DE3346820A1 - Hydrostatic drive for a concrete piston pump - Google Patents

Abstract

Hydrostatic drive for a concrete piston pump having two alternately discharging concrete pump pistons and a concrete flow switchover unit, each of the two concrete pump pistons being linked to one double-acting hydraulic plunger 11 and 15, respectively, which can move in a hydraulic cylinder 10 and 14, respectively, a connection line being provided between the two pressure chambers on the piston-rod sides of said two hydraulic cylinders, and the pressure chambers on the piston side of the two cylinders being connected to a hydraulic pump operating in a closed circuit, the concrete flow switchover unit 2 furthermore having switchover pistons, each movable in one switchover cylinder, each switchover cylinder being connected with control units, which are controlled as a function of the distance covered by the hydraulic plungers, and the energy of the stream flowing alternately to one switchover cylinder 45 and 47, respectively, being derived from the energy of the stream delivered by the hydraulic pump 1, 2, and the switchover cylinders 45, 47 being connected to the pressure chambers 52, 54 on the piston rod side of the hydraulic cylinders 10, 14. <IMAGE>

Description

Hydrostatic drive for a concrete piston pump

The invention relates to a hydrostatic drive for a concrete piston pump with two alternately extending concrete pumping pistons and a concrete flow control device, each of the two concrete pumping pistons with one double-acting hydraulic piston each is connected, which is displaceable in a hydraulic cylinder, with between the one of the two pressure chambers on the piston rod side of each of the hydraulic cylinders there is a connecting line connecting the two hydraulic cylinders and the piston-side Pressure chambers of both cylinders to a hydraulic pump working in a closed circuit are connected and furthermore the concrete flow control device, for example can be designed as a slide or a swivel tube, with two in one each Reversing cylinder is connected to displaceable reversing piston and each of these reversing cylinders with one dependent on the hydraulic piston connected to the concrete pump piston covered path controlled control member is connected.

Hydrostatic drives of this type, i.e. with a closed one Circulating hydrostatic Pump, are only recently Time has been developed, the known drives are designed such that a constant auxiliary pump is provided to pressurize the reversing cylinder, in one of the closed circuit that acts on the hydraulic cylinder Pump-separated hydraulic system, which contains a pressure accumulator, steadily conveyed in, so that the relatively small steady stream is stored in the memory can become a storage volume that corresponds to the volume of the reversing cylinder. This results in various disadvantages, on the one hand insofar as in Change in the pumping speed at which the concrete flow is conveyed, the The time at which the reversing movement is initiated is only optimal for one pump speed can be interpreted. In addition, the fact that the system is at a standstill Internal combustion engine is under the pressure of the pressure accumulator, hazards arise, if repair work is carried out on the reversing device in the event of a fault Need to become. Therefore it must be indicated by warning signs that before such repair work the pressure accumulator must be emptied. The emergence hard pressure surges in the concrete pumping stream can be alleviated by then, if the pressure rises too steeply in the closed circuit with the result, that as a result of the elasticity of the pipelines a considerable volume in addition is stored in these and as a result in the low-pressure line of the closed Circuit, the pressure drops unacceptably sharply, via a non-return valve into this Low pressure line from a pressure chamber of the actuating cylinder of the pump of the closed Circuit is sucked off, so that the pump contrary to the preset setting is set to a smaller stroke volume.

The previously common hydrostatic drives for concrete piston pumps are designed so that the pump in open circuit to a directional control valve promotes, through which either one of the two hydraulic cylinders is applied will. In doing so, a current flowing into each hydraulic cylinder is generated from this A branch flow is diverted via a branch line, which flows via a further switching valve is fed to the reversing cylinders of the reversing element, this further valve is controlled depending on the position of the hydraulic piston. With this system are hard pressure surges in the concrete flow can only be alleviated by considerable additional effort. Such hard pressure surges not only lead to strong, pop-like noises, but also to high loads on the pipes and especially the pipe connecting elements, through which the concrete flow is promoted, especially when this pipe is guided over a high and long boom, the pressure surges to dangerous Cause vibrations of the mast. Attenuators were already used to influence the switching times of the reversing devices are provided, but are only limited To achieve satisfactory results, especially since it depends on the viscosity and the accuracy depend on the setting. A considerable amount of effort is required for the precise setting necessary. Inaccurate coordination of the reversing times leads to a poor degree of filling the concrete pump cylinder, which in turn leads to higher and harder pressure surges.

It is also known, instead of one hydraulic pump, two to each other to use hydraulic pumps connected in parallel. This results in two advantages, namely on the one hand that in the event of failure of one of the two hydraulic pumps still with the other can be conveyed at half the conveying speed, at least as long as the flow through the other pump is shut off, for example way in that the pump is in the zero stroke position or cannot rotate or by means of of a valve is shut off. Another advantage can be economic, in that two small pumps manufactured in large numbers are cheaper as a big one.

The invention is based on the object of a drive system of To improve the type mentioned at the beginning with a closed cycle, in particular that Interaction of the reversing member or the reversing cylinder that actuates it to improve with the hydraulic cylinders and pressure surges in the concrete pump cylinders to avoid.

This object is achieved according to the invention in that in one hydrostatic drive with closed circuit for a concrete piston pump Energy of the flow flowing into the reversing cylinders from the energy of the Hydraulic pump is branched off the energy flow flowing into the concrete pump piston. The reversing cylinders are controlling control organs by means of their actuation connected to the pressure chambers of the hydraulic cylinders on the piston rod side.

The same system can also be used if the the hydraulic pump outgoing lines to the piston rod side pressure chambers the hydraulic cylinder are connected and the two piston-side pressure chambers of the two hydraulic cylinders are connected to one another by the connecting line are.

In this case, the ones leading to the reversing cylinders must then be used Lines must be connected to the piston-side pressure chambers. It is crucial that the reversing cylinders are connected to the two pressure chambers on the other side of the hydraulic piston are like the one on the hydraulic pump connected Pressure chamber of the respective hydraulic cylinder.

The system according to the invention achieves on the one hand that only a lower construction cost is required, on the other hand, the reversing speed but also kept constant regardless of the concrete flow rate the point in time at which the reversal process was initiated was inevitably kept favorable. In addition, the present invention enables numerous further developments, each of which brings further advantages.

For a hydrostatic drive according to the invention, in which the Setting element of the hydraulic pump with a hydraulic pump that is dependent on a control pressure Control device is provided, there is an expedient further development in that on each hydraulic cylinder in an area that of the hydraulic piston is passed over before reaching the end position on the piston rod side and when it is reached the piston rod-side end position of the hydraulic piston part of the piston-side pressure chamber is, a line is connected which leads to a measuring throttle point, wherein A valve control line is connected to this line between the measuring throttle point and the cylinder is connected, which leads to a pressure chamber of a control valve that is connected to a the control pressure line which guides the control pressure that determines the setting of the hydraulic pump connected. As a result, when the hydraulic piston is on its piston rod side End position reached, the hydraulic pump to a stroke volume and thus a flow rate which corresponds to the desired speed of the reversing piston regardless of the speed at which the hydraulic piston previously operated and so that the concrete pumping piston was moved.

A particularly useful further development for this results, if on the line between the hydraulic cylinder and the measuring throttle point a Branch line is connected leading to an input of one of a pressure compensator controlled valve leads, the second side of the pressure compensator of this valve is connected to the line behind the measuring throttle point, i.e. the pressure drop at this measuring throttle point is used to control this drain valve, so that then, if there is a sufficiently large pressure gradient at this measuring throttle point, Pressure medium from the line leading to the measuring throttle point and thus from the Hydraulic cylinder is drained. Appropriately, the process of this is from the Pressure compensator controlled valve with the rod-side pressure chamber of the other Hydraulic cylinder connected, so that the flowing out of one hydraulic cylinder Pressure medium flows into the rod-side pressure chamber of the other cylinder, so that the cycle remains closed. What is essential is the interaction with the called control valve, that is, when the valve controlled by the pressure compensator Releases pressure medium, the control valve is influenced at the same time, which the The setting of the hydraulic pump is determined.

Feeding. of the pressure medium flowing out of a hydraulic cylinder in the rod-side pressure chamber of the other hydraulic cylinder can expediently take place in that the flow of the valve controlled by the pressure compensator connected line to the connecting line between the two piston rod sides Pressure chambers of the two hydraulic cylinders is connected.

Furthermore, it is provided according to one embodiment that the of from the measuring throttle point leads to the reversing cylinder.

The mouth of the connecting line is expediently between the rod-side pressure chambers of the two hydraulic cylinders in each of them arranged in an area that is before and when reaching the piston rod side The end position of the hydraulic piston is covered by this, so that the hydraulic piston even when reached its end position controls the mouth.

Furthermore, it is provided according to a further embodiment that in the Area of the hydraulic cylinder, which is before and when it reaches the piston rod side The end position of the hydraulic piston is covered by this on each of the hydraulic cylinders a line is connected to which a pressure-dependent reversing changeover valve is connected, with this pressure-dependent reversing on each input side Shuttle valve each one of these lines is connected and the output of this pressure-dependent reversing changeover valve is connected to two lines, of each of which opens into one of the two reversing cylinders in an area of the same, which lies in front of the end face of the reversing piston when it is on its piston rod side Has reached its end position.

It is also provided that each of the two has a hydraulic cylinder in an area of the same before and when the piston rod-side end position is reached of the hydraulic piston is covered by this, another connected lines pressure-dependent switchover valve is connected to its second inlet the line behind the measuring throttle point assigned to the respective other hydraulic cylinder is arranged and connected to the output of a four-way / two-position valve is, at the two outputs of each one leading to one of the reversing cylinders connected.

Appropriately, the two lead each in front of a measuring throttle point connected lines to a pressure-dependent changeover valve and the two lines behind each measuring throttle point to a second depending on the pressure switching shuttle valve, where the two of each of these Shuttle valves outgoing lines to the two control pressure chambers of a two -connection / two-position directional control valve lead to the control pressure line in the the control pressure leading to the setting of the hydraulic pump is connected is, when opening this two-way / two-position valve, the control pressure on one predetermined value is lowered, with the result that the hydraulic pump on predetermined stroke volume is set. For this purpose it is expedient a preload valve connected in series with the two-way / two-port valve. Furthermore, it is expediently parallel to this two-way / two-position directional control valve an electrically controlled pressure reducing valve that is open when the solenoid is de-energized switched.

