JPH03130493A - Dehydration device - Google Patents

Abstract

PURPOSE: To obtain more larger treating capacity by specifying a ratio of a radius of curvature of a segmental sliding guide plane which forms an-inlet gap on a dewatering drum and radius of a press roll to a radius of a dewatering drum. CONSTITUTION: An inlet gap 6 is formed in the region of a dewatering drum 4 and in a radial and inner direction with respect to a bent part by the segmental sliding guide plane 3. The radius of curvature R of the segmental sliding guide plane 3 is at least 3 times of an outer radius of the dewatering drum 4, and the outer radius R of the dewatering drum is at least 2 times the minimum outer radius of a press roll 9-13. The dewatering effect in the inlet gap 6 is more enlarged, and the same residual material concentration as in the past can be obtained from material of a lower concentration.

Description

Detailed Description of the Invention [Objective of the Invention] <Industrial Application Field> The present invention provides a perforated dehydration drum as a first dehydration stage and a perforated dehydration drum behind it, particularly for concentrating a fiber suspension. the dewatering drum and press rolls arranged parallel to each other;
A dewatering device comprising two wire belts that are partially wound around both the dewatering drum and the press rolls so that n-1 compression gaps are formed between the press rolls, corresponding to the number n of the press rolls. Regarding.

<Prior art> The dewatering device as described above is disclosed in West German Patent No. 2138.
It is well known from the specification No. 072. 1 In this dewatering apparatus, a head box that supplies a suspension to a region of a wire belt that is partially directly wrapped around the dewatering drum and that is arranged in front of the dewatering drum is provided with a head box that supplies a suspension to a region of a wire belt that is partially wrapped directly around the dewatering drum and that is arranged in front of the dewatering drum. the suspension is supplied to the former or first of the wire belts, and the first wire belt and the latter or the second of the wire Improvements have been made in that an artificial gap is formed between the dewatering drum and the dewatering drum by suitably changing the direction of the second wire belt. It was thus possible to collect the liquid passing through the first wire belt already in the area of the applicator device and to remove it from the suspension already at an early stage.

<Problems to be Solved by the Invention> The object of the present invention is to form a dewatering device which can obtain a larger processing capacity and in particular can lower the concentration of the material to be received due to the effect of a larger initial dehydration process. It's about doing.

[Structure of the Invention] Means for Solving the Problems According to the present invention, the above-mentioned object is achieved by providing a perforated dehydration drum as a first dehydration stage and a subsequent two wires that are partially wound around both the dewatering drum and the press roll so that n-1 compression gaps are formed between the dewatering drum and the press roll, corresponding to the number n; an inlet gap is formed by an arcuate sliding guide surface for the wire belt disposed radially inwardly on the dewatering drum, and the radius of curvature of the arcuate sliding guide surface is equal to that of the dewatering drum. This is achieved by providing a dewatering device, characterized in that the outer radius of the dewatering drum is at least three times the outer radius, and the outer radius of the dewatering drum is at least twice the smallest outer radius of the press roll.

Furthermore, according to the invention, in particular the number of press rolls is at least 4 and they are substantially radially inward and radially outward with respect to the curved part of the wire belt radially inward of the dewatering drum. The wire belts are arranged in parallel in one row, and the wire belts are connected to the press rolls of at least one of the press roll rows at an acute angle of about 70 degrees to the connecting surface of the central longitudinal axis of the other press roll row. More favorable effects can be achieved with a dewatering device characterized in that it is provided with a pressing element with a central longitudinal axis inclined with respect to the surface manipulation direction.

Effect> What determines the throughput of the dewatering device is primarily the amount of suspension entering the inlet gap, ignoring the control or setting of the rotational speed of the dewatering drum or the rotational speed of the wire belt. According to the invention, in the region of the arcuate sliding guide surface in the population gap, the compressive force of the wire belt increases relatively slowly until it reaches a higher first value on the dewatering drum. . This results in a good squeezing out of the embeddings to form a fleece-like material, but otherwise the suspension would easily splash out from the sides of the inlet gap. Advantageously, this arcuate sliding guide surface is formed with an arc of 15 degrees in the region of the inlet gap.

<Examples> Hereinafter, the present invention will be described in detail using examples with reference to the accompanying drawings.

The belt-type compression filter shown in the figure is characterized by two wire belts 1.2 which co-operate and partially wrap around both the circumferentially perforated dewatering drum 4 and the following press rolls 9-13. have

The wire belt 2 on the inside in the radial direction is further connected to the direction changing roll 2
5.27 and the radially outer wire belt 1 with respect to the dewatering drum 4 is connected to the dewatering rolls 28 to 5.
It is wrapped around 31.

In the area of the dewatering drum 4 an artificial gap 6 is formed, which inlet gap 6 is directed downwardly by means of an arcuate sliding guide surface, preferably made of smooth plastic material and partially perforated on the filter. That is, it is formed radially inward with respect to the concave portion of the wire belt 2 that directly presses against the dewatering drum 4. This allows the water (liquid content) forced out of the suspension in the inlet gap to be discharged into the collection trough 38. The suspension is
An inlet socket 41 feeds into an upper container 40 which feeds onto the wire belt 2 in close contact with the dewatering drum 4 . The liquid that has passed through the wire belt 21 at this position is also collected in the collection trough 38.

The dewatering drum 4 has a perforated circumferential surface, and preferably a filter is pasted on the perforated cylindrical surface. The side of the dewatering drum 4 is sealed by a plate 34 provided with a drain port 35. The dewatering drum 4 is attached at both ends to bearings 32 supported by upper support beams.

Two of the press rolls 9 to 11 in the lower row following it and the press rolls 12, 13 in the upper row in both adjacent rows
The press rolls always create a compression gap or gap between them. The press rolls 12.13 of the upper press roll row are supported by hydraulic piston and cylinder arrangements 14.15 which are supported on the upper support beam 20. The central axes of these press elements 14,15 are inclined at an angle of approximately 70 degrees in the running direction of the wire belt with respect to the connection plane of the central longitudinal axes of the lower press roll rows 9-11. As a result, the upper press roll 12
．． 13 is pressed against the lower press rolls 9-11 so that two compression gaps are formed. Depending on the size of this gap, an increasing compressive force is applied in the range of 100 to 60 ON/cm.

The squeezed out water (liquid content) is collected in the lower collection trough 36 and removed via the drainage socket 37. The entire dewatering device is supported on the base plate 4 by support members 45 , 46 carrying the lower cross beam 21 . Furthermore, the upper cross beam 20 is supported on the lower cross beam 21 by longitudinal support columns 22.23. Turning roll 25 as shown
．． 33 is supported by similar bearings, but the deflection roll 28 is supported by a swinging arm 51 and a hydraulic element 52 to create tension in the wire belt. The structure of the upper direction conversion roll 27 of the other wire belt 2 is also similar, and the lever 53 and the pneumatic element 54
are established for the same purpose. These pneumatic elements act on levers 53, 56 respectively.

The rate radius R of the arcuate sliding guide surface 3 is at least three times the outer radius of the dewatering drum 4, and the outer radius R of the dewatering drum 4 is at least twice the minimum outer radius r of the press rolls 9-13. .

This belt compression filter has the further advantage that, due to the relatively gentle and technically very favorable dewatering process, materials with relatively low initial substance concentrations can be used in the region of the population gap 6. The good dewatering effect results in residual substance concentrations that are approximately similar to conventional dewatering devices of this type.

Depending on the stock type, the inlet stock concentration ranges from 2.5% to 2.5%.
It is in the range of 9%. The radius of the arcuate sliding guide surface 3 is at least three times the outer radius of the dewatering drum 4, and the outer radius R of the dewatering drum 4 is at least twice the smallest outer radius r of the press rolls 9-13. be.

<Effects of the Invention> As described above, according to the present invention, it is possible to obtain a greater dewatering effect than before, especially in the area of the inlet gap,
As a result, a final residual substance concentration similar to that of the prior art can be obtained from a material with a lower concentration, thereby increasing the throughput of the dewatering device.

[Brief explanation of the drawing]

The drawing is a sectional view schematically showing the basic configuration of a belt-type compression filter using the present invention. 1.2...Wire belt, 4...Dehydration drum, 6.
・・Inlet gap, 9 to 13 ・・Press roll, 14
．． 15...Hydraulic piston/cylinder device, 20...
Upper cross beam, 21...lower cross beam, 22
．． 23...Support column, 25.27.28...Direction changing roll, 28-31...Dewatering roll, 32...
Bearing, 33... Direction conversion roll, 34... Plate, 35... Drain port, 36... Lower collection trough, 37
...Drain socket, 38...Collection trough, 40...
- Upper container, 45. 46... Support member, 48... Base plate, 51... Swinging arm, 52... Hydraulic element, 53... Lever 54... Pneumatic element, 56
...Lever patent applicant: Yotsut M.V.

Claims (6)

[Claims] (1) In particular, in order to concentrate the fiber suspension, there is a perforated dehydration drum as a first dehydration stage, a press roll arranged behind the dehydration drum and parallel to each other, and between the press rolls. and two wire belts partially wrapped around both the dewatering drum and the press roll so that n-1 compression gaps are formed corresponding to the number n of the dewatering apparatus, the dewatering apparatus comprising: an inlet gap is formed by an arcuate sliding guide surface for the wire belt arranged radially inwardly on the dewatering drum, the radius of curvature of the arcuate sliding guide surface being at least three times the outer radius of the dewatering drum; and the outer radius of the dewatering drum is at least twice the minimum outer radius of the press roll. (2) the number of the press rolls is at least 4;
and the presses of at least one row of press rolls are arranged in parallel in substantially one row on the radially inside and radially outside with respect to the curved portion of the wire belt radially inside the dewatering drum; characterized in that the roll is provided with a pressing element having a central longitudinal axis inclined with respect to the running direction of the wire belt at an acute angle of about 70 degrees with respect to the connecting plane of the central longitudinal axis of the other press roll row. A dehydration device according to claim 1. (3) The pressing element is a hydraulic or pneumatic cylinder.
The dewatering device according to claim 1 or 2, which is a piston device. (4) Any one of claims 1 to 3, wherein the pressing element is disposed radially inward with respect to the curved portion of the wire belt, which is disposed radially inward with respect to the dewatering drum. The dehydration device described in . (5) The dewatering device according to any one of claims 1 to 4, wherein the press roll row is arranged approximately horizontally or within a maximum range of 25 degrees from a horizontal plane. (6) The dewatering device according to any one of claims 1 to 5, wherein the radius of curvature of the arcuate sliding guide surface is approximately four times the radius of the dewatering drum.