EP1776525A1 - Hydrostatic rotary cylinder engine - Google Patents

Abstract

The invention relates to a hydrostatic, slow-speed rotary cylinder engine comprising a power part (1) which acts as an output, said power part comprising a central, stationary stator (4), a rotary cylinder (6) which is used as a rotor and a shaft (2) which is mounted in a central manner on both sides of the roller bearings (10, 11) which are arranged directly adjacent to the power part (1). Supply and discharge of tooth chambers comprising the working fluid is controlled by means of a disk-shaped rotational valve (3) which is mounted in a continuously centred manner in relation to the shaft (2) and the stator (4). A toothed wheel drive is arranged between a shaft external toothing (14) and an internal toothing (17) of a stationary internal toothed ring (28; 92) as a synchronous drive for the rotational valve (3). The toothed wheel drive is subsequently arranged in the leakage oil region of the engine and is formed by a planetary gear (80) or, preferably, by an eccentric gear (30).

Description

 Hydrostatic rotary engine

The invention relates to a hydrostatic, low-speed rotary piston engine according to the preamble of the independent claims 1 and 2.

A hydrostatic rotary piston engine of this type is known from EP 1 074 740 Bl. An advantage of the disclosed there formation of a rotary piston engine is compared to previous solutions is that the bearings of the hydrostatically highly loaded part of the shaft are arranged immediately adjacent with small axial distance in the fixed housing, so a small amount of bending and tooth deformation on the shaft and, accordingly, a maximum Printing performance and thus to torque delivery can be achieved. Because of this bearing arrangement, there is no way to create a 1: 1 rotary connection between the acting as a rotor rotary piston and responsible for the commutation rotary valve, it has been proposed to synchronously drive the rotary valve via a gear transmission from the shaft. In the known embodiment, this gear transmission is an eccentric internal gear, in which the disk-shaped rotary valve itself acts as an eccentric member of this transmission and thus performs an unavoidable orbital movement. Extensive experiments have shown, however, that this initially striking thought in practice at high working pressures can not be realized because the necessary eccentric movement of the rotary valve relative to the fixed control plate does not allow sufficiently accurate ^' commutation of the machine. The result is highly fluctuating torque output on the shaft, unsatisfactory volumetric efficiency and high noise, since the outer part of the eccentric gear must work in the high pressure range. Also the axial compensation of the on Rotary valve axially acting hydraulic forces through the balance piston was not optimal due to the eccentric movement of the rotary valve.

Since the teeth of the eccentric drive generate a displacement effect, similar to an internal gear pump, it is unfavorable because of the resulting hydrostatic losses when this displacement occurs in the high pressure part of the machine.

The invention has as its object to eliminate these deficiencies and at the same time reduce the caused by the orbital movement slightly increased friction at the rotary valve and the production costs.

This object is achieved by the realization of the characterizing features of the independent claims. Features which further develop the invention in an alternative or advantageous manner can be found in the dependent claims.

The invention eliminates these disadvantages while retaining the above-mentioned advantages of such machines.

The hydrostatic, low-speed rotary piston engine according to the invention comprises a power unit acting as an output with a centric fixed stator, a rotary piston as the rotor and a centrically mounted shaft. The stator has an internal toothing with the number of teeth d. The rotary piston has a part in the

Internal teeth of the stator engaging external teeth with a number of teeth c and an internal teeth with a number of teeth b. The shaft meshes with its external teeth with a number of teeth a partially the internal toothing of the rotary piston, wherein the rotary piston for performing an orbital movement is arranged and dimensioned eccentrically such that with working fluid ver and disposable tooth chambers between the inner teeth of the stator and the outer teeth of the rotary piston form. An inlet and outlet part is used for supply and disposal of the power unit with the working fluid. By means of a disc-shaped rotary valve, which according to the invention is mounted centrically running to the shaft and the stator, the control of the supply and disposal of the tooth chambers with the working fluid. In addition, the rotary piston engine comprises a toothed gear, which is arranged between a - formed in particular by a sun gear - shaft external teeth of the shaft with a number of teeth w and an internal toothing of a fixed internal gear with a number of teeth z as a synchronous drive for the rotary valve. The shaft is mounted on both sides of the power section immediately adjacent bearings arranged. According to the invention, the gear transmission is arranged exclusively in the leakage oil region of the engine and is arranged by a planetary gear with at least one planet carrier, which is rotatably connected to the rotary valve and on which planet gears between the shaft outer teeth and the stationary inner ring gear are arranged, or preferably by an eccentric with an eccentric , which is rotatably connected to the rotary valve formed.

Since a continuous shaft with large shaft diameters and high torsional strength can be used in the hydrostatic, low-speed rotary piston engine according to the invention, it is possible to expose both shaft ends to a high torque flux and, for example, both shaft ends as output, or one shaft end as output and the other shaft end for connection a brake or a second drive, whereby the entire drive unit can be made considerably more compact.

Because of the allowable by the invention omission of the orbit movement of the rotary valve, by the placement of the eccentric in Leckölraum of the engine and by the use of cost-effective extruded or sintered parts as gear members thus creates an optimal, compact and inexpensive construction. The drive of the rotary valve 1: 1 to the rotary piston of the power unit via a wobbling cardan-like wave is known from the earlier designs. There, however, the wobble shaft must compensate for the full eccentricity of the rotary piston in the power section, so that a very large wobble angle is created. The inventive wobble gear requires a much smaller eccentricity, which according to the invention is independent of the eccentricity of the rotary piston in the power section, so that this wobble angle is substantially smaller than half of that wobble angle of the earlier construction. Thus, caused by the tumbling and necessarily enlarged gear plays the transmission can be drastically reduced. The resulting rattling noises and the wear are much smaller in the inventive construction.