Another refinement of the invention serves the purpose to prevent the hydraulic piston from being subjected to the force exerted by the concrete pumping piston exerts on him, withdraws in an undesirable manner, being on the concrete pumping piston the possibly considerable pressure of the in the concrete delivery line, which under certain circumstances standing concrete column acts at a considerable height. To that end is according to a further embodiment of the invention provided that in the hydraulic pump line leading to the end of the piston-side pressure chamber of the hydraulic cylinder a non-return valve opening towards the hydraulic cylinder is arranged, which that is, when the hydraulic pump does not deliver to the hydraulic cylinder, it blocks. On the other hand, the hydraulic pump needs to reach the end of the piston-side pressure chamber the line leading to the hydraulic cylinder is not necessarily a non-return valve included Regardless of whether a non-return valve is arranged in this line is, branches a branch line from this line, namely in the Case of the existing non-return valve between this and the hydraulic pump, which is slightly offset in the direction of the piston-side end in the hydraulic cylinder opens into an area of the same which is swept over by the hydraulic piston, and in which a non-return valve opening towards the hydraulic pump is arranged. The purpose of this line is to control the piston displacement during normal operation at this point to end.

In series with this non-return valve that opens towards the hydraulic pump an arbitrarily operable shut-off valve can be arranged and if present a return valve blocking the hydraulic pump can be parallel to this an arbitrarily operable shut-off valve may be present. These shut-off valves or at least one of these are operated arbitrarily, for example when the piston is to be moved to an extreme end position around the concrete pump piston move out of the concrete pumping cylinder to change the seal on the concrete pumping piston. This is because this is relatively often the case with the highly abrasive conveying means.

What is new according to the invention is that in a drive system with a in a closed circuit pump only one circuit for hydraulic cylinders and reversing cylinder is used. But the design of the sequential circuit is also new between hydraulic cylinder and reversing cylinder, as well as the current control for the Current that flows to the reversing cylinders.

Furthermore, the setting of the hydraulic pump to a relative one is new low predetermined flow rate, which is the one at the desired reversing speed un- corresponding to the current consumed by the reversing cylinder, during the actuation time of the reversing device. Correcting is also new the end position of the hydraulic piston through return oil from the hydraulic cylinder, which executes the suction stroke in each case, namely return oil from the hydraulic pump circuit and the reversing cylinder circuit. The electro-hydraulic limitation of the Swiveling angle of the hydraulic pump to change the pump speed. What's new is also the electrical interlocking of the switching solenoids for the switching valve for safety the movement of the reversing organ. Another new feature is the removal of the in the correction phase in the circuit through the surface transfer of excess oil through a pressure relief valve, which is controlled by the exit device and to the connection line or the piston rod-side pressure chambers of the hydraulic cylinders are connected is.

According to the. Invention provided sequential circuit between hydraulic cylinders and reversing cylinder inevitably ensures the correct sequence of movements of the reversing element even if a conveying speed for the concrete flow is set, the strongly deviates from another adjustable speed and or or the work resistance in the concrete column changes significantly or the Temperature changes a lot. This results in an improved degree of filling the concrete pumping cylinder. The arrangement of the mouths of the corresponding lines In certain areas of the hydraulic cylinder enables path-dependent monitoring the piston strokes and prevents pressure peaks in the cylinder end positions. From this it follows a smooth run and steady flow of concrete, an exact end position of the reversing device, which in turn reduces the risk of the concrete delivery lines clogging, and one result in less stress on the components.

The one in the previously known device with closed circuit additionally required pressure accumulator, this is not necessary according to the invention and avoids the risk of accident 'which is then given when maintenance work is carried out must be carried out under pressure storage, and reduces the construction costs considerably, increases operational reliability and eliminates the need for setting and tuning the switching sequences between the hydraulic cylinder main circuit and the reversing cylinder circuit. The regulation of the current flowing to the reversing cylinders ensures a constant flow Reversal adjustment time of the reversing member even without such a pressure accumulator and enables one with the movement of the reversing organ temporally overlapping retraction the stroke volume of the hydraulic pump. The actuating time for the reversing device is as long constant as the pumping speed greater than or equal to one for a given Actuating time of the reversing device specifiedi st. Due to the size difference of Hydraulic cylinder and reversing cylinder is assured that the relationship between maximum concrete pumping speed and minimum concrete pumping speed at which the actuating time of the reversing element would be influenced, for everyone in practical use occurring possible pumping speeds is sufficient. That coincides with the Movement of the reversing device overlapping reduction of the stroke volume of the hydraulic pump has the following advantages: a) There are smaller losses b) The time for the Swinging back the hydraulic pump to the zero stroke position becomes smaller and thus becomes the dead time is smaller, in which there is no conveyance of the concrete flow.

c) By starting the pump in the opposite direction in a situation in which the pump was previously close to the zero flow situation, results a gentle pushing of the concrete column and thus reduced pressure surges in the concrete pipe.

Another advantage of the device according to the invention is that no additional feed is required, rather the correction of the end position of the Hydraulic piston takes place through return oil.

The electro-hydraulic setting of the settings of the hydraulic pump is independent of the viscosity in the main or in the control circuit and is made possible in a simple and inexpensive way to build a remote control with which the setting signal is given by means of a portable control panel, which is confusing Construction sites can easily be carried to another location. The electric lock of the reversing switching valve ensures that only after the reversing cylinder has completed its stroke the switchover takes place.

By limiting the amount of oil flowing in during the correction phase the hydraulic cylinder whose associated concrete pump piston begins the suction phase, it is sufficient to provide a relatively small feed-out device.

Despite the alternating back and forth movement of the concrete pumping pistons the aim is to achieve as continuous a steady flow of concrete as possible, that is Dead times in the switching phases and partial idle stroke of the concrete pumping pistons should should be avoided if possible. This is made possible through appropriate refinements achieved the invention.

