EP1003972B1 - Turning control device with brake and control valves - Google Patents

Abstract

The invention relates to a hydraulic control device (1) comprised of an adjusting device (6) for regulating an adjusting piston (7). Said piston is located between two adjusting pressure chambers (11, 12) and is acting on the displacement volume of a hydraulic pump (4). The adjusting piston is regulated according to the pressure difference between two adjusting pressure lines (13, 14), said lines each being connected to one of the adjusting pressure chambers (11, 12). Each adjusting pressure chamber (11, 12) is assigned to a brake valve (19, 20). Said brake valve reduces the backflow of the hydraulic fluid from the assigned adjusting pressure chamber (11, 12) in a hydraulic fluid tank (21). A control valve (27, 28) is arranged in each adjusting pressure line (13, 14). Said control valve can be reversed between an open and a closed valve position. Within each adjusting pressure line (13, 14), a branch (15, 16) is located between the assigned control valve (27, 28) and the assigned adjusting pressure chamber (11, 12). The assigned brake valve (19, 20) is arranged between the branch (15, 16) and the hydraulic fluid tank (21). Said brake valve is reversible between a reduced valve position (24, 25) and a closed valve position (22, 23). The brake valves (19, 20) and the control valve (27, 28) are controlled through adjusting pressure lines (33, 44), whereby the brake valves (19, 20) are reduced and the control valves (27, 28) are closed. This results when the larger of the control pressures prevailing in the controlling lines (33, 34) is less than a predetermined threshold value.

Description

The invention relates to a hydraulic control, in particular for controlling the Slewing gear of an excavator.

A hydraulic control according to the preamble of claim 1 is known from the DE 196 20 664 C1 known. With the resulting from this document Slewing gear control is an adjustment device for adjusting one between two Signal pressure chambers arranged on the displacement volume of a hydraulic pump acting piston provided. The adjustment piston is adjusted in Dependence on the pressure difference between two with one each Signal pressure chambers connected signal pressure lines. The signal pressure in the Signal pressure lines are connected to a manual control transmitter by two Control lines specified. There is a separate brake valve in each signal pressure line provided that the return flow of the pressure fluid from the associated with the brake valve Throttling pressure chamber in a pressure fluid tank and thus a slow one After the hand control by the Operator has been returned to its neutral position. By using it of two separate brake valves, each connected to one of the working lines are, which a hydraulic motor driving the slewing gear with the hydraulic pump into one Connect working circuit, it is achieved that the slow braking by the Brake valves is turned off when the slewing gear against resistance, e.g. B. a Heap, swings out.

A disadvantage of the known hydraulic control, however, is that the brake valves in the signal pressure lines are arranged and thus burdened by the signal pressure. When the control piston is deflected to accelerate the slewing gear, the Brake valves therefore from the pressure fluid filling the corresponding signal pressure chamber flows through and therefore exposed to increased pollution. The course of the Pressurized fluids to the pressurized fluid tank take place via the manual control transmitter over a relatively long time Line paths. Therefore, not only the throttle provided in the brake valve acts limiting for the pressure fluid reflux, but also the cross section of the Control lines and the opening cross-section of the manual control transmitter. This allows the Time constant for the backflow of the pressure fluid from the signal pressure chambers of the Adjustment device via the throttle cross-section of the brake valves only to a limited extent reproducible setting. It should be noted that the line length of the Control lines, the hand control transmitter used and other structural parameters of the Type of excavator in which the hydraulic slewing gear control is to be installed, varied. The throttle cross section of the brake valves must therefore be on every excavator type can be individually adapted, which requires a lot of assembly effort. Also are the throttle cross sections of the brake valves used in DE 196 20 664 C1 are not adjustable, so that a comparison after installation is not easily possible.

DE 196 20 665 C1 shows a further slewing gear control. At this Slewing gear control becomes the signal pressure for the signal pressure chambers of the adjustment device from the feed pressure of an infeed device via one or two pressure control valves derived. There is only one brake valve common to both signal pressure chambers provided that downstream of a pilot control or a Pilot valve is arranged. In this embodiment, too, the backflow Pressurized fluid first passed through the pilot valve, which also throttles the return flow, before it reaches the brake valve. The effective throttle cross section is therefore not only dependent from the throttle cross section of the brake valve, but also from that Throttle cross section of the pilot valve and of the cross sections of the Connecting lines. The setting of the effective throttle cross section for the Return flow of the pressure fluid and thus the setting of the braking of the slewing gear is therefore also difficult with this design of the slewing gear control, especially since a variable, adjustable throttle cross section is not provided for the brake valve.

The invention is therefore based on the object of a hydraulic control, in particular for controlling the slewing gear of an excavator, to specify in which the Throttle cross section for the backflow of pressure fluid through the brake valves more accurate is predeterminable and contamination of the brake valves is also counteracted.

The object is in connection with the characterizing features of claim 1 solved with the generic features.

The invention is based on the knowledge that it is advantageous to use the brake valves without Interposition of further valves directly between the signal pressure chambers of the Arrange the adjustment device and the pressure fluid tank. This results in short Line paths for the backflow of the pressure fluid from the signal pressure chambers to the Pressurized fluid tank via the brake valve, so that the effective throttle cross section in essentially from the throttle cross section specified by the brake valve and only in depends negligibly on the cable cross-sections. In the return flow path apart from the brake valve, no other valves that cause additional throttling, intended. The fact that the brake valves only from the refluxing pressure fluid however from that to the signal pressure chambers in the event of acceleration of the slewing gear flowing pressure fluid flows through, the pollution of the brake valves significantly reduced. To in the event that the hydraulic pump and the Actuation of the signal pressure lines with signal pressure a hydraulic short circuit Avoid signal pressure lines via the brake valves to the pressure fluid tank and on the other hand, a backflow of the backflowing pressure fluid into the signal pressure lines or to avoid control lines, is one downstream in the return flow direction each brake valve leading branch arranged a control valve. The Control valves and the brake valves are controlled by those in the control lines Control pressure controlled according to the invention so that the control valves in the case of Open the swing out of the hydraulic pump and close the brake valves and vice versa close the control valves and open the brake valves to their throttled valve position, when the pressurized fluid flows back from the actuating pressure chambers to the pressurized fluid tank.

The measures specified in claims 2 to 12 represent advantageous Developments of the invention.

According to claim 2, it is advantageous to the throttle cross section of the brake valves provide adjustable. This is only due to the solution according to the invention, the Brake valves not in the signal pressure lines, but in to the pressure medium tank to arrange branch lines that are subjected to a lower pressure are exposed to less pollution. The brake valves in the known hydraulic control are designed as seat valves to the To withstand signal pressure there and less susceptibility to contamination exhibit. The formation of an adjustable throttle cross section is with seat valves not possible or only with difficulty. An adjustable throttle cross section can be easier a slide valve be formed. A slide valve can, however, in the known hydraulic control can not be used, as it can jam when dirty can and can therefore lead to considerable malfunctions. In the case of the invention Further development is the use of a slide valve in the pressurized fluid tank leading secondary line possible however according to claim 3. It can Brake valve according to claim 3 a movable in a brake valve housing Have brake valve piston with a control edge of the brake valve housing cooperates and has a bevel. The brake valve piston can according to claim 4 strike against an adjustable stop that the Throttle cross-section of the brake valve specifies by covering the bevel of the brake valve piston is fixed with the control edge of the brake valve housing. The brake valve can have a brake valve spring, which presses the brake valve piston against the stop.

The control valves can be designed as seat valves and each have a control valve piston, each in a control valve housing is movable. The control valve piston can have a conical section, which cooperates with a valve seat surface to form a sealing seat. Training the Control valves as seat valves is advantageous because it makes them relatively large Have pressure resistance and insensitivity to dirt. each Control valve can have a control valve spring according to claim 7, which Control valve piston presses against the valve seat surface. The control valve piston is according to claim 8 preferably formed as a step piston, a step of Control valve piston is acted upon by the actuating control pressure, so that a hydraulically controlled seat valve is created.

The brake valves and the control valves can according to claim 9 Pressure change valve to be connected to the control lines. According to claim 10 can be provided a feed device, the feed pressure in a feed line generated. The signal pressure lines can each have an assigned pressure control valve be connected to the feed line, the signal pressure in the signal pressure lines is regulated by the control pressure prevailing in the control lines. If according to claim 11, a pressure control valve spring is provided, the signal pressure is set slightly higher than the control pressure, so is at vanishing control pressure there is a low signal pressure, which is used for refilling serves the signal pressure chamber, the volume of which swings back when Hydraulic pump enlarged. A suction device with a relatively large size dimensioning filter is therefore not necessary.

The control lines can according to claim 12 by a Control pressure supply and the control transmitter connected to the pressure fluid tank alternately can be acted upon with control pressure.

Fig. 1

ein erstes Ausführungsbeispiel der erfindungsgemäßen hydraulischen Steuerung in einem hydraulischen Prinzipschaltbild;

Fig. 2

ein zweites Ausführungsbeispiel der erfindungsgemäßen hydraulischen Steuerung in einem hydraulischen Prinzipschaltbild; und

Fig. 3

eine schematisierte, konstruktive Realisierung des in Fig. 1 dargestellten Ausführungsbeispiels.

Preferred exemplary embodiments are described below with reference to the drawing. The drawing shows:

Fig. 1

a first embodiment of the hydraulic control according to the invention in a hydraulic block diagram;

Fig. 2

a second embodiment of the hydraulic control according to the invention in a hydraulic block diagram; and

Fig. 3

a schematic, constructive implementation of the embodiment shown in Fig. 1 .

Fig. 1 shows a first embodiment of the hydraulic control according to the invention. The hydraulic control, generally designated by reference number 1, is used in particular to control the slewing gear of an excavator. The slewing gear of the excavator is driven by a hydraulic motor, not shown, which is connected to the hydraulic pump 4 to form a working circuit via a first working line 2 and a second working line 3. The hydraulic pump 4 is z. B. driven for an internal combustion engine, not shown, via the drive shaft 5. The direction of delivery of the hydraulic pump is reversible, so that either the working line 2 or the working line 3 works as a high-pressure line depending on the desired direction of rotation of the slewing gear.

The displacement volume of the hydraulic pump 4 is via an adjusting device 6 adjustable. The adjusting device 6 has an actuating piston 7, which in one Actuating cylinder 8 is movable and without two centering springs 9 and 10 Pressurization in its neutral position shown in Fig. 1 with zero displacement is centered. The actuating piston 7 divides the actuating cylinder 8 into one first signal pressure chamber 11 and a second signal pressure chamber 12. The first Signal pressure chamber 11 is connected to a first signal pressure line 13, while the second signal pressure chamber 12 is connected to a second signal pressure line 14, which supply the signal pressure to the signal pressure chambers 11, 12.

According to the invention, there is a branch 15 in the signal pressure lines 13 and 14 or 16 provided. In each case a secondary line 17 or 18 branches to one Brake valve 19 or 20, so that the first actuating pressure chamber 11 via the brake valve 19th is connected to the pressure fluid tank 21 and the second signal pressure chamber 12 via the Brake valve 20 is connected to the pressure fluid tank 21. The brake valve 19 or 20 has a closed valve position 22 or 23, in which the flow through the respective brake valve 19 or 20 is interrupted, and a throttled valve position 24 or 25 on, in which the flow through the respective brake valve 19 or 20th is throttled. The throttle cross section that the brake valve 19 or 20 in its throttled valve position 24 or 25, is preferably adjustable. The Brake valves 19 and 20 are so through a common control pressure line 26 controlled that they fall below a predetermined threshold value of the control pressure in the control pressure line 26 change over to its throttled valve position 24 or 25 or switch. If the control pressure in the control pressure line 26 is the predetermined Exceeds the threshold value, the brake valves 19 and 20 are in their closed valve position 22 or 23 and are locked. If the control pressure in the Control pressure line 26, however, is less than the predetermined threshold, the Brake valves 19 and 20 pressed into their throttled valve positions 24 and 25, respectively, so that the Brake valves 19 and 20 a throttled, preferably adjustable flow exhibit. The threshold value is preferably set to a very low, almost or completely disappearing control pressure is specified and is via the brake valve springs 29 and 30 adjustable.

A control valve 27 or 28 is located in each signal pressure line 13 or 14 Control valves 27 and 28 are arranged so that the branches 15 and 16th between the control valves 27 and 28 and the control pressure chambers 11 and 12 respectively Adjustment device 6 are. The brake valves 19 and 20 are therefore on the Branches 15 and 16 directly with the signal pressure chamber 11 assigned to them or 12 connected without the hydraulic line between the Signal pressure chambers 11 and 12 and the pressure fluid tank 21 in addition to the brake valves 19th and 20 other hydraulic valves. Preferably, the brake valves 19 and 20 in close proximity to the signal pressure chambers 11 and 12 below Use of only small cable routes for the line section of the Signal pressure line 13 or 14 to branch 15 or 16 and for the secondary line 17 or 18 arranged.

The control valves 27 and 28 are also through the in the control pressure line 26th prevailing control pressure controlled. The control valves 27 and 28 open when the Control pressure in the control pressure line 26 exceeds a predetermined threshold. In contrast, the control valves 27 and 28 close when the control pressure in the control pressure line 26 falls below the predetermined threshold. The control valves 27 and 28 are preferably as seat valves z. B. formed in the form of check valves while the brake valves 19 and 20 are preferably designed as slide valves.

The signal pressure in the signal pressure lines 13 and 14 and thus the deflection of the Hydraulic pump 4 is in the illustrated embodiment by a manual Control transmitter 32 specified, the two control lines 33 and 34 depending on the desired Direction of rotation of the slewing gear alternately with a control pressure feed 35 or Pressurized fluid tank 21 connects. Depending on the intended direction of rotation of the slewing gear either the control line 33 or the control line 34 is subjected to control pressure. The Control lines 33 and 34 are in the exemplary embodiment via throttling points 36 and 37 the control valves 27 and 28 directly connected. The in the signal pressure lines 13th and 14 prevailing signal pressure is therefore from those in the control lines 33 and 34 prevailing control pressures in the embodiment shown in Fig. 1 immediately derived. This embodiment saves a pilot control and is Particularly suitable for slewing gear controls with a small nominal size.

The control lines 33 and 34 are via a pressure change valve 38, each of which selects the highest of the control pressures prevailing in the two control lines 33 and 34 connected to the control pressure line 26. The control pressure line 26 therefore prevails the highest of the control pressures prevailing in the control lines 33 and 34. The Control pressure line 26 is via a pressure cut-off valve 39 with the pressure fluid tank 21 connected. The pressure cut-off valve 39 is designed as a pressure limiting valve and limits the pressure in the control pressure line 26 to preferably one electrical transmitter 40 predetermined maximum pressure. The control pressure line 26 is over another pressure relief valve 41 connected to the pressure fluid tank 21, which via a pressure swing valve 42 of the highest in the working lines 2 and 3 prevailing working pressure is controlled and a working pressure dependent Pressure limitation enabled.

A feed device 43 is also provided. The feed device 43 includes one Via the common shaft 5 connected to the hydraulic pump 4 feed pump 44, which in a feed line 46 via a feed filter 45 through the pressure relief valve 47 limited feed pressure generated. The feed pressure is in each case the low pressure leading working line 2 or 3 fed via a check valve 48 or 49. The maximum working pressure in the working lines 2 and 3 is the Pressure relief valves 50 and 51 limited.

The hydraulic control according to the invention works as follows:

In order to accelerate the rotating mechanism driven by the hydraulic motor (not shown), the hydraulic pump 4 connected to the hydraulic motor is pivoted out by actuating the control stick 53 of the control transmitter 32. Depending on the intended direction of rotation of the slewing gear, either the control line 33 or the control line 34 is acted upon with a metered control pressure via the control pressure feed 35, while the respective other control line 34 or 33 is connected to the pressure fluid tank 21. The control pressure building up in the control line 33 or 34 is also present in the control pressure line 26 and causes the control valves 27 and 28 to open. The control pressure lines 13 and 14 are therefore via the control valves 27 and 28 in the exemplary embodiment shown in FIG. 1 directly connected from the control lines 33 and 34, so that the signal pressure in the exemplary embodiment shown is derived directly from the control pressure. As a result, one of the two control pressure chambers 11 and 12 is acted upon by the control pressure and the other control pressure chamber 12 and 11 is vented to the pressure fluid tank 21 via the respective control valve 27 or 28 and the control transmitter 32. The adjusting piston 7 of the adjusting device 6 is shifted accordingly and the hydraulic pump 4 is pivoted out in the intended direction. The brake valves 19 and 21 are acted upon by the control pressure in the control pressure line 26 so that they are in their closed valve positions 22 and 23 and thus no pressure losses occur in the control pressure lines 13 and 14 via the brake valves 19 and 20.

As soon as the slewing gear has reached the desired speed, the Release the operator stick 53 so that the control transmitter 32 in his Neutral position is returned, in which he the control lines 33 and 34 with the Pressurized fluid tank 21 connects. Thus there is no longer any control pressure in the Control lines 33 and 34 and also the common control pressure line 26 do not carry any Control pressure more. As a result, the control valves 27 and 28 are driven by the control valve spring 54 and 55 closed, while the brake valves 19 and 20 through their Brake valve springs 29 and 30 reversed into their throttled valve positions 24 and 25, respectively become. The hydraulic pump 4 is still in its pivoted delivery position with the adjusting piston 7 moved from the neutral position. The centering springs 9 and 10 gradually guide the actuating piston 7 back into its neutral position shown in FIG. 1 back, the time constant required for this by the brake valves 19 and 20 caused throttling depends. Since the restriction of the backflow of the pressure fluid from the signal pressure chambers 11 and 12 to the pressure fluid tank 21 almost exclusively is determined by the throttle cross section of the respective brake valve 19 and 20, respectively this time constant is set very precisely and reproducibly. Since the Throttle cross section of the brake valves 19 and 20 is preferably designed to be variable, a corresponding fine-tuning can be carried out. According to the invention Brake valves 19 and 20 immediately without the interposition of further valves or Longer hydraulic lines connected to the signal pressure chambers 11 and 12, so that the effective throttling of the return flow is determined solely by the brake valves 19 and 20 is. A backflow of the pressure fluid into the control lines 33 and 34 is impossible because block the control valves 27 and 28 in this operating state.

The threshold value for switching between the valve positions of the brake valves 19 and 20 and the control valves 27 and 28 is by the brake valve springs 29 and 30 and the control valve springs 54 and 55 adjustable.

Fig. 2 shows a second embodiment of the hydraulic according to the invention Control. Elements already described with reference to FIG. 1 are identical Provide reference numerals, so that a repetitive description is unnecessary.

The embodiment shown in FIG. 2 differs from that already based on Embodiment described in FIG. 1 in that two pressure control valves 60th and 61 are provided which are connected to the control pressure lines 13 and 14 at their outputs are connected upstream of the control valves 27 and 28, respectively. One of each Inputs of the pressure control valves 60 and 61 is connected to the pressure fluid tank 21, while another input of the pressure control valves 60 and 61 via a Connection line 62 is each connected to the feed line 46. each Pressure control valve 60 or 61 is at a first control input with an associated Control line 33 or 34 and at a second control input with the control pressure line 13 or 14 connected via a detour line 63 or 64. Each pressure control valve 60 or 61 is therefore assigned by a pressure difference between the control pressure in the Control line 33 or 34 and the signal pressure in the assigned signal pressure line 13 or 14 controlled. This leads to the signal pressure in the signal pressure line 13 or 14 essentially with the control pressure in the associated control line 33 or 34 matches.

Since the pressure control valves 60 and 61 have a pressure control valve spring 66 and 67, respectively are also slightly impacted in the opening direction, is in the Signal pressure line 13 or 14 prevailing signal pressure slightly, for. B. by 1 to 2 bar, higher than the control pressure in the associated control line 33 or 34. In the Signal pressure line is therefore also a slight pressure when in the assigned control line 33 or 34, there is no control pressure. In which Return the actuating piston 7 to its predetermined by the centering spring 9 and 10 Neutral position can therefore via the feed device 43, the connecting line 62 and the associated pressure control valve 60 or 61 and the associated control valve 27 or 28 pressure fluid flow into the signal pressure chamber 11 or 12, the volume of which enlarged when the control piston 7 is returned to the neutral position. A After-suction device with a correspondingly large after-suction filter is therefore not necessary.

Due to the reduction caused by the pressure control valves 60 and 61 of the Control pressure-dependent signal pressure is the embodiment shown in Fig. 2 also for hydraulic controls with large nominal size, d. H. for large size Slewing gear controls, suitable.

3 shows an example of a structural design of the brake valves 19 and 20 and the control valves 27 and 28 in a schematic representation. For understanding to facilitate, the hydraulic circuit in accordance with Fig. 1 is also specified. Elements already described with reference to FIG. 1 are identical Provide reference numerals, so that a repetitive description is unnecessary.

The brake valves 19 and 20 are preferred in the Fig. 3 shown Embodiment designed as slide valves. A brake valve piston 80 or 81 is arranged axially movable in a brake valve housing 82 and 83, respectively by means of the brake valve spring 29 or 30 against a preferably adjustable one Stop 84 or 85 acted upon. The stop 84 or 85 is in one Cylinder bore 86 and 87, respectively, in the respective brake valve housing 82 and 83 is formed axially in front. The axial board can, for. B. be adjusted in that the stop 84 or 85 has a thread that fits into the brake valve housing 82 or 83 can be screwed in. The position of the stops 84 and 85 can also by a z. B. electromagnetic or hydraulic encoder by the operator of the excavator be adjustable so that the hesitant, soft swiveling of the slewing gear through Changing the throttle cross section of the brake valves 19 and 20 via the stops 84 and 85 can be set flexibly.

The brake valve piston 80 or 81 has a chamfer 88 or 89. and works with a control edge 92 or 93 formed on an annular groove 90 or 91. The control pressure line 26 is guided to a pressure chamber 94 or 95, to which the Brake valve pistons 80 and 81 are adjacent. With increasing pressure in the control pressure line 26, the brake valve piston 80 or 81 is therefore against the brake valve spring 29 or 30 shifted and the control edge 92 or 93 is not by the sealed chamfered area of the brake valve piston 80 or 81. With decreasing pressure in the control pressure line 26, the brake valve piston 80 or 81 through the brake valve spring 29 or 30 in Fig. 3 to the left or right pushed back so that the bevels 88 and 89 the control edge 92 and 93 increasingly releases. The throttle opening of the brake valve 19 or 20 in the The stop position on the stop 84 or 85 is determined by the position of the stop 84 or 85 and is determined by changing the position of the stop 84 or 85 adjustable.

The control valves 27 and 28 are preferred in the one shown in FIG Embodiment designed as seat valves. The control valve pistons 96 and 97 are each movable in a control valve housing 98 or 99. The control valve pistons 96 and 97 each have a tapered portion 100 and 101, respectively. The control valve pistons 96 and 97 are so through the control valve spring 54 and 55, respectively acts on the conical section 100 or 101 against the valve seat surface 102 or 103 is pressed and thus a sealing seat is created. Upstream of the conical Section 100 and 101, a first valve chamber 104 and 105 is formed, the with is connected to the valve inlet. In the embodiment shown in FIG. 3 the valve input is connected directly to the associated control line 33 or 34. The valve outlet is connected to the associated signal pressure line 13 or 14 in Connection. A second valve chamber 106 or 107 is from the first Valve chamber 104 or 105 through a sealing stage 108 or 109 of the control valve piston 96 and 97 isolated and connected to the control pressure line 26. The Indian Control pressure line 26 prevailing control pressure engages on a surface 110 or 111 of the Control valve piston 96 or 97 on and moves the control valve piston 96 or 97 against the control valve spring 54 or 55. If one is exceeded by the control valve spring The conical section 100 or 101 raises 54 or 55 predetermined threshold value from the valve seat surface 102 or 103 and gives the flow through the control valve 27 or 28 free.

The brake valves 19 and 20 and the seat valves 27 and 28 can also be constructed in be formed in another way. In particular, it is possible to control valves 27 and 28 also form as simple check valves that a return flow of the pressure fluid in prevent the control line 33 and 34 or into the pressure control valves 60 and 61.

Claims (12)

1. Hydraulic control system (1), in particular for activating the slewing gear of a digger, comprising an adjusting apparatus (6) for adjusting an actuating piston (7), which is disposed between two actuating pressure chambers (11, 12) and influences the displacement volume of a hydraulic pump (4), in dependence upon the pressure difference between two actuating pressure lines (13, 14) which are each connected to one of the actuating pressure chambers (11, 12), wherein the actuating pressure prevailing in the actuating pressure lines (13, 14) is defined by two control lines (33, 34), and
   one braking valve (19, 20) associated with each of the actuating pressure chambers (11, 12) and throttling the return flow of hydraulic fluid from the associated actuating pressure chamber (11, 12) into a hydraulic fluid tank (21),
   characterized in that disposed in each actuating pressure line (13, 14) is a control valve (27, 28), which is switchable between an open and a closed valve position,
   that a branch (15, 16) is provided in each actuating pressure line (13, 14) between the associated control valve (27, 28) and the associated actuating pressure chamber (11, 12), wherein the associated braking valve (19, 20) is disposed between the branch (15, 16) and the hydraulic fluid tank (21) and switchable between a throttled valve position (24, 25) and a closed valve position (22, 23), and
   that the braking valves (19, 20) and the control valves (27, 28) are activated by the control lines (33, 34), wherein the braking valves (19, 20) are closed and the control valves (27, 28) are opened when the greater of the control pressures prevailing in the control lines (33, 34) is greater than a defined threshold value and the braking valves (19, 20) assume their throttled valve position (24, 25) and the control valves (27, 28) are closed when the greater of the control pressures prevailing in the control lines (33, 34) is lower than the defined threshold value.
2. Hydraulic control system according to claim 1,
   characterized in that in each case a throttle area, which each braking valve (19, 20) assumes in its throttled valve position (24, 25), is adjustable.
3. Hydraulic control system according to claim 2,
   characterized in that the braking valves (19, 20) take the form of slide valves and comprise a braking valve piston (80, 81), which is movable in a braking valve housing (82, 83) and cooperates with a control edge (92, 93) of the braking valve housing (82, 83) and has a bevel (88, 89).
4. Hydraulic control system according to claim 3,
   characterized in that the braking valve piston (80, 81) strikes against an adjustable stop (84, 85), which defines the throttle area which the bevel (88, 89) of the braking valve piston (80, 81) releases at the control edge (92, 93) when the braking valve (19, 20) assumes its throttled valve position (24, 25).
5. Hydraulic control system according to claim 4,
   characterized in that each braking valve (19, 20) comprises a braking valve spring (29, 30), which loads the braking valve piston (80, 81) towards the stop (84, 85).
6. Hydraulic control system according to one of claims 1 to 5,
   characterized in that the control valves (27, 28) take the form of seat valves and each comprise a control valve piston (96, 97), which is movable in each case in a control valve housing (98, 99), wherein the control valve piston (96, 97) on a sealing valve step (108, 109) has in each case a conical portion (100, 101), which cooperates with a valve seat (102, 103) so as to form a sealed seat.
7. Hydraulic control system according to claim 6,
   characterized in that each control valve (27, 28) comprises a control valve spring (54, 55), which loads the control valve piston (96, 97) towards the valve seat (102, 103).
8. Hydraulic control system according to claim 6 or 7,
   characterized in that the control valve piston (96, 97) takes the form of a stepped piston and a step of the control valve piston (96, 97) is loaded by the activating control pressure.
9. Hydraulic control system according to one of claims 1 to 8,
   characterized in that the braking valves (19, 20) and the control valves (27, 28) are connected by a pressure change valve (38) to the control lines (33, 34).
10. Hydraulic control system according to one of claims 1 to 9,
    characterized in that a supply device (43) is provided, which supplies a supply pressure in a supply line (46),
    that the actuating pressure lines (13, 14) are connected in each case by an associated pressure control valve (60, 61) to the supply line (46), and that each pressure control valve (60, 61) is loaded in each case by the pressure difference between the control pressure prevailing in one of the control lines (33, 34) and the actuating pressure prevailing in the associated actuating pressure line (13, 14).
11. Hydraulic control system according to claim 10,
    characterized in that each pressure control valve (60, 61) is additionally loaded by a pressure control valve spring (66, 67) in such a way that the actuating pressure prevailing in the associated actuating pressure line (13, 14) is slightly higher than the control pressure prevailing in the associated control pressure line (33, 34).
12. Hydraulic control system according to one of claims 1 to 11
    characterized in that the control lines (33, 34) are either loadable with control pressure or relievable towards the hydraulic fluid tank (21) by means of a control transmitter (32), which is connected to the hydraulic fluid tank (21) and a control pressure supply (35).

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