SE447412B - HYDRAULIC CONVERTER WITH A HYDRAULIC ENGINE ON A PRIMARY SIDE AND A HYDRAULIC PUMP ON A SECOND SIDE - Google Patents

Description

DJ 447 412 by using slide control valves or shut-off valve systems, and more rarely also by adjusting the pump's separate control device.

Both systems have the same disadvantage that if a pump is to be kept in operation, simultaneous parallel operation of several independent control elements is possible only with the aid of additional special elements permitting this mode of operation as well as by using flow deflectors, flow stabilizers and the like. For this reason, this system becomes too cumbersome and very expensive.

The present invention eliminates the disadvantages of the prior art system and provides a hydraulic transducer in which road and quantity control is realized by means of simple technical means and whose control device from case to case also enables integration of pressure limiting and flow deflector functions.

A hydraulic transducer of the type specified in the preamble of the appended main claims is characterized according to the present invention by the special features specified in the characterizing part of the claim.

Volume control is performed according to the invention by changing volume characteristics. As a result, previously open circuits or sub-circuits can be converted to closed circuits, whereby the energy loss of the system is reduced to a minimum value. During operation, there is proportionality between the changes in working volumes and the changes in the quantities of oil transported.

The hydraulic machines according to the invention used as motor or pump preferably work according to the displacement principle. With the maneuverable element displacing the element in the zero position, the liquid transport is equal to zero. If the actuator is displaced past the zero position to the negative position, liquid transport occurs in the opposite direction¿ and the quantity transported changes proportionally to the changeover of the actuator. This results in directional reversal and the desired speed is set in proportion to the changeover of the actuator.

It is also possible to combine the different embodiments according to claims 1-H with each other, e.g. by coupling a hydraulic motor trained as a wing machine 3,447,412 to a hydraulic pump 1 formed as an axial piston machine 1, corresponding to the principle of the invention.

The hydraulic transducer trained according to the invention is significantly more advantageous than previously known constructions, because both setting possibilities, ie. the setting option for the hydraulic motor on the primary side and that for the hydraulic pump on the secondary side enables a significantly larger control range and at the same time the significant energy losses associated with e.g. with a strangulation.

By using the invention, it is possible to use a central pump without a flow distributor valve even in such cases, in which at the same time several independent working means are to be operated and regulated separately. If several hydraulic transducers are connected in a row on the primary side, this makes it possible to realize separate sub-circuits.

For speed control in closed circuits, the use of a hydraulic converter is economically more favorable than the use of controllable motors or pumps. The hydraulic converter is trained with a fixed volume pump and with a motor. In the hydraulic transducer trained in accordance with the present invention, the change or setting of the geometry of the working space is feasible mechanically, electrically, hydraulically, pneumatically or by manual operation. With reference to the accompanying drawing, various embodiments of the hydraulic transducer according to the invention are described below as examples. In the drawing Fig. 1 shows such an embodiment of the hydraulic converter according to the invention with hydraulic machines designed as wing machines, Fig. 2 another embodiment according to the invention with hydraulic machines designed as axial piston machines, Fig. 3 an embodiment according to the invention in which hydraulic machine as radial piston machines, Fig. Ü another embodiment according to the invention, in which both the hydraulic motor and the hydraulic pump are formed as hydraulic wing machines with rotors arranged in each other, and Fig. 5 a section along line AA in Fig. 4.

In the embodiment of the hydraulic converter according to the invention shown in Fig. 1, the hydraulic motor 1 on the primary side and the hydraulic pump 2: on the secondary side are similarly formed as winding machines with rotors 3 and 3, respectively. 6, wings 8 which are radially displaceable in the rotors and stator rings Ä resp. 5, which cooperates with the wings for displacement of these and is arranged eccentrically in relation to the corresponding rotor 3 resp. 6. The hydraulic motor 1 and the hydraulic pump 2 or their rotors 3 resp. 6 are connected to each other via a common shaft 7. In this embodiment, the volume characteristics of the hydraulic motor 1 and the hydraulic pump 2 are adjusted by radially adjusting the stator rings H, 5 in relation to their corresponding rotors 3 and 3, respectively. 6, ie by adjusting the eccentricity. Conversion means suitable for the purpose are previously known, whereby their construction is not discussed in more detail below. The hydraulic motor 1 is driven via a central pump_ (not shown).

The rotor 6 of the hydraulic pump 2 is driven via the shaft 7 by the rotor 3 of the hydraulic motor 1, the actuator or actuator (not shown), which is connected in the hydraulic circuit, is driven by the hydraulic pump 2.

In the embodiment according to Fig. 2, both the hydraulic motor 1 and the hydraulic pump 2 are formed as hydraulic axial piston machines with inclined discs 28, axial pistons 23 and a common shaft 25, which interconnect their rotors 2U. Change of resp. The working volumes of machines are carried out on both sides by angular adjustment of the corresponding inclined disc 28 by means of the adjusting member 29, which is driven by the associated control unit 22. Depending on which adjusting member 29 is operated, the angular setting of the associated inclined disc 28 changes and thereby the geometric working volume on the primary side and / or secondary side of the hydraulic transducer.