An expedient further development achieves that although after switching over the reversing device Hydraulic pump still promotes for a short time in the previous direction before it passes through the zero stroke position is swiveled in the new conveying direction, prevents the concrete column from sinking back will. According to this further development of the invention, this sinking in can be prevented and the delivery gap can be halved by installing the non-return valve already mentioned into the hydraulic pump, which opens directly at the end of the piston-side displacement house-going performance. This backstop valve is based on / then during the rest of the swing back the pressure of the hydraulic pump and the delivery begins immediately after the passage the hydraulic pump through the zero stroke position.

The following is the invention and its possible further developments and their mode of operation is explained using an exemplary embodiment.

In the embodiment, two hydraulic pumps 1 and 2 are provided, which are connected in parallel to each other.

The actuator of the hydraulic pump 1 is connected to an actuating piston 3, which is provided with a conventional servo-boost control device, so that the setting of the pump 1 by the control pressure lines 4 and 5 pending control pressure is determined. The pump 1 is with the closed Circulation working usual devices such as pressure relief valve 6, filter and so on, which are arranged together in a housing 7. With the The same facilities are also provided for the pump 2, in which these facilities are arranged in the housing 8. The actuator of the pump 2 is with the actuating piston 9 connected, which in turn is part of a servo-assist device that is acted upon by the control pressure in lines 4 and 5.

A hydraulic piston 11 is displaceable in the hydraulic cylinder 10, its piston rod 12 with the concrete pump piston no longer shown in the drawing is connected, which is also no longer shown in one in the drawing Concrete pump cylinder is displaceable.

There is another one between the hydraulic piston 11 and the piston rod 12 Stop part 13 is arranged.

In the same way, a hydraulic piston is located in the hydraulic cylinder 14 15 slidable, which is connected to a piston rod 16, which in turn in turn is connected to a concrete pump piston no longer shown in the drawing, in a concrete pump cylinder also no longer shown in the drawing is movable. There is also a stop part between the hydraulic piston 15 and the piston rod 16 13 provided.

The hydraulic pump 1 delivers either in one of the two lines 17 or 18 and draws in from the other of these two lines 17 and 18. The hydraulic pump 2 optionally delivers into one of the two lines 19 or 20.

The two lines 17 and 20 are through the linking line 22 connected to one another at the junction point 21.

In the same way, the two lines 18 and 19 are through the Linking line 24 connected to one another at node 25. The two Pumps 1 and 2 are thus connected in parallel to one another and jointly deliver on the one hand into the line 26 going out from the connection point 21, on the other hand into that of the connection point 25 outgoing line 27, the line 26 to the piston-side end of the hydraulic cylinder 10 connected and the line 27 to the piston-side end of the hydraulic cylinder 14 is connected. A non-return valve 28 is arranged in the line 26 and before the return valve 28 branches off a branch line 29, which in the Hydraulic cylinder 10 opens into an area from the hydraulic piston 11 can be painted over. In this branch line 29 is a non-return valve 30 arranged, this non-return valve 30 blocks towards the cylinder 10 while the non-return valve 28 opens towards the cylinder 10. In series with the non-return valve 30, an arbitrarily actuatable shut-off valve 31 is provided in the branch line 29 and in parallel with the non-return valve 28 is an arbitrarily actuatable shut-off valve 32 arranged.

In the same way, a non-return valve is in the line 27 33 arranged and branches off from the line 27 from a branch line 34, in which a non-return valve 35 is arranged, likewise the branch line 34 opens into a region of the hydraulic cylinder 14 which is supported by the hydraulic piston 15 can be painted over.

In the area of the piston rod end position of the hydraulic piston 11, an annular groove 36 is provided, from which a line 37 branches off, which leads to a Input of a pressure-dependent switchover valve 38 leads. In the same way On the cylinder 14 there is an annular space 39 in the area of the piston rod side End position of the piston 15 is provided, a line 40 branching off from the annular groove 39, which leads to the second input of the shuttle valve 38. The output of the shuttle valve 38 is connected to the two lines 41 and 42, the line 41 doing one Annular groove 43 on the reversing cylinder 45, in which the reversing piston 44 is displaceable is, while the line 42 leads to an annular groove 46 on the reversing cylinder 47 is provided, in which the reversing piston 48 is displaceable. With both of them Reversing piston 44 and 48 is connected to reversing member 50, through which alternately the two no longer shown in the drawing Concrete pumping cylinder either with the concrete delivery pipe or with the concrete suction pipe or the Concrete storage tub to be connected.

In the hydraulic cylinder 10 is on the piston rod side of the piston 11 a pressure chamber 52 is formed and is a pressure chamber on the piston side of the piston 11 53 formed.

In the same way is in the hydraulic cylinder 14 on the piston rod side of the piston 15, a pressure chamber 54 is formed and is on the piston side of the hydraulic cylinder 14 a pressure chamber 55 is formed.

On the one hand in the annular groove 36 of the hydraulic cylinder 10 and on the other hand The connecting line 51 ′ opens into the annular groove 39 of the hydraulic cylinder 14 that of the piston rod side pressure chamber 52 of the hydraulic cylinder 10 and the piston rod side Pressure chamber 54 of the hydraulic cylinder 14 are connected to one another, so that these two pressure chambers 52 and 54 on the piston rod side together with the connecting line 51 form a system of communicating tubes, with the result that when the hydraulic piston 11 moves in one direction, the hydraulic piston 15 moves in the other direction moves at the same speed because the pistons 11 and 15 are the same Have diameter and the piston rods 12 and 16 also have the same diameter exhibit.

In addition to the annular groove 36, opposite this in the direction of the piston-side A second annular groove 56 is formed on the hydraulic cylinder 10, which in the end position of the hydraulic piston 11 on the piston rod side in front of its end face lies. A line 57 in which a measuring throttle point extends from this annular groove 56 58 is arranged.

Before this measuring throttle point 58 between this and the hydraulic cylinder 10 is to the line 57 via a Line 59 is an input of the a pressure compensator controlled valve 60 connected, the second side of the Pressure compensator of this valve 60 is connected to the connecting line 51.

In the same way, there is an annular groove on the hydraulic cylinder 14 61 formed, from which a line 62 extends to a measuring throttle point 63 leads, with a line 64 from the line 62 upstream of the measuring throttle point 63 branches off, which leads to an input of the valve 65 controlled by a pressure compensator, the second side of this pressure compensator, in turn, being connected to the connecting line 51 is.

The line behind the measuring throttle point 58 and the spring chamber of the valves 60 controlled by a pressure compensator are connected to a line 66, which are connected to an input of a pressure-dependent reversing valve 67, the second input of which is connected to line 40 via line 68.

In the same way, the output of the measuring throttle point 63 and the line connected to the spring chamber of the valve 65 is connected to a line 69, which leads to one input of a pressure-dependent reversing valve 70, the second of which Input via line 71 is connected to line 37.

The two outputs of the shuttle valves 67 and 70 are connected to the two Inlets of a four-way / two-position valve 72 connected, one of which is a line 73 leads to the reversing cylinder 45 and a line 74 to the reversing cylinder 47 leads.

On the reversing member 50 are two electrical contacts 75 and 76 provided.

The two inputs are still on the two lines 66 and 69 a pressure-dependent switching valve 77 connected and to the line 57, a control line 78 is connected in front of the measuring throttle point 58 and to the Line 62 is connected to a control line 79 upstream of the measuring throttle point 63, the two control lines 78 and 79 to the two inputs of a pressure-dependent lead switching shuttle valve 80. The output of the shuttle valve 77 is'mit a control pressure line 81 is connected and the output of the shuttle valve 80 is connected to a control pressure line 82. The two control pressure lines 81 and 82 lead to the two control pressure chambers of a spring-loaded two-way / two-position valve 83, which is connected in series with a spring-loaded preload valve 84 and is connected in parallel with an electrically controlled pressure reducing valve 85. On the one hand to the series connection of the valves 84 and 83, on the other hand to the Valve 85 leading line 86 goes from a power limiter 87 known per se Kind of out.

To line 95, which in turn via line 96 to the feed pressure line the hydraulic pump 1/7 is connected, a pressure reducing valve 94 is connected, on the other hand a Leitng 92 is connected to an input of a Four-way / three-position way valve 91 leads, the second of which; on the same page horizontal connection is connected to a pressureless container 106. To the exit of this four-way / three-position valve 91 are the two inputs of an electrical one controlled four-way / two-position reversing valve 90 connected. At an exit this four-way / two-position reversing valve 90 is a line 88 connected, which is connected to the control pressure line 4, each of which is one Pressure chamber of the adjusting device of the pump 1/7 and the adjusting device of the pump 2/8 lead. To the second output of the four-way / two-position reversing valve 90 line 89 is connected, which in turn is connected to line 5 is that of the respective opposite control pressure chamber on the one hand of the actuating device - - - or two 1enr] cnt, ung the pump 1/7 and on the other hand / the pump 2/8 leads.

The feed-out device 98 is via the line 99 at the connection point 23 linked to lines 20 and 22 and on the other hand via line 100 and the connection point 23a is linked to the lines 18 and 24. The exit device 98 contains a pressure-dependent controlled three-way / three-position valve 101, on whose Output a pressure relief valve 102 is connected, upstream of which via a control pressure line 104 the pressure relief valve 105 is connected.

The drawing shows the neutral position in which the piston-side Pressure chambers 53 and 55 of the hydraulic cylinders 10 and 14 with that also in the lines 95, 96, 97 applied feed pressure.

In the rod-side pressure chambers 52 and 54 of the hydraulic cylinder 10 and 14 there is a higher pressure than in the piston-side pressure chambers 53 and 55, corresponding to the ratio of the ring area around the piston rods 12 and 16 to the full face of pistons 11 and 15 and corresponding to the friction on the hydraulic pistons 11 and 15 and the concrete pumping pistons connected to them. The shuttle valves 70, 67 and 80 assume the switching position shown in the drawing. The exit device 98 is closed, possibly excess tax and Amount of cooking oil flows via the control pressure relief valve arranged in the housing 7 or in the housing 8 in the respective interior of the housing 7 or 8 and cools there and flows from there back to the pressureless storage tank.

By arbitrarily applying an electrical signal to the electrical controlled valve 91, the two pumps 1 and 2 are swiveled out in one conveying direction, so that the pump 1- in line 17 and the pump 2 in line 20 promotes with the As a result, there is pressure in the piston-side pressure chamber of the hydraulic cylinder 10 builds up the hydraulic piston 11 and the concrete pumping piston connected to it to the right in the drawing. The pressure in line 22 is transferred through the line 99 to the discharge device 98, which opens and for a predetermined, fixed in advance output flow the way to the unpressurized Container 106 releases.

The one shifting in the hydraulic cylinder 10 to the right in the drawing Hydraulic piston 11 displaces pressure medium on its rod side from pressure chamber 52, which flows via the connecting line 51 into the pressure chamber 54 and the hydraulic piston 15 shifts to the left in the drawing. In the one shown in the drawing However, the position is the annular groove 39 and thus the connecting line 51 through the Hydraulic piston 15 covered. A line 107 branches off from the line 40, however in which a non-return valve 108 opening towards the pressure chamber 54 is arranged is, so that the pressure medium from the pressure chamber 52 via the connecting line 51, the Line 40, line 107 and non-return valve 108 into pressure chamber 54 can flow. Parallel to the non-return valve 108 is between the line 107 and a throttle point 109 is provided in the pressure chamber 54 on the piston rod side. Moves namely, in a different work phase, the piston 15 according to the drawing on the right, so from the moment when the hydraulic piston 15 closes the annular groove 39, through the piston 15 volume from the ver pressure chamber 54 / pushes, which only through the throttle 109 can flow off, so that the movement of the hydraulic piston 15 muffled will. Such a damping device with a line 107, a non-return valve 108 and a throttle point 109 is also provided on the hydraulic cylinder 10.

The hydraulic piston 11 moves to the right in the drawing, as soon as the pressure on its end face as a result of the pressure prevailing in the pressure chamber 53 acting force is greater than the working resistance on the assigned concrete pumping piston including the friction on this and on the piston rod 12.

As a result of the flow resistance in the connecting line 51 is the pressure in the pressure chamber 52 is somewhat greater than the pressure in the pressure chamber 54. Conditional Due to this pressure difference, the shuttle valves 38 and 67 also switch into the switching position which corresponds to the switching position of the changeover valves 70, 77 and 80. The same pressure prevails in both reversing cylinders 45 and 47.

Since a large force is required for each movement of the reversing member 50 is, this does not move.

Reached with the further displacement of the hydraulic piston 11 after in the drawing to the right of this its end position, the connection between the two is Reversing cylinders 45 and 47 separately. First, the hydraulic piston 11 separates the Annular groove 56 from the rod-side pressure chamber 52 and gives in the event of further displacement in front of its end face, the pressure chamber 53 is free up to the annular groove 56.

As a result, the pressure prevailing in the pressure chamber 53 is via the line 57 is also given to the switching valve 80 and divides through this into the control pressure line 82 with. The movement of the hydraulic piston is controlled by the damping device 107, 108, 109 11 braked to the right.

In line 66, too, there is now a pressure that is greater than the Switching valve 67 notifies the reversing cylinder 47, so that the reversing member now the connection between the space in front of the concrete pumping piston connected to the piston rod 12 and the concrete delivery pipe separates and on the other hand the connection of the space in front of the Front side of the concrete pump piston connected to the piston rod 16 with the concrete storage space separates and connects the space in front of this concrete pumping piston with the concrete delivery pipe.

The reversing device should be as independent as possible of the speed, with which the hydraulic pistons 11 and 15 have moved in a predetermined Toggle time. For this switchover, the respective reversing cylinder 45 or 47 only flow in a current that is less than a maximum of about a third of the current that flows to the pressure chamber 53 or the pressure chamber 55 at a maximum.

The rest is transferred to the rod side via a flow control device Discharge pressure chamber. This flow control device consists of the measuring throttle point 58 and the valve 60 controlled by a pressure compensator. The function of this flow control device is the following: To a constant the respective reversing cylinder 45 or 47 to maintain the inflowing oil flow, the pressure drop at the measuring throttle point must 58 can be kept constant. This pressure gradient at the measuring throttle point 58 is predetermined by the spring on the pressure compensator of the valve 60. Will this pressure gradient at the measuring throttle point 58 is greater than that predetermined by the spring preload Pressure gradient, the valve 60 opens and directs the excess flow into the connecting line 51 and thus into the rod-side pressure chamber 54 of the respective other cylinder. This function only occurs when the hydraulic piston 11 is assigned to it The rod-side pressure chamber 52 is separated from the connecting line 51 and for this purpose via the annular groove 56 connects the line 57 to the piston-side pressure chamber 53.

In addition to this aforementioned function, however, the measuring throttle point 58 another signal is picked up by which the control pressure for the hydraulic pumps 1 and 2 is changed in such a way that these are reduced to a smaller stroke volume per revolution can be set. As soon as the pressure difference at the measuring throttle point 58 exceeds about two thirds of the measuring pressure gradient at this measuring throttle point, this signal switches the directional control valve 83 to free via the shuttle valves 77 and 80 Flow rate, since the signal pressure in the control pressure line 82 increases by the pressure drop the measuring throttle point 58 is greater than the signal pressure in the control pressure line 81. This increases the control pressure for hydraulic pumps 1 and 2 to the pressure supplied by the Pre-load valve 84 lowered predetermined pressure, so that the hydraulic pumps 1 and 2 can be set to a flow rate which corresponds to that for the reversing cylinder 45 or 47 corresponds to the desired current. This in addition to the aforementioned Flow control device acting lowering function of the control pressure and thus withdrawal of the pump delivery flow of hydraulic pumps 1 and 2 shortens the dead time when switching from the pump stroke in the hydraulic cylinder 10 to the pump stroke in the hydraulic cylinder 14, because the time during which hydraulic pumps 1 and 2 swivel back and the time in which the reversing member 50 reverses, partially overlap. Furthermore, the starting shock decreased in the opposite direction, since the hydraulic pumps 1 and 2 do not run out of maximum Swivel the pivoting angle out in the opposite direction, but also out of the pivoting angle out to which those of valve 83 were set.

