RU2358154C2 - Driving device for double-cylinder pump for high-density materials and method of its operation - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: invention is related to method for operation of driving device for double-cylinder device for double-cylinder pump for high-density materials or to driving device for double-cylinder pump for high-density materials with two driving cylinders (1, 2) actuated by means of liquid, which via tubular transition device (RW) alternately, in particular, by means of driving cylinders (FR,FL) send high-density material, in particular, concrete, into common pressure pipeline. Tubular transition device is actuated with the help of liquid by means of actuating cylinder (SZ) and already during final travel of piston of every driving cylinder in piston travel before it achieves final position, at least part of liquid flow prepared for actuation of driving cylinders is used for actuation of actuating cylinder.

EFFECT: provides for fast change-over of transition device.

36 cl, 3 dwg

Description

The invention relates to a method for operating a two-cylinder pump for high-density materials or to a drive device for a two-cylinder pump for high-density materials according to the preamble of claim 1 or the restrictive part of claim 20.

Double-cylinder pumps for high-density materials are used, for example, for concrete. In this case, concrete, for example, is pumped to considerable heights and large distances using appropriate distribution supports. When operating such two-cylinder pumps for high density materials, the injection cylinders are connected to a common discharge pipe by means of a transition device, in particular a pipe transition device, the transition device alternately connecting one or the other injection cylinder to the discharge pipe, so that an almost continuous flow is obtained as a whole high density material or concrete.

Due to the inevitable change in the connections of the discharge cylinders to the common discharge pipe by means of a transition device, short supply interruptions occur during the switching process.

This follows, for example, from the block diagram in figure 2, which shows a hydraulic actuator for a two-cylinder pump for high density materials. The indicated block diagram corresponds to the so-called single-circuit system in which the drive cylinders 1, 2 of the pressure cylinders FR, FL, as well as the actuator cylinder SZ of the pipe adapter are supplied with hydraulic oil or create working pressure with only one supply unit. This single supply unit has two pumps P1 and P2, which are connected through oil pipelines L1 and L2 to a switching unit 3, which, depending on the operating condition, supplies oil pumped by pumps P1 and P2 through pipelines L4 to one drive cylinder 1 or drive cylinder 2 for discharge cylinders FR and FL or through other pipelines L4 to the actuating cylinder or rotary cylinder SZ of the pipe adapter RW.

The use of such a configuration, however, is associated with relatively long switching processes, since only at the end of one stroke of the piston of the drive cylinder 1 or 2, the control unit 3 is turned on so that the total flow rate of the pumps P1 and P2 is provided to the actuator or rotary cylinder SZ.

Only after turning the pipe transition device by actuating the actuator or rotary cylinder SZ, then by switching in the control unit 3, all the pumping power of the pumps P1 and P2 is again transferred to the drive cylinders 1 or 2.

To eliminate such long switching periods, the so-called double-circuit system is known from the prior art (see figure 3), in which the pumps P1 and P2 are installed separately for the drive cylinders 1 and 2 of the pressure cylinders FR and FL, on the one hand, as well as for the executive cylinder or a rotary cylinder SZ of a pipe adapter RW, on the other hand.

Thus, in this case, there are two independent pumping units with, respectively, at least one pump P1 and P2, i.e. the so-called dual-circuit system. With this configuration, the pressure cylinders and the slave cylinder or slave cylinders can be actuated in parallel in time to reduce feed interruption.

It seems obvious that the disadvantage of this system is the need to have two separate pumping units, and pump P1 must have more power so that it is possible to provide the necessary oil flow volume to the hydraulic system for the operation of drive cylinders 1 and 2.

Two-cylinder pumps for high-density materials and methods for their operation are known from DE 19503986 A1 and DE 3505541 A, as well as from DE 9217574 U1.

The objective of the invention is to provide quick switching of the transition device for connecting two pressure cylinders to a common pressure pipe, as well as reducing circuit costs and hydraulic costs of the drive or pressure cylinders and the Executive cylinder for the transition device.

This problem is solved by using a method or a drive device with the characteristics of claims 1 or 20 of the claims. Preferred embodiments are the subject of the dependent claims.

The invention is conceptually based on the notoriety that when driving drive cylinders or injection cylinders of a two-cylinder pump for high density materials using a fluid, in particular hydraulic oil, in the final piston motion region, i.e. at the end of the stroke, full drive power is no longer required. Based on this information, it is possible, using excess or residual drive power, to shorten the switching time due to the fact that excess drive power can be used to drive a transition device, in particular to drive a rotary or actuating cylinder for a pipe transition device. Thus, there is no longer any need to wait until the piston stroke in the drive or pressure cylinder ends, but you can put in place the switching process and thereby actuate the pipe adapter even before the end of the piston stroke.

To this end, according to the invention, the position of the piston in the drive cylinder or in the injection cylinder is controlled and at least the piston is fixed in a certain position shortly before reaching the end position so that, based on this information, a part of the volumetric flow of liquid, preferably volumetric, could be provided fluid flow for the hydraulic system to actuate the actuator or rotary cylinder of the adapter.

The determining device used for this can be of a mechanical, electrical or hydraulic type, the latter being most relevant in the case when all control of the drive is largely carried out using fluid or oil for hydraulic systems. In this case, the corresponding switching valves, which are controlled by known hydraulic control lines, can be used in a simple way.

For a preferred embodiment, appropriate recording devices may be provided for recording the position of the piston of the actuator cylinder of the pipe adapter so that this information can be used for the switching process.

Preferably, the hydraulic circuit has a configuration that allows the use of two pumping units to prepare the appropriate fluid flow or create operating pressure, which, comparable to the dual-circuit system, would first be used independently, on the one hand, to drive the working cylinders, and on the other hand, to drive the actuator or a rotary cylinder for a transition device. In view of the concept underlying the invention and that the drive power for drive cylinders or pressure cylinders should not exceed 100% before connecting the adapter, it is possible to combine both independent pump units so that during travel of the piston of the drive cylinder or discharge cylinder, the second pump installation gave its supply power to the drive or discharge cylinders, while before switching on the second pump snaya installation would only used exclusively to actuate the actuator or rotary cylinder of the adapter.

Thus, it is possible to effectively use the pump power or the discharge power of the drive or to use components with less power.

Preferably, the actuator is designed such that the operating pressure, in particular the second pumping unit in operating mode, remains on the actuator or rotary cylinder.

Changing the direction of the volumetric fluid flow in a simple way can be done using the appropriate switching valve to reduce the cost of switching devices.

Although the invention is described below with an example of a hydraulic actuator with hydraulic oil as a fluid, it goes without saying that the invention can also be used with other fluids and devices for generating pressure and / or supplying fluid.

Other advantages, features and differences of the present invention are illustrated by the description of an example of its implementation with reference to the figures of the drawings, including

figure 1 depicts a block diagram of a drive device according to the invention,

figure 2 is a block diagram of a known single-circuit system,

figure 3 is a block diagram of a known dual-circuit system.

Figure 1 depicts a block diagram of a hydraulic drive of a two-cylinder pump for high density materials with a first drive cylinder 1 and a second drive cylinder 2, which are connected by means of corresponding pistons to the first discharge cylinder FR and the second discharge cylinder FL.

The pressure cylinders FR and FL are connected via a pipe transition device RW to a common pressure pipe so that an alternating stroke of the pressure cylinders FL and FR achieves an almost continuous pumping power for high density material. To this end, the pipe adapter RW, by means of an actuator or a rotary cylinder SZ, must alternately be brought into the connection position between the first discharge cylinder FR and the common discharge pipe or second discharge cylinder FL and the common discharge pipe.

To supply the hydraulic drive, two pumping units are provided, which may respectively have one or more pumps connected in parallel. In the shown block diagram, for each pump unit, only one pump is provided, respectively. The pumping units P1 and P2 are connected through the supply lines L1 and L2 to the control unit 3, which contains the switching valves 3.1 and 3.2, which are also connected to the pipelines L4 and L4a for the hydraulic medium.

An intermediate pipe is provided between the supply lines L1 and L2 for interconnecting, into which the switching valve 6 is mounted, so that hydraulic oil that is pumped by the first pump unit P1 in the discharge pipe L1 can be pumped into the second discharge pipe L2. In particular, the switching valve 6 serves to ensure that hydraulic oil that is pumped from the second pump unit P2 in the discharge line L2 to maintain a sufficient oil flow for driving the drive cylinders 1 and 2 can flow into the first discharge line L1.

The hydraulic oil in the supply line L1 is then fed through the switching valve 3.2, respectively alternately through the supply lines L4, to the first drive cylinder 1 or the second drive cylinder 2, in order to actuate the pressure cylinders FR and FL with their help. Through the pipeline L9, the oil flows back.

Switching valves VFR and VFL are provided on the drive cylinders 1 and 2, by means of which the alternating reciprocating motion in the driving cylinders 1 and 2 is controlled. Due to the alternating reciprocating motion of the pistons of the driving cylinders 1 and 2, they are hydraulically connected to each other via control pipes SL5 , SL6 and SL9.

The switching valves VFR and VFL simultaneously form a so-called power switch, with which you can determine the position of the piston in the drive cylinders 1 and 2. At the same time, the control pipelines SL8 and connected to the switching valves VFR and VFL are respectively loaded SL10, which again control the switching valves 3.1 and 3.2 in the control unit 3 or switching valve 6.

This is done in such a way that when changing the discharge stroke of the discharge cylinder FR relative to the discharge cylinder FL or vice versa, the adapter tube must also be actuated by means of an actuating cylinder or a rotary cylinder SZ. To this end, the actuating cylinder SZ is switched on by means of a switching valve 3.1 by means of a second pump unit P2 and supply lines L2 and L4a with an appropriate amount of hydraulic oil or is pressurized. In order to enable quick switching with the switching valve 6 before reaching the corresponding end position of the piston of the drive cylinder 1 or 2, the switching valve 3.1 and the switching valve 6, respectively, are triggered by hydraulic signals via the control lines SL8 and SL10, respectively.

In this case, the switching valve 6 blocks the connecting pipe between the discharge lines L1 and L2 so that the oil flow no longer flows from the discharge line L2 into the discharge line L1 and thus can no longer supply the drive cylinders 1 and 2. However, the power the pressure of the second pump unit P2 is completely transmitted to the rotary cylinder SZ, and the switching valve VSZ is also actuated by means of the corresponding hydraulic control pipes SL18 and SL19 the actuator or rotary cylinder SZ or it gives the appropriate control signals to the switching valve 6.

Due to the use of the switching valve 6, the volumetric flow of oil, which is usually used to drive the drive cylinders 1 and 2 with the help of the second pump unit P2, in the final phase of the movement of the pistons of the corresponding drive cylinders 1 and 2, when this volumetric flow is not strictly necessary, first It is used to actuate the rotary cylinder to reduce the pump stopping time for high density materials.

Since the second pump unit P2 through the supply pipe L2 is directly connected to the switching valve 3.1 or through hydraulic pipelines L4a with the rotary or slave cylinder SZ, the working pressure of the second pump unit P2 is directly at the disposal of the rotary cylinder SZ during the entire operating cycle.

In the shown embodiment, we are talking, therefore, about the preferred combination of a single-circuit system and a dual-circuit system, in which the pumping power of the second pump installation is optionally used both to drive the drive cylinders 1 and 2, and the rotary or Executive cylinder SZ. In particular, at the end of the reciprocating movement, in which the entire supply power of the pumping units is not necessary to actuate the drive cylinder before being brought to its final position, it is thus obtained that it is preferable to prepare part of the volumetric flow of oil for actuating the swivel cylinder transition pipe, thereby minimizing the reduction in interruption of the injection flow.

Claims (36)

1. A method of driving a two-cylinder pump for high density materials, preferably for concrete injection, with two alternately driven discharge cylinders (FL, FR), which by means of a transition device (RW) feed high density material into the common discharge pipe, the discharge the cylinders (FL, FR) are driven by fluid through the drive cylinders (1, 2) and the adapter (RW) is also driven by fluid through the actuator Indra (SZ), whereby a first pumping unit (P1) is provided, the volumetric fluid flow of which is first supplied to the drive cylinders (1, 2) by means of the first supply pipe (L1), and the second pumping unit (P2), whose volumetric fluid flow is through the second the supply pipe (L2) is first supplied to the slave cylinder (SZ), characterized in that, during the piston stroke of the drive cylinder (1,2), at least a portion of the volumetric fluid flow of the second pump unit (P2) passes to the volumetric fluid flow of the first pumping mouth ovki (P1) for actuating cylinders (1,2). 2. The method according to claim 1, characterized in that the volumetric fluid flow or part of it passing through the second supply pipe to the rotary cylinder (L2) is directed through an intermediate pipe into which the switching device is mounted into the first supply pipe to the drive cylinders ( L1). 3. The method according to claim 1 or 2, characterized in that the volumetric flow of fluid in the first supply pipe (L1) using the switching valve (3.2) alternately directs to the first drive cylinder (1) or to the second drive cylinder (2). 4. The method according to claim 2, characterized in that the volumetric flow of fluid in the first supply pipe (L1) using the switching valve (3.2) alternately directs to the first drive cylinder (1) or to the second drive cylinder (2). 5. The method according to one of claims 1 to 4, characterized in that before reaching the end position of the piston of the drive cylinder (1,2), the switching device blocks the passage of the volumetric fluid flow through an intermediate pipe located between the supply pipes (L1) and (L2) . 6. The method according to one of claims 1 to 4, characterized in that the final position of the piston in the drive cylinders is determined using the power switch to configure the switching device. 7. The method according to claim 5, characterized in that the final position of the piston in the drive cylinders is determined using a power switch to configure the switching device. 8. The method according to one of claims 1 to 4, 7, characterized in that the volumetric fluid flow is formed by a pumping unit (P1, P2), respectively, by one or more pumps. 9. The method according to claim 5, characterized in that the volumetric flow of liquid is formed by a pump unit (P1, P2), respectively, by one or more pumps. 10. The method according to claim 6, characterized in that the volumetric flow of liquid is formed by a pumping unit (P1, P2), respectively, by one or more pumps. 11. The method according to one of claims 1 to 4, 7, 9 and 10, characterized in that the liquid used is oil for hydraulic systems. 12. The method according to claim 5, characterized in that the liquid used is oil for hydraulic systems. 13. The method according to claim 6, characterized in that the liquid used is oil for hydraulic systems, 14. The method according to claim 8, characterized in that the liquid used is oil for hydraulic systems. 15. The method according to one of claims 1 to 4, 7, 9, 10, 12-14, characterized in that the drive cylinders (1, 2) are controlled by an actuating cylinder (SZ) and / or other switching valves required for operation with using hydraulics. 16. The method according to claim 5, characterized in that the drive cylinders (1, 2) are controlled by an actuating cylinder (SZ) and / or other switching valves required for operation by hydraulics. 17. The method according to claim 6, characterized in that the drive cylinders (1, 2) are controlled by an actuating cylinder (SZ) and / or other switching valves required for operation by hydraulics. 18. The method according to claim 8, characterized in that the drive cylinders (1, 2) are controlled by an actuating cylinder (SZ) and / or other switching valves required for operation by hydraulics. 19. The method according to claim 11, characterized in that the drive cylinders (1, 2) are controlled by an actuating cylinder (SZ) and / or other switching valves required for operation by hydraulics. 20. Drive device for a two-cylinder pump for high-density materials with two driven drive cylinders (1, 2), which by means of an adapter (RW), in particular a tube adapter, alternately, in particular by means of driven discharge cylinders (FR, FL) direct a high-density material, in particular concrete, into a common discharge pipe, the pipe adapter being also driven by liquid by means of an actuating cylinder (SZ), in hours stnosti, to implement the method in accordance with one of claims 1 to 19 using the first pumping unit (P1), through which the liquid through the first supply pipe (L1) under a working pressure is first supplied to the drive cylinders (1, 2) and using a second pump installation, through which the liquid through the second supply pipe (L2) is first supplied under operating pressure to the actuating cylinder, and a sensing device (VFR, VFL) is provided for establishing at least one piston position of each drive cylinder RA (1, 2), made in such a way that the position of the piston is determined in the final range of motion before reaching the final position of the piston stroke, characterized in that between the first and second supply pipelines (L1, L2) an intermediate pipeline is provided for interconnection into which a switching valve (6) is mounted, configured to discharge at least a portion of the fluid flow produced by the pumping units (P1, P2), so that the fluid can pass from the first supply pipe (L1) to the second supply pipe water supply (L2), moreover, during the piston stroke of the drive cylinder (1, 2), fluid can transfer from the second supply pipe (L2) to the first supply pipe (L1), while the switching valve (6) is actuated after determining the position of the piston by determining device. 21. The drive device according to claim 20, characterized in that one pump installation is provided with one or more pumps for supplying the drive cylinder and the executive cylinder. 22. The drive device according to PP.20 or 21, characterized in that the liquid used is oil for hydraulic systems. 23. The drive device according to PP.20 or 21, characterized in that the determining device (VFR, VFL) contains one or more mechanical, electrical or hydraulic sensing elements for determining the position of the piston. 24. The drive device according to item 22, wherein the determining device (VPR, VFL) contains one or more mechanical, electrical or hydraulic sensing elements for determining the position of the piston. 25. The drive device according to one of paragraphs.20, 21 and 24, characterized in that the recording device (VSZ) for registering the position of the piston of the actuator or rotary cylinder of the pipe adapter contains one or more mechanical, electrical or hydraulic sensing elements for determining the position of the actuator or rotary cylinder. 26. The drive device according to item 22, wherein
a recording device (VSZ) for recording the position of the piston of the actuating or rotary cylinder of the pipe transition device comprises one or more mechanical, electrical or hydraulic sensing elements for determining the position of the actuating or rotary cylinder. 27. The drive device according to item 23, wherein the recording device (VSZ) for registering the position of the piston of the actuator or rotary cylinder of the pipe adapter contains one or more mechanical, electrical or hydraulic sensing elements for determining the position of the actuator or rotary cylinder. 28. The drive device according to one of paragraphs.20, 21, 24, 26 and 27, characterized in that the drive cylinders (1, 2) are hydraulically connected so that only one or two sensing elements are provided on one of the drive cylinders for determining the position piston in the respective drive cylinders. 29. The drive device according to claim 22, characterized in that the drive cylinders (1, 2) are hydraulically connected so that only one or two sensing elements are provided on one of the drive cylinders to determine the position of the piston in the respective drive cylinders. 30. The drive device according to item 23, wherein the drive cylinders (1, 2) are hydraulically connected so that only one or two sensing elements are provided on one of the drive cylinders to determine the position of the piston in the respective drive cylinders. 31. The drive device according A.25, characterized in that the drive cylinders (1, 2) are hydraulically connected so that only one or two sensing elements are provided on one of the drive cylinders to determine the position of the piston in the respective drive cylinders. 32. The drive device according to one of paragraphs.20, 21, 24, 26, 27, 29, 30 and 31, characterized in that the switching device is hydraulically controlled and, in particular, includes a switching valve (6). 33. The drive device according to item 22, wherein the switching device is hydraulically controlled and, in particular, includes a switching valve (6). 34. The drive device according to item 23, wherein the switching device is hydraulically controlled in particular, includes a switching valve (6). 35. The drive device according A.25, characterized in that the switching device is hydraulically controlled, in particular, includes a switching valve (6). 36. The drive device according to p. 28, characterized in that the switching device is hydraulically controlled, in particular, includes a switching valve (6).

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