KR20020029784A - Rotary type compressive filtrating machine - Google Patents

Abstract

It provides a rotary compression filter which can be expected to improve the dewatering efficiency in the discharged dewatered cake. The feedstock solution is continuously introduced into the filtration chamber 10 having a rectangular cross section and extending in a ring shape, and the donut-shaped screen 5 having water permeability is continuously rotated in the longitudinal direction of the filtration chamber 10. In the rotary compression filter 1 which moves and compresses the processing stock solution sequentially in the longitudinal direction by friction with the screen 5 in the filtration chamber 10 by moving, the pressure plate 13 in the filtration chamber 10. The cross section of the filtration chamber 10 is configured to gradually decrease with the movement of the processing stock solution by providing the.

Description

ROTARY TYPE COMPRESSIVE FILTRATING MACHINE}

Apparatus for separating solids and liquids include centrifuges, centrifugal filters, filter presses, screw presses, rotary vacuum filters, rotary compression. There are several types, such as filters. Among them, the rotary compression filter is, for example, the one described in the publication of Canadian Patent Application No. 404223 (filed June 1, 1982) and the structure as shown in Figs. .

Fig. 7 is a perspective view of a part of the structure of a conventional rotary compression filter 101 according to the related art. As clearly shown in these drawings, the rotary compression filter 101 basically includes a rotary shaft 102, an inner ring spacer 103, an outer ring spacer 104, and two donut shaped screens. 105, 105, separator 106 and back pressure device (not shown), external casing, drive device and the like.

More specifically, the rotating shaft 102 is supported almost horizontally and is supplied at a low speed (about 0.2 to 1.3 revolutions per minute) in the direction of the arrow B shown in Fig. 7 by supplying a driving force by a driving device not shown. It is supposed to rotate. The inner ring spacer 103 is fixed around the rotating shaft 102 to rotate in the same direction along the rotating shaft 102.

The outer ring spacer 104 is disposed on the outer side of the inner ring spacer 103 and is supported by an outer casing not shown in the drawing. The outer ring spacer 104 is approximately 240 degrees on the concentric circle of the rotating shaft 102 from the base end 104a. It consists of a circle-shaped part extending over 300 degrees and a straight part extending in the tangential direction of the concentric circles to the end portion 104b. Further, the outer ring spacer 104 is disposed such that its inner circumferential surface 104c always faces the outer circumferential surface 103a of the inner ring spacer 103 at regular intervals in a circular portion, and in the axial direction of the rotating shaft 102. The thickness W1 of the outer ring spacer 104 in E2 corresponds to the thickness W2 of the inner ring spacer 103.

In the two screens 105 and 105, the inner peripheral edge portions 105a and 105a are respectively fixed on both sides of the inner ring spacer 103, and the outer peripheral edge portions 105b and 105b are arranged as positions and sizes in contact with both sides of the outer ring spacer 104. Therefore, when the rotating shaft 102 rotates, the screens 105 and 105 rotate in the same direction along the inner ring spacer 103, and the outer peripheral edges 105b and 105b slide on both sides of the outer ring spacer 104 at this time.

In addition, each of the screens 105 and 105 is provided with a plurality of small pores having a diameter of about 0.18 mm in order to ensure water permeability, and a filter for removing water from the processing stock solution as described later. It acts as a filter.

The separating plate 106 is supported substantially horizontally and in a direction orthogonal to the axial direction of the rotating shaft 102, and the thickness W3 of the separating plate 106 in the axial direction of the rotating shaft 102 is the thickness W1 of the outer ring spacer 104 and the thickness W2 of the inner ring spacer 103. Is consistent with The inner end portion 106a of the separating plate 106 is formed so as to be in surface contact with the curvature of the outer circumferential surface 103a of the inner ring spacer 103 and to slide.

In the separating plate 106, an end (outer end 106b) opposite to the inner end 106a is formed between the base end 104a and the end 104b of the outer ring spacer 104, respectively. It is supported at predetermined intervals. The space secured between the outer end portion 106b and the outer ring spacer 104 base end 104a is a feedstock supply hole 108, which is used to supply the processing liquid flowing into the apparatus, and the outer end 106b and the outer ring spacers. The space secured between the 104 terminal portions 104b functions as a cake outlet 109.

The bottom surface 106c of the separating plate 106 coincides with the tangential direction of the outer circumferential surface 103a of the inner ring spacer 103 and extends in parallel with the upper surface 104d of the straight portion of the outer ring spacer 104. On the other hand, this rotary compression filter 101 has a structure that is closed by an outer casing except for the stock solution supply port 108, the cake outlet 109 and the liquid discharge port not shown in the drawing.

