DE102009008517A1 - Slurry pump i.e. concrete pump, has boost pressure device fitted at suction line to compress slurry, where medium flow is supplied to another medium flow for temporary reinforcement of former medium flow - Google Patents

Abstract

The pump has a pumping unit (21) connected to a conveyor line (29) in a pumping mode and to a suction line (28) in a suction mode by a changeover device (25). A boost pressure device (23) is fitted at the suction line to compress slurry i.e. concrete. A secondary pressure medium source e.g. hydraulic pump unit, is provided for the pressure device. A secondary pressure medium flow is supplied to a primary pressurized medium flow from a primary pressure medium source (5) for temporary reinforcement of the secondary pressure medium flow, by the secondary pressure medium source.

Description

The Invention relates to a slurry pump with continuous flow of thick matter, especially for pumping concrete.

Such a device usually consists of two pumping units ( 21 + 22 ), each of a delivery cylinder and a hydraulic drive cylinder ( 1 + 2 ), which by a pressure medium source ( 4 ) are driven.

The pumping units ( 21 + 22 ) are by the Umstellinrichtung ( 25 ) in pumping operation with the delivery line ( 29 ) and in suction mode with the suction line ( 28 ) connected.

At this is a separately acting boost pressure device ( 23 ), which causes in the final phase of the sowing operation, a compression of the thick material and during the changeover pressure and flow in the delivery line ( 29 ).

To enable both, the performance of the boost pressure device ( 23 ) above that of the pumping units ( 21 + 22 ) are in suction mode.

Both Goals can be achieved by using a sufficiently large Achieve pressure medium source according to the requirements the boost pressure device must be controlled.

Such a slurry pump is in the EP 1235982 described.

These The solution, however, has the disadvantage that the control is limited to short-term, unpredictable changes in the required pressure medium flow often can not react fast enough, so the constant River, just from a clean customization is not always fully achieved.

It is therefore the object of the invention to propose a solution which allows the operation of the boost pressure device ( 23 ) according to the requirements, cost-effective and easy to control enabled.

This is done by the means of claim 1, characterized in that a secondary pressure medium source ( 6 . 7 ) for the boost pressure device ( 23 ) is provided by means of the to a primary pressure medium flow from the pressure medium source ( 5 ) of the boost pressure device ( 23 ) For at least temporarily reinforcing the same at least a secondary pressure medium flow can be fed.

The boost pressure device ( 23 ) At the beginning of their stroke requires at times an increased pressure medium flow with low pressure and in the final phase, for the compression of the material, increased pressure but reduced pressure medium flow.

The connection of the secondary pressure medium source ( 6 . 7 ) takes place expediently with the start of the boost pressure device ( 23 ). This is determined by a predetermined position ( 19 ) of a piston ( 30 ) the drive cylinder ( 1 + 2 ) of the pumping units ( 21 + 22 ) in suction mode.

Via a switching valve ( 11 ), which in the connection between the secondary pressure medium source and the drive cylinder ( 3 ) of the boost pressure device ( 23 ), the switched-on secondary pressure medium flow can be fed to the tank as required ( 17 ) and thus manage the temporary action. The connection and disconnection of the secondary pressure medium flow can be time, pressure or path dependent.

An additional secondary fluid flow can be achieved by a simple hydraulic pump ( 6 ) be generated.

It is conceivable that as a secondary source of pressure medium, a memory ( 7 ) is used. This memory can z. B. be filled with a separate pump, which must, however, be designed for slightly higher pressure, so that the memory ( 7 ) shows sufficient effect to the primary pressure medium source ( 5 ) to support.

Another solution is that the memory ( 7 ) from the primary pressure medium source ( 5 ) is filled. Since the boost pressure device ( 23 ) is only in action for a short time, in some embodiments sufficient time for the primary pressure medium source ( 5 ), a memory ( 7 ) to fill.

Another possibility is that with, when retracting the drive cylinder ( 3 ) of the boost pressure device ( 23 ) from its piston-side space ( 9 ) displaced pressure medium for charging the memory ( 7 ) is used. For this solution, no additional pump is needed, the memory ( 7 ) is bypassed from the primary pressure medium source ( 5 ).

The operation of the pump units ( 21 +22) of the slurry pump requires a primary source of pressurized fluid ( 4 ), which can provide both high volume and considerable pressures.

The from the bar side room ( 8th ) the drive cylinder ( 1 + 2 ) of the pumping units ( 21 + 22 ) displaced pressure medium can be used as a secondary pressure medium flow to support the primary pressure medium source ( 5 ) of the boost pressure unit ( 23 ) by temporarily inserting it into the piston side room ( 9 ) of the drive cylinder ( 3 ) of the boost pressure device ( 23 ).

