WO2018153606A1

WO2018153606A1 - Gear machine and method for operating a gear machine

Info

Publication number: WO2018153606A1
Application number: PCT/EP2018/051698
Authority: WO
Inventors: Jakob Branczeisz; Matthias RIEDLE; Guido Bredenfeld
Original assignee: Robert Bosch Gmbh
Priority date: 2017-02-24
Filing date: 2018-01-24
Publication date: 2018-08-30
Also published as: DE102017203028A1

Abstract

The invention relates to a gear machine (1), wherein, for axial compensation of a gap (25a, 25b) formed between a respective bearing bracket (36, 40) and the gear arrangement (14), an axial force (F) can be applied to the gear arrangement (14) by means of at least one piston (30). The invention further relates to a method for operating the gear machine (1).

Description

Description title

Gear machine and method for operating a gear machine

The invention relates to a gear machine. The invention further relates to a method for operating a gear machine.

State of the art

In known series constructions of gear machines, in particular external gear machines or pumps, a thrust bearing via a

Gear end face and a corresponding counterpart such as a bearing bush or thrust washer formed. In order to minimize leakage through this bearing point, takes place in the pump an axial

Force compensation, with a balance of forces between the inner and outer field is set. The aim is to press the two bearing partners together via an axial force.

This axial compensation can take place according to the operating state of the pump as follows. In a first operating state, the pump is starting up. The bearing bushes / glands have seals on the opposite side to the thrust bearing. This seal is an axial field seal, of which one per pump side is provided. These seals separate on the one hand in operation, the high pressure side of the

Low pressure side. On the other hand, the seals are biased in their grooves and can press the bearing bush / goggles directly or via the bushing / goggles a thrust washer against the gear end face at the start of the pump. In a second operating state, the pump is in operation and promotes against an operating pressure. In the pressure-loaded state, a defined pressure field is established via the aforementioned axial field seal Thrust bearing constructed / delimited. This pressure field generates in addition to the bias from the axial field seal an axial force on the thrust bearing. According to the design of the pump, ie the installation position of

Axial field seal, the axial force acts asymmetrically on the thrust bearing.

Aggressive media, such as Ethanol, cyclopentane, refrigerants, or the like, can chemically decompose the structure of the axial field gasket, particularly the elastomer, or cause the gaskets to swell or harden. Such a damaged seal can not fully apply the required axial force during startup and / or operation, resulting in increased leakage in the

Thrust bearing and thus loss of efficiency in the pump leads.

In addition to the delimitation of the axial field, the axial field seal also takes over a separation of the high-pressure region from the low-pressure region. In the area of an engine bore or on its contour, this seal is realized via lugs on the axial field seal. Low viscosity media, e.g. ORC media, associated with assembly errors, e.g. a squeezed seal or a defect in an external shape of the seal can unintentionally lead to leaks and thus also to a loss of efficiency.

DE 199 24 057 AI discloses a gear machine with a housing having an interior, in which at least one gear arrangement is arranged, which has at least two meshing with each other in external engagement gears on the axial seal on a first gear end face at least a first axially sliding component and on a second

Side surface is pressed at least a second axially displaceable component.

DISCLOSURE OF THE INVENTION The present invention provides a gear machine having a housing having an internal space in which at least one gear arrangement having at least first and second gears meshing with each other in external engagement, the first gear and the second gear being provided by means of a gear Bearing glasses are mounted, wherein for the axial compensation of a formed between the bearing glasses and the gear arrangement gap an axial force can be applied by at least one piston on the bearing goggles. Thus, the leakage through the gap is reduced by reducing the height of the gap. The present invention further provides a method of operating a gear machine.

The method includes providing a housing having an interior.

The method includes providing at least one gear assembly disposed within the housing having at least a first and a second gear meshing with each other in external engagement.

The method further includes supporting the first gear and the second gear by means of bearing glasses.

The method further comprises applying an axial force by at least one piston to the gear assembly for axially compensating a gap formed between the bearing gland and the gear assembly.

One idea of the present invention is to replace the axial compensation implemented via a pressure field in conjunction with the axial field seal or to relocate it to other geometry elements such as the pressurizable piston. Due to the elimination of the axial field seal or the provision of the

pressurizable piston, the gear machine is much more resistant to aggressive media such as ORC media. In addition, the tooth arrangement can always be acted upon over the life of the gear machine with a definable pressure.