On the side of the cake outlet 109, there is provided a back pressure device having a movable valve 107 as shown in FIG. The movable valve 107 of this back pressure device is formed of a flexible material, and is bent until the end portion 107a on the cake outlet 109 side comes into contact with the inner wall of the outer casing 113 on the opposite side. The opening area of the cake outlet 109 can be freely adjusted from the fully open state shown in 12 (1) to the fully closed state shown in Fig. 12 (2).

Here, the operation method and operation principle of the conventional rotary compression filter 101 having the above-described structure will be briefly described with reference to Fig. 9 (sectional view of the rotary compression filter 101 in Fig. 7 cut through CC line) and Fig. 12. Explain. First, at the start of operation, as shown in (2) of FIG. 12, the movable valve 107 of the back pressure device is fully closed, and the filtration chamber 110 (inner ring spacer 103, separation plate 106) is discharged from the stock solution supply port 108 shown in FIG. And the outer ring spacer 104. The cross section is a space having a rectangular shape (see Fig. 8), and a portion extending in an annular shape (C shape) (a ring portion) and a portion extending in a straight shape (straight line shape). And the process stock solution is sequentially introduced into the space from the stock solution supply port 108 through the annular portion and the straight portion to the cake outlet 109). At this time, since the movable valve 107 of the back pressure device is in a developed state as described above, the processing raw liquid flowing in is stored in the filtration chamber 110 without being discharged from the cake outlet 109 to the outside.

All of the annular portions and some of the straight portions in the filtration chamber 110 are closed by two screens 105 and 105 opposite to each other (hereinafter referred to as lateral by these screens 105 and 105 in the filtration chamber 110). Although the closed portion is referred to as a "screen portion", the screen 105 is provided with a large number of pores for securing water permeability as described above, so that the process liquid is stored in the filtration chamber 110. At this time, the water in the feedstock passes through the pores of the screen 105 and is gradually discharged out of the filtration chamber 110. Then, the process stock solution increases the solid content concentration to form a slurry, and a part of it adheres to the screen surface. Meanwhile, the water discharged out of the filtration chamber 110 flows into the inner wall of the outer casing and the screen 105 to be discharged from the liquid outlet to the outside of the apparatus.

In this state, a drive device not shown in the drawing is driven to supply a driving force to the rotating shaft 102 to rotate the rotating shaft 102 at a low speed (about 0.2 to 1.3 revolutions per minute) in the direction of the arrow B shown in FIG. Then, the inner ring spacer 103 fixed around the rotating shaft 102 and the screen 105 fixed on both sides of the inner ring spacer 103 rotate in the same direction.

When the screen 105 is rotated, the processing liquid introduced into the filtration chamber 110 is moved from the stock feeding port 108 toward the cake outlet 109 toward the cake outlet 109 by the friction force generated between the rotating screen 105 or the slurry-like processing liquid attached thereto. Proceeds sequentially. In this way, when the slurry-like processing stock proceeds to the inside of the filtration chamber 110, dehydration further progresses in the process, and the slurry-like processing stock becomes gradually cake-like (dehydrated cake). The friction between the screen 105 is also greater and the dewatered cake is conveyed forward by the increased friction but is not conveyed at constant speed with the screen 105 because it is resisted by the preceding dehydrated cake. On the contrary, it compresses the preceding dewatering cake. For this reason, dehydration of a preceding dewatering cake advances further.

In this way, as the processing liquid introduced into the filtration chamber 110 approaches the cake outlet 109, dehydration proceeds, and the dehydrated cake stays in the vicinity of the cake outlet 109 in the filtration chamber 110. When the operation valve 107 of the back pressure device is opened after a predetermined time has elapsed since the start of operation, the first dewatered cake staying near the cake outlet 109 is extruded by a subsequent dewatered cake, and the cake outlet 109 It is discharged to the outside. When the first dehydrated cake is discharged, the start operation is completed and the operation returns to the normal operation.

In the normal operation, as in the start operation with the operation valve 107 of the back pressure device shown in Fig. 12 open, the processing liquid is sequentially introduced into the filtration chamber 110 from the stock solution supply port 108, and the screen 105 is rotated at a predetermined speed. The stock solution is continuously filtered and dehydrated to discharge the dehydrated cake from the cake outlet 109. In this normal operation, the filtration and dewatering action from the inflow of the processing stock solution to the discharge of the dewatering cake is not fundamentally different from the start operation described above, but the supply amount of the processing stock solution, the rotational speed of the screen 105 and the back pressure device By appropriately adjusting the opening degree of the movable valve 107, the dewatered cake can be discharged at a desired degree of dehydration.