When using an eccentric, the particular disc-shaped eccentric is rotatably connected via a cup-shaped connecting part with the rotary valve via Mitnehmerverzahnungen in the speed ratio of 1: 1. The eccentric has, for example, an internal toothing with a number of teeth x and an external toothing with a number of teeth y and is arranged between the shaft external toothing and the internal toothing of the stationary internal toothed ring, so that the corresponding internal and external teeth mesh with each other in a known manner.

The following equation represents the speed ratio shaft to the rotary piston or shaft to the rotary valve:

b _j x

• d-c -z-y a w d -c z-y

As one can easily see from this equation, the numbers of teeth of the eccentric gear can be carried out quite differently.

A first option would be, for example, the design exactly as in the power section with w = 12, x = 14, y = ll and z = 12. It only needs to be considered that the eccentricity of the two internal gears are exactly the same. The equation expression is a positive integer, preferably equal to 3. It must also be striven that in this area, the diameter of the shaft is sufficiently large, so that their torsional strength for a possibly connected holding brake for the maximum

Torque is still sufficient. Here, however, the eccentricity of the transmission is relatively large, so that the wobble angle is correspondingly large. However, then the speed of eccentricity would be quite small.

The relationship between the rotational speed Ne of the eccentricity of the eccentric gear and the rotational speed Nw of the shaft is given by the equation

Ne _ wy Nw xzwy 'where this ratio is preferably between -3 and -9. A second option is the preferred design of the number of teeth according to a = 12, b = 14, c = ll, d = 12, w = 12, x = 13, y = 23 and z = 24 or after a = 12, b = 14 , c = ll, d = 12, w = 9, x = 10, y = 17 and z = 18, each with a very small eccentricity. As can be easily calculated from the above equation Ne / Nw, then the rotational speed of the eccentricity becomes higher, but still remains below the value of the wobble wave of earlier known constructions.

In the design of the eccentric with the numbers of teeth a = 12, b = 14, c = ll, d = 12, w = 12, x = 13, y = 23 and z = 24, there are advantages: As in the assembly of the engine Rotary position of the rotary valve must always exactly match the rotational position of the motor power unit in the phase position, it makes sense that the number of teeth w and their rotational position on the shaft is exactly the same as the number of teeth a of the external teeth on the shaft on the power unit and its rotational position. Thus, the shaft can be mounted at all times, without having to pay attention to what rotational position it is, whereby the assembly is considerably simplified.

The proposed numbers of teeth a = 12, b = 14, c = ll, d = 12, w = 9, x = 10, y = 17 and z = 18 have the advantage with respect to the toothing for the eccentric gear that the toothing module becomes larger, the stability of the shaft in this area increases and in particular the negative-running speed of the eccentric axis of the eccentric disc drops sharply, resulting in a smoother running of the transmission. It is thereby accepted that the wobble angle is about larger, and dispenses with the above-described advantage during assembly.

Experiments have shown that very good results are achieved when the joint eccentricity of the ^'■ . Exzentergetriebes the 0.013 to 0.015-fold or 0.015 to 0.022 times the mean pitch circle diameter of the control slots in the control plate.

Since in the conventional machines with carding shaft between the rotary piston and the output shaft (of which currently about 1.2 million pieces are produced worldwide), the large hydrostatic radial force on the rotary piston completely absorbed by the teeth between the acting as a rotor rotary piston and the stator must be, is the Hertz'sehe pressure and thus the friction between them

Teeth very large, because the propeller shaft is known to absorb any radial forces. Especially at low speed and high working pressure therefore the friction losses and the wear of the teeth are extremely large. Therefore, the starting efficiency of these machines is correspondingly poor and is only about 63 to 71%.

For high working pressures - especially over 120 bar - it is therefore indispensable in these earlier designs with cardan shaft as a torque connection between the rotary piston and the output shaft, that the teeth of the internal teeth on the stator are formed by rollers in their precisely machined caverns in the stator by a transient hydrodynamic oil film are rotatably mounted. The rollers must be high hardness and best

Surface quality are performed, as well as the necessary precise caverns in the stator.

In the machine according to the invention, the radial load of the teeth between the rotary piston and the stator is only one

Fraction of the ratios described above, so that the pressure performance of the engine can be considerably increased even without roles in the stator. Nevertheless, it is also in the machine according to the invention advantageous if the usual roles in the stator are maintained, which leads to further increased printing performance and excellent life. Measurements have shown that in the machine according to the invention the starting efficiency and also the mechanical-hydraulic efficiency can be increased by 3 to 5% through the transition to rollers in the stator. The start-up efficiency reaches values of more than 90%.

When using the hydrostatic, low-speed high-torque motor according to the invention as a wheel motor, the output-side roller bearing requires a higher radial load capacity for additional reception of the wheel load. It should be located as close to the center of the wheel. Since, for example, in material handling equipment shock-like elevations of the static wheel load can occur, it is advantageous if this

Bearing is as close as possible to the wheel flange and optionally located outside the leakage space of the rotary engine with a rolling bearing grease permanent filling directly in the housing part of the rotary piston engine.

The rotary piston engine according to the invention is due to the advantageous bearing arrangement and the powerful continuous shaft, inter alia, excellent as a wheel motor or winch drive for direct driving a wheel or a cable drum. In this case, the shaft is preferably formed integrally with a wheel flange on which a wheel or a cable trench for direct drive can be mounted directly. The device according to the invention is described in more detail below purely by way of example with reference to concrete exemplary embodiments shown schematically in the figures, with further advantages of the invention also being discussed.

