DE835236C - Control element for generating pressure effects through hydraulic power lifts - Google Patents

Description

The very different forces effects on the working cylinder of a hydraulic power lift in love and lowering farm implements and ^j in these two operations required versdiieden 'high working speeds are taken low of cylinders having different sized work surface. In particular, cylinders with differential switching of the two piston surfaces offer the advantage of simple regulation, which also makes it possible to regulate variable displacement pumps depending on the pressures prevailing in the cylinder according to the required output.

The control of the power lift cylinder in the direction of lifting and lowering gives rise to the desire to be able to exert pressure effects with this device when lowering. The easy one Construction of a control member in a working cylinder with differentially switched spaces the generation of compressive forces in the direction of the lowering movement increases only to a very small extent. Around To be able to exert effective forces on the agricultural implements, a special facility must therefore be created which is the subject of the invention.

This facility, which enables the paver of the agricultural implements to be used without regard to their operational properties as easy to build as their strength allows, and if necessary to replace the necessary weight for the cultivation of the soil by pressure effects that In addition, they also have to be changed if the respective soil conditions appear to be indicated

must be able to act on the device with greater or lesser pressure.

Fig. Ι shows a differential piston that consists of the two step transverse sections ι and 2 together- j is set, the stage 2 being filled through the cylinder housing 3 to the outside and the Enables intervention on the power lift. The cylinder is divided into working spaces 4 and 5 by the stepped piston. The room 4 is about a line of oil is supplied. Inside the differential coll A control piston 7 is arranged, which is connected to its working chamber 4 via the j standing annular space can let oil through the bore S into the working space 5. The control piston 7 is operated by a control rod 9. The power lift shaft 10 is connected by a crank arm 11 connected to piston 2. A pump 12 whose stroke volume can be regulated, which is shown in the figure for example as a spatially working swash plate pump with a variable swivel angle is formed, the oil sucks in from the sump 13 and sends it into the pressure line 6. A spring 14 pulls the adjusting member of the pump 12 into the position of the full delivery rate. An opposite Acting return piston 15 receives control oil from a line 16. The example cited Pump 12 rotates with its cylinder block, which contains the delivery piston 17, under an oblique wedge> e 18. which can be pivoted in the area of the angle 19 to change the stroke.

The line 16 opens into a pressure regulator 24, which has an actuating rod 25, a piston .26, a spring 27 and a control piston 28 contains, on the one hand in the housing 24 and on the other hand a tube 29 is slidably arranged, the two openings 30 and 31 of which by moving the Control piston 28 can be opened and closed. A line 32 ensures pressure equalization between the two pistons. It is connected to the work space 5. Above the operating rod is indicated schematically with a triangle 33, the variable pressure on the agricultural implement. On the crank arm 11, an arrow indicates the direction of lifting and a second arrow indicates the direction in which the device can lower and push.

Fig. 2 shows an analog system; the designations from 1 to 19 are taken from Fig. 1 and provided with an index number 1 'to 19'. The return of the pump to a smaller delivery volume is achieved by a double-acting Piston 20 made, on the one hand via a line 21 to the pressure regulator 24 'in the sense of] a stroke reduction is connected, while the other side of the piston 20 via a line 22 receives pressure from the working chamber 5 'and acts on the piston 20 in the sense of an increase in stroke. The positions of the pressure regulator 24 'to 33' are the same as in Fig. 1 and with an index mark Mistake. Correspondingly, the directions lifting, lowering and are also indicated by the arrow on the crank arm 11 ' Press indicated.

The operation of the system is as follows: The operating rod 25 in Fig. 1 is placed so that no or only the slightest pressure effects are exerted by the power lift. Should a lifting process are initiated, the control rod 9 is moved in the corresponding direction. The control piston 7 releases a cross section of the bore 8 and releases the pressure present in the working space 5. Through this the oil pressure in front of the return piston 15 will also drop and the spring τ4 will open the pump Bring a larger swivel angle and greater delivery rate. The connection between the Working space 5 and the line 16 is secured for this process, since the position of the actuating rod 25 the piston 28 allows the Arlieitsraum 5 to be connected directly to line 16 * The lifting process is ended at the moment in which the differential piston has reached the control slide 7 again and the bore 8 is blocked. An oil pressure now develops in the working space 5 and in front of the return piston 15, which controls the pump reset to delivery rate XuIl. A corresponding one Process enables lowering. In this case, the working space 4 is controlled by the control slide 7 and the bore 8 is connected to the working space 5. The lowering process is only minor Expression of force possible because of the effective piston area in room 5 due to the full back pressure in room 4 only equal to the difference of the full one Piston cross-section 1 and the piston ring surface in space 4, i.e. equal to the cross-section of the piston part 2, which is only about a quarter of the full piston cross-section at ι. Should this be a greater pressure effect, as initially requested is referred to, are achieved, the spool 7 is brought into a position that the Serik process corresponds, and the actuating rod 25 in a desired pressure position, so after left, pushed. Here, the spring 27 will move the control piston 28 along with the line 16 shut off from the work space 5 by looping the opening 30 and depressurized via an opening 31 do. The pressure in the working space 4 and thus the same pressure in the working space 5 increase until the control piston 28 overcomes the resistance of the spring 27 to the right moves and finally releases the opening 30 after it has previously closed the opening 31. Now the line 16 and with it the return piston 15 receives oil pressure, which resets the Causes pump to zero. During this process, a line 32 conducts pressure oil from the working space 5 on the piston 26, which forms the abutment of the pressure regulating spring 27. Since the tube 29 and the operating rod 25 with the same diameter, the spring piston system 26, 27, 28 is powerful completely balanced and adjustable from the outside without the use of force. It's functional. the actuating rod 25 and the control rod 9 or the lifting arm 11 with one another in such a manner to connect that the pushing process on the lowering process after exceeding the deepest lowering position of the device can follow and that the lifting process is only possible when the control unit is switched off is.

Claims (7)

The effect of Fig. 2 is corresponding Working space 5 'controlled, but the differential pressure between the working spaces 5' rind 4 '. As The picture indicates, in this embodiment the cross section of the piston part 2 'is larger than the piston ring area in space 4 '. The surfaces or cross-sections behave roughly like one to another three. Due to the differential pressure effect, it prefers to work to the right with greater force, since in In this case the pressure in space 5 'acts against the full counter pressure in space 4', and the effective piston area in space 5 ', as already mentioned above, the cross section of the now opposite corresponds to the annular surface in the space 4 'of the larger piston part 2'. As a result, hel> en are also and lowering in this arrangement reversed compared to Fig. 1. Accordingly, the pump be influenced in other ways. Is the process by the movement of the control rod 9 ' Initiated lifting, so pressurized oil from the pump 12 'via the line 6' into the working space 4 'and through the control piston 7' and the bore 8 'into the working space 5'. Its predominantly larger area compared to 4 'makes the power lift run in the lifting direction. Of the Pressure in the working chamber 5 'is shared via the line 22 with the piston 20, which is the position of the Sehiefscheilx; 18 the oil pump in full swing 19 'holds. As in Fig. 1, the pressure regulator 24 ' are / unachsi in the position of lowest pressure and from the piston 28 'pressure oil via the line 21 can get in front of the right piston 20. As long as the control slide 7 'connects the working spaces 4' and 5 'to one another, is also in front of the both pistons 20 have the same oil pressure, so that the spring 14 'alone secures the full angular position 19'. When the bore 8 'is closed by the control slide 7', the pressure in the working space 4 'is over that of the working space 5 'rise, so that the pressure of the line (V, 21 has a greater effect on the Κοίΐκίη 2o exerts than the pressure from line 22. The pump adjusts itself to zero. The lowering process is carried out by pushing the control rod 9 ' initiated in the lowering direction, the control slide 7 'opening the working space 5' via 8 '. That Pressure oil is drained off and the oil pressure prevailing in the working space 4 'is able to move forward of the working piston, which leads to a decrease in the pressure in line 6 ' leads, which is finally overcome by the spring 14 'through the piston 20 and the pump brings full delivery rate (gml.ler angle 19 '). The pushing process is initiated by adjusting the control rod 9 'to lowering and by setting the actuating rod 25' to the desired pressure 33 '. The spring 27 'secures the oil pressure required in the line (·>' for pressing, without a counterpressure having to develop in the line 21. Only when the desired oil pressure is exceeded will the control piston 28 'release the opening 30' and open it Reset the pump via the line 2r and the piston 20. The actuation of the rod 25 ' is in the same way as that shown in Fig. 1, through the line 32' without any reaction from the oil pressures controlled by it. Fig. Ι and 2 show two possible circuits Arrangements of differential pistons in which as a result of the differential pressure effect of the Piston surfaces for the lifting process a larger force cross-section is available than for the Lowering process. Both differential pistons are housed in a cylinder, from which the smaller one Step protrudes through a stuffing box. The described method can be used in the same way also train for differentially switched pistons, which as plungers in two opposite Cylinders protrude. The cases according to Fig. 1 and 2 can also be implemented here, depending on how the size ratio of the two pistons is chosen to one another. PATKNTANSPIi (T. HE: τ. Control element for generating pressure effects by hydraulic power lifts, the work according to the differential piston design and equipped with an automatically controlled pump are, characterized in that the control member (24 to 32) is the reset mechanism (15 or 20) of the pump (12, 17, 18) pressure oil to actuate the reset only allows the oil pressure in front of the working piston (1) to reach the required level has reached.- 2. Control member according to claim 1, characterized ge too indicates that its Steuerkoll> en (28) and a counter-piston (26) arranged on the actuating rod (25) and which determines the power lift pressure Enclose the spring (27) between them. 3. Control member according to claim 2, characterized in that that the starting position of the spring (27) is adjustable within the cylinder (24) leading the control and counter piston (28, 27). 4. Control member according to claim 2, characterized in that no indicates that the control piston (28) within the control cylinder (24) on a pipe section (29) is slidably seated, which has bores (30,31) to be opened and closed, which in turn establishes the connections with the return piston (15 or 20) of the pump (12, 17, 18) produce. 5. Control member according to claims 1 to 4, characterized in that on the one hand control piston (28) and opposing piston (27) and on the other hand the pipe section (29) and the actuating rod (25) each have the same cross section and one of the two effective piston surfaces connecting relief line (32) is provided, so that the control member of the to be controlled Pressing is reaction-free. 6. Control member according to claim i, characterized in that that its operating rod (25) with the lifting rod (9 or 11) in the Coupled or interlocked way is that the lifting process only occurs when the control unit is switched off (24 to 32) takes place. 7. Control member according to claim r, characterized in that its actuating rod (25) is locked or coupled to the linkage (9 or 11) of the power lift in such a way that its pressure-generating effect only begins after the lowest lowered position has been exceeded. 1 sheet of drawings 0 3674 3.