As described above, the rotary compression filter 101 can appropriately separate the processing liquid into a liquid (moisture) and a solid (dehydrated cake) by simply rotating the inner ring spacer 103 and the screen 105 at low speed. Since the noise is small and sealed by the outer casing, it is easy to manage in the sanitary aspect of food processing, and the generation of odor can be minimized in the case of waste treatment. There is this.

However, this rotary filter 101 has the following problems. That is, the dewatered cake 111 is discharged to the outside from the cake outlet 109 in the state as shown in FIG. 10, but discharged at a lower position relatively close to the outer ring spacer 104 among them (for example, to L in this figure). The dewatered cake of the marked area is lower in the degree of dehydration compared to that discharged at an upper position relatively close to the separating plate 106 (for example, the dehydrated cake of the portion indicated by H in this figure) ( In other words, the moisture content is high).

This problem is peculiar to this type of rotary compression filter 101, and its cause is considered to be approximately as follows. First, as shown in Fig. 11, since the screen 105 rotates in the direction of arrow B, the frictional force between the dewatering cake and the screen 105 is in the direction of rotation of the screen 105, that is, in the direction of arrows F (F1 to F5) shown in Fig. 11. It will work. Among these, near the bottom of the rotating shaft 102, the directions F1 and F2 in which the frictional force acts coincide with the traveling direction D4 of the dehydrated cake. In other words, it acts toward the bottom surface 106c of the separating plate 106.

For this reason, the dewatering cake located at F1 proceeds in the direction of F3 along the frictional force with the screen 105, but the frictional force acts toward the bottom surface 106c of the separating plate 106 at the position of F3. While pressing the bottom surface 106c of the separating plate 106, it proceeds to the position of P1 along the bottom surface 106c. The dewatering cake located outside the F1 (outer ring spacer 104 side) acts in the direction of F3 or F4 while the dewatering cake located at F1 reaches the position of P1 along the bottom surface 106c of the separator 106 from the position of F1. As the friction force continues to move toward the bottom surface 106c of the separation plate 106, so-called force collisions occur, so that near the bottom surface 106c of the separation plate 106, especially near P1, the dewatering cake is not only compressed at high pressure, Compression is performed by changing the relative positions of the fine particles of the dehydrated cake.

On the other hand, the dewatered cake located at F2 proceeds in the direction of F5 along the frictional force with the screen 105 and is extruded in the direction of P2 by the subsequent dewatered cake, but at the position of F5 the frictional force is at the bottom surface of the separator 106c. Since the dehydrating cake located at F2 is partially directed to the separation plate 106, the dewatered cake located at F2 flows to the position of P2. Therefore, the density and pressure of the dehydrated cake at the position of P2 are smaller than that of the dehydrated cake at the position P1, and since the force collisions occurring near the separator 106 do not occur near P2, Positional change is also unlikely to occur.

Due to this action, the dewatering cake in the filtration chamber 110 is compressed to some extent in the region close to the separator 106 and dewatered. On the contrary, in the region close to the outer ring spacer 104, the dewatering cake is not compressed so strongly and the dehydration degree is low. It is discharged to the outside at the cake outlet 109 as it is.

In addition, in the conventional rotary compression filter 101 as shown in Fig. 7, operation is performed by controlling the rotational speed of the rotating shaft 102, the feed amount of the liquid feedstock and the movable valve 107 of the back pressure device at the cake outlet 109, and the rotational speed of the rotating shaft 102 and the stock solution. Even when the supply amount is made constant, the degree of dehydration in the dewatered cake to be discharged can be controlled to some extent by adjusting the back pressure in the back pressure device.

However, if the back pressure is increased to obtain a higher degree of dehydration, the cake path 112 in Fig. 9 (parts other than the screen portion in the filtering chamber 110, and the space from the end of the screen portion to the cake outlet 109) in Fig. 9 is shown. As the pressure increases, friction between the inner wall of the cake passage 112 and the dewatered cake increases, which prevents the movement of the dehydrated cake and causes blockage or damage to the apparatus due to internal pressure.

The present invention can solve the above problems by improving the conventional rotary compression filter, and can expect a remarkable improvement in the average degree of dehydration in the discharged dewatered cake, and also improve the dewatering efficiency and smooth discharge of the dewatered cake. It is an object to provide a rotary compression filter.

The present invention is a dehydration process by filtering and compressing a raw material of processed food, a semi-processed product thereof, or a water-containing product (treatment stock solution) such as sludge. TECHNICAL FIELD This invention relates to a compression filter which performs water, and in particular, a rotary type which dehydrates by gradually applying pressure to the processing liquid as it progresses in a ring-shaped filtration chamber formed around a rotating shaft. The present invention relates to a compression filter.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a sectional view showing the basic structure of a first embodiment in a rotary compression filter 1 according to the present invention.

Fig. 2 is a sectional view showing the basic structure of the second embodiment of the rotary compression filter 1 according to the present invention.

Fig. 3 is a sectional view showing the basic structure of the third embodiment of the rotary compression filter 1 according to the present invention.

Fig. 4 is a cross-sectional view showing the basic structure of the fourth embodiment in the rotary compression filter 1 according to the present invention.

FIG. 5 is a front view of a screen 5 used for the rotary compression filter 1 in FIG.

6 is a cross-sectional view showing the basic structure of a fifth embodiment in the rotary compression filter 1 according to the present invention.

7 is a perspective view cut away from a part of the basic structure of a conventional rotary compression filter 101 of the related art.

FIG. 8 is a cross-sectional view taken along line AA of the rotary compression filter 101 of FIG.

FIG. 9 is a cross-sectional view of the rotary compression filter 101 of FIG. 7 taken along line CC.

FIG. 10 is an enlarged sectional view of the vicinity of the cake exit 109 of the rotary compression filter 101 shown in FIG.

FIG. 11 is a cross-sectional view for explaining the operation of the rotary compression filter 101 in FIG.

12 is an explanatory view of a movable valve 107 of a back pressure device provided near the cake outlet 109 of the rotary compression filter 101 in FIG.

The present invention has a rectangular cross section, and continuously flows in the processing stock solution into a filtration chamber extending in a ring shape, and at least one wall surface constituting the filtration chamber is filtered. An apparatus for sequentially moving and compressing longitudinally in a longitudinal direction by friction with the wall surface for rotating the processing liquid in the filtration chamber by continuously rotating in the longitudinal direction of the fruit. At least one wall constituting the fruit is formed of a material having water permeability, so that when the processing liquid is compressed, the dewatering cake remaining after removing water from the processing liquid is left in the cake passage. Rotary compression filter configured to be discharged from the cake outlet to the outside through In the device, in order to solve the above problems, by providing a pressurizing means in the filtration chamber, the cross-sectional area of the filtration chamber is configured to gradually decrease with the movement of the processing stock solution or the dehydrated cake. It features.

In this way, the dewatering cake can be compressed in a direction orthogonal to the moving direction of the dewatering cake, and as a result, the average dewatering degree in the dewatering cake discharged can be improved.

In addition, the filtration chamber has an outer circumferential surface of an inner ring spacer that is fixed around the rotating shaft and rotates along the rotating shaft, and an inner circumferential surface of an outer ring spacer disposed outside the inner ring spacer. And inner side surfaces of two screens each having an inner circumferential edge portion fixed to both sides of the inner ring spacer, and arranged as a position and a size in which the outer circumferential edge portion is in contact with both sides of the outer ring spacer, It is preferable to configure each inner surface of the screen to continuously rotate in the longitudinal direction of the filtration chamber. In this case, the pressurizing means may be provided on either the inner ring spacer side or the outer ring spacer side in the filtration chamber. In the case where the pressurizing means is provided on the inner ring spacer side, a plurality of small holes having at least two kinds of diameters having different diameters are provided, and the small holes having smaller diameters are located on the outer side than the small holes having larger diameters. If the pressure means is formed to close the pores with a large diameter inward at a portion where the pressure in the filtration chamber is increased by using the screen arranged, it is expected to improve the dehydration efficiency as a whole apparatus.

In addition, when the pressure plate is provided in the filtration chamber as the pressure means, and the pressure plate is configured to be displaceable in the vertical direction, it is possible to set the position of the pressure plate suitable for normal operation and also to the cake passage. The dehydration cake can be prevented from being blocked.

EMBODIMENT OF THE INVENTION Hereinafter, the Example of this invention is described using drawing. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a sectional view showing the structure of a first embodiment in a rotary compression filter 1 according to the present invention. The rotary compression filter 1 is basically a rotary shaft 2, an inner ring spacer 3, an outer ring spacer 4, and two donut shaped screens as in the prior art. 5, the separator 6 and an external casing, a driving device, etc. not shown in the drawing, and are formed between the filtration chamber 10 (inner ring spacer 3, separating plate 6 and outer ring spacer 4). Which has a rectangular cross section and has a ring-shaped portion (ring portion) and a straight portion extending portion (straight portion). Through the undiluted portion and straight portion, the solution is opened through the undiluted feed hole 8 in the space leading to the cake exit 9. The screen 5, which is one of the wall surfaces constituting the filtration chamber 10, is continuously rotated in the longitudinal direction of the filtration chamber 10, so that the treatment stock is filtered through the screen 5 in the filtration chamber 10. While moving sequentially in the direction of the arrow D, and at the same time to compress, at this time to remove the water from the processing stock solution through the screen 5 formed of a water-permeable material, the remaining dewatered cake The cake is configured to be discharged from the cake outlet 9 to the outside.

As clearly shown in Fig. 1, this rotary compression filter 1 is provided with a pressure plate 13 in the filtration chamber 10 as a pressurizing means, and the cross-sectional area of the filtration chamber 10 is treated as raw material or dewatered. It is configured to gradually decrease along the moving direction of the cake. For this reason, when the process stock solution or dehydration cake proceeds through the filtration chamber 10, the cross-sectional area of the filtration chamber 10 gradually decreases, and the process stock solution or dehydration cake generates pressure in a direction orthogonal to the traveling direction along the progress. do.

As described above, the rotary compression filter 1 of the present embodiment can compress the processing stock solution or the dewatered cake not only in the traveling direction of the filtration chamber 10 but also in a direction orthogonal to the traveling direction. High dehydration degree is obtained.

In this embodiment, the pressure plate 13 is provided along the outer circumferential surface 3a of the inner ring spacer 3 and the bottom surface 6c of the separation plate 6, and the pressure plate 13 is mainly provided by the screen 5 (screen 5 in the filter chamber 10). The cross-sectional area of the filtration chamber 10 is gradually reduced in the side closed portion, while the cake passage 12 (parts other than the screen portion in the filtration chamber 10, from the end of the screen portion to the cake outlet 9). In the space up to, the bottom surface of the pressure plate 13 and the upper surface 4d of the outer ring spacer 4 are substantially parallel, and in the cake passage 12, the cross-sectional area of the filtration chamber 10 is almost reduced, so that the conventional rotary compression filter Compared to the filtration chamber 10, the filtration and dehydration In a number of higher cake dewatering is obtained.

In more detail with regard to this point, the cake passage 12 is constituted by the bottom surface of the pressure plate 13 and the top surface 4d of the outer ring spacer 4, and the inner side of the outer casing not shown in the drawing. Since the dehydration cake is compressed in a direction orthogonal to the traveling direction in the cake passage 12, only water can not be effectively separated from the dewatering cake. Although it does not promote filtration and dehydration of the cake, when dewatering cake is compressed in the direction orthogonal to the traveling direction from the screen part, the water is quickly discharged to the outside through the screen 5, so that it is efficiently filtered and dewatered. When draining dehydrated cake It is that it is possible.

In the present embodiment, the screen 5 is formed of a smooth metal plate having a large number of small pores, but has a water permeability as a porous material. If provided, it may be formed of, for example, plastic, metal or ceramic sintered body.

Fig. 2 is a sectional view showing the structure of the second embodiment of the rotary compression filter 1 according to the present invention. As shown in this figure, the rotary compression filter 1 according to the present embodiment has a structure in which the pressure plate 13 is provided along the upper surface 4d of the outer ring spacer 4, and the screen portion gradually reduces the cross-sectional area of the filtration chamber 10. have. Therefore, similarly to the rotary compression filter 1 in the first embodiment, the processing stock solution or the dewatering cake which proceeds inside the filtration chamber 10 can be compressed in a direction orthogonal to the traveling direction. As a result of the screen part being quickly discharged, the filter can be efficiently filtered and dewatered as compared with the conventional rotary compression filter 1, and the dewatered cake can be discharged with a higher degree of dehydration.

In addition, in the conventional rotary compression filter, the dewatering cake of the portion close to the outer ring spacer is less dehydrated because the change in relative position of the microparticles is less likely to occur and the compression is low, but in the rotary compression filter 1 of the present embodiment, Filtration and dehydration are also promoted with respect to the dewatering cake of the portion close to the outer ring spacer 4 (for example, the portion indicated by P in Fig. 2), thereby obtaining a higher degree of dehydration. This can be caused by the action of the pressure plate 13 installed along the outer ring spacer 4 to deform the fine portion (particulate group) of the dewatering cake near the outer ring spacer 4 so that the water surrounded by the fine particle group can be extruded. Because the chances are high.

In addition, although both embodiments of the first and second embodiments have shown an example in which a single pressure plate 13 is attached to one apparatus, the number of the pressure plates 13 is not necessarily limited to one, but is shown in FIG. The pressure plate 13 as shown in FIG. 2 and the pressure plate 13 as shown in FIG. 2 may be appropriately adjusted, and both of them may be provided in one rotary compression filter 1.

In addition, with respect to the pressurizing means, as in the first and second embodiments (Figs. 1 and 2), it is not necessary to provide a pressurizing plate 13 which is an independent member apart from these other than the separating plate 6 or the outer ring spacer 4, The separation plate 6 or the outer ring spacer 4 itself may be formed in a shape and a dimension that gradually reduce the cross-sectional area of the filtration chamber 10 so as to compress the processing stock solution or the dewatering cake in a direction orthogonal to the traveling direction.

Fig. 3 is a sectional view showing the structure of the third embodiment of the rotary compression filter 1 according to the present invention. In this embodiment, the pressing portion 6e on the inner lower portion of the separating plate 6 has a function as a pressing means, and as shown in Fig. 3, the displacement pressing plate 13a has an arbitrary point of rotation. I) 16, the cake outlet 9 side is configured to be displaceable in the vertical direction or to be displaced (that is, rotated) at regular intervals. Although the description for the mechanism for displacing the pressure plate 13 is omitted, a cam mechanism, a crank mechanism, and the like can be suitably used.

In this way, the pressure plate 13 is configured to be displaceable so that the position of the pressure plate 13 suitable for normal operation can be set, and at the start of operation, sufficient stock solution or dehydration cake is accumulated inside the apparatus to provide sufficient internal pressure for filtration and dehydration. It can also be used to extremely narrow the cake passage 12 so that dehydrated cake that has not yet been sufficiently filtered and dehydrated until this occurs is not discharged from the cake outlet 9 to the outside. Therefore, the back pressure device provided with the movable valve 107 as shown in Fig. 12 used in the conventional rotary compression filter can be omitted in the rotary compression filter 1 in this embodiment.

In addition, when the pressure plate 13 is configured to be rotatable, stable operation is possible even when the dehydration cake is prevented from clogging in the cake passage 12 and the pressure plate 13 is set to increase the maximum pressure.

3 shows an example in which the displacement or rotatable pressure plate 13 is provided on the separation plate 6 side, but the pressure plate 13 can be configured to be rotatable even when the pressure plate 13 is installed along the outer ring spacer 4 as shown in FIG. Also in this case, the same effects as described above can be expected. In addition, the pressure plate 13 may be configured to displace the entirety, or may be configured to displace only a portion thereof.

The displacement of the pressure plate 13 as shown in Fig. 3 can also be applied to automatic control. For example, in the case where there is a temporal or seasonal variation in the concentration of solids or the components of the solids, if the operating conditions such as the rotation shaft, the amount of feed of the feed, and the displacement of the pressure plate 13 are constant, The degree of dewatering of the dewatered cake discharged also varies depending on the nature and condition of the dehydrated cake, but a pressure sensor is attached to the surface of the pressure plate 13 in the filtration chamber 10 to detect the pressure in each part of the filtration chamber 10. When the pressure plate 13 is configured to be displaced, the pressure inside the filtration chamber 10 can be easily controlled, and the degree of dehydration of the discharged dewatered cake can also be controlled within a desired range.

In addition, in the case of the conventional rotary compression filter (see FIG. 9), the inner wall of the cake passage 112 and the filtration chamber 110 when the movable valve 107 (see FIG. 12) of the back pressure device are displaced using the same detection device. The integrated value of the frictional force of the dewatered cake from the cake exit 109 to the cake outlet 109 became an error factor and satisfactory control was not possible.

4 is a cross-sectional view showing the structure of the fourth embodiment in the rotary compression filter 1 according to the present invention. As is apparent from this figure, in this embodiment, the separating plate 6 is shaped to gradually reduce the cross-sectional area of the filtration chamber 10, and the separating plate 6 itself functions as a pressing means. More specifically, in the conventional rotary compression filter 101 (see Fig. 9), the bottom surface 106c of the separating plate 106 extends in parallel with the top surface 104d of the straight portion of the outer ring spacer 104 to reduce the cross-sectional area of the filtration chamber 110. Although not constituted, the bottom surface 6c of the separating plate 6 in this embodiment has an outer end portion from the inner end portion 6a which is in surface contact with the outer circumferential surface 3a of the inner ring spacer 3. (B) over 6b initially extending in a direction substantially perpendicular to the top surface 4d of the straight portion of the outer ring spacer 4, then extending toward the cake outlet 9 with a gentle curve and finally extending substantially parallel to the outer ring spacer 4 in the cake passage 12 The cross section of the filtration chamber 10 gradually decreases in the screen portion, reaching the outer end 6b.

Therefore, even in this embodiment, the dewatering cake traveling in the filtration chamber 10 can be compressed in the direction perpendicular to the traveling direction at the screen portion, so that the dewatering cake can be efficiently filtered and dewatered as compared with the conventional rotary compression filter. Can get dehydrated cake.

Also in this embodiment, the screen 5 is formed of a smooth metal plate having water permeability by a plurality of small pores. As shown in Fig. 5, the pores are formed with different diameters in the zone G1 on the inner peripheral edge portion 5a and the zone G2 on the outer peripheral edge portion 5b. More specifically, zone G1 has a small hole 14 having a diameter of about 0.16 mm to 0.20 mm (preferably 0.18 mm), and zone G2 has a diameter of about 0.11 mm to 0.15 mm (preferably 0.13 mm) of small holes 15 having a smaller diameter than the small holes 14 of zone G1. That is, on the screen 5, the small diameter small hole 15 is arrange | positioned outward from the large diameter small hole 14 (outer peripheral part 5b side). In addition, the line 5c shown in FIG.4 and FIG.5 is a boundary line of zone G1 and zone G2.

Thus, in the present embodiment, by forming small pores 15 having a smaller diameter than the conventional one on the outer peripheral edge portion 5b side of the screen 5, suspended solids (fine particles) in the processing stock solution than the conventional rotary compression filter. The trapping efficiency by the screen 5 is improved. In more detail with regard to this point, first, the treatment stock flowing into the apparatus is characterized in that the filtration zone K (see FIG. 4) in the filtration chamber 10 is in the range of about 200 ° from the top surface 6d of the separator 6. On the way through, most of the water (free water) passes through the small holes 14 and 15 of the screen 5 and is discharged out of the filtration chamber 10.

The dehydration effect in the filtration zone K is relatively low in pressure (0.1 MPa or less), so that the diameter formed in the zone G1 on the inner circumferential edge portion 5a of the screen 5 is large (the same degree as in the prior art). Diameter size) Although there is no possibility of being discharged out of the filtration chamber 10 through the small holes 14, in the compression zone J (see FIG. 4), the pressure in the filtration chamber 10 is controlled by the separating plate 6 which functions as a pressurizing means. Alternatively, as the dehydration cake progresses, the pressure in the filtration chamber 10 gradually increases (up to about 0.6 MPa), so that the microparticles in the processing solution or the dehydration cake pass through the pores 14 of the screen 5 by the increased internal pressure. There is a possibility of being discharged outward (the small holes 15 formed in the zone G2 on the outer periphery 5b side are conventionally small in diameter, so the filtration chamber 1 Even if the internal pressure of zero increases, it is not so large as to worry that the fine particles pass through. In this case, the trapping efficiency of the fine particles decreases.

However, in this embodiment, since the separating plate 6 is formed to gradually reduce the cross-sectional area of the filtration chamber 10, the process stock solution or the dewatered cake located on the inner ring spacer 3 side of the filtration chamber 10 is separated by this separating plate 6. As it progresses inside the fruit 10, it is gradually separated from the inner ring spacer 3 and moved to the outer ring spacer 4 side. Then, in the position where the internal pressure is increased by the separator 6 in the filtration chamber 10 (the position indicated by M in FIG. 4), the processing stock solution or the dewatering cake is applied to the zone G2 (the conventional edge 5b side of the screen 5). The small holes 14 having a diameter smaller than that of the same size as the conventional one formed in the zone G1 on the inner circumferential edge portion 5a side of the screen 5 are separated by the separating plate 6. It is closed on the inside. Therefore, the fine particles of the processing stock solution or the dewatered cake are not discharged out of the filtration chamber 10 from the pores 14, so that the problem of lowering the efficiency of trapping the fine particles in the processing stock solution can be avoided.

In addition, in this embodiment, two kinds of small holes 14 and 15 having different diameters are formed on the screen 5, and small holes 15 having smaller diameters are disposed outside than small holes 14 having larger diameters. For example, 10 types (or more) of small pores with different diameters may be formed on the screen 5, and the diameter of the small pores formed from the inside to the outside may be gradually reduced.

