and the other bearing body, the one which does not lie in the direction of action of the axial force component, is not subjected to load. The axial force components reduced by the counter-forces can then be provided as axial-gap compensation for a sliding gap between the toothed wheels and the bearing bodies lying in the direction of action of the resultant force. Axial-gap compensation for a sliding gap between the toothed wheels and the bearing bodies that do not lie in the direction of action of the axial force component can be employed independently of the axial force components. It is furthermore possible, by means of the counter-force, to reduce loading due to the axial force component on the housing cover and the housing.
The toothed wheels of the toothed wheel machine are preferably helically toothed.
It is advantageous if the first bearing body, which lies in the direction of the effective axial force component, is pressed against a housing cover of the housing mechanically by way of the toothed wheels and/or hydraulically by way of a pressure force.
To make the second bearing body press lightly on the toothed wheels, a hydraulic pressure is applied to the bearing body at an end face facing away from the toothed wheels.
The counter-force acting on the toothed wheels and/or bearing shafts is preferably a hydraulic pressure force and/or a mechanical force.
It is advantageous if the counter-force acts on at least one toothed wheel by means of a pressure field between at least one toothed wheel and the first bearing body. A pressure pocket can simply be introduced into that axial surface of the at least one toothed wheel which faces the first bearing body in order to delimit the pressure field.
The axial surface of one toothed wheel consists of tooth faces and of an annular surface, and the pressure pocket is preferably an annular groove introduced into the annular surface and running approximately concentrically around a longitudinal axis of the corresponding toothed wheel. To enlarge the pressure field and hence the area of application of the hydraulic pressure, the annular groove can be enlarged by tooth pocket sections introduced into the tooth faces of the toothed wheel.
As a further development of the disclosure, the annular groove is introduced into that axial surface of the driving toothed wheel which faces the first bearing body, and the annular groove together with the tooth pocket sections is introduced into that axial surface of the driving toothed wheel which faces the first bearing body since the axial force component on the driving toothed wheel is larger than that on the driven toothed wheel.
It is expedient if the pockets are in pressure-medium communication with a high pressure of the toothed wheel machine.
A pressure field can be introduced into that end face of the second bearing body which faces away from the toothed wheels, and this can be brought about by pressing the second bearing body lightly against the toothed wheels.
It is advantageous if that end face of the second bearing body which faces away from the toothed wheels has introduced into it a first pressure groove, running concentrically all the way round a first bearing eye, and a second pressure groove, spanning a partial circle around a second bearing eye. The pressure grooves are then in pressure-medium communication with the high pressure of the toothed wheel machine via a pressure-medium port.
In a preferred embodiment of the toothed wheel machine, for each bearing shaft there is a piston supported in an axially movable manner in the housing cover of the housing, approximately coaxially with respect to the toothed wheel longitudinal axis, for applying force to the bearing shafts. The respective piston is arranged so as to rest approximately, by means of a first piston end face, against a shaft end face of the bearing shaft which faces in the direction of the axial force component, and has pressure applied to it by way of a second piston end face. The piston is a simple means of applying the mechanical counter-force to the bearing shafts.
For application of pressure, the second piston end faces are connected to the high pressure of the toothed wheel machine. The pressure force acting on the bearing shafts can be determined by means of the piston end face diameter.
Other advantageous developments of the hydraulic toothed wheel machine in accordance with the disclosure is set forth below.
Preferred illustrative embodiments of an disclosure are explained in greater detail below with reference to schematic drawings. In the drawings:
The housing covers 4, 6 are aligned on the machine housing 2 by means of centering pins 42. A housing seal 44 is arranged between the housing covers 4 and 6 and the machine housing 2. Respective axial seals 46 are furthermore inserted into the end faces 38 and 40 of the bearing bodies 26 and 28 to separate a high-pressure zone from a low-pressure zone of the toothed wheel machine 1. A radial shaft seal ring 48 seals off the first bearing shaft 8 where it passes through the housing cover 6 on the right in
Hydraulic and mechanical forces arise during the operation of the toothed wheel machine 1, this being illustrated schematically in detail in
The toothed wheels 10 and 12 subjected to axial force components 47, 49 are each supported by axial surfaces 34 and 36, respectively, on the bearing body 28 on the left in
In
The mechanical counter-force acting on the bearing shafts 8, 16 is determined by means of the piston diameter of the pistons 70, 72 and the level of pressure in the pressure chamber 86. Since the magnitude of the axial force components 47, 49 shown in
Owing to the mechanical counter-force applied to the toothed wheels 10, 12 via the bearing shafts 8, 16, the remainder of the axial force is introduced into the housing 2, while bypassing bearing body 28.
In the case of the driving toothed wheel 10, the axial force component 47 acting is greater than in the case of the driven toothed wheel 12, see
As already explained, the counter-forces applied to toothed wheels 10, 12 via pressure pockets 50 and 52 are less than or equal to the respective axial force components 47, 49 in
The bearing body 26 on the right in
In the case of the illustrative embodiments shown in
The operation of the axial-gap and axial-force compensation explained above is independent of the construction of the bearing elements used and can therefore be employed for all components suitable for axial sealing of toothed wheel machines. The same applies also to the type of toothing and the parameters thereof. Such axial-gap and axial-force compensation can be employed both in external and internal toothed wheel machines.
The toothed wheel machine can be used as a gear pump or motor.
The disclosure is of a toothed wheel machine having a housing for accommodating two intermeshing toothed wheels. These are supported in a sliding manner axially by axial surfaces between bearing bodies accommodated in the housing and radially by respective bearing shafts accommodated in the bearing bodies. During the operation of the toothed wheel machine, an axial force component of a force resulting from hydraulic and mechanical forces arising during operation acts on each toothed wheel in the same axial direction. A counter-force against the respective axial force component is then applied to the toothed wheels and/or bearing shafts, the magnitude of said counter-force being equal to or less than that of the respective axial force component.
Number | Date | Country | Kind |
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10 2009 012 853 | Mar 2009 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2010/001163 | 2/25/2010 | WO | 00 | 1/30/2012 |
Publishing Document | Publishing Date | Country | Kind |
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WO2010/102722 | 9/16/2010 | WO | A |
Number | Name | Date | Kind |
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3658452 | Kita | Apr 1972 | A |
4343602 | Meywald et al. | Aug 1982 | A |
4781552 | Malfit | Nov 1988 | A |
Number | Date | Country |
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199 24 057 | Nov 2000 | DE |
1 291 526 | Mar 2003 | EP |
1124357 | May 1986 | IT |
2004057193 | Jul 2004 | WO |
Entry |
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English language machine translation of WO 2004/057193. |
International Search Report corresponding to PCT Application No. PCT/EP2010/001163, mailed Jul. 18, 2011 (German and English language document) (8 pages). |
Ivantysyn et al., Hydrostatische Pumpen und Motoren, 1993, pp. 337, 341, 347, and 348. |
Rabie, M. Galal, Fluid Power Engineering, 2009, pp. 114-115, McGraw Hill. |
Voith Turbo, IPH Catalog, High-pressure internal gear pumps, pp. 1-4, 2005. |
Number | Date | Country | |
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20120114514 A1 | May 2012 | US |