In detail show:

1 shows a first embodiment of a rotary piston engine with an eccentric gear in a longitudinal section along the section line C-C of Fig. 2,

Fig. 1.1 of a second embodiment of a

Rotary piston engine with a planetary gear in a partial longitudinal section along the section line C-C of Fig. 2,

1.2 is a cross section through the eccentric gear of the first embodiment of the rotary piston engine,

Fig. 2 shows a cross section along the section line D-D of Fig. 1 by the rotor-stator system of the first

Embodiment,

3 shows a cross section through the rotor-stator system of an embodiment with rotationally mounted rollers as internal toothing in the stator,

4 is a view X on Fig. 1 on an SAE connection of an embodiment, a partial section along the line A and a partial section along the line B of Fig. 3,

5 shows a longitudinal section through an embodiment of a wheel motor according to the invention, 6 shows a longitudinal section through a wheel motor according to the

Invention with coupled on the shaft parking brake as a multi-disc brake,

7 shows a longitudinal section through a wheel motor according to the invention with the second coupled to the shaft

Motor as 2/3-stage motor,

8 shows a cross section of the 2/3-stage motor along the section line E-E of Fig. 7,

9 shows a possible hydraulic circuit diagram for controlling the 2/3-stage motor according to FIG. 7 and FIG. 8 with exemplary technical data, FIG.

10 is a longitudinal section through an inventive rotary piston engine with a coupled to the shaft, large-dimensioned working brake as a multi-disc brake,

11 is a longitudinal section through an advantageous development of an inventive rotary piston engine with a circumferential axial relief groove on the axial sliding surface between rotary valve and balance piston,

12 is a cross-sectional view of the control mirror of the control plate of the rotary piston engine of FIG. 11,

Fig. 13 is a longitudinal section through the rotary valve and the

Balancing piston of the rotary piston engine of FIG. 11 in a detailed view and

14 is a left side view of the rotary valve and the balance piston of FIG. 13th In the following, possible embodiments with reference to several figures, which partially show a single embodiment in different views with sporadically different levels of detail, explained, reference being made in part to already mentioned in previous figures reference numerals.

Fig. 1 shows a first embodiment of an inventive rotary piston engine with a

Exzentergetriebe in a longitudinal section, while Fig. 2 shows a cross section through the rotor-stator system of the first embodiment along the section line D-D of Fig. 1. Furthermore, in FIG. 2 the cutting direction of FIG. 1 can be seen from the section line C-C in FIG. The rotor-stator system of the power unit 1 of the rotary piston engine comprises a centric fixed stator 4 with an internal toothing 5, hereinafter referred to as first internal toothing 5, into which an eccentrically arranged for performing an orbit movement, acting as a rotor rotary piston 6 with a hereinafter as first external toothing 7 called external teeth at least partially engages. A centrally mounted by means of two on both sides of the power unit 1 immediately adjacent bearings 10, 11 mounted shaft 2 has an external toothing 9 - the second external teeth 9 -, which in turn at least partially engages in an internal toothing 8 of the rotary piston 6, called the second internal toothing 8. The forward direction of rotation of the rotor-stator system of the rotary engine is defined for the following explanations as the direction of rotation in which the

Rotate the rotary piston 6 in the direction of rotation 60 and the shaft 2 in the direction of rotation 61 as shown in FIG. Accordingly, in FIG. 2, the expanding swallow cells lie between the first internal toothing 5 and the first external toothing 7 Always on the left and the compressing feed cells always to the right of an eccentric axis 62. Since the eccentric axis 62 performs one of the direction of rotation 61 of the shaft 2 and the direction of rotation 60 of the rotary piston 6 entgegensetze direction of rotation 64, creates a rotating field for the radial hydraulic force on the rotary piston 6, if always High pressure is supplied to the expanding swallow cells. The control of this rotating field worried a rotary valve 3 as a commutator, similar to a DC motor. To cause a forward rotation of a fluid - in particular pressure oil as working fluid - a high pressure port 55 in an inlet and outlet part 70 and thus a first annular space 56 is supplied, which surrounds the rotary valve 3 sealed. According to the numbers of teeth of the first internal toothing 5 of the stator 4 and the first external toothing 7 of the rotary piston 6 in the first

Embodiment, the rotary valve 3 has eleven evenly distributed on the circumference, with the first annulus 56 in communication high-pressure window 21a.

A control plate 22 with control slots 21 has twelve uniformly distributed on the circumference pressure window 33 a, which are connected via feed bores 33 with the twelve toothed chambers between the first internal toothing 5 of the stator 4. Because of the circumferential distribution eleven to twelve of the high-pressure window 21a of the rotary valve 3 and the pressure window 33a of the control plate 22 is always only one half of the tooth chambers of the stator 4 under high pressure, and that with the correct phase position of the rotary valve 3 with the rotary piston 6 always those tooth chambers, in of Fig. 2 are left of the eccentric axis 62. Since the rotary valve 3 between the high-pressure windows 21a evenly distributed identically designed low-pressure window 21b has, the other half of the twelve Zahnkammern- the stator 4 via connecting holes 58a having a ring grooves 108 and 109 second Annulus 58 and thus connected to a low pressure port 57, so that the compressing feed cells displace the fluid under low pressure in the low pressure side and thus in the low pressure port 57.

It should therefore be ensured that the separation axis of the rotary valve 3 in a high-pressure side and a low-pressure side as exactly as possible the same speed and direction of rotation as the rotor-stator system. This condition is met when the rotary valve is the same

Direction of rotation and the same speed as the rotary piston 6 has about its own axis. In the case of the rotary piston engine according to the invention, in a preferred embodiment, the shaft 2 is mounted roller-mounted directly in the housing on the left and right of the rotor-stator system, so that the drive of the rotary valve 3 must take place via the shaft 2, which due to the system performs a different rotational speed than the rotary piston 6. In the illustrated embodiment, the shaft 2 runs three times as fast about its axis as the rotary piston 6 about its own axis. Accordingly, the rotary engine according to the

Invention, a transmission between the shaft 2 and the rotary valve 3 with the same translation to slow. This can be done by means of an eccentric gear 30, as in the first embodiment according to FIG. 1 and FIG. 1.2, or by means of a planetary gear 80, as shown in a second embodiment according to FIG. 1.1.

Fig. 1.1 shows the second embodiment of an inventive rotary piston engine with a planetary gear 80 in a partial longitudinal section along the

The planetary gear 80 includes a sun gear 13 on the shaft 2, the shaft outer teeth 14 meshes with planetary gears 90, which ^{• are} mounted on a planet carrier 91, the 1: 1 with the rotary valve 3 torsionally rigid is coupled. The planet gears 90 mesh simultaneously with a fixed internal gear ring 92, which has twice the number of teeth as the sun gear 13 on the shaft 2. According to the laws of the planetary gear is then the translation of the shaft 2 to the rotary valve 3 exactly 3: 1 slow.

Preferably, however, as shown in the first embodiment in Fig. 1 and Fig. 1.2, a simpler constructed eccentric gear 30 is used, which includes a sun gear 13 on the shaft 2 with a Wellenaussenverzahnung 14 and a fixed inner ring gear 28, the inner teeth 17, hereinafter fourth internal toothing 17 called, compared to the number of teeth of the shaft outer teeth 14 double the number of teeth. Interposed is a disk-shaped eccentric 26, which has an internal toothing 15 in the interior - the third internal toothing 15 - and outside an external toothing 16, referred to as the third external toothing 16, has. Preferably, this eccentric gear 30 is executed with tooth shapes that allow the number of teeth difference between the shaft outer toothing 14 and the third inner toothing 15 and the third outer toothing 16 and the fourth inner toothing 17 is equal to 1. With involute teeth such transmissions are usually not feasible, as in this case, dental head interference takes place. Also, they do not allow exact radial centering of the wheels against each other under these conditions. It should therefore be resorted to other tooth shapes. In the example of FIG. 1.2, a double-cycloidal internal-external toothing is preferably used, as is known, for example, from German Patent DE 39 38 346, to which reference is hereby made. This eccentric gear 30 also has a reduction ratio between the shaft 2 and the disk-shaped eccentric 26 of exactly 3: 1 in the slow. As can be seen from Fig. 1, the disc-shaped eccentric 26 is 1: 1 rotationally connected via a cup-shaped connecting part 27 rotatably connected to the rotary valve 3, wherein Mitnehmerverzahnungen 31 and 32 allow the cup-shaped connecting part 27 together with the disc-shaped eccentric 26 a small wobbling movement corresponding to Exzenterbewegung the disc-shaped eccentric 26 performs. The backlash of the shaft outer teeth 14, the third internal teeth 15 of the eccentric 26, the third external teeth 16 of the eccentric 26, the fourth internal teeth 17 of the internal ring gear 28 and the Mitnehmerverzahnungen 31 and 32 are designed to be slightly larger than usual because of the wobbling motion.

In order for the rotary valve 3 to be rotatably but well sealed axially against leakage from the high pressure, an axial compensating piston 65 is provided in a known manner.

FIG. 3 shows a cross-section through the rotor-stator system of a further exemplary embodiment, in which rollers 81 mounted in rotation are used as the first internal toothing 5 in the stator 4. These rollers 81 should always be trapped in their cavities 82 in the stator 4, i. the caverns 82 should taper toward the shaft 2 beyond the roller radius so that the rollers 81 can not move radially inward out of the caverns 82. This would lead to a blockage of the rotary engine. In Fig. 3, the shape of caverns 82 is clearly illustrated.

As can be seen from Figs. 2 and 3, must in a compact construction of the inventive Rotary piston engine with correspondingly small

Partial diameter of the screws, the first internal toothing 5 of the stator 4 in the transition to rollers 81 are offset as teeth in the stator 4 by half a pitch, as shown in Fig. 3. This means that the feed bores 33 and the associated pressure windows 33a and control slots 21 are correspondingly offset on a pitch circle in the control plate 22. Therefore, it is advantageous if the number of teeth of Mitnehmverzahnungen 31, 32 is twice as large as the number of teeth c of the first outer toothing 7 of the rotary piston 6 of the power section 1. In this interpretation, the number of teeth of Mitnehmverzahnungen 31, 32 can then in all cases the rotary valve and the control plate 22 can be used without change. In the case of the preferred design with the numbers of teeth a = 12, b = 14, C = Il, d = 12, w = 12, x = 13, y = 23 and z = 24 or a = 12, b = 14, C = Il, d = 12, w = 9, x = 10, y = 17 and z = 18 would then be the number of teeth of Mitnehmverzahnungen 31, 32 with 22 to choose.

The housing parts, which include a bearing flange 25, the stator 4 and the input and Auslassteil 70 must be centered against each other during assembly. In Fig. 3 and in Fig. 4, which shows a view X on a SAE connection, a partial section along the line A and a partial section along the line B of Fig. 3, it is also shown that two of the twelve screws are designed as fitting screws 93, which are to be used in the assembly of the engine as the first. From Fig. 4 is also in the partial section A of Fig. 3 can be seen that the rotary engine should be designed very compact due to the specified by the international SAE standard hole patterns for mounting the engine so that dimensions and weight are optimized. A flange screw connection for the high and low pressure connection 55 or 57 according to SAE standard is also shown here ^' . " One application for the rotary piston engine according to the invention is the use as a wheel motor, as shown in its simplest form as a longitudinal section in FIG. 5. Extremely advantageous in this embodiment of a wheel motor is the formation of a driven-side roller bearing 11 outside a leakage space 85 directly in the housing part 84 of the engine. Since such wheel motors do not require high speeds, a permanent rolling bearing fat filling is sufficient as lubrication, which is sealed by a NILOS ring 72 to the outside. By this construction, it is possible that a wheel flange 40 can be made integral with the shaft 2, so that for large wheel loads, the shaft 2 is very robust ausbildbar.