Another secondary pressure medium flow can from the rod-side space ( 8th ) of the drive cylinder ( 3 ) of the boost pressure device ( 23 ), whereby this by appropriate circuit (overdrive) in the piston-side space ( 9 ).

Finally, it is also conceivable that the pressure medium flows from the drive cylinder ( 1 + 2 ) of the pump unit ( 21 + 22 ), as well as from the drive cylinder ( 3 ) of the boost pressure device ( 23 ) and together on the piston side ( 9 ) of the drive cylinder ( 3 ) of the boost pressure device ( 23 ). This may be appropriate if a very poor efficiency of the suction power of the pumping units ( 21 + 22 ) by a greatly increased piston speed of the drive cylinder ( 3 ) of the boost pressure device ( 23 ) must be compensated.

The functions of the pump units ( 1 + 2 ) and the boost pressure device ( 3 ) must be coordinated.

This can be achieved in a simple and unambiguous manner by virtue of the fact that the pressure medium flows from the two primary pressure medium sources ( 4 + 5 ) are largely identical. The identical pressure medium flows are to equal or approximately equal areas of the pistons in the drive cylinders ( 1 + 2 + 3 ) to meet.

This ensures that, whenever pumping is performed, even during the changeover phase, identical conditions in both the pumping units ( 21 + 22 ) as well as in the boost pressure device ( 23 ) are representable.

C. Examples

1st example - s. 1

The invention to be described is part of a slurry pump, in particular a concrete pump. This has two pumping units ( 21 + 22 ), each consisting of a delivery cylinder and a hydraulic drive cylinder ( 1 + 2 ). The drive cylinders ( 1 + 2 ) are connected to the bar via a connection ( 12 ) by a primary pressure medium source ( 4 ). The from the piston side room ( 9 ) of a first drive cylinder displaced pressure medium is via the rocking line ( 16 ) in the piston-side space ( 9 ) of a second drive cylinder.

If one of the two drive cylinders ( 1 + 2 ) of the pumping units ( 21 + 22 ) the end position switches a signal out of position ( 20 ) these via the switching valve ( 10 ) around. At the same time, the changeover device ( 25 ) the filled delivery cylinder with the delivery line ( 29 ) and the emptied with the suction line ( 28 ).

Since the active power of the pump units ( 21 + 22 ) is unsatisfactory in the suction mode and for the duration of the conversion, the changeover device ( 25 ) can not maintain the flow, there is a considerable interruption of the same.

To avoid this, a boost pressure device ( 23 ) to the suction line ( 28 ), which compensates both the delivery gap from the reduced active power and the changeover time. The position ( 19 ) located in the end region of a drive cylinder ( 1 + 2 ), the boost pressure device ( 23 ) and closes the reservoir ( 27 ) through the slider ( 26 ).

The switching signals, the interaction of the drive cylinder ( 1 + 2 + 3 ), by a length measuring system ( 24 ) along the drive cylinder ( 1 + 2 + 3 ) be generated.

The boost pressure device ( 23 ) needs to accomplish its task for a short time a much higher pressure medium flow, as the pumping units ( 21 + 22 ). To illustrate this, the pressure medium flow from the primary pressure medium source ( 5 ) a further pressure medium flow from a secondary pressure medium source via the switching valve ( 11 ).

As a secondary source of pressure medium, the rod-side space ( 8th ) the drive cylinder ( 1 + 2 ) of the respective pump unit ( 21 + 22 ) used in the pumping operation, in which the pressure medium displaced therefrom to the switching valve ( 11 ). By a suitable switching position, the pressure medium in the circuit of the boost pressure device ( 23 ), where it depends on the inflow from the primary pressure medium source ( 5 ) meets.

The check valve ( 15 ) prevents a compensation in the direction of the circuit of the pressure medium source ( 4 ) can take place. The combined pressure medium flow passes through the switching valve ( 10 ) to the connection ( 13 ) of the drive cylinder ( 3 ) of the boost pressure device ( 23 ). As soon as a preset pressure is reached, the pressure switch ( 14 ) the changeover valve ( 11 ), so that the pressure medium flow from the secondary pressure medium source ( 8th ) to the tank ( 17 ) is redirected.

The primary source of pressure ( 5 ) now takes over the sole supply of the drive cylinder ( 3 ) of the boost pressure device ( 23 ). This compresses the thick matter in the pumping units ( 21 + 22 ) in suction mode. Is the drive cylinder ( 3 ) of the ark printing device ( 23 ) to the switching point ( 18 ), this is through the switching valve ( 10 ) and the slider ( 26 ) open.

In order to produce a continuous slurry flow, it is necessary that the boost pressure device ( 23 ) in the final phase of the suction operation of a pump unit ( 21 + 22 ) makes identical movements at identical pressures. The same applies to the period of the changeover phase.

This is achieved by using the primary pressure medium source ( 4 ) on the ring surface on the rod side ( 8th ) the drive cylinder ( 1 + 2 ) of the pumping units ( 21 + 22 ), which is equal to the area of the piston side of the drive cylinder ( 3 ) of the boost pressure device ( 23 ) derived from the primary source of pressurized fluid ( 5 ) is charged with the same volume and pressure.

2nd example - s. 2

The movements of the pump units ( 21 + 22 ) proceed as described in Example 1. The boost pressure device ( 23 ) is again through the primary pressure medium source ( 5 ) operated. To increase the pressure medium flow to the drive cylinder ( 3 ) of the boost pressure device ( 23 ) becomes a memory ( 7 ) used during the suction process of the supercharger ( 23 ) with the displaced pressure medium from the piston-side space ( 9 ) whose drive cylinder ( 3 ) is filled and biased.

The start of the boost pressure device / ( 23 ) is indicated by the signal ( 19 ) from one of the drive cylinders ( 1 + 2 ). It first supplies the memory ( 7 ), simultaneously with the primary pressure medium source ( 5 ) Pressure medium in the piston-side space ( 9 ) of the drive cylinder of the boost pressure unit ( 3 ).

Since the accumulator pressure is initially higher than that of the primary source of pressurized fluid ( 5 ), a check valve ( 15 ) for the flow exclusively in the direction of the drive cylinder ( 3 ) of the boost pressure device ( 23 ). As soon as the pressure of the primary pressure medium source ( 5 ) of the secondary pressure medium source ( 7 ), the first takes over the supply exclusively.

Reaches the drive cylinder ( 3 ) of the boost pressure device ( 23 ) the switching point ( 18 ), the valve ( 10 ) around. The drive cylinder of the boost pressure device ( 3 ) is retracted. By a suitable position of the valve ( 11 ) is the memory ( 7 ) filled. When the preset accumulator pressure is reached, the pressure switch ( 14 ) the pressure medium flow through the valve ( 11 ) to the tank ( 17 ) around. The memory ( 7 ) is now to correct the next stroke to a signal from the position ( 19 ) ready.

3rd example - s. 3

In 3 is the secondary pressure medium source ( 6 ) designed as a hydraulic pump. The secondary pressure medium flow thus produced is constant until a predetermined pressure is reached, which reflects the desired compression of the pumping medium. The shutdown of the secondary pressure medium flow can via a switching valve ( 11 ) in such a way that the secondary flow of pressure medium into the tank ( 17 ) is redirected.

It is also conceivable that the secondary pressure medium source ( 6 ) adjusts the production of the secondary pressure medium flow.

1

Drive cylinder of a first pump unit ( 21 )

2

Drive cylinder of a second pump unit ( 22 )

3

drive cylinder the boost pressure device

4

Primary pressure medium source for the pumping units ( 21 + 22 )

5

Primary pressure medium source for the boost pressure device ( 23 )

6

secondary Pressure medium source (hydraulic pump)

7

secondary Pressure medium source (cylinder, storage)

8th

Rod-side space of a drive cylinder ( 1 + 2 + 3 )

9

Piston-side space of a drive cylinder ( 1 + 2 + 3 )

10

switching valve for primary pressure medium source

11

switching valve for secondary pressure medium source

12

connection rod side of a drive cylinder

13

connection piston side of a drive cylinder

14

pressure switch

15

check valve

16

swing line

17

tank

18

switching point the boost pressure device fully extended

19

switching point the boost pressure device completely retracted

20

Switching point master cylinder ( 1 + 2 ) Switch

21

First pump unit

22

Second pump unit

23

Pressure boosting device

24

Length measuring system

25

Transfer device between the pump units ( 21 + 22 )

26

Gate valves

27

reservoir

28

suction

29

delivery line (Pressure line)

30

Piston of a drive cylinder ( 1 + 2 + 3 )

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• EP 1235982 [0007]

Claims (18)

Slurry pump for generating a continuous thick material flow, by at least two pump units alternating in the pumping and suction operation (US Pat. 21 . 22 ), each comprising a conveyor and a hydraulic drive cylinder ( 1 + 2 ), a pressure medium source ( 4 ), a support line ( 29 ), a suction line ( 28 ) and a conversion direction ( 25 ), whereby by means of the changeover device ( 25 ) a pump unit in pumping operation with the delivery line ( 29 ) and in suction mode with the suction line ( 28 ) and an attached, by a gate valve ( 26 ) detachable storage container ( 27 ) is connectable, and wherein the suction line ( 28 ) a separate from the pump unit charge pressure device ( 23 ) is mounted for compressing the sealant, characterized in that a secondary pressure medium source for the boost pressure device ( 23 ) is provided by means of the to a primary pressure medium flow from the pressure medium source ( 5 ) of the boost pressure device ( 23 ) For at least temporarily reinforcing the same, at least one secondary pressure medium flow can be fed. Slurry pump according to claim 1, characterized in that the boost pressure device ( 23 ) At the beginning of their stroke, an increased pressure medium flow at relatively low pressure and in the final phase a reduced pressure medium flow is supplied at elevated pressure temporarily. Slurry pump according to claim 1, characterized in that with the signal from the position ( 19 ) of a piston ( 30 ) the drive cylinder ( 1 + 2 ) of the pumping units ( 21 + 22 ) in the suction mode, the start of the boost pressure device ( 23 ) is initiated. Slurry pump according to the preceding claims, characterized in that in the connection of a secondary pressure medium source with the drive cylinder ( 3 ) of the boost pressure device ( 23 ) a switching valve ( 11 ), which is the secondary pressure medium flow to the tank ( 17 ) switches. Slurry pump according to the preceding claims, characterized in that the switching of a secondary Pressure medium flow time, pressure or path-dependent takes place. Slurry pump according to the preceding claims, characterized in that a secondary pressure medium source is a separate pump ( 6 ). Slurry pump according to the preceding claims, characterized in that the secondary pressure medium source is a reservoir ( 7 ). Slurry pump according to claim 7, characterized in that the memory ( 7 ) by means of a separate pump ( 6 ) is filled. Slurry pump according to the preceding claims, characterized in that the memory ( 7 ) from the primary pressure medium source ( 5 ) is filled. Slurry pump according to the preceding claims, characterized in that the memory ( 7 ) with the from the piston-side space ( 9 ) of the drive cylinder ( 3 ) of the boost pressure device ( 23 ) displaced pressure medium is filled. Slurry pump according to the preceding claims, characterized in that the secondary pressure medium source the drive cylinder ( 1 + 2 ) of the pumping units ( 21 + 22 ), whereby the from the drive cylinders ( 1 + 2 ) displaced pressure medium as a secondary pressure medium flow to the primary pressure medium flow from the pressure medium source ( 5 ) of the boost pressure device ( 23 ) can be fed. Slurry pump according to the preceding claims, characterized in that the secondary pressure medium source the rod-side space ( 8th ) of the drive cylinder ( 3 ) of the boost pressure device ( 23 ), whereby the from the rod-side space ( 8th ) of the drive cylinder ( 3 ) displaced pressure medium as a secondary pressure medium flow to the primary pressure medium flow from the pressure medium source ( 5 ) of the boost pressure device ( 23 ) can be fed. Slurry pump according to the preceding claims, characterized in that the secondary pressure medium sources, the drive cylinder ( 1 + 2 ) of the pumping units ( 21 + 22 ) and the bar side room ( 8th ) of the drive cylinder ( 3 ) of the boost pressure device ( 23 ), whereby the from the drive cylinders ( 1 + 2 + 3 ) displaced pressure medium as a bundled secondary pressure medium flow to the primary pressure medium flow from the pressure medium source ( 5 ) of the boost pressure device ( 23 ) can be fed. Slurry pump according to the preceding claims, characterized in that the pressure medium flow of the primary pressure medium source ( 4 ) for driving the drive cylinder ( 1 + 2 ) of the pumping units ( 22 + 23 ) is equal to or approximately equal to that of the primary source of pressurized fluid ( 5 ) for driving the drive cylinder ( 3 ) of the boost pressure device ( 23 ). Slurry pump according to the preceding claims, characterized in that the of the primary pressure medium source ( 4 ) acted upon surface of the drive cylinder ( 1 + 2 ) of the pumping units ( 21 + 22 ) and from the primary pressure medium source ( 5 ) acted upon surface of the drive cylinder ( 3 ) of the boost pressure device ( 23 ) are equal or approximately equal. Slurry pump according to the preceding claims, characterized in that during the changeover phase of a first pump unit ( 21 ) to a second ( 22 ) the piston speed of the drive cylinder ( 3 ) of the boost pressure device ( 23 ) equal to or approximately equal to the piston speed of the drive cylinder ( 1 + 2 ) of the pumping units ( 21 + 22 ). Slurry pump according to the preceding claims, characterized in that the pumping power of the boost pressure device ( 23 ) during the changeover phase of a first pump unit ( 21 ) to a second ( 22 ) equal to or approximately equal to the pumping power of the pumping units ( 21 + 22 ) is in pumping mode. Slurry pump according to the preceding claims, characterized in that during the changeover phase of a first pumping unit ( 21 ) to a second ( 22 ) the drive cylinder ( 3 ) of the boost pressure device ( 23 ) exclusively from the primary pressure medium source ( 5 ) is supplied.