JP2021115591A - Screw press - Google Patents

Abstract

To provide a screw press which can reduce an installation space.SOLUTION: A screw press includes: a filtering tube 1 to which a liquid content is charged; a first screw 3 and a second screw 4 which are arranged in the filtering tube 1 so as to be concentric to the filtering tube 1 and transfer the liquid content in a predetermined transfer direction; a first rotary mechanism 7 for rotating the first screw 3; and a second rotary mechanism 20 for rotating the second screw 4 independently from the first screw 3. The second screw 4 is arranged on the downstream side of the first screw 3 in the transfer direction, and the second rotary mechanism 20 includes a revolving bearing 21 for rotatably supporting the second screw 4, and a driving mechanism 22 for rotating the second screw 4 through the revolving bearing 21.SELECTED DRAWING: Figure 1

Description

The present invention relates to a screw press that squeezes a liquid-containing material such as sludge to separate the liquid from the liquid-containing material.

Conventionally, a screw press has been used as a device for squeezing sludge (liquid-containing matter) discharged from a liquid treatment facility such as a water and sewage treatment plant and a urine treatment plant to separate (that is, dehydrate) water from the sludge. Are known. This screw press includes a filter tube formed of a screen (perforated plate) and a screw arranged inside the filter tube. The screw has a screw shaft arranged concentrically with the filtration cylinder and a screw blade fixed to the outer surface of the screw shaft. The sludge charged into the filtration tube is squeezed and dehydrated by rotating the screw blades by a rotating mechanism connected to the screw shaft. A back pressure plate that dams up sludge is placed at the downstream opening end of the filtration tube, and the back pressure plate allows the cake (dehydrated sludge) sent by the rotating screw blades to stay and plugs made of cake (dehydrated sludge). A stopper) is formed. Back pressure is applied to the cake to which this plug is sent later to further squeeze the cake, thereby reducing the water content of the sludge in the filter tube.

Patent Document 1 discloses a biaxial screw press. This type of screw press includes a first screw and a second screw arranged in series in a filtration tube. These first screw and second screw are configured to be able to rotate at different speeds by different drive devices. Therefore, by controlling the rotation speeds of the first screw and the second screw, it is possible to form a plug in the filter cylinder and squeeze the sludge in the filter cylinder without providing a back pressure plate.

Japanese Unexamined Patent Publication No. 2018-15582

However, since the above-mentioned biaxial type screw press inevitably includes two drive devices for rotating the two screws, an installation space for these drive devices is required, and as a result, the entire screw press is large. It turns into.

Therefore, the present invention provides a screw press that can reduce the installation space.

In one aspect, a filter cylinder into which the liquid-containing material is charged, and a first screw and a second screw which are arranged concentrically with the filter cylinder in the filter cylinder and transfer the liquid-containing material in a predetermined transfer direction. A first rotation mechanism for rotating the first screw and a second rotation mechanism for rotating the second screw independently of the first screw are provided, and the second screw is said to have the same in the transfer direction. The second rotating mechanism is arranged on the downstream side of the first screw, and includes a swivel bearing that rotatably supports the second screw, a drive mechanism that rotates the second screw via the swivel bearing, and a drive mechanism that rotates the second screw. A screw press equipped with is provided.

In one aspect, the drive mechanism comprises a rotary gear, and the swivel bearing comprises a plurality of teeth that mesh with the rotary gear.
In one aspect, the plurality of teeth are fixed to the outer ring of the swivