DE2541496C2 - Reversible mechanism for a reversible plow - Google Patents

Description

The invention relates to a turning mechanism for a plow according to the preamble of claim 1.

Such a turning mechanism is already known as the prior art, in which to carry out the Pivoting movement requires a buffer as well as a mechanical lock with a roller and another role and a spring are required (DE-AS 2129 862). This results in a Considerable structural effort, especially due to the interaction of the corresponding parts, namely the buffer and the mechanical lock, the rotation can be carried out exactly.

Another disadvantage is that in order to carry out the rotation in the buffer stored pressure medium is absolutely necessary. However, this pressure of the pressure medium falls increasingly from, so that the effect of the buffer can not be precisely controlled.

In contrast, it is the object of the present invention to provide a construction of the ArI mentioned at the beginning create, which is designed so that they can be easily and without major structural effort for both Double-acting as well as single-acting control devices can be used in towing vehicle hydraulics is.

This object is achieved with the features specified in the characterizing part of claim 1. This has the advantage that the rotation is effected via the tractor hydraulics, with in a simple manner, the control device causes this rotation to be carried out properly.

Advantageous further developments result from the subclaims.

The invention is explained in more detail below with reference to exemplary embodiments shown in the drawing described. In the drawing shows

1 shows a schematic rear view of the turning mechanism;

FIG. 2 is a sectional side view of the turning mechanism in another embodiment of FIG Invention;

Fig. 3 is a further sectional side view of the Turning mechanism according to another embodiment;

F i g. 4 the control unit in section;

F i g. 5 shows a section along the line V-V in FIG. 4;

F i g. 6 and 7 the control device according to FIG. 5 in two different working positions.

The turning mechanism for a reversible plow shown in Fig. 1 consists essentially of a plow head 1 with a mounted on the plow head, relative to this around a turning axis in two different working positions pivotable plow frame carrying the plow body. On the plow head 1 is a double-acting The piston-cylinder unit 7 is fastened via a bearing part 10 and a bearing pin 11.

The piston rod 8 of the piston-cylinder unit 7 is provided with a rotary drive part which causes a full rotation 31 (Fig. 2, 3) of the turning axis 2 connected. The rotary drive part 31 is mounted on the plow head 1.

The plow head 1 has a cross member 6 on which the two Seiter.lenkeran connections 3 and 4 are located. The plow head also has 1 in the upper area

the top link connection 5.

According to the embodiment of Figure 5 is the Cross member 6 designed as an intermediate store 14. This intermediate store 14 is filled with a liquid, in the present case oil 15, fillable. In the upper area of the Intermediate storage 14 is compressed air 16, which can be controlled via a pressure gauge 22.

The piston-cylinder unit 7 is via the lines 19 and 20 are connected to the control unit 17. This control unit 17 also has a line 21 which protrudes below the surface of the oil 15 within the intermediate storage 14. In addition, that is Control unit 17 connected via a line 18 to a control device 13, which together with the tractor hydraulics 12 is part of the towing vehicle.

The towing vehicle thus has a single-acting control device 13. This control device 13 can be switched between areas I and II. For example, if the control device 13 is located in the Area I, the tractor hydraulics 12 can deliver pressurized oil to the turning mechanism. Will on the other hand, the control device 13 is switched to the area II, so the tractor hydraulics 12 are pressureless, and via the line 18 and the area II of the control device 13 oil can be in the container 24 of the The tractor hydraulics flow. Here it is possible via line 23 oil from the container 24 into the Tractor hydraulics 12 returned.

If the control device 13 is in the area I, in one case it flows through the tractor hydraulics 12 Prints! via line Ί8 to control unit 17, the pressurized oil flowing into the cylinder 9 of the piston-cylinder unit 7 via the line 20. This will the piston of the piston-cylinder unit 7 and thus the piston rod moves upwards, with the rotation of the working part is carried out from one position to the other.

During this movement, oil is generated on the other side of the piston within the piston-cylinder unit 7 Transferred via the line 19, the control unit 17 and the line 21 to the buffer 14.

So!! the working device is returned from one working position to the other, so will be for a short time the control device 13 switched from the area I to the area II, whereby the line 18 is pressureless. Here, the buffer 14 becomes effective and presses oil through the line 21 and the Control unit 17 and line 18 into container 24.

The control device 13 is now switched again from the area II to the area I. The Towing vehicle hydraulics can control unit 17 via line 18 and line 19 can move the piston within of the cylinder 9 so that the rotation into the other working position is carried out properly.

In the embodiment according to FIG. 2, the intermediate store 14 is within the turning axis 2 arranged, this turning axis is hollow. Inside this hollow turning axis is located Oil 15 and compressed air 16. Via a connecting line 70, the compressed air 16 can be carried inside the cross member 3 existing compressed air 16 'be connected. This advantageously results in a good structural Utilization of the hollow turning shaft 2 and the hollow cross member 6. The oil 16 within the hollow turning axis 2 is connected via the line 21 to the control unit 17, which via the line 18 with the control device 13 and the towing vehicle hydraulic system 12 is in communication. Is via lines 19 and 20 the control unit 17 is connected to the piston-cylinder unit 7 or its cylinder 9.

Another embodiment of the invention is shown in FIG. 3. Here, inside the hollow Turning axis 2, a sealing element 29 is arranged, which is under the action of a compression spring 30. This sealing element 29 thus divides the hollow turning axis 2 into an area within which

: ti the oil 15 is located, and in an area with the Compression spring 30. In this area, compressed air 16 can also be present, which is supplied via an air valve 28 is insertable.

When the rotary drive part 31 is rotated, the plow (not shown in more detail) moves from one to the other transferred to another working position, oil enters the hollow via the control unit 17 and the line 21 Turning axis. With this newly added oil, the sealing element 29 is counteracted by the spring 30 shifted, which results in an increase in pressure. Is now about the piston-cylinder unit 7 and the The piston rod 8 and the rotary drive part 31 of the plow are transferred to the other working position, so that inside the hollow turning axis 2 arranged below

? "> Oil 15 under pressure under the action of spring 30 as well as the compressed air 16 via the line 21 to the hydraulic control device 17 and to the container 24 gelörderi.

The control device 17 shown in FIGS. 4, 5 and 6, 7

^{i :)} consists essentially of a housing 32 in which a recess 41 and a space 51 are provided. A control slide 33 is arranged to be movable to and fro in the recess 41, while a control piston 34 is movable in the space 51. This control piston 34

«Has a truncated cone on each of its front sides 52 and 53.

The movable in the recess 41 control slide 33 is cylindrical and has on his Front sides each have a cylinder bore 35 and 36. Am

4 ″ end of these two cylinder bores 25 and 36, the control slide 33 has a circumferential outer side Annular space 45 or 46. The respective annular spaces 45 and 46 are connected via small bores 47 and 48, respectively the respective cylinder bores 35 and 36 connected

■:> the. Between the annular spaces 45 and 46, the Control slide 33 has a circumferential annular space 71 on the outside.

A piston 37 and 38, respectively, is located within the two cylinder bores 35 and 36 of the control slide 33

'■■> led. Each of these pistons has a pin,

which is surrounded by a spring 39 and 40, respectively. This spring 39 or 40 is attached to the housing 32 Brackets 57 and 58 stored.

The housing 32 also has a connection

^r ) ^r i of the feed line 18 to the tractor hydraulics, as well as a connection to the one cylinder side or to the line 19 and a connection to the line 20, which leads to the other side of the piston-cylinder unit 7, both connections from the control piston 34

»Ο have operable shut-off valves. In the middle area has the control unit according to FIG. 5 has a connection which is connected to the line 21, which leads to the buffer 14. This connection, i.e. H. the line 21 points inside the housing 32

•>, 'vein loaded balls 59 and 60 on which are arranged between a bore 61. A connection to a can be established via a bore 62 Bore 42, this bore 42 according to FIG. 4 to

25 4t

the feed line 18 leads. In the flow area of the Control piston 34 are still bores 50 and 54.

The control unit 17 works as follows: If the piston with the piston rod 8 according to FIG. 1 of a '■. are moved lower into the upper position, the control device 13 of the tractor hydraulics 12 is switched to the range I. As a result, pressurized oil reaches the control unit 17 via the line 18. According to FIG. 4, the pressure oil flows through the bores 42 and u> 49 into the space 41 and further via the bore 50 and the space 51 into the supply line 20. Via this supply line

20 pressure oil flows according to FIG. 1 in the cylinder 9 of the piston-cylinder unit 7 and then moves the Piston up. '' '

This pressurized oil presses the piston 37 upward in the direction of the arrow in the space 41, which in the cylinder bore 36 located oil through the bore 48 to the line

21 flows. At the same time, pressurized oil flows through the supply line 18 into the annular space 45 of the control slide and from this annular space 45 via the small bore 47 into the cylinder bore 35 of the control slide. Through this there is an increasing amount of pressure oil within the cylinder bore 35 and thus displaced the piston 38 according to FIG. 4 in the direction of the arrow, d. H. against the action of the spring 3S until the rear end of the pin of the piston 38 rests against the bearing part of the holder 57.

While the pressure oil conveyed by the towing vehicle hydraulic system 12 according to FIG. 4 is shown in dashed lines Direction of the arrow flows from the line 18 to the line 20 and thus the piston within the piston-cylinder unit 7 moves upwards, this movement causes oil from the top of this piston through the line 19 is pressed and thus according to FIG. 4 in the upper area into the steering device 17. It flows through this. how indicated by arrows, above the raised shut-off valves, via the bores 54 and 55 and the bore 56 and the recess 71 of the control slide in the Line 21. wherein the oil via this line 21 according to FIG. 1 arrives in the buffer 14.

If the reverse rotation is to be carried out into the first starting position, then according to FIG. 1 the Control device switched from area I to area II, whereby the line 18 is depressurized. As a result, the piston 38 and the spring 39 come into effect with respect to the control slide 33 and pushes Via the oil-filled cylinder bore 35, the control slide is moved from its upper to the lower one Position. When the line 18 is depressurized, stored oil flows through the line 21 into the control unit Ϊ7. this oil according to FIG. 5 through hole 61 against the action of the spring-loaded ball 60 enters the bores 62 and 42 and via the line 18 in the oil tank 24 of the tractor hydraulics is returned.

In the further course of the downward movement of the control slide 33, a situation according to FIG. 6. The control device 13 now switches back from the area II to the area I (Fig. \\ so that the line 18 is again under pressure via the tractor hydraulics 12 41 and the bore 54 reach the line 19 and thus act upon the piston within the piston-cylinder unit 7 from above and perform the rotation (FIG. 7).

At the same time pressure oil occurs through the bore 42 and and the annular space 46 and the small bore 48 in the Inner space 36 and thus pushes the piston 37 downwards against the action of the spring 40 until the piston pin of the piston 37 rests against the holder 58. So that the cylinder bore 36 is filled with pressure oil and the Piston 37 is again in the tensioned state, so that when it is switched over again, this causes the control slide 33 into its starting position shown in FIG can be traced back.

During the aforementioned turning process, the flows below the piston of the piston-cylinder unit 7 arranged oil via the line 20, the space 51 and the bore 63 and the recess 65 in the line 21, from which it flows into the intermediate store 14. The pressure oil in the upper Boreich of the space 41 presses the piston 38 into the cylinder recess 35, whereby oil located in this via the small bore 47 into the Line 21 and thus to the buffer 14 arrives.

During the process described above, the control piston 34 moves from the position shown in FIG. 4 shown Location in the in F i g. 7 position shown, wherein in the upper area of the space 73 within the housing to the free Flow of the pressure oil is released. The piston 34 has the function of the implement in one or to secure against undesired movement in the other working position, which can be done with the help of the check valves takes place in lines 19 and 20. The control piston 34 has truncated cones 52 and 53 on the front side which actuate the shut-off valves in lines 19 and 20 accordingly.

The hydraulic control described above with the aid of the control unit 17 makes it possible to even with a single-acting towing vehicle hydraulic system with a single-acting control device 13 Cylinder 9 of a piston-cylinder unit 7 to act on alternately, the intermediate storage 14 the Function. excess pressure oil from the piston-cylinder unit 7 to collect and returned to the oil container 24.

Through the in F i g. 5 illustrated, spring-loaded balls 59 and 60 is when the line 18 is under pressure stands, the bore 61 is blocked, whereas draining of the oil via the spool 33 is against Action of the ball 59 via the line 21 in the intermediate storage 14 is possible. In the opposite case blocks the ball 59. and the oil can via the line 21 from the intermediate storage 14 via the bores 62 and 42 get into line 18.

According to a simpler embodiment of the invention, the line 21 could instead of the buffer 14 can also be connected directly to the container 24 of the tractor hydraulics.

If a tractor or a towing vehicle has, for example, a double-acting control device. so the line 21 can also be connected to the tractor hydraulics, so that the lines 18 and 21 a connection to the control device of the tractor hydraulics is established. That can be done Apparatus of the present invention advantageously for both single and double acting Use control hydraulics, so that there is a considerable increase in the area of application. Above the air pressure within the intermediate storage 14 is in cooperation with the tractor hydraulics Readjustment of the pressure within the intermediate store 14 is possible.

The intermediate store 14 can also have, for example, a bladder that can be filled with air or gas.

so that a clear separation of liquid and gaseous medium is guaranteed.

The device according to the invention can be used not only for a turning device but for a plow for example, also use for front loaders, whereby the rocker arm can be designed as a container. Even an application to a semi-mounted plow with tools is feasible.

In addition 6 sheets of drawings

Claims (11)

Patent claims: 1. Wendewerk iür a reversible plow, with one on a towing vehicle with hydraulics and control device attachable plow head and a mounted on the plow head, relative to this by a The turning axis can be pivoted into two different working positions and the plow frame carrying the plow body and with a double-acting piston-cylinder unit. its piston rod with a rotary drive part of the turning axis and its cylinder with the plow part and on both sides with a automatically switching, hydraulic, connected to the control device via a line The control unit is connected to the control slide that moves back and forth between two working positions, characterized in that the control slide (33) of the control device (17) is at the front each has a cylinder bore (35, 36), in each of which a spring-loaded piston (37, 38) and that the cylinder bore (35, 36) each has a bore (47, 48) smaller Diameter can be connected to the supply line (18) to the control device (! 3). 2. Turning mechanism according to claim 1, characterized in that that the control unit (17) via a line (21) with a pressurized oil-filled intermediate store (14) is connected and that in each case the one via the control slide (33) Line (19 or 20) of the piston-cylinder unit (7) with the supply line (18) and the other line (20 or 19) can be connected to the intermediate store (14). 3. turning mechanism according to claim!, Characterized in that that the hydraulic control device (17) has a control piston next to the control slide (33) (34) for check valves located in the supply and discharge lines (19, 20) of the piston-cylinder mechanism (7) having. 4. Turning mechanism according to claim 3, characterized in that the sieve piston (34) is on the end face each has a truncated cone (52, 53), each truncated cone lying in the region of the shut-off valves. 5. turning mechanism according to claim 2, characterized in that part of the plow head (1) or the Plow frame is designed as an intermediate store (14). 6. turning mechanism according to claim 5, characterized in that the intermediate store (14) below Exposure to compressed air. 7. turning mechanism according to claim 5, characterized in that the intermediate store (14) in the cross member (6) and / or is arranged in the hollow turning axis (2) of the plow head (1). 8. turning mechanism according to claim 7, characterized in that a sealing element in the turning axis (2) (29) is arranged, which a compression spring (30) against the in the turning axis (2) Seals liquid. 9. turning mechanism according to claim 8, characterized in that the area of the turning axis in which the compression spring (30) is arranged and can be acted upon with compressed air. 10. turning mechanism according to claim 9, characterized in that the compressed air (16) via a Pressure valve (28) can be introduced into the turning axis (2). 11. Turning mechanism according to claim 2, characterized characterized in that the intermediate store (14) has a bladder which can be filled with air or gas.