By the given sequential connection between hydraulic cylinder 10 and respectively 14 and reversing cylinder 45 or 47, the exact switching sequence also remains received if by arbitrarily changing the tax pressure the stroke volume of the hydraulic pumps 1 and 2 and thus the speed of movement of the hydraulic piston 11 or 15 is changed significantly. Big ones too Changes in the resistance in the concrete delivery pipe have no effect. The flow control device ensures constant, load-independent reversal times, as long as not through arbitrary If the control pressure is set, the stroke volume of hydraulic pumps 1 and 2 is already adjusted before opening the valve 83 was set to a pressure which is less than that determined by the preload valve 84 pressure.

During the movement of the hydraulic piston 11 according to in the drawing right and the corresponding movement of the hydraulic piston 15 according to in the drawing On the left, the 01 displaced from the rod-side pressure chamber 52 is transferred to the rod-side Pressure chamber 54 out. This proves itself to a limited extent at low working pressures Friction and the ratio between the annular surface around the piston rod 16 and the face the hydraulic piston 15 is a pressure difference between the pressure chambers 54 and 55 a, the higher pressure prevailing in the pressure chamber 54, with the result that on the hydraulic piston 15 past pressure medium from the pressure chamber 54 into the pressure chamber 55 can flow with the result that the movement of the hydraulic pistons 11 and 15 does not runs exactly symmetrically, and the further consequence that when the hydraulic piston 11 reaches its end position on the piston rod side, the hydraulic piston 15 reaches its end position has not yet reached and rather the mouth of the line 34 is still shutting off. These However, at the end of each stroke, the misalignment is caused by the valve 60 and the Connecting line 51 and pressure medium flowing into the rod-side pressure chamber that from the reversing cylinder 45 to which the lower pressure is applied or 47 outflowing pressure medium corrected. Each Hydraulic pistons that are not subjected to the high pressure of hydraulic pumps 1 and 2 11 or 15 continues until it reaches the mouth of the line 34 or 29 releases. In this correction phase, in the. the piston 11 until the release of the The mouth of the line 29 moves or the piston 15 is up to Releasing the line 34 shifts, it would even cut off the gear ratio between the annular surface around the piston rod 12 and 16 in relation to each other to the end face of the respective hydraulic piston 11 or 15 to one Oversupply of 01 come in the cycle. That could lead to pressure peaks and to responding the overpressure valves of the pumps. That can be avoided by a sufficiently large exit device 98 or by the arrangement on the rod side of the pressure relief valve 105. In order to avoid that the discharge device 98 excessively becomes large, the solution with a pressure relief valve is preferable. The pressure relief valve is also controlled as a function of the exit volume to ensure that it only responds at the desired time.

At the end of the reversing process of the reversing member 50, the reversing piston opens an outlet hole, so that the inflowing oil via the shuttle valve 38 and the rod-side pressure chamber 54 of the respective in the suction phase of the concrete pump cylinder located hydraulic cylinder 14 can flow back into the circuit without pressure. This avoids pressure peaks and avoids impact noises at the end of the stroke. A defined end position of the reversing piston is ensured by short opening strokes. At the same time, when the end position of the reversing piston 44 or 48 an electrical contact 75 or 76 actuates the electromagnet of the solenoid valve 90 applies voltage and thus the gradient the Control pressures between the control pressure lines 4 and 5 changes, so that the hydraulic pumps 1 and 2 are swiveled in the opposite direction of conveyance. It sinks first of all the flow rate of pumps 1 and 2 and thus the pressure drop across the respective effective measuring throttle point 58 or 63 with the result that the signal is passed on via the shuttle valves 77 and 80, and the two-port / two-position valve 83 switches back to its original position. This means that the full control pressure can be used again are built up and the hydraulic pumps 1 and 2 at their maximum swivel position can be set.

The electrical magnets of the solenoid valve 90 are electrical such locked against each other that during the switching of the reversing member 50 of each The last actuated magnet of valve 90 remains energized until the counter magnet is switched on. This known locking means that disturbances in the switching phase of the reversing device avoided. After reversing, the pressure chamber is 55 of the cylinder 14 is applied, so that, mutatis mutandis, the same effect and the same workflow results as described for the pressurization of the pressure chamber 53.

The respective effective control pressure in one of the control pressure lines 4 and 5 can be arbitrarily influenced by means known per se to the Adapt the pump speed to the respective requirements, for example to for this purpose via a potentiometer no longer shown in the drawing The excitation current at the pressure reducing valve 85 can be changed sensitively.

For the purpose of emptying the concrete pump at the end of work on one At the construction site or when the concrete delivery pipe has clogged, suction mode is activated switched.

Only the direction of movement of the hydraulic piston 11 and 15 assigned to the opposite position of the reversing element 50, so that not is sucked in from the feed container but from the concrete delivery line. To this The purpose of this is the magnet of valve 91 which is opposite to the normal case in each case the corresponding magnet of the valve 92 is applied jointly to voltage.