In this embodiment, the primary side is trained as an energy converter with an unambiguous flow direction. Under the action of the uniform flow of the hydraulic fluid, the rotor 23 of the hydraulic motor 1 is set in rotation by means of its pistons 23, so that the secondary side, i.e. the pump rotor, is driven via the common shaft 2§. As a result, a certain amount of liquid is transported with a certain pressure from the secondary side and through the distribution unit 26, which is arranged centrally between the hydraulic machines. The pressure and volume of the pumped liquid is proportional to the ratio between the geometric working volumes of the primary side and the secondary side. when the energy converter on the secondary side is reversibly trained, so that there is a possibility to steplessly change the amount of hydraulic fluid in both the transport directions between zero and In the case of FIG. 3 illustrates the embodiment of the new hydraulic converter, both the hydraulic motor 1 on the primary side and the hydraulic pump 2 are connected in a heap via a common shaft 3ß and between which a central I distribution pin 39 is inserted. In the embodiment shown, the radial pistons 36 are formed as spheres, while the linear ones, in which the spheres are displaceable, are hollowed out like radial rings in the rotary shaft 35 which sit on the common axis. The pistons, however, are, as usual, also designed as cylindrical pistons. The adjusting means 32 are connected to a control unit 31. The hydraulic transducer is closed at both ends by a cover 33, in which the shaft 3U is rotatably mounted and which are connected to housing rings 38, which surrounds the stator rings 37 of the hydraulic machines, and with a distribution unit 59, which is common to both hydraulic machines and which is arranged axially between them, into a compact crank unit.

The function of this embodiment is completely identical to the embodiment of the axial piston machines. The deviation consists in that in the embodiment according to Fig. 3 the eccentricity between the associated rotor 35 and its stator ring 37 is changed by the alternative movement of the adjusting member 32, while according to Fig. 2 the position of the inclined disc 28 is adjusted.

Figures H and 5 show a hydraulic transducer in which the hydraulic motor 1 as well as the hydraulic pump 2 are designed as wing machines which are inserted radially into each other. The hydraulic motor 1 on the primary side has an annular rotor 47 with radially inwardly directed wings 50 which cooperates with the radial outside of a stator ring H8 inserted in the annular rotor # 7, which stator ring 48 simultaneously serves as the externally located stator of the hydraulic pump 2, wherein the rotor H9 of the hydraulic pump 2, which is arranged inside the stator ring ÄB, is formed with radially outwardly directed wings 51. The rotor H7 of the hydraulic motor 1 and the rotor H9 of the hydraulic pump 1 are fixedly connected 447 412 6 gi / \ -; __, __ »- with vapggdra by means of dough common end plate 43; Depending * on // excegtíïëísetÉB, n6šÉštatorringen H8, which is common to the engine nafz ..í ”6eh * §ímšenñš, is obtained on the primary side a specific fluid through- * _ / liïšlglöaeíššr operation of the engine 1 rotor Ä? via the rotor blades Sh or _4on the secondary side a determined by the pump 2 wings-51 \ pumped amount of liquid. '”_T * r-a U. . . . . . ~ «~” '”' / Ø / - / In this form of automation, the M8 of the stator ring M8 is eccentr1c1tet-I“ in relation to the centric rotors H7, H9 which can be adjusted by means of the adjusting means ï which is controlled by the common control unit H1. In this embodiment; J; = g. . It is important to simultaneously change the geometric arrays of both hydräüïñäškinšr at the primary side and the secondary side. Because the geometric work volumes on the primary side and on the secondary side change at the same time, the possibility of changing the direction of rotation is eliminated.

The invention is not limited to the embodiments shown and described. Where applicable, the primary side is feasible with deviation from the secondary side. In particular, the following embodiment forms a favorable solution in some cases: the hydraulic motor is trained as an axial piston machine with a constant working volume, while the hydraulic pump is trained as a wing machine with a variable working volume. Of course, other combinations of different types of prior art hydraulic machines are also useful.

The hydraulic transducer trained according to the invention is advantageously useful in currently used hydraulic systems.

IN!

Claims (5)

447 412 Patggtkrav Hydraulic converter with a hydraulic motor (1) on a primary side and a hydraulic pump_ (2) on a secondary side. feel that the drive end of the hydraulic motor (1) and the driven end of the hydraulic pump (2) are non-rotatably coupled to each other (shaft 7. 25. 34. clutch disc 54). and that the hydraulic motor (1) and / or the hydraulic pump (2) is designed as a hydraulic machine with adjustable working volume for any pressure increase or pressure reduction from the primary side to the secondary side. A hydraulic transducer according to claim 1, characterized in that at least one of the hydraulic machines. formed by the hydraulic motor (1) and the hydraulic pump (2) is designed as a wing machine. whose stator ring (5) cooperating with the wings (3, 6) of the rotor (3, 6) is radially adjustable in relation to the rotor (Fig. 1). 3. '3. Hydraulic transducer according to claim 1, characterized in that at least one of the hydraulic machines. formed by the hydraulic motor (1) and the hydraulic pump (2). is trained as an axial piston machine with adjustable bevel (28) (fig. 2). Hydraulic transducer according to claim 1, characterized in that at least one of the hydraulic machines. formed by the hydraulic motor (1) and the hydraulic pump (2) is designed as a radial piston machine. whose stator ring (37) cooperating with the pistons (36) of the rotor (35) is eccentrically adjustable relative to the rotor. Hydraulic transducer according to Claim 2, characterized in that the hydraulic motor (1) and the hydraulic pump (2) are designed as wing machines, the hydraulic motor (1) having a rotor (47) with internal wings and one inside the rotor. inserted stator ring (48). which at the same time forms an externally arranged stator ring for the rotor (49) of the hydraulic pump (2) with external wings and is adjustable relative to the concentric of the hydraulic rotor and the hydraulic 447 412 = pump. arranged rotors (47. 49). which are connected to each other via a coupling disc (43) (Figs. 4 and S). L: