KR20160041910A - Two-cylinder thick matter pump having a transfer tube - Google Patents

Abstract

The present invention relates to a dense material pump having a material supply container (10) and two transfer cylinders (16, 17), wherein the two transfer cylinders (16, 17) are each connected by an end orifice opening Is connected to passage openings (18 ', 19') in the vessel wall (20). The transfer cylinders 16 and 17 can be alternately connected to the inside of the transfer line 14 and the container 21 by a transfer tube 24 arranged in the interior of the material supply container 10, 16, 17) perform the filling stroke and the transfer stroke alternately. The transfer tube 24 has an inlet opening oriented in the direction of the orifice opening 18,19 and formed as a slot 28 bent in an arcuate shape, the width of the inlet opening corresponding to the diameter of the orifice opening 18,19, The length of the inlet opening corresponds to the outer space of the orifice openings 18 and 19 and each has one sealing attachment 30 and 31 protruding beyond the outer edge of the slot 28 in the pivot rotation direction, The direction size corresponds to the space between the orifice openings. In accordance with the present invention, the delivery tube 24 includes a metallic ring element 32 having an arcuate slot 28, and a metallic ring 32 having an arcuate slot 28, to ensure a stable sealing of the coupling joint between the vessel wall 20 and the delivery tube 24. [ And a cushioning element 36 arranged between the rotary tube 34 and the ring element 32. The pivoting rotary tube 34 is connected to the delivery line 14 at the output side and a hole 38 and the ring element 32 can be moved axially with respect to the pivot rotary tube 34 and under the action of the delivery pressure in the delivery tube 24 can be transmitted through the cushioning element 36 to the container wall 20 As shown in Fig.

Description

[0001] TWO-CYLINDER THICK MATTER PUMP HAVING A TRANSFER TUBE WITH TRANSFER TUBE [0002]

The present invention relates to a dense material pump having a material supply container and two transfer cylinders, wherein the two transfer cylinders are each connected to an orifice opening in the container wall by an end orifice opening, And the transfer piston of the transfer cylinder alternates between a filling stroke and a transfer stroke. Thus, the transfer tube has an inlet opening directed in the direction of the orifice opening and formed as a slot bent in an arcuate shape, the width of the inlet opening corresponding to the diameter of the orifice opening and the length of the inlet opening corresponding to the outer space of the orifice opening, (DE-195 03 986 A1), each having a sealing attachment which protrudes beyond the outer edge of the inlet opening in the direction of pivot rotation, the longitudinal extent corresponding to the distance between the orifice openings.

The known dense material pumps are capable of at least at least two, preferably at least two, at least during the pivoting or switching operation of the transfer tube, due to the fact that the two openings for the transfer tube and the inlet opening formed as a bent slot, The transfer cylinder is short-circuiting. Thus, during the transfer process of the transfer tube, both transfer cylinders are often separated from the interior of the material supply container and coupled to the transfer line, while being shorted to each other, so that one transfer piston completes the transfer stroke And at the same time, another transfer piston can already start the transfer stroke. The transfer piston that completes the transfer stroke will not perform the fill stroke thereafter until the transfer cylinder is connected to the interior of the container once again between the two orifice openings. For a stable function, during both the transfer process and the conversion process, the transfer tube needs to be fixed and sealed against the container wall in the region of the passage opening. However, the above-mentioned type of known rich-substance pump has a lot of room for improvement from the sealing technology standpoint.

Accordingly, it is an object of the present invention to provide a method and apparatus for separating a transfer tube from a container, such as a well-known dense substance pump of the aforementioned kind, .

A method of combining the features described in claim 1 to implement the above object is proposed. Preferred embodiments and further improvements of the invention are described in the dependent claims.

According to the invention, the transfer tube has a metallic ring element with an arcuate slot, and a cushioning element arranged between the pivoting rotating tube and the ring element, the pivoting tube being connected to the delivery line on the output side, The ring element can be moved axially with respect to the pivoting rotary tube and under compression of the transfer pressure in the transfer tube is compressed against the inner surface of the container wall through the cushioning element . According to the present invention, the sealing effect is maintained not only in a stationary state at the step position of the transfer tube, but also during the rotational movement of the transfer tube. In this case, the transfer tube is stably sealed against the interior of the container in all switching and operating conditions. This is provided in the region of the sealing attachment because the cushioning element protrudes into the sealing attachment creating a pressing action originating from the interior of the pipe. It should be noted that in this case, due to the sealing attachment, the thick matter can be pre-compressed during the course of the conversion process when the transfer stroke is started. According to the present invention, the cushioning element has a non-circular, two-dimensional cross-sectional shape. Preferably, the flexible rubber material uniformly delivers hydraulic pressure in all directions, in a substantially non-compressible manner, similar to a liquid. This means that the pressure of the material conveyed from the inside of the transfer tube is ideally uniformly propagated across the cushioning element and is precisely propagated into the sealing attachment. Thereby, the metallic ring element can be compressed against the inner surface of the container wall, but only the inlet contour of the cushioning element comes into contact with the compressed conveying medium. In this case, by providing a gel pocket or a fluid pocket within the cushioning element, a further improvement can be realized, in which pressure can be delivered more efficiently through the fluid pocket or gel pocket.

According to a further preferred embodiment of the invention, on the inner surface facing the ring element, the container wall carries a replaceable wear plate provided with a passage opening. This makes it relatively easy to replace in the case of wear. Also, materials with a higher wear resistance for the material container are used, and more expensive materials may be used for this purpose.

According to a further preferred embodiment of the present invention, the ring element is adapted to be fitted to the cushion element via an external contour and a stepped molding pocket for accommodating a cushion element arranged on the side of the pivot rotary tube. molded pocket. In this regard, it is further preferred that the ring element is delimited in the slot direction by the stepped pocket wall and the height of the pocket wall is smaller than the outer pocket edge. Thus, the cushioning element is embedded securely between the ring element and the pivoting rotation tube, for example during a flushing operation, when the suction pressure is generated, .

In placing the ring element on the pivoting rotating tube, a limited arch-shaped elevation is penetrated by a pivoting tube channel on the cylinder end of the pivoting rotating tube It is further preferred that they are arranged such that they have an outline contour corresponding to the pocket in the ring element.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be described in more detail below on the basis of illustrative examples schematically illustrated in the accompanying drawings. In the drawings,
Figure 1 schematically shows a two-cylinder rich material pump;
2 is an exploded view schematically depicting key portions of a rich chemical pump;
Figures 3a and 3b are exploded views schematically illustrating a delivery tube having a wear plate viewed from various directions;
Figure 4a shows the delivery tube with the wear plate in the assembled state of the delivery tube according to Figure 3a;
Figure 4b is a view according to Figure 4a in which the transfer tube is partially open;
Figures 5a-5c are top, cross-sectional and schematic exploded views of an embodiment viewed from opposite directions of a ring element with cushioning elements.

The concentrate pump shown in Fig. 1 has a material supply vessel 10 for receiving a thick matter, e.g., liquid concrete. The liquid concrete is conveyed through the pipe elbow 12 into the transfer line 14, which is shown here only in outline. This is accomplished with two transfer cylinders 16 and 17 each having passage openings 18 ', 19 ' in the vessel wall 20 by respective end-side orifice openings 18 and 19, , And the transfer pistons (22, 23) of the transfer cylinders alternate between a filling stroke and a delivery stroke. A transfer tube 24 is arranged in the interior of the material supply vessel 10 through which the transfer cylinders 16 and 17 are alternately connected inside the transfer line 14 and the vessel 21 . In this case, the transfer tube 24 may be pivotally rotated by a hydraulic drive mechanism to a desired position relative to the orifice openings 18, 19, respectively. The transfer pistons 22, 23 are displaced by hydraulic cylinder / piston units 26, 27, only the cylinder of which is schematically shown in Fig. The transfer tube 24 has an inlet opening formed as a slot 28 bent in an arcuate shape in the direction of the orifice openings 18 and 19, The width of the inlet opening corresponds to the diameter of the orifice openings 18 and 19 and the length of the inlet opening corresponds to the outer space of the orifice openings 18 and 19, Has a closure attachment (30, 31) protruding beyond the outer edge of the slot (28) in a pivoting direction, and the longitudinal extent Approximately corresponds to the space between the orifice openings 18, 19.

According to one aspect of the invention, the transfer tube comprises a metallic ring element 32 with an arcuate slot 28, and an array (not shown) between the ring element 32 and the pivot rotary tube 34 connected to the delivery line on the output side. And a cushioning element (36). The cushioning element 36 has a hole 38 surrounding the slot 28 within the ring element 32. In this case, the ring element 32 can be displaced axially relative to the pivoting rotary tube 34, and the action of the delivery pressure created in the delivery tube 24 in the course of the delivery stroke Can be compressed against the inner surface of the vessel wall (20) through the ring element (32). Above the inner surface facing the ring element 32 the vessel wall 20 is provided with a replaceable metallic wear plate 20 'with bearing bores 40 for the bearing pins 42 and with passage openings 18', 19 ' .

5a-5c, the ring element 32 has a stepped molding pocket 44 for receiving a cushioning element 36 arranged above the pivoting rotation tube side, the molding pocket having an outer contour is fitted into the cushion element (36) through an external contour. In this example, the ring element 32 is delimited in the direction of the slot 28 by the stepped inner pocket wall 46, and the height of the inner pocket wall is smaller than the outer pocket edge 48 . An elevation 50 in the form of a limited arch is arranged on the cylinder end of the pivot rotary tube 34 which is pierced by the pivot rotary tube channel 52 having a contour corresponding to the pocket 44 within the penetrating ring element 32 (FIG. 3B). The axial orientation of the ring element 32 on the pivot rotary tube 34 is improved and stabilized by these features.

To ensure a stable transfer of pressure, the cushioning element 36 is made of a flexible, resilient or flexible rubber material. In addition, the cushioning element 36 can be further improved in the pressing action in that it includes a filling configured as an incompressible fluid.

The inlet opening of the ring element or delivery tube is configured to be short-circuited in the form of a bent slot, through the orifice openings 18, 19 within the slot 28, two transfer cylinders 16, 17. If both of the transfer cylinders 16, 17 can carry out the transfer stroke to the transfer pistons 22, 23 in this position, a smooth and rapid change-over switching process can be ensured. In order to prepare for the conversion process, initial pressure is built up in the previously filled transfer cylinder while the hermetic attachment portions 30, 31 are transferred to the transfer tube 24. As a result, for example, during the switching process, a further improvement is realized for the continuous flow through the delivery line. On the other hand, this means that the piston speed, and the duration of the stroke due to the piston speed, are different during the filling stroke and during the delivery stroke, Because of the specific features described, there is less time available for the filling stroke than the transfer stroke.

In summary, the present invention is directed to a dense material pump having two transfer cylinders 16, 17 and a material supply container 10, wherein the transfer cylinders 16, 17 each have an end-side orifice opening 18, 19 'within the vessel wall 20 by means of the openings 18, 19. The transfer cylinders 16 and 17 are alternately connected to the inside of the transfer line 14 and the container 21 by a transfer tube 24 arranged in the interior of the material supply container 10, (22, 23) alternately perform a filling stroke and a delivery stroke. The transfer tube 24 has an inlet opening oriented in the direction of the orifice opening 18,19 and formed as a slot 28 bent in an arcuate shape, the width of the inlet opening corresponding to the diameter of the orifice opening 18,19, The length of the inlet opening corresponds to the outer space of the orifice openings 18 and 19 and has one sealing attachment 30 and 31 protruding beyond the outer edge of the slot 28 in the pivot rotation direction respectively, The direction size corresponds to the space between the orifice openings. In order to ensure reliable sealing of the coupling joint between the container wall 20 and the delivery tube 24, according to the present invention, the delivery tube 24 has an arcuate slot 28 A metallic ring element 32 and a cushioning element 36 arranged between the pivoting rotary tube 34 and the ring element 32. The pivoting rotary tube 34 is connected to the delivery line 14 at the output side With the aperture 38 surrounding the slot 28 the ring element 32 can be moved axially relative to the pivot rotary tube 34 and under the action of the transfer pressure in the transfer tube 24, Can be compressed against the inner surface of the vessel wall 20 through the openings 36.

10: Material supply container 12: Pipe elbow
14: transfer line 16, 17: transfer cylinder
18, 19: orifice opening 18 ', 19': passage opening
20: container wall 20 ': wear plate
21: inside of the container 23, 23: transfer piston
24: transfer tube 26, 27: cylinder / piston unit
28: Slots 30, 31: Sealing attachment
32: ring element 34: pivot rotating tube
36: cushion element 38: hole
40: bearing bore 42: bearing pin
44: pocket 46: pocket wall
48: pocket edge 50: rising portion
52: pivot rotating tube channel

Claims (8)

The two transfer cylinders 16 and 17 are each a concentrate pump having a material supply container 10 and two transfer cylinders 16 and 17. The two transfer cylinders 16 and 17 are connected to the container wall 20 by respective end orifice openings 18 and 19, And the transfer cylinder 16 and 17 are connected to the transfer line 14 and the container (not shown) by a transfer tube 24 arranged in the interior of the material supply container 10, 21 and the transfer pistons 22 and 23 alternately perform a filling stroke and a delivery stroke and the transfer tube 24 is connected to the orifice openings 18 and 19 And the width of the inlet opening corresponds to the diameter of the orifice opening (18, 19) and the length of the inlet opening is equal to the diameter of the orifice opening (18, 19) Each of which protrudes beyond the outer edge of the slot 28 in the pivot rotation direction, (30, 31), characterized in that the high-
The transfer tube 24 has a metallic ring element 32 with an arcuate slot 28 and a cushioning element 36 arranged between the pivot rotating tube 34 and the ring element 32, 34 has an aperture 38 connected to the delivery line 14 at the output side and surrounding the slot 28 and the ring element 32 can be moved axially relative to the pivot rotary tube 34, Is compressible against the inner surface of the vessel wall (20) through the cushion element (36) under the action of the transfer pressure in the tube (24). 2. A device according to claim 1 characterized in that the container wall (20) on the inner surface facing the ring element (32) carries a replaceable wear plate (20 ') provided with passage openings (18', 19 ' Rich material pumps. 3. A method according to claim 1 or 2, characterized in that the ring element (32) has a stepped molding pocket (44) for receiving a cushion element (36) arranged on the side of the pivot rotary tube, Is adapted to fit into the cushion element (36) through the outer contour while forming the pocket edge (48). The method of claim 3 wherein the ring element is delimited by the stepped pocket wall in the direction of the slot and the height of the pocket wall is greater than the height of the outer pocket edge Richer pump characterized by smaller. 5. A method according to claim 3 or 4, characterized in that a limited arch-shaped elevation part (50) is arranged on the cylinder end of the pivot rotary tube (34), said elevation part (50) Has a contour corresponding to the pockets (44) in the inner wall (32). 6. A dense substance pump according to any one of claims 1 to 5, characterized in that the cushion element (36) is composed of a flexible or elastic material. 7. The dense substance pump according to any one of claims 1 to 6, characterized in that the cushioning element (36) is composed at least partly of a flexible rubber material. 8. A dense substance pump according to any one of claims 1 to 7, characterized in that the cushion element (36) comprises a filling configured as an incompressible fluid.

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