DE969121C - Arrangement for controlling infinitely variable hydrostatic pumps, fluid motors or gears - Google Patents

Description

Arrangement for controlling infinitely variable hydrostatic pumps, Fluid motors or gears The invention relates to an arrangement for controlling infinitely variable hydrostatic pumps, liquid motors or Transmission, the adjustable part of which can be adjusted by a hydraulic booster learns whose control member is moved by a switching element. The hydraulic one The purpose of the amplifier is to develop the adjustment forces, which are sometimes considerable Achieve values. The hydraulic booster control member requires only one low actuating force. The switching element therefore does not need to develop a great deal of force and can be designed accordingly light and small. In particular, it can therefore adjust directly by a measuring element that does not have to apply a large actuating force able. The switching element must, however, be able to control the control element in both Control directions to move. In order to be able to achieve this in a simple manner, according to the invention on the control element of the amplifier either as a result of incomplete hydraulic relief of this control member or by a spring that is on the one hand on the hydraulically driven booster member and on the other hand on the control member of the amplifier is supported, a force is constantly exerted in the direction of the switching element, which produces a frictional connection between this and the control member.

The amplifier can be used in a manner known per se. from a hydraulic Piston and consist of a hydraulic control member that is movable on the same axis. Special The invention offers advantages when applied to an arrangement for controlling continuously adjustable gear, the pump part and motor part of which their adjustment by a common Learn switching element, for example by a common cam drum. Until now In this case it was necessary to use the cam drum with positive locking To provide cam grooves, each of which on its associated control member of the pump part or motor part is able to exert a force in both steep directions. A margin-free, precise production of such thrust cam grooves is expensive and time consuming. According to the invention this deficiency is avoided by the fact that the common switching element Control elements of two power amplifiers for adjusting the pump part and motor part be operated. This also offers the advantage that the common switching element Can be adjusted with separate radial gears without significant effort.

The common switching element can be used in the known manner as a control drum be formed. This is then axially parallel to the force amplifiers arranged. Since according to the invention on the control member constantly a force in the direction is exercised on the control drum, this control drum no longer needs how earlier to be provided with thrust cam grooves on their circumferential surface, but it can with its edge designed as a thrust curve on the control members of the two Power boosters work.

According to the invention, it is also possible to use the common switching element act with separate radial curves on the two control elements of the power amplifier allow.

The invention also has the advantage that it is a simple Preselection enabled. This can be achieved by hydraulic driven amplifier member is mechanically or hydraulically locked and in locked state to the control member of the amplifier one of the stroke to be amplified corresponding movement is granted, which only after releasing the lock of the hydraulically driven amplifier member is followed.

The power booster can also be used as a torque booster be designed that the hydraulically driven amplifier member and its control member are rotatable coaxially to the switching element and form a torque amplifier, which amplifies the torque adjusting the switching element on the adjustable one Transferring part of the pump or the liquid motor.

In the drawing, two exemplary embodiments of the invention are shown, namely Fig. I shows two power amplifiers controlled by a common switching element to adjust the delivery rate of the pump part and to adjust the swallowing capacity of the motor part of a fluid transmission and FIG. 2 shows a modified embodiment of the switching element belonging to FIG. i In Fig. I left are schematically the Pump part and the motor part of a fluid transmission shown, each as Vane pump are designed. The runners of the pump part and the motor part are mounted on a fixed axis, while the housing is relative to this axis can be adjusted with regard to their eccentricity. Through this adjustment the delivery rate of the pump part or the absorption capacity of the motor part changes. In Fig. I the two rotors of the pump and motor part are indicated by circles Io and the adjustable housing indicated by circles II. Adjustment of the housing II is carried out by a hydraulic booster, the control element of which is 12 or II2 is moved by a switching element.

First, the hydraulic booster of the engine part will be described.

The hydraulic booster consists of one in the present case stationary cylinder I6, a displaceable therein and with the housing II through Rod 18 connected piston 17 and from a sleeve-shaped control slide I9, which is rigidly connected to the control member 12.

The arrangement is made so that the piston i7 the command movement of the control member 12 simulates with the least possible delay.

For this purpose, the cylinder 16 has an inner annular groove 21 which is connected to a pressure line 23 through a channel 22 and a second inner annular groove 2q. The piston rod 18 passes through one end wall of the cylinder 16. The other end wall of the cylinder 16 has an opening through which the control member i2 protrudes. This control member is attached to the control slide bushing i9, which is fitted with a sliding fit in the cylinder 16, covers the two annular grooves 21 and 24 and receives a control piston 28 which is rigidly connected to the piston 17 by a shaft 29. The spaces on both sides of the piston 28 and the spaces to the right of the socket i9 are in constant communication through channels 30. The cylinder space to the left of the piston 17 is connected to the pressure channel 22 by a branch channel 3i. Finally, the socket i9 has two inner annular grooves 32 and 33 arranged at a distance from one another. The groove 32 is constantly connected to the groove 2i through radial bores in the socket i9. In a corresponding manner, the groove 33 is constantly connected to the groove 2.4 through radial channels in the socket i9. The length of the piston 28 essentially corresponds to the distance between the left edge of the groove 32 and the right edge of the groove 33.

The mode of operation of this hydraulic booster is as follows: In the position shown, the grooves 32 and 33 are closed by the piston 28. The cylinder space to the right of the piston 17 is therefore separated from the pressure line 23 and from the discharge line 26. The piston 17 - is therefore blocked by the amount of liquid enclosed on the right of it and stands still. It is now assumed that the control member 12 moves to the left, which can happen without substantial fluid resistance because the bores 3o compensate for the pressure prevailing on both sides of the socket 19. Then the right side of the piston 17 is connected via the exposed groove 32 to the pressure line 23, with which the cylinder space located to the left of the piston 17 is also connected through the branch line 31. Since the right side of the piston is larger than the left ring surface, the pressure acting on the piston I7 to the left predominates and drives the piston 17 and with it the piston 28 to the left until the piston 28 has closed the groove 32 again.

It is now assumed that the control member 12 differs from that shown in FIG Position is adjusted to the right. As a result, the right of the control piston 28 The space located through the longitudinal bore 3o of the control piston with the cylinder space is in communication to the right of the piston 17, connected to the discharge channel 26. Of the Piston 17 is therefore relieved of pressure on its right side and is through the its left side flowing oil flow from the pressure line 23 and the channels 22 and 3I driven to the right. Here he takes the control piston 28 with, so that this closes the groove 33 again. So the hydraulic booster works so that the housing II is adjusted in exactly the same way as if it were with the control member 12 rigidly connected, but without affecting the control member I2.

Now both sides of the socket I9 are under the same Fluid pressure thanks to the arrangement of the balancing bore 3o, but both have Pages different surfaces because the left side is the full internal cross-section of the Cylinder 16 corresponds, while the right side, in contrast, to the cross section of the control member I2 is reduced. So there is a little more pressure the socket I9 to the right than to the left. This pressure difference causes the control member 12 moved to the right and held in frictional connection with the switching element.

For explanation it should also be noted that the pressure to the right of the piston 17 in the steady state compared to the pressure from the left of the piston I7 automatically adjusts to the ratio that the two surfaces of the piston I7 have to one another. If the control sleeve I9 moves to the left, the full auxiliary pressure from the line 23 prevails to the right of the piston 17; If the control sleeve I9 is moved to the right at high speed, this pressure can temporarily drop to zero. However, this state only lasts until the after-running of the piston 28 has led to the pressure being built up again, which happens immediately.

The power amplifier used to adjust the pump part with the Control member 112 is designed somewhat differently. There the frictional connection between the control member II2 and the switching element maintained by a spring.

The cylinder II6 has a bore 35 of larger diameter on the left Receipt of a piston I 17 and on the right a bore 1:24 smaller diameter, which are both separated by a wall 37. The hole 124 is right through a Cover 38 completed, which has an opening for the passage of the control member II2. The piston. II7 is connected to the housing II of the pump part by a piston rod 118 tied together. The bore 35 has an inner annular groove 121 which is attached to a branch 122 of the Pressure line 23 is connected.

The piston 117 has an axial bore open to the right for receiving a piston slide 128 rigidly connected to the control member II2, which protrudes through a central opening in the wall 137 into the bore I24 and is penetrated by compensating bores I3o, which form the spaces on both sides of the piston slide 128 constantly connect and are also connected to annular grooves 39 and 4o of the piston valve. The spaces connected by these compensating bores 130 are now constantly connected to the discharge line 26 through a branch 125 which opens into the cylinder bore 124.

Between the two annular grooves arranged at some distance from one another The piston valve has 39 and 40, which are constantly connected to the drain line 128 an annular groove 132. This is constant through radial bores in the piston II7 connected to the annular groove 12I and thereby to the pressure line I22. The spool sections, which lie between the grooves 132, 39 and 40, close in the illustrated Central position two annular grooves 41 and 42, which are arranged in the inner wall of the piston 117 are. The annular groove 41 is constantly with the right side through a longitudinal bore 43 of the piston 117 connected, while the annular groove 42 through a longitudinal bore 44 of the Piston wall is constantly with the left side of the piston 117 in communication.

A is supported on the left end face of the piston valve 128 Helical spring 45 which rests on the bottom of the axial bore of the piston 117 and the control member 112 keeps in constant contact with the switching member.

The mode of operation is as follows: When the control member 112 moves to the left is the left side of the piston 117 via 44, 42, 40, 13o, 124, 125 and 26 switched to drain, while the right side of the piston 117 via 43, 41, 132, 121, 122 and 23 is pressurized with oil. As a result, the piston will run 117 to the left until the two grooves 41 and 42 are closed again. The reverse Switching action occurs when the control member 112 is displaced. So here too the piston 117 simulates the movement that is predetermined for it by the control member 112 without being able to exert any force on this control member goes beyond the bias of the spring 45. This arrangement offers the advantage that the control member 112 at all times with the same invariable force to the Switching element is pressed.

In the embodiment shown is for the two control members 12 and 112 of the two power amplifiers of the pump and fluid motor common Switching element in the form of a shaft 5o with two radial cam disks 51 and 52 intended. The two cams are shown in plan in FIG. although in reality they are of course perpendicular to the plane of the drawing, so perpendicular to their common axis 5o. This can be adjusted using a hand crank 53.

The two cam disks 51 and 52 are expediently known Way profiled so that each of the two cam profiles from one to Axis concentric circular arc is formed and that only one of the two Control members 12; 112 - rests against this circular arc. That has the effect that at a rotation of the hand crank 53 only one of the two control members 12, 112 is adjusted. Here, the control member 12 assumes the left end position in which the motor part is set to the largest displacement, while the pump part is adjusted by the control member I12, and the motor part learns through the control member 12 its adjustment; while at the same time the pump part to the highest flow rate is set by the control member 112. The control can be designed in this way be that the pump part through its central zero position through in both directions is adjustable to enable a reversal of the engine part.

Switching on the power amplifier has the advantage that the switching element 50, 51, 52 is very easy to adjust and, thanks to its simple shape, no significant Requires manufacturing cost.

In Fig. 2 is another embodiment of the common switching element shown. This is designed as a control drum 15o, which has a handle 153 and can be rotated about an axis 154. This axis runs parallel to the two power amplifiers. The two control members 12 and 112 are frictionally engaged at the curves 151 and 152 of the control drum I5o.

Devices can be provided for the purpose of preselection control to lock the hydraulically driven booster member 17 and 117, respectively. This locking can be brought about mechanically or hydraulically, z. B. by closing organs in channels 31 and 44. As long as this: - organs closed are, the pistons 17 and 117 cannot move when the switching element 5o, 51, 52 or I5o, 151, 152 adjusted. With the help of this adjustment you can first preselect the transmission ratio of the gearbox. After the preselection has ended you then only need the locking by opening the closure organs in the channels 31 and 44 to solve. Then pistons 17 and 117 will immediately move in the position that instructed them by the adjusted control members 12 and 112 is.

If rotatable members are used to adjust the transmission, e.g. B. screw spindles, so the amplifiers can be used as mechanical or hydraulic torque amplifiers be designed for which the most diverse configurations are known. Of course In this case, the control members are also rotatable instead of displaceable. While at In the illustrated embodiment, the pressure oil is supplied by a gear pump 55 that can be coupled to the input shaft of the transmission, the arrangement can also be taken so that the lines 23 and 26 to the liquid circuit of the transmission are connected. In this case, the hydraulic fluid is to operate the power amplifier supplied by the fluid transmission itself.

The two amplifiers described are to be regarded as examples. They can be used in the same design on the pump and motor side.

Claims (7)

PATENT CLAIMS: I. Arrangement for controlling continuously variable hydrostatic Pumps, fluid motors or gears, the adjustable part of which can be adjusted experiences through a hydraulic booster, the control element of which through a switching element is moved, characterized in that the control member (12, 112) of the amplifier either as a result of incomplete hydraulic relief of this control element or by a spring (45) on the one hand on the hydraulically driven booster member (117) and on the other hand supported on the control member (112) of the amplifier, constantly one Force is exerted in the direction of the switching element (5o, 51, 52, 15o, 151, 152), which produces a frictional connection between this and the control member (12, 112). 2. Arrangement according to claim I, characterized in that the amplifier in itself known way from a hydraulic piston (17, 117) and from an equiaxed there is also a movable hydraulic control member (12, I9, 112, 128). 3. Arrangement according to claim I and 2 for controlling continuously variable transmission, the pump part and motor part of which experience their adjustment by a common switching element, characterized in that the control members (50, 51, 52, 150, 151, 152) by the common switching element ( 12, r12) of two power amplifiers for adjusting the pump part and motor part. 4. Arrangement according to claim 3, characterized characterized in that the common switching element as -an axially parallel to the force amplifiers arranged control drum (i5o) is formed. 5. Arrangement according to claim 3, characterized characterized in that the common switching element with separate radial curves (51, 52) acts on the two control members (12, 112) of the power amplifier. 6. Arrangement according to claim i to 5, characterized in that the hydraulically driven Amplifier element (17, 117) can be locked mechanically or hydraulically and is locked State of the control member (12, 112) of the amplifier to the stroke to be amplified corresponding movement is granted, which only after Release the lock followed by the hydraulically powered booster link. 7. Arrangement according to claim 1 with a rotatably mounted switching element, characterized in that the hydraulically driven amplifier member and its control member are coaxially rotatable with the switching element and form a torque amplifier which transfers the torque adjusting the switching member to the adjustable part of the pump or the liquid motor . Considered publications: German Patent Nos. 876 473, 873 642, 613 704, 460 465; Swiss patents No. 264 802, 2o6 885, 181 173, 173 836 172 834, 172 833, 158 936, 153 924 121 94; French Patent Nos. 907 361, 901 255, 888 474; USA. Patent Nos 2,566,380, 2,393,622., 2: 867 29o, 2178356, 2178355, 2 152 0 25.