Finally, a fifth embodiment of the rotary compression filter 1 in which the cake passage 12 is not horizontal will be described with reference to FIG. The description so far has shown an example in which the cake passage 12 is arranged almost horizontally, but this is for convenience of explanation, and the present invention does not limit the angle of the cake passage 12 at all. When starting the operation when the cake passage 12 is disposed at the bottom of the machine and there is no mechanism for closing the cake passage 12 and the cake outlet 9, a part of the processing liquid passes through the pores 14 and 15 of the screen 5. Since it flows from the cake outlet 9 through the cake passage 12 instead, the apparatus for temporarily closing the cake passage 12 (for example, a back pressure device having a movable valve 107 as shown in Fig. 12) is required. On the other hand, as shown in Fig. 6, when the cake passage 12 faces upward, it is possible to wait for the accumulation of the processing stock solution or the dehydrated cake without taking special measures when starting the operation.

As mentioned above, although the Example of this invention was described, this invention is not limited to these Examples. In this specification, the words "water" are used, such as "water permeability", "dehydration", "water", etc., but these are used for convenience of explanation, and are not intended to exclude "oil". It means "liquid".

The rotary compression filter in the present invention can expect a significant improvement in the average degree of dehydration in the discharged dewatered cake and can also expect an improvement in the dewatering efficiency. In addition, the pressure of the screen portion in the pressing zone can be increased by the action of the pressing means, so that the pressure of the final dewatering portion of the filtration chamber can be increased, and consequently, the dewatering degree of the entire dewatering cake can be improved.

In addition, when a pressure plate is provided in the filtration chamber as a pressurizing means, and the pressure plate is rotatable up and down, it is possible to widen the range of selecting stable operating conditions and to dehydrate at a higher pressure. Dehydration is improved. In addition, by automatically controlling the displacement of the pressure plate in combination with a signal such as a pressure sensor, it is possible to converge the dehydration degree of the dewatering cake to a certain range in response to the change in the nature and state of the processing stock solution.

In addition, although the rotary compression filter in this invention can be used for the purpose of isolate | separating what is called a solid-liquid mixing process liquid, the solid content contained in a process liquid is compressed and it has a high density property. When it is provided, it is particularly remarkable in comparison with other solid-liquid separators. For example, fruits and vegetables can be used for the separation of juice from shredded products, for the separation of juice, for the separation of soy milk, and for the treatment of liquids containing fine fibers such as papermaking waste liquid. Can be. In addition, when dewatering sludge in a sewage treatment plant, as described above, parts other than the cake outlet can be sealed, thereby minimizing environmental pollution due to odor and deterioration of the working environment. Incineration of dewatered cakes can save fuel and contribute to energy savings.

Claims (6)

The cross section is rectangular in shape, and the feedstock is continuously introduced into the filtration chamber extending in an annular shape, and at least one wall surface constituting the filtration chamber is in the longitudinal direction of the filtration chamber. An apparatus for sequentially moving and compressing in a longitudinal direction by friction with the wall surface for rotating the processing stock solution in the filtration chamber by continuously rotating in a filtration chamber. At least one wall surface is formed of a material having water permeability, so that when the processing liquid is compressed, water is removed from the processing liquid and the remaining dewatered cake is left at the cake outlet through the cake passage. In rotary compression filters configured to be discharged to the outside. Stand, a rotary compression filter, characterized in that by providing the pressing means (加壓 手段) in the filter chamber comprising a cross-sectional area of the filter chamber so as to decrease gradually with the movement of the treatment liquid concentrate or dehydrated cake. The method of claim 1, The filtration chamber includes an outer circumferential surface of an inner ring spacer that is fixed around the rotating shaft and rotates along the rotating shaft, and an inner circumferential surface of an outer ring spacer disposed outside the inner ring spacer. And each inner side of two screens each having an inner circumferential edge fixed to both sides of the inner ring spacer, and arranged as a position and a size in which the outer circumferential edge is in contact with both sides of the outer ring spacer, and rotating the rotary shaft. Rotary compression filter, characterized in that configured to continuously rotate each inner surface of the filter chamber in the longitudinal direction. The method of claim 2, The pressing means is a rotary compression filter, characterized in that installed on the inner ring spacer side in the filtration chamber. The method of claim 2, The pressing means is a rotary compression filter, characterized in that installed on the outer ring spacer side in the filtration chamber. The method of claim 3, The screen includes at least two types of small pores having different diameters, and the small pores having a small diameter are arranged on the outside of the small pores having a larger diameter. Rotary compression filter. The method according to any one of claims 1 to 5, A pressurizing plate is provided in the filtration chamber as the pressurizing means, and the pressurizing plate is configured to be displaceable in the vertical direction.