Advantageous embodiments and further developments emerge from the dependent claims and from the description with reference to the figures. According to a preferred embodiment it is provided that the first gear is mounted on or integral with a first shaft, which is guided to the outside and sealed by a shaft seal, and the second gear is mounted on a second shaft or formed integrally therewith, wherein the piston is arranged in a housing cover of the gear machine and pressurizable, and wherein the piston in a in the

Housing cover of the gear machine formed first recess is arranged axially movable. Thus, a definable force can be applied to the gear assembly by the first piston.

According to a further preferred refinement, it is provided that the first shaft has a first shaft section arranged adjacent to a first end face of the first gear and a second shaft section arranged adjacent to a second end face of the first gear, the second shaft being adjacent to a first end face of the first shaft second

Gear arranged first shaft portion and a second shaft portion disposed adjacent to a second end face of the second gear, wherein the first shaft portion of the first gear and the first shaft portion of the second gear are mounted in a first bearing glasses, and wherein the second shaft portion of the first gear and the second

Shaft portion of the second gear are stored in a second bearing glasses. Thus, advantageously, the first gear and the second gear can be acted upon in parallel by only one piston with the axial force. The bearing glasses are preferably formed of a material having tribologically advantageous properties.

According to a further preferred embodiment, it is provided that in the first bearing glasses a first bearing bush for the storage of the first

Shaft portion of the first gear and a second bearing bush for bearing the first shaft portion of the second gear are pressed, wherein in the second bearing glasses, a third bearing bush for supporting the second shaft portion of the first gear and a fourth bearing bush for

Storage of the second shaft portion of the second gear are pressed, and wherein the arranged in the housing cover of the gear machine piston is arranged such that the first bearing glasses and the second Bearing glasses acted upon in parallel with the axial force. Thus, the bearing glasses may be formed of any suitable material while the

Bushings are formed of a material having tribologically advantageous properties.

According to a further preferred embodiment, it is provided that the piston has at an axial end portion to a central longitudinal axis of the piston substantially concentrically arranged second recess, wherein in the formed in the housing cover of the gear machine first recess, a first Axialdruckfeder is arranged, which is located on a a first axial end portion on a wall surface of the housing cover and a second axial end portion on a wall surface of the second

Recess of the piston is supported. By providing the first axial compression spring, both a spring force and a fluid pressure can thus advantageously be applied to the first piston.

According to a further preferred embodiment, it is provided that the piston in a drive-side first housing cover, which has an opening for receiving the shaft of the gear machine, or in a, opposite to the drive-side first housing cover, second

Housing cover is arranged. An arrangement of the piston can thus be formed according to respective structural or systemic requirements.

According to a further preferred embodiment, it is provided that the first recess of the housing cover has an opening, which for

Pressure supply of the piston with a supply line from a high pressure region of the gear machine, in particular the gear pump fluidly communicates. Thus, the pressure of the high-pressure area generated by the gear machine can be advantageously used for pressurizing the piston. Thus, the pressure supply does not have to be provided separately.

According to a further preferred embodiment, it is provided that during a start-up phase of the gear machine, the axial compensation of the gap formed between the bearing glasses and the gear arrangement by means of the first axial compression spring and during an operating phase of Gear machine by means of the first axial compression spring and by means of a

Actuation of the piston with a fluid pressure is feasible. Thus, in an advantageous manner, regardless of a speed or a

Operating condition of the gear machine, a required pressure to be applied to the piston.

According to a further preferred embodiment, it is provided that in the housing cover the piston and a further piston are arranged, wherein the piston axially movable in a formed in the housing cover of the gear machine first recess and the further piston in a formed in the housing cover of the gear machine third recess are arranged. By providing a piston and another piston, a higher pressure can be advantageously applied to the gear arrangement.

Storage of the second shaft portion of the second gear are pressed, and wherein the arranged in the housing cover of the gear machine piston and the further piston are arranged such that these act on the first bearing glasses and the second bearing glasses in parallel with the axial force. Thus, the bearing glasses may be formed of any suitable material, while the bearing bushes are formed of a material having tribologically advantageous properties.

According to a further preferred embodiment, it is provided that the first recess of the housing cover and the third recess of the

Housing cover for supplying pressure to the piston and the other piston fluidly communicate with a supply line from a high pressure region of the gear machine, in particular the gear pump, wherein the first recess of the housing cover and the third recess of the

Housing cover are fluidly connected by an opening. Consequently can be used to pressurize the first and further piston advantageously the pressure generated by the gear machine of the high pressure area. Thus, the pressure supply does not have to be separate

to be provided.

Recess of the piston is supported, and wherein the further piston has at one axial end portion to a central longitudinal axis of the further piston substantially concentrically arranged fourth recess, wherein formed in the housing cover of the gear machine third recess a second Axialdruckfeder is arranged, which at a first axial end portion on a wall surface of the housing cover and at a second axial end portion on a wall surface of the fourth recess of the further piston is supported.

By providing the first and second thrust spring can thus in

Advantageously, both a spring force and a fluid pressure are applied to the first and second pistons.

According to a further preferred development, it is provided that the piston and / or the further piston has a relief groove on a section adjacent to the gear arrangement. This relief groove serves to remove the bearing leakage from the radial bearings. By providing the relief groove in the piston or by the displacement of the relief groove in the piston simplification of the production of the bearing bushes can be achieved, since a cutout of the bearing bushes / goggles deleted.

According to a further preferred development, it is provided that an inlet pressure to the piston and / or further piston can be regulated via a valve arranged upstream of the piston and / or further piston. Thus, in advantageously be controlled in an operating phase of the gear machine, the pressure regardless of the operating pressure of the gear machine.

The described embodiments and developments can be combined with each other as desired.

Further possible refinements, developments and implementations of the invention also include combinations, not explicitly mentioned, of features of the invention described above or below with regard to the exemplary embodiments.

Brief description of the drawings

The accompanying drawings are intended to provide a further understanding of the

Embodiments of the invention mediate. They illustrate

Embodiments and in conjunction with the description serve to explain principles and concepts of the invention.

Other embodiments and many of the stated advantages will become apparent with reference to the drawings. The illustrated elements of the drawings are not necessarily shown to scale to each other.

Show it:

Fig. 1 is a longitudinal sectional view of a gear machine according to a first

Embodiment of the invention;

Fig. 2 is a longitudinal sectional view of the gear machine according to a second

Embodiment of the invention;

Fig. 3 is a longitudinal sectional view of the gear machine according to a third

Embodiment of the invention; and

4 is a flowchart of a method for operating the

Gear machine according to the first to third embodiments of the invention. In the figures of the drawings, like reference characters designate like or functionally identical elements, components or components, as far as nothing is concerned

The contrary is stated.

Fig. 1 shows a longitudinal sectional view of a gear machine according to a first embodiment of the invention.

The gear machine 1 has a housing 10, which has an inner space 12, in which at least one gear arrangement 14 with at least one first and one second gear 16, 18 is arranged. The first gear 16 and the second gear 18 mesh with each other in external engagement.

The first gear 16 and the second gear 18 are mounted by means of a bearing goggles 36, 40, wherein for the axial compensation of a formed between the bearing glasses and the gear assembly 14 gap 25a, 25b, an axial force F by at least one piston 30 on the bearing glasses 40, and thus Also indirectly on the gear assembly 14 can be applied.

The first gear 16 is fixed to or integrally formed on a first shaft 20, which is guided to the outside and sealed by a shaft seal 22. The second gear 18 is mounted on a second shaft 24 or integrally formed with the piston 30 in a

Housing cover 26, 28 of the gear machine 1 and arranged

is pressurizable. The piston 30 is disposed axially movably in a first recess 32 formed in the housing cover 26, 28 of the gear machine 1.

The first shaft 20 has a first shaft portion 20a adjacent to a first end face 16a of the first gear 16 and a first shaft portion 16b adjacent to a second end face 16b

arranged second shaft portion 20b.

The second shaft 24 has a first shaft portion 24a adjacent to a first end face 18a of the second gear 18 and a shaft portion 24a adjacent to a second end face 18b of the second gear 18

arranged second shaft portion 24b.

The first shaft portion 20a of the first gear 16 and the first one

Shaft portion 24a of the second gear 18 are mounted in a first bearing glasses 36. The second shaft portion 20 b of the first gear 16 and the second shaft portion 24 b of the second gear 18 are mounted in a second bearing glasses 40.

In the first bearing glasses 36 are a first bearing bush 34 for supporting the first shaft portion 20a of the first gear 16 and a second

Bearing bush 35 for supporting the first shaft portion 24 a of the second gear 18 is pressed. The bushings 34, 35 are optional.