In the case of a wheel motor according to FIG. 5, a right-handed and a left-handed version is usually required. Here, too, it is advantageous if the rotary valve can be offset during assembly by half a pitch, so that hereby with the same pressure connection and thus at the same flow direction of the working fluid, the direction of rotation of

Motors is reversible for the same physical operating conditions.

A hydrostatic wheel bearing usually requires a spring-loaded, automatically spring-loaded parking brake, which is independent of the hydraulic pressure, in order to prevent the parked vehicle from rolling away. Fig. 6 shows a possible realization of such a wheel motor in longitudinal section, in which on the side opposite the output a spring-loaded parking brake 42 is arranged in the form of a multi-disc brake. The inventive rotary piston engine allows advantageously a form suitable for large torques through shaft 2 with a large ^'sized wool extension 41 so that the slats of the parking brake 42 directly via a hub 73 can transmit their braking torque to the shaft 2. In this case, the shaft outer toothing 14 for the eccentric gear 30 is extended outwardly in manufacturing technology, on which the hub 73 can be wedged torque-effective torsionally effective. This spring-loaded parking brake 42 is a wet-running multi-disc brake, which can be released with greatly reduced hydraulic pressure via the separate port 43. As a spring, a plate spring 74 is provided here. As can be seen from Figs. 5 and 6, the fixed fourth

Internal toothing 17 for the eccentric gear 30 incorporated directly into the inlet and outlet part 70, e.g. by means of a gear-pushing machine or by means of a broach. This results in the advantage that the shaft outer teeth 14 on the shaft 2 in diameter is larger, so that the

Wave extension 41 receives a larger torque capacity. This is of particular importance, in particular with wide moving sets in the power unit 1, as explained below. Since with the broadening of the moving set of the power unit 1 and the torque transmitting second internal teeth 8 of the rotary piston 6 and the second external teeth 9 of the shaft 2 widened automatically, here the high pressure level can be largely maintained and thus an increase in performance can be achieved. In the machines with propeller shaft drive between the rotor and the output shaft, this is not possible. Therefore, there is usually only allowed a lower pressure level at wider Laufsätzen with the stator 4 and the rotary piston 6. Motors with wide Laufsätzen run because of the higher absorption rate usually slower, so that the life of the bearings 10 and 11 is not a major problem.

Increasingly, a so-called ^{'' • ■ • ■} "secondary control" is required in the market, not only in hydraulic wheel drives, but increasingly also with hydraulically driven winches. The aim is to increase the speed range at the output without having to increase the capacity of the pump in relation to the flow rate. This is called rapid traverse operation, which usually occurs with reduced torque requirements. In Fig. 7 and in Fig. 8, a hydraulic motor is shown in longitudinal section or cross section according to the invention, in which except the first power part 1 on an extended shaft end 44 of the shaft 2 a torsionally rigid coupled to the first power unit 1 second, preferably narrower power unit 46 is arranged with its own radial bearing 47, which can be operated via the ports 75 and 76 separately with working fluid, preferably from one and the same hydraulic pump. A proposal on the control of such a 2/3 stage motor with the first power section 1 and the second power section 46 is shown in Fig. 9 in the form of a hydraulic circuit diagram with exemplary performance data. By two separate 3/4-way valves 48 and 49 commercially available design can thus be driven at the same flow rate of a pump 83 up to three output speeds, as exemplified in Table 77. The forward and reverse positions of the 3/4-way valves are indicated by the letters F and R, respectively. It should be noted that the one motor stage that is switched to circulation and thus does not output torque, both on the displacement side, as well as especially on the intake side to be operated under high pressure, otherwise cavitation occurs at high speeds on the intake side. In the scheme shown in Fig. 9 this fact is taken into account. A throttle valve serves as a brake valve 87, in particular when driving downhill of the vehicle. By means of a valve 86, the operating state of the drive from operation D to neutral N can be switched. In Fig. 10, a further rotary engine according to the invention is shown in longitudinal section, which can of course also be designed as a wheel motor according to FIG. In the embodiment, a hydraulically releasable spring-loaded working brake 50, designed as a disk brake, is arranged on a shaft extension 52. This work brake 50, the braking force is applied by means of springs 78, for example, in a hydrostatically driven winch for car or ship cranes the task of keeping the full permissible Seijlast that corresponds to the maximum pressure and thus the highest torque of the engine in the balance , without support hydraulic pressure on the engine. The load should be able to be sensitively manipulated upwards and downwards, so that during the transition from upward to downward movement and vice versa the pressure oil inflow on the rotary piston engine has to be switched from primary to secondary. In this phase of change, the rotary engine has no torque because the pressure drops to zero. The spring-loaded work brake 50 takes over the holding torque at this moment and must therefore be designed so large that it can take over the maximum torque of the rotary piston engine. The size and number of springs 78 is to be sized accordingly, as well as the size and number of blades of the working brake 50. As can be seen from Fig. 10, a connectable via a separate port 51 to the high-pressure pump high-pressure piston 79 is provided in is able to release the working brake 50, provided that the applied pressure on the high-pressure piston 79 by overcoming the spring forces of the springs 78 is large enough. In practice, it has been proven that this pressure must be between 8 and 12 bar, so that the load does not drop until the required support pressure is built up on the rotary piston engine. It has been discussed a lot about whether such a large-sized brake for a high-torque motor, as it is present in the invention makes sense. The previous arrangement for such winch drives provides that instead of a rotary piston engine about a factor of 6 faster-running axial piston motor is used, which drives the sun gear of a planetary gear stage. Its torque is correspondingly smaller by a factor of 6. Between the axial piston motor and the planetary stage is then the correspondingly smaller by a factor of 6 dimensioned

Slider brake of the same type connected, similar to that shown in FIG. 10. During operation of the winch, which must be driven in rapid traverse for reasons of saving time, this small brake runs relative to the housing, for example with 6 times the speed as the big brake according to the invention.

Wet-running multi-disc brakes have a particular advantage because they can be connected to the oil cooling system of the entire system through the oil passage. In addition, they are largely abrasion-free, so that the oil pollution is low. The disadvantage is that with oil-filled brake considerable, oil viscosity caused, loss-producing slip performance. According to the Newtonian law of shear stress in an oil gap, the

Slip performance between two plates with the square of the relative speed, thus also between the running and fixed slats of a released brake. Assuming that when comparing the slip performance of a large brake according to FIG. 10 and a small one described above

Brake the oil viscosity, the thickness of the oil gap between the lamellae and the specific pressure on the lamellae are the same by the spring forces, then with the 6 times faster running, small lamellar brake this slip performance is about It is thus obvious that, apart from the less expensive solution, the compact version of a holding brake according to the invention together with the high-torque motor described here improves the overall efficiency of such a brake Winch causes.

For the axial hydrostatic balance and the reduction of the axial running gap to micrometer thickness between the

Control plate 22 and the rotary valve 3 on the one hand and between the rotary valve 3 and the axial balancing piston 65 on the other hand, see Fig. 1, very precise hydrostatic effective axial annular surfaces must be present. These are annular surfaces, which are defined by the respective average web diameter. They are not particularly marked in FIGS. 1, 5, 6, 7 and 10. However, as can be seen there, the diameter of the connecting holes 58a in the axial balance piston 65 and the subsequent holes in the rotary valve 3 are very small because the annular surface between the rotary valve 3 and the axial balance piston 65 is computationally relatively narrow. Although in the axial balance piston 65 very many such connection holes 58a are mounted on the circumference, so that the passage cross-section is relatively large. In contrast, in the rotary valve 3, the number of subsequent holes is very limited, because this must be based on the number of high-pressure windows 21a of the rotary valve 3.

This results in the problem that in these relatively small holes of the rotary valve 3, the flow velocity is very high. In hydraulics, the principle applies that at no point in the aggregate does the oil velocity in the high pressure range reach 10 to 12 m / s should exceed. Otherwise there will be strong turbulence, low static pressure according to Bernouilli's equation and possible cavitation damage to the canal walls. In addition, occurs at these locations at high flow rates on a disproportionate pressure drop, which reduces the performance and efficiency of the engine. Compared with known constructions, this disadvantage arises from the fact that in the inventive design, the rolling bearing right of the power unit has a large outer diameter. Thus, due to the system, the rotary valve 3 facing annular surface with the pressure windows 33a of the control plate 22 is relatively narrow (smaller diameter difference of the sealing webs). Accordingly, then the difference in the diameter of the mating ring surface between the rotary valve 3 and the axial balance piston 65 is smaller.

According to a development of the invention it is now proposed to move the counter-annular surface between the rotary valve 3 and the axial balancing piston 65 for the second annular space 58 in a smaller diameter range. In the event that the high pressure for the reverse direction of rotation is passed into the second annular space 58, the area of the annular surface must be the same for the balance of forces in this case as before. Thus, the

Diameter difference of the sealing webs considerably larger. In FIG. 11, which shows a longitudinal section through the advantageous development of the rotary piston engine according to the invention, these relationships are clearly shown. Starting from the central web diameter 95 and 96 of the control plate 22, see Figs. 11 and 12, and the corresponding central web diameters 97 and 98 of the rotary valve 3, see Figs. 11, 13 and 14, which are shown by the dotted lines, remains first the outer middle Stegdurchmesser 99 between the rotary valve 3 and the axial balancing piston 65, see FIGS. 11 and 13, the same, because this together with the web diameter 97 causes the force balance on the rotary valve 3 in the event that the high pressure is supplied to the first annular space 56. In the other case, that the high pressure is supplied to the second annular space 58, the axial balance of the rotary valve 3, the new, in the inner diameter annular surface is responsible, which is determined by the new average web diameter 100 and 101.

The two to the left in Fig. 11 and 13 acting on the rotary valve 3 with their respective hydrostatic compensating forces annular surfaces are now completely separate from each other. This is done according to the invention by a screwed between the middle web diameters 99 and 100 circumferential axial relief groove 102, as can be seen in Fig. 11 and 13. The axial relief groove 102 circulating on the axial sliding surface 110 between the rotary valve 3 and the axial compensating piston 65, see FIGS. 11 and 13, thus lies between the first annular space 56 surrounding the rotary valve 3 and the high-pressure port 55 and the annular grooves 108 and 109 of the second annulus 58 connected to the low pressure port 57.

So that this relief groove 102 is really their separating

Function, it is connected to the leakage space 85 through the communication hole 103. The relief groove 102 and its communication hole 103 may be attached both in the rotary valve 3 and in the axial balance piston 65.

