EP0452572A1 - Dewatering apparatus and corresponding process - Google Patents

Abstract

Drainage apparatus for removing excess liquid from building material mouldings under pressure, having a frame, a support, a pressing element for the moulding, a, preferably pneumatic, drive device serving to press the pressing element against the moulding and, if appropriate, restraining means for the moulding, at least one of the surfaces of the support and of the pressing element which lies against the moulding and is adapted thereto being provided with run-off channels for running off the liquid pressed out of the moulding, in which a hollow body (14) which can be filled with a medium and which essentially completely covers the surface of the moulding (21) against which the hollow body lies is provided in the operating direction of the pressing element (11), the hollow body (14) being connected to a compressor (15) for a medium which fills the hollow body (14). <IMAGE>

Description

The invention relates to a drainage device of the type specified in the preamble of claim 1 and a method for removing excess liquid.

Such methods and devices are known for example from DD-A 23 28 71 and from and on the other hand from DE-A 17 71 866.

The method described in DD-A 23 28 71 relates to the production of concrete products, such as concrete slabs. The fresh concrete is poured into a casting mold and, after hardening in a vacuum chamber, separated from the excess liquid still remaining in the concrete slab. A press ram acting on the concrete slab and a mold wall opposite the press ram, designed as a slotted plate and acting as a counter-holder, presses the liquid out of the concrete slab under vacuum conditions, the concrete slab being arranged between the press ram and the mold wall. The moisture is thus removed on the one hand due to the pressure of the ram acting on the plate and as a result of the conditions in the vacuum chamber from the concrete plate.

However, this design of the dewatering device has the disadvantage that it is very complex and, measured in terms of effort, provides an unsatisfactory drying result. In particular, it proves to be a disadvantage that the vacuum chamber requires a powerful, energy-intensive vacuum pump and complex seals for the vacuum. Vacuum generation is still very time-consuming since a vacuum atmosphere must be created for each dewatering process. Therefore, the drainage performance of this version is very low. Because of the simple way of pressing the concrete slab together, there is also the risk of deformation and uneven drainage, so that high reject rates are the result.

From DE-A 17 71 866 a further possibility for removing excess water from gypsum boards is known, the finished gypsum boards being treated with compressed air from five sides in a pressure chamber. By means of compressed air, the moisture is pressed out of the plate in such a way that the liquid escapes from the sixth side. This side of the gypsum board lies on a drainage frame in which the water pressed out of the board can flow off.

This design of a dewatering device has the disadvantage that the plate treated in this way bends when pressurized and thus adversely changes its predetermined geometry. It is also unfavorable that the compressed air attacks from several sides, so that the liquid inside the plasterboard must be pressed in the direction of the sixth side. A lot of energy is required for this.

The invention has for its object to improve the method and the construction in a dewatering device of the type mentioned while eliminating the disadvantages mentioned so that the moldings can be dewatered quickly, easily and with a low reject rate.

This object is achieved with the characterizing features of claim 1.

The invention is based on the finding that a uniform, bilateral, in particular large area on the molded body, contact pressure on a, preferably plate-shaped, molded body, the excess liquid can be most efficiently pressed out of the molded body without changing the contours of the molded body or damaging it. This also enables continuous, uniform drainage in an advantageous manner. The uniformity of the pressure and thus that of the dewatering process is achieved by a hollow body lying against the molded body, which can be filled with a medium, and by a pressure element acting on the molded body, the pressure inside the hollow body being increased by additional measures with increasing contact pressure of the pressure element. The pressure on the molded body is then generated both by the pressure element and by the stiffening and slightly elastically deforming hollow body. The hollow body is arranged in a frame in the effective area of the pressure element connected to a drive device.

It is particularly advantageous that the hollow body which can be filled with a medium is provided on at least one side in the direction of action of the pressure element. This essentially completely covers the surface of the molded body against which it rests, the hollow body being connected to a compressor for the medium filling the hollow body. This achieves that while the excess liquid is pressed out of the building material body, the pressure forces acting on the molded body on both sides act evenly on the molded body.

The following advantageous further developments are particularly advantageous:
In order to be able to match the pressure within the hollow body and the contact pressure of the pressure element on the molded body, the, in particular pneumatic, drive device and the hollow body have a common compressor and a control device. The control device is provided between the compressor and the hollow body and increases the pressure in the hollow body with increasing contact pressure, in particular from a certain predetermined value. As a result, the molded body is substantially uniformly loaded on both sides. In a preferred embodiment, the control device has a check valve and a pressure reducing valve.

Furthermore, it proves to be advantageous that a plurality of hollow bodies and molded bodies arranged in the frame with respect to the pressure element are provided. In this way, the excess liquid can be withdrawn in a shape-retaining manner at the same time by pressing out several shaped bodies. The hollow bodies and the shaped bodies are arranged in the context of the drainage device in such a way that a shaped body or a hollow body follows alternately after the pressure element.

In a preferred development, the dewatering device in each case has a dewatering body resting on one side of the shaped body, which essentially also has the shaped body on the adjacent side completely covered. The squeezed out liquid can thereby drain in a targeted manner, the drainage body for this purpose having a surface formation, in particular provided with drainage grooves.

In the case of a dewatering device designed for a plurality of shaped bodies, a hollow body or a dewatering body are alternately provided between the shaped bodies. This is based on the knowledge that it has proven sufficient for uniform loading of the shaped body to arrange the hollow body on only one side of the shaped body. As a result, the pressure lines and seals of the supply lines for the medium moved by the compressor are only required once for each shaped body to be arranged in the dewatering device. The result is favorable material and manufacturing costs of the drainage device according to the invention.

In particular, damage or undesired deformation of the shaped bodies is prevented by the surfaces of the dewatering body or hollow body bearing against the shaped body having a design adapted to the shaped body. In addition, a uniform contact pressure is also guaranteed.

In a further advantageous embodiment of the invention, a part of the clamps, in particular those provided in the lower region of the shaped bodies, is movably mounted in the frame. The occurrence of moments between the frame and the clamps or the molded body is hereby prevented from the outset and thus also the danger possible undesirable deformations of the molded body. The dewatering bodies and / or hollow bodies arranged between the shaped bodies are likewise mounted in the frame in the direction of action for the same reasons.

In order to be able to measure the forces occurring on the molded body continuously, a force measuring device is provided in the effective area of the pressure element.

The outflow of the pressed-out liquid is facilitated in particular by the fact that the clamps, which are preferably arranged in the lower region of the shaped bodies, have smaller dimensions in the effective direction of the pressure element than the amount by which the shaped body extends in the effective direction. The liquid can thus also emerge from the downward-facing surfaces, which may not be covered by the drainage or hollow body, and flow away in the space resulting from the different designs of the clamps and the molded body.

A particular advantage of the dewatering device is its economically advantageous applicability, since the most economical energy consumption and universal applicability represent typical performance parameters.

It has also proven to be advantageous that the shaped bodies are dewatered using the dewatering device according to the invention in the following process steps:

First, the molded body is placed in the effective area of the drainage device. On one side is here at least one hollow body which can be filled with a medium is provided and completely covers the surface of the shaped body against which it rests. The molded body is connected to the clamps and the pressure element then moves in the direction of the molded body until a predetermined contact pressure is reached on the molded body. When this contact pressure is reached, the pressure inside the hollow body is increased by further inflow of the medium into the hollow body. The pressure inside the hollow body is in particular lower than the contact pressure of the pressure element. After the liquid has been pressed out of the molded body, the pressure inside the hollow body and the contact pressure are reduced or completely reduced by the pressure element and the molded body is removed from the dewatering device. In a favorable further development of the method, the shaped body is heated in a drying room for a certain time, so that the possibly still remaining moisture is removed from the shaped body by the evaporation favored by the heat development.

The process is characterized in particular by the fact that the moisture is withdrawn uniformly from the shaped body and the predetermined geometry of the shaped body is not changed. Both the drainage device is simple in design and the necessary manipulations of the operating personnel during the process are reduced to a minimum. The drainage performance is optimized while maintaining the dimensional stability kit, so that large numbers of panels can be dewatered with little effort.

• Figuren 1a und 1b eine Seitenansicht sowie eine Draufsicht eines bevorzugten Ausführungsbeispiels der Erfindung und
• Figuren 2a und 2b ein Detail des Ausführungsbeispiels der Erfindung in Seitenansicht und Draufsicht.

Advantageous developments of the invention are characterized in the subclaims or are shown below together with the description of the preferred embodiment of the invention with reference to the figures. Show it:

• Figures 1a and 1b a side view and a plan view of a preferred embodiment of the invention and
• Figures 2a and 2b show a detail of the embodiment of the invention in side view and top view.

A drainage device is shown in a side view and a top view in FIGS. 1a and 1b. The dewatering device essentially consists of a frame 10, a pressure element 11 connected to a drive device 12, dewatering bodies 13, hollow bodies 14, a compressor 15 which is connected to the hollow bodies 14 via lines 16, and a control device 17.

The frame 10, which carries the individual parts of the dewatering device, has uprights 18 running perpendicular to its storage surface and upper or lower horizontal supports 19 and 20 extending transversely to the post 18. The hollow bodies 14, the drainage bodies 13 and the gypsum boards 21 to be dewatered are provided between the upper horizontal support 19 and the lower horizontal support 20. Starting from the pressure element 11, a hollow body 14, a plasterboard 21 and a drainage body 13 alternate. A total of six gypsum boards 21, four hollow bodies 14 and three drainage bodies 13 are arranged in the frame 10. A hollow body 14 acting as a counter element is thus firmly connected to the frame 10 adjacent to the post 18 on the side remote from the drive device 12. This arrangement of the individual elements ensures a compact and stable design of the drainage device.

The drainage body 13 and the hollow body 14 are firmly connected at their upper end to the upper horizontal support 19. At their lower end, however, they are mounted so that they can be guided in the effective direction of the pressure element 11 on the lower horizontal support 20, so that no harmful moments can occur in this area. The gypsum boards 21 are fixed in the frame 10 via clamps 22. The upper clamps 22 are arranged so that the plasterboard 21 can be inserted centrally between the hollow body 14 and the drainage body 13. The lower clamps 22 are each connected to a guide means 23 which fixes the drainage body 13.

Due to the vertical arrangement of the gypsum boards 21, the drainage body 13 and the hollow body 14, the water squeezed out of the gypsum board can flow downward favorably in the drainage bodies.

The guide means 23 is screwed to the hollow body 14 on one side and to the drainage body 13 on the other side. The lower end of the drainage body 13 and the hollow body 14 and the guide means 23 are each mounted on the lower horizontal support 20 so that they can be guided in the effective direction. As a result, no moments deforming the gypsum board 21, the drainage body 13 or the hollow body 14 can occur in this area.

The pressure element 11 can be moved in the horizontal direction via the pneumatically designed drive device 12. A force measuring device (not shown here) is arranged in the effective area, so that the forces acting on the gypsum board 21 can advantageously be determined. The drive device 12 consists of a piston 24 and a pressure cylinder 25, wherein the pressure cylinder 25 is connected to the frame 10 at its post 18 with screws in relation to the forces occurring. The lines 16 run from the pressure cylinder 25 and from the hollow bodies 14 to the compressor 15, the control device 17 being arranged between the compressor 15 and the hollow bodies 14. The control device 17 essentially has a check valve and a pressure reducing valve. A hollow body 14 is connected to the compressor 15 via two connections, so that the compressed air very quickly enters and exits the hollow body. can be moved out.

The clamps 22 are each adapted to the narrow end faces of the molded body 21 in such a way that the plasterboard 21 and the clamps 22 can be connected to one another in a form-fitting manner. As a result, the gypsum board 21 can be fixed by pushing it laterally into the frame 10 or into the clamps 22, and can be arranged in accordance with the process.

The sandwich arrangement of the gypsum boards 21, the drainage body 13 and the hollow body 14 enables in a simple manner that a plurality of gypsum boards 21 can be freed of the excess water at the same time. The gypsum boards 21 are first guided into the upper and lower clamps 22. The pressure element 11 now moves vertically towards the hollow body 14 and presses it together with the gypsum boards 21, the drainage bodies 13 and the further hollow bodies 14. The abutting surfaces of the gypsum boards 21, the drainage body 13 and the hollow body 14 are adapted to each other, so that the gypsum boards 21 are each loaded with a uniform contact pressure generated by the pressure element 11.

From a predetermined contact pressure by the pressure element 11 on the plasterboard 21, the compressed air generated by the compressor 15 is also pressed into the hollow body 14 by the control device 17. This increases the pressure within the hollow body 14 and counteracts the pressure element 11 by virtue of their stiffening and slight elastic expansions generated due to the pressure. The pressure on the gypsum board 21 is thereby increased further, the contact pressure of the pressure element 11 and the pressure in the hollow bodies 14 increasing up to a predetermined value. During the pressing process, there is a predetermined pressure difference between the air pressure in the pressure cylinder 25 and the air pressure in the hollow bodies 14, which is ensured by the control device 17. The excess liquid in the shaped bodies 21 is almost completely pressed out during the pressing and runs down along the drainage body 13 into a collecting trough, not shown here, arranged between the lower cross members 20.

The pressure in the lines 16 is now reduced by releasing the pressure via the control device 17, so that the pressure element 11 moves back into its starting position and the gypsum boards 21 can be removed. The gypsum boards 21 are now placed in a drying room which is heated until the residual moisture in the gypsum boards 21 has evaporated.

A drainage body 13 is shown in a side view and a top view in FIGS. 2a and 2b.

This has drain grooves 26 extending from its upper end to its lower end at right angles to its edges. The drainage grooves 26 are arranged on both sides of the drainage body 13, so that liquid pressed out of the gypsum boards 21 resting on both sides of the drainage body 13 can drain downward favorably.

The embodiment of the invention is not limited to the preferred exemplary embodiment specified above. Rather, a number of variants are conceivable which make use of the solution shown even in the case of fundamentally different types.

Claims (10)

Dewatering device for removing excess liquid from molded building material bodies under pressure, with a frame, a counter-holder, a pressure element for the molded body, a, preferably pneumatic, drive device for pressing the pressure element against the molded body and optionally clamps for the molded body, at least one of which on the Molded surfaces of the counter-holder and the pressure element which are adapted to this mold are provided with drainage channels for draining the liquid pressed out of the molded body,

characterized by

that in the effective direction of the pressure element (11) there is provided a hollow body (14) which can be filled with a medium and which substantially completely covers the surface of the shaped body (21) against which the hollow body rests, the hollow body (14) being equipped with a compressor ( 15) for a medium filling the hollow body (14). Dewatering device according to claim 1, characterized in that the drive device (12) and the hollow body (14) are connected to a common compressor (15), the pressure in the hollow body (14) being between the compressor (15) and the hollow body (14) ) increasing control pressure (17) is provided with increasing contact pressure, in particular above a predetermined contact pressure. Drainage device according to one of the preceding claims, characterized by a plurality of hollow bodies (14) and molded bodies (21) arranged within the frame (10) and acting in series with respect to the pressure element (11), in particular the hollow bodies (14) and the molded bodies (21 ) follow each other alternately. Dewatering device according to claim 3, characterized in that a dewatering body (13) which bears on one side of the shaped body (13) and essentially covers it is provided, which has a surface formation, in particular provided with drainage grooves (26), so that the surface formation Molded body (21) liquid to be squeezed out. Drainage device according to claim 4, characterized in that a hollow body (14) and a drainage body (13) are arranged alternately between the shaped bodies (21). Drainage device according to one of the preceding claims, characterized in that a part of the clamps (22), in particular the drainage bodies (13) and / or provided in the lower region of the molded body (21) and / or between the molded bodies (21) Hollow bodies (14) are guided in the effective direction in the frame (10). Dewatering device according to one of the preceding claims, characterized in that a force measuring device is provided in the effective area of the pressure element, so that the forces occurring on the molded body (21) when the pressure element (11) is moved can be measured continuously. Drainage device according to one of the preceding claims, characterized in that the clamps (22), preferably arranged in the lower region of the shaped body (21), have smaller dimensions in the effective direction of the pressure element (11) than that of the shaped body (21). Drainage device according to one of the preceding claims, characterized in that the control device (17) has a check valve and a pressure reduction valve which are arranged between the compressor (15) and the hollow body (14). Method for dewatering molded building materials with a dewatering device according to claim 1, characterized by the following method steps:

Inserting the shaped body (21), which may have been heated in a drying room for a certain time, into the effective area of the dewatering device (13), at least one hollow body (14) which can be filled with a medium being provided on one side and completely covering the surface of the shaped body (21) against which it rests,

Moving the pressure element (11) in the direction of the molded body (21) until a predetermined contact pressure is reached on the molded body (21),

Increasing the pressure of the medium within the hollow body (14) with increasing contact pressure,

Reduce the pressure in the hollow body (14) and the contact pressure by the pressure means (11) and

Take out the molded body (21).

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