In the second bearing glasses 40 are a third bearing bush 38 for supporting the second shaft portion 20b of the first gear 16 and a fourth

Bearing bush 39 for supporting the second shaft portion 24b of the second gear 18 is pressed. The bushings 38, 39 are optional.

The arranged in the housing cover 26, 28 of the gear machine 1 piston 30 is arranged such that it acts on the first bearing glasses 36 and the second bearing glasses 40 in parallel with the axial force F.

The piston 30 has at an axial end portion 30 a to a

Center longitudinal axis M1 of the piston 30 substantially concentrically arranged second recess 42. In the housing cover 28 of the

Gear machine 1 formed first recess 32 is a first

Axialdruckfeder 44 arranged, which at a first axial

End portion 44a on a wall surface 28a of the housing cover 28 and at a second axial end portion 44b on a wall surface 42a of the second recess 42 of the piston 30 is supported.

The piston 30 is in a drive-side first housing cover 26 having an opening 27 for receiving the shaft 20 of the gear machine 1, or in one, to the drive-side first housing cover 26th

arranged opposite, second housing cover 28 is arranged. The first recess 32 of the housing cover 26, 28 has an opening 46 which communicates fluidically to the pressure supply of the piston 30 with a supply line from a high-pressure region of the gear machine 1, in particular the gear pump.

During a start-up phase of the gear machine 1, the axial compensation of the gap 25a, 25b formed between the bearing glasses 36, 40 and the gear arrangement 14 by means of the first axial compression spring 44 and during an operating phase of the gear machine 1 by means of the first axial compression spring 44 and by means of an impact of the piston 30 with a fluid pressure feasible.

Furthermore, the housing cover 26, 28 are formed to a

Heat dissipation of arranged in the gap 25 a, 25 b fluid to realize an environment.

Fig. 2 shows a longitudinal sectional view of the gear machine according to a second embodiment of the invention.

In the housing cover 26, 28 of the piston 30 and another piston 48 are arranged, wherein the piston 30 in a formed in the housing cover 26, 28 of the gear machine 1 first recess 32 and the other piston 48 in a housing cover 26, 28 of the Gear machine 1 formed third recess 50 are arranged axially movable.

Bearing bush 39 for supporting the second shaft portion 24b of the second gear 18 is pressed. The bushings 38, 39 are optional. The arranged in the housing cover 26, 28 of the gear machine 1 piston 30 and the other piston 48 are arranged such that these act on the first bearing glasses 36 and the second bearing glasses 40 in parallel with the axial force F.

The first recess 32 of the housing cover 26, 28 and the third recess 50 of the housing cover 26, 28 for the pressure supply of the piston 30 and the other piston 48 communicate with a supply line of a

High-pressure region of the gear machine 1, in particular the gear pump fluidly.

The first recess 32 of the housing cover 26, 28 and the third recess 50 of the housing cover 26, 28 are fluidly connected to each other through an opening 46.

The piston 30 has at an axial end portion 30 a to a

Center longitudinal axis M1 of the piston 30 substantially concentrically arranged second recess 42.

In the in the housing cover 26, 28 of the gear machine 1 formed first recess 32, a first Axialdruckfeder 44 is arranged, which at a first axial end portion 60 a on a wall surface 28 a of

Housing cover 26, 28 and at a second axial end portion 44b on a wall surface 42a of the second recess 42 of the piston 30 is supported.

The further piston 48 has at one axial end section 48a a fourth recess 58 arranged concentrically to a central longitudinal axis M2 of the further piston 48.

In the in the housing cover 26, 28 of the gear machine 1 formed third recess 50, a second axial compression spring 60 is arranged, which at a first axial end portion 60 a on a wall surface 44 a of

Housing cover 26, 28 and at a second axial end portion 60 b on a wall surface 58 a of the fourth recess 58 of the further piston 48 is supported. The piston 30 and the other piston 48 have at one to the

Gear arrangement 14 adjacent portion 30 b, 48 b, a relief groove 52, 54 on.

Alternatively, in addition to the provision of the piston 30, which in the formed in the housing cover 28 of the gear machine 1 first

Recess 32 is arranged to be axially movable, a further axially movable piston arranged in the second recess 42 of the piston 30 may be provided. This acts as a pressure booster for increasing a pressure relative to the pressure which can be generated only by the first piston 30.

3 shows a longitudinal sectional view of the gear machine according to a third embodiment of the invention.