For a better understanding of the commutation of the rotary valve 3 are in Figures 12 and 14, the required pressure window 33 a of the control plate 22 for supplying the tooth chambers of the power unit 1 and the high and Low-pressure window 21a and 21b shown in the rotary valve 3. The control plate 104 of the control plate 22, Fig. 12, between the pressure windows 33 a still sized blind windows 105 which are only a few tenths of a millimeter deep for a better isotropy of the lubricating film between the control mirror 104 and the rotary valve. 3

The advantages of this embodiment of the rotary piston engine according to the invention are considerable. A comparative examination of the conditions according to Figures 1, 5, 6, 7, and 10 and the further developed embodiment according to Figures 11 to 14 has shown that the diameter 106 of the bores in the rotary valve 3 can be increased by a factor of about 7/5 , Since this is the narrowest point in this flow system, this improvement means that the oil flow and thus the speed of the rotary engine at the same oil speed at this point can be increased to about double. At the same time, the flow resistance is reduced and thus the pressure loss, so that the efficiency increases. Since now also increases the diameter 107 of the connecting hole 58a in the axial balance piston 65 in about the same ratio, the flow loss is reduced there and the number of required connection holes 58a on the circumference of the axial balance piston 65 may be smaller, which

Saves manufacturing costs. The axial annular grooves 108 and 109 of the second annular space 58, see FIGS. 11 and 13, are enlarged in cross-section, which also contributes to a reduction of the flow losses. Overall, this improvement means a considerable increase in performance and a higher overall efficiency of the rotary piston engine.

Of course, it is possible, the development of the invention shown in FIGS. 11 to 14 with features previously to combine described embodiments and equip, for example, a wheel motor or a winch drive with the last-described further development features.

Claims

claims

1. Hydrostatic, low-speed rotary engine, with

• one acting as an output power section (1) ^π a central, stationary stator (4) d with a first inner toothing (5) with the number of teeth, ⁰ a rotary piston (6) with a partially engaged in the first internal toothing (5) first External toothing (7) with a number of teeth c and a second internal toothing (8) with a number of teeth b and ^D a centrally mounted shaft (2) with a partially in the second internal toothing (8) engaging second external toothing (9) having a number of teeth a, wherein the rotary piston (6) is arranged and dimensioned eccentrically for performing an orbital movement such that tooth chambers which can be supplied and disposed of with working fluid form between the first internal toothing (5) and the first external toothing (7), an inlet and outlet part (70 ) for the supply and disposal of the power unit (1) with the working fluid,

A disc-shaped rotary valve (3) for controlling the supply and disposal of the tooth chambers with the working fluid, an axial compensating piston (65) for sealing against leakage at the rotary valve (3),

• A gear transmission between a - in particular by a sun gear (13) formed - Welleaussenverzahnung (14) of the shaft (2) and a fixed inner ring gear (92) as a synchronous drive for the rotary valve (3) and • two on both sides of the power section (1) immediately adjacent to the shaft (2) arranged rolling bearings

(10, 11), characterized in that • the rotary valve (3) is mounted to the shaft (2) and to the stator (4) centric running,

• The gear transmission is arranged exclusively in the leakage oil area of the rotary piston engine and

• the gear transmission as a planetary gear (80) with at least one planet carrier (91) with the

Rotary valve (3) is rotatably connected and on which planetary gears (90) between the shaft outer toothing (14) and the stationary inner ring gear (92) are arranged is formed.

2. Hydrostatic, low-speed rotary engine, with

• one acting as an output power section (1) ^π a central, stationary stator (4) d with a first inner toothing (5) with the number of teeth, ^π a rotary piston (6) with a partially engaged in the first internal toothing (5) first External toothing (7) with a number of teeth c and a second internal toothing (8) with a number of teeth b,

° a centrally mounted shaft (2) with a partially in the second internal toothing (8) engaging second external toothing (9) having a number of teeth a, wherein the rotary piston (6) for carrying out a

Orbit movement is so eccentrically arranged and dimensioned that with working fluid ver and disposable dental chambers between the first

Internal toothing (5) and the first external toothing (7) form, An inlet and outlet part (70) for the supply and disposal of the power part (1) with the working fluid,

A disk-shaped rotary valve (3) for controlling the supply and disposal of the tooth chambers with the working fluid,

An axial compensating piston (65) for sealing against leakage at the rotary valve (3),

• A gear transmission between a - in particular of a sun gear (13) formed - Welleaussenverzahnung (14) of the shaft (2) with a number of teeth w and a fourth internal toothing (17) of a fixed internal gear (28) with a number of teeth z as a synchronous drive for the rotary valve (3), and

• two on both sides of the power section (1) immediately adjacent to the shaft (2) arranged rolling bearings

(10, 11), characterized in that

• the rotary valve (3) is mounted to the shaft (2) and to the stator (4) centric running, • the gear mechanism is located exclusively in the leakage oil area of the engine and

• The gear transmission as an eccentric (30) with an eccentric (26) which is rotatably connected to the rotary valve (3) is formed.

3. Hydrostatic, low-speed rotary engine according to claim 2, characterized in that

• the eccentric gear (30) as a wobble gear and • the eccentric disk-shaped eccentric (26) which is rotatably connected via a cup-shaped connecting part (27) with the rotary valve (3) via Mitnehmerverzahnungen (31, 32) in the speed ratio of 1: 1, is trained.

4. Hydrostatic, low-speed rotary piston engine according to claim 2 or 3, characterized in that the eccentric (26)

A third internal toothing (15) having a number of teeth x and a third external toothing (16) having a number of teeth y,

Between the shaft outer toothing (14) and the fourth internal toothing (17) is arranged and

• with its third internal toothing (15) meshing with the shaft outer toothing (14) of the shaft (2) and with its third external toothing (16) with the fourth internal toothing (17) of the fixed internal gear rim (28).

5. Hydrostatic, slow-speed rotary engine according to claim 4, characterized in that the numbers of teeth (a, b, c, d) of the power unit (1) and the numbers of teeth (w, x, y, z) of the eccentric (30) the equation b , x

-'D ~ c - z ~ y a_jw d-c z-y and this equation expression is a positive integer.

6. Hydrostatic, slow-speed rotary engine according to claim 5, characterized in that the positive integer is equal to 3.

7. Hydrostatic, low-speed rotary engine according to claim 6, characterized in that the eccentric gear (30) is designed such that the ratio between the rotational speed Ne of the eccentricity (20) of the eccentric (30) and the rotational speed Nw of the shaft (2) the equation

Ne_w-y Nwx-z~w-y is between -3 and -9.

8. Hydrostatic, slow-speed rotary engine according to claim 5 to 7, characterized in that the number of teeth (a, b, c, d) of the power unit (1) is equal to a = 12, b = 14, c = ll and d = 12 and the Number of teeth (w, x, y, z) of the eccentric (30) is equal to w = 12, x = 13, y = 23 and z = 24.

9. Hydrostatic, low-speed rotary piston engine according to claim 5 to 7, characterized in that the number of teeth (a, b, c, d) of the power unit (1) is equal to a = 12, b = 14, c = ll and d = 12 and the Number of teeth (w, x, y, z) of the eccentric gear (30) is equal to w = 9, x = 10, y = 17 and z = 18.

10. Hydrostatic, low-speed rotary piston engine according to one of claims 2 to 9, characterized in that the common eccentricity (20) of the eccentric gear (30) the 0.013 to 0.015 times the mean pitch circle diameter of Steuerschlitzen- (21) in a control plate (22). is.

11. A hydrostatic, low-speed rotary piston engine according to any one of claims 2 to 9, characterized in that the common eccentricity (20) of the eccentric (30) the ^" 0.015 to 0.022 times the mean pitch circle diameter of control slots (21) in a control plate (22 ).

12. Hydrostatic, low-speed rotary piston engine according to one of claims 2 to 11, characterized in that the number of teeth of the Mitnehmerverzahnungen (31, 32) between the eccentric (26) and the rotary valve (3) is twice as large as the number of teeth c of the first outer toothing (7) of the rotary piston (β) of the power unit (1).

13. Hydrostatic, low-speed rotary piston engine according to claim 1 to 12, characterized in that the first internal toothing (5) of the stator (4) is formed by rotationally mounted rollers (81).

14. A hydrostatic, low-speed rotary piston engine according to one of claims 1 to 13, characterized in that on a shaft extension (41) of the shaft (2) on that of the aborting side of the shaft (2) opposite side of the shaft (2) a spring-loaded parking brake ( 42) is arranged, which is hydraulically unlocked via a separate connection (43).

15. Hydrostatic, slow-running rotary engine according to one of claims 1 to 13, characterized in that on a shaft extension (52) of the shaft (2) on that of the abortive side of the shaft (2) opposite side of the shaft (2) a spring-loaded working brake (50) is arranged, which via a separate terminal (51) the working pressure of the rotary engine is unlocked.

16. Hydrostatic, low-speed rotary piston engine according to one of claims 1 to 13, characterized in that on an extended shaft end (44) of the shaft (2) on that of the abreibendes side of the shaft (2) opposite side of the shaft (2), a second power unit (46) is arranged, which is rotationally rigidly coupled to the first power part (1) and in particular a separate radial bearing (47) for the extended shaft end (44).

17. Hydrostatic, low-speed rotary engine after

Claim 16, characterized in that the specific absorption amount of the second power part

(46) is designed substantially smaller than that of the first power section (1).

18. Hydrostatic, low-speed rotary piston engine according to claim 16 or 17, characterized in that the first power part (1) and the second power part (46) by two separate 4/3-way valves (48) and (49) are switchable.

19. A hydrostatic, low-speed rotary piston engine according to claim 18, characterized in that the respectively switched on circulation power unit (1, 46) is switchable under supply pressure both on the diverging and on the converging side of the swallow or displacer system.

20. A hydrostatic, low-speed rotary piston engine according to one of claims 1 to 19, characterized in that on the abreibendes side of the shaft (2) a wheel bottle (40) is arranged rotationally fixed, for direct drive on the wheel flange (40) can be arranged wheel.

21. A hydrostatic, low-speed rotary piston engine according to claim 20, characterized in that the output side roller bearing (11) of the two sides of the power unit (1) immediately adjacent to the shaft (2) arranged rolling bearing (10, 11) outside the leakage space (85) of Rotary piston engine with a rolling bearing grease permanent filling is arranged directly in the housing part (84) of the rotary piston engine.

22. Hydrostatic, low-speed rotary engine according to claim 20 or 21, characterized in that the wheel flange (40) is integral with the shaft (2).

23. Hydrostatic, low-speed rotary engine according to one of claims 1 to 13, characterized in that an encircling axial relief groove (102) is provided on an axial sliding surface (110) between the rotary valve (3) and the axial balancing piston (65), which between a first annular space surrounding the rotary valve (3) and connected to a high pressure port (55) 56) and annular grooves (108, 109) of a low-pressure connection (57) connected to a second annular space (58).

24. Hydrostatic, slow-speed rotary engine according to claim 23, characterized in that the axial relief groove (102) through a connecting bore (103) with the leakage space (85) of the rotary piston engine is in communication.

25. Hydrostatic, low speed rotary engine according to claim 24, characterized in that the relief groove (102) and the connecting bore (103) in the rotary valve (3) are arranged.

26. Hydrostatic, Landsamming rotary engine according to claim 24, characterized in that the relief groove (102) and the connecting bore (103) in the axial balancing piston (65) are arranged.

27. Hydrostatic, low-speed wheel motor, characterized by a hydrostatic rotary piston engine according to one of claims 20 to 22, wherein on the wheel flange (40) is arranged a directly drivable by the hydrostatic rotary piston engine wheel.

28. A hydrostatic, low-speed winch drive, characterized by a hydrostatic rotary piston engine according to one of claims 20 to 22, wherein on the wheel flange (40) is arranged a drivable directly from the hydrostatic rotary piston engine cable drum.