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Claims (13)

Claims Hydrostatic drive for a concrete piston pump with two alternately extending concrete pumping pistons and a concrete flow control device, each of the two concrete pumping pistons with one double-acting hydraulic piston each is connected, which is displaceable in a hydraulic cylinder, with between the one of the two pressure chambers on the piston rod side of each of the hydraulic cylinders There is a connecting line and the piston-side pressure chambers of both cylinders a hydraulic pump operating in a closed circuit are connected and furthermore, the concrete flow control element with two displaceable in one reversing cylinder each Reversing piston is in operative connection and each reversing cylinder is dependent on Path of the hydraulic piston controlled control organs is connected, characterized in that that the energy of the reversing cylinder (45 or 47) flowing current derived from the energy of the current conveyed by the hydraulic pump (1,2) is and the. Reversing cylinders (45, 47) to the piston rod side by means of the control elements Pressure chambers (52, 54) of the hydraulic cylinder (10, 14) connected are. 2. Hydrostatic drive according to claim 1 with an adjustable Hydraulic pump, the setting element with a control pressure-dependent hydraulic Tax input. direction is provided, characterized in that on each hydraulic cylinder (10, 14) in an area that is different from the one in this hydraulic cylinder (10 or 14) displaceable hydraulic piston (11 or 15) before reaching the piston rod side End position is passed and when the piston rod-side end position of the Hydraulic piston (11 or 15) with the piston-side pressure chamber (53 or 55) is connected, a line (57 or 62) is connected to the a measuring throttle point (58 or 63) leads, between this measuring throttle point (58 or 63) and the associated hydraulic cylinder (10 or 14) to this (57 or 62) a valve control line (78 or 79) is connected, which leads to a pressure chamber of a control valve (83) that in a control pressure which determines the setting of the hydraulic pump (1,2) Control pressure line (4, 5, 86) is arranged. 3. Hydrostatic drive according to claim 2, characterized in that that to the line (57 or 62) between the hydraulic cylinder (10 or 14) and measuring throttle point (58 or 63) a branch line (59 or 64) is connected to an input of a pressure compensator controlled Valves (60 or 65) leads, the second side of the pressure compensator with of the line (66 or 69) behind the measuring throttle point (58 or way 63) is connected and the drain of this valve (60 or 65) with the rod-side pressure chamber (54 or 52) of the other hydraulic cylinder (14 or 10) is connected. 4. Hydrostatic drive according to claim 3, characterized in that that the drain line of the valve controlled by a pressure compensator (60 or 65) is connected to the connecting line (51). 5. Hydrostatic drive according to claim 2, characterized in that that the line (66 or 69) leads to the reversing cylinder (45 or 47). 6. Hydrostatic drive according to claim 2, characterized in that that the mouth of the connecting line (51) in the hydraulic cylinder (10 or 14) is arranged in an area of the same, which is before and when reaching the piston rod side The end position of the hydraulic piston (11 or 15) is covered by this. 7. Hydrostatic drive according to claim 5, characterized in that that in the area of the hydraulic cylinder that is before and when reaching the piston rod side End position of the hydraulic piston (11 or 15) is covered by this on each of the hydraulic cylinders (10 and 14) a line (37 and 40) is connected to which a pressure-dependent reversing valve (38) is connected, with each side of this pressure-dependent reversing valve (38) one of these lines (37 and 40) connected and the output of this pressure-dependent reversing changeover valve (38) with two lines (41 and 42) is connected, each in a reversing cylinder (45 and 47) open in an area of the same, which is in front of the face of the in this reversing cylinder (45 or 47) displaceable reversing piston (44 or 48) is located, when this has reached its end position on the piston rod side and in other positions of the reversing piston (44 or 48) is covered by this. 8.Hydrostatic drive according to claim 5, characterized in that indicates that each of the two has one hydraulic cylinder in one area of the same, when the piston rod-side end position of the hydraulic piston is reached (11 or 14) is covered by this, outgoing lines another pressure-dependent switching Shuttle valve (67 or 70) is connected to its second inlet the line (69 or 66) behind the other hydraulic cylinder (14 or 10) associated measuring throttle point (63 or 58) connected is and connected to the output of a four-way / two-position valve (72) is, at the two outputs of each one to one of the reversing cylinders (45 and 47) leading line (73 and 74) is connected, the four-way / two-position valve (72) is electrically switchable at will. 9. Hydrostatic drive according to claim 2, characterized in that indicates that the two are connected in front of a measuring throttle point (58 or 63) Lines (78 or 79) to a pressure-dependent changeover valve (80) and the two lines behind each measuring throttle point (58 or 63) to a second pressure-dependent changeover valve (77) lead and that the two of each of these two shuttle valves (77 and 80) outgoing lines to the two control pressure chambers of a two-way / two-position valve (83) that is connected to the control pressure line of the hydraulic pump (1, 2) is, with the valve (83) open, the hydraulic pump (1, 2) to a predetermined Stroke volume is set. 10. Hydrostatic drive according to claim 9, characterized in that that in series with the two-way / two-position valve (83) a preload valve (84) is switched. 11. Hydrostatic drive according to claim 9, characterized in that that parallel to the two-way / two-position valve (83) an electrically controlled, in the de-energized state of the solenoid, open pressure reducing valve (85) is switched. 12. Hydrostatic drive according to claim 1, characterized in that that on the one hand to the hydraulic pump (1, 2), on the other hand to one end of the piston-side pressure chamber (53 or 55) of the hydraulic cylinder (10 or 14) line connected to this hydraulic cylinder (10 or 14) opening non-return valve (28 or 33) is arranged. 13. Hydrostatic drive according to claim 12, characterized in that that parallel to the hydraulic cylinder (10 or 14) a non-return valve (28 or 33) opening towards an arbitrarily operable one Valve (32) is arranged.