The embodiment shown in Fig. 3 corresponds substantially to the embodiment shown in Fig. 1 with the difference that the pressurization of the piston regardless of the operating pressure or operating phase of

Gear machine, in particular the gear pump 1, is controllable. One

Supply pressure to the piston 30 is controllable via a piston 56 upstream of the valve 56. For example, the valve 56 may also be used in the embodiment shown in FIG.

Recess 32 is arranged to be axially movable, a further axially movable piston arranged in the second recess 42 of the piston 30 may be provided. This acts as a pressure booster for increasing a pressure relative to the pressure which can be generated only by the piston 30.

FIG. 4 shows a flowchart of a method for operating the

Gear machine according to the first to third embodiments of the invention.

The method comprises providing S1 a housing having a

Interior has. The method comprises providing S2 at least one gear arrangement arranged in the housing with at least one first and one second gear, which mesh with each other in external engagement.

The method further comprises supporting S3 of the first gear and the second gear by means of bearing glasses.

The method further comprises applying S4 an axial force by at least one piston to the gear assembly for axially compensating a gap formed between the bearing gland and the gear assembly.

Although the present invention has been described above with reference to preferred embodiments, it is not limited thereto but is modifiable in a variety of ways. In particular, the invention can be varied or modified in many ways without deviating from the gist of the invention.

For example, a shape, size and / or nature of the components of the gear machine can be modified according to respective structural or constructive requirements.

Claims

claims

A gear machine (1) comprising a housing (10) having an interior space (12) in which at least one gear arrangement (14) is arranged with at least a first and a second gearwheel (16, 18) meshing with each other in external engagement in which the first toothed wheel (16) and the second toothed wheel (18) are respectively mounted by means of a bearing eyeglasses (36, 40), wherein for the axial compensation of a gap formed between the respective bearing eyeglasses (36, 40) and the toothed wheel arrangement (14) 25a, 25b) an axial force (F) by at least one piston (30) on the bearing glasses (36, 40) can be applied.

2. Gear machine according to claim 1, characterized in that the first gear (16) mounted on a first shaft (20) or formed integrally therewith, which led to the outside and via a

Shaft seal (22) is sealed, and the second gear (18) on a second shaft (24) attached or formed integrally therewith, wherein the piston (30) in a housing cover (26, 28) of the gear machine (1) and arranged is pressurizable, and wherein the piston (30) in a in the housing cover (26, 28) of the gear machine (1) formed in the first recess (32) is arranged axially movable.

3. gear machine according to claim 1 or 2, characterized in that the first shaft (20) adjacent to a first end face (16 a) of the first gear (16) arranged first shaft portion (20 a) and adjacent to a second end face (16 b) the second shaft (24) has a first shaft section (24a) arranged adjacent to a first end face (18a) of the second gear (18) and one adjacent to a second end side (16) of the first gear (16). 18b) of the second gear (18) arranged second shaft portion (24b), wherein the first Shaft portion (20a) of the first gear (16) and the first

Shaft portion (24a) of the second gear (18) in a first bearing glasses (36) are mounted, and wherein the second shaft portion (20b) of the first gear (16) and the second shaft portion (24b) of the second gear (18) in a second Bearings (40) are stored.

Gear machine according to one of the preceding claims, characterized in that in the first bearing glasses (36) has a first bearing bush (34) for supporting the first shaft portion (20a) of the first gear (16) and a second bearing bush (35) for supporting the first

Shaft portion (24a) of the second gear (18) are pressed, wherein in the second bearing glasses (40) has a third bearing bush (38) for supporting the second shaft portion (20b) of the first gear (16) and a fourth bearing bush (39) for storage of the second shaft portion (24b) of the second gear (18) are pressed, and wherein in the

Housing cover (26, 28) of the gear machine (1) arranged piston (30) is arranged such that it acts on the first bearing glasses (36) and the second bearing glasses (40) in parallel with the axial force (F).

Gear machine according to one of the preceding claims, characterized in that the piston (30) at one axial end portion (30a) to a central longitudinal axis (M1) of the piston (30) substantially concentrically arranged second recess (42), wherein in the a first axial compression spring (44) is arranged, which at a first axial end portion (44a) on a wall surface (28a) of the housing cover (28) and a second axial end portion (44a) on the first housing (28) of the gear machine (1) axial end portion (44b) on a wall surface (42a) of the second recess (42) of the piston (30) is supported.

Gear machine according to one of the preceding claims, characterized in that the piston (30) in a drive-side first housing cover (26) having an opening (27) for receiving the shaft (20) of the gear machine (1), or in one, to the

drive-side first housing cover (26) opposite one another

arranged, second housing cover (28) is arranged. Gear machine according to one of claims 4 to 6, characterized

characterized in that the first recess (32) of the housing cover (26, 28) has an opening (46) which communicates fluidically to the pressure supply of the piston (30) with a supply line from a high pressure region of the gear machine (1), in particular the gear pump.

Gear machine according to one of claims 5 to 7, characterized

characterized in that during a starting phase of the gear machine (1), the axial compensation of the between the bearing glasses (36, 40) and the gear arrangement (14) respectively formed gap (25a, 25b) by means of the first axial compression spring (44) and during an operating phase of the

Gear machine (1) by means of the first axial compression spring (44) and by means of an actuation of the piston (30) with a fluid pressure is feasible.

Gear machine according to one of claims 1 to 3, characterized

characterized in that in the housing cover (26, 28) of the piston (30) and another piston (48) are arranged, wherein the piston (30) in a in the housing cover (26, 28) of the gear machine (1) formed first recess (32) and the further piston (48) in one in the

Housing cover (26, 28) of the gear machine (1) formed third recess (50) are arranged axially movable.

0. A gear machine according to claim 9, characterized in that in the first bearing glasses (36) has a first bearing bush (34) for supporting the first shaft portion (20a) of the first gear (16) and a second bearing bush (35) for supporting the first Shaft portion (24a) of the second gear (18) are pressed, wherein in the second bearing glasses (40) has a third bearing bush (38) for supporting the second shaft portion (20b) of the first gear (16) and a fourth bearing bush (39) for storage of the second shaft portion (24b) of the second gear (18) are pressed, and wherein in the housing cover (26, 28) of the gear machine (1) arranged piston (30) and the further piston (48) are arranged such that these first bearing glasses (36) and the second bearing glasses (40) act in parallel with the axial force (F).

1 1. Gear machine according to claim 9 or 10, characterized in that the first recess (32) of the housing cover (26, 28) and the third recess (50) of the housing cover (26, 28) for the pressure supply of the piston (30) and the further piston ( 48) with a supply line from a high pressure region of the gear machine (1), in particular the

Fluidly communicate gear pump, wherein the first recess (32) of the housing cover (26, 28) and the third recess (50) of the

Housing cover (26, 28) through an opening (46) are fluidly connected together.

12. Gear machine according to one of claims 9 to 1 1, characterized

characterized in that the piston (30) has, at an axial end portion (30a), a second recess (42) substantially concentric with a central longitudinal axis (M1) of the piston (30), wherein in the housing cover (26, 28) Gear machine (1) formed first

Recess (32) a first Axialdruckfeder (44) is arranged, which at a first axial end portion (60 a) on a wall surface (28 a) of the housing cover (26, 28) and at a second axial end portion (44 b) on a wall surface (42 a ) of the second recess (42) of the piston (30) is supported, and wherein the further piston (48) at an axial end portion

(48a) has a to a central longitudinal axis (M2) of the further piston (48) arranged substantially concentrically fourth recess (58), wherein in the in the housing cover (26, 28) of the gear machine (1) formed third recess (50) has a second axial compression spring (60) is arranged, which at a first axial end portion (60a) on a wall surface (44a) of the housing cover (26, 28) and at a second axial end portion (60b) on a wall surface (58a) of the fourth

Recess (58) of the further piston (48) is supported. 13. Gear machine according to one of claims 9 to 12, characterized

in that the piston (30) and / or the further piston (48) has a relief groove (52, 54) on a section (30b, 48b) adjacent to the gear arrangement (14).

14. Gear machine according to one of claims 1 to 6, characterized

characterized in that an inlet pressure to the piston (30) and / or further piston (48) via a piston (30) and / or further piston (48) upstream of the valve (56) is controllable.

15. A method of operating a gear machine (1), comprising the steps of:

Providing (S1) a housing (10) having an interior space (12); Providing (S2) at least one gear arrangement (14) arranged in the housing (10) with at least one first and one second gearwheel (16, 18) which mesh with each other in external engagement;

Supporting (S3) the first gear (16) and the second gear (18) by means of a respective bearing glasses (36, 40); and

Applying (S4) an axial force (F) by at least one piston (30) to the gear arrangement (14) for the axial compensation of a between the respective bearing glasses (36, 40) and the gear arrangement (14)

formed gap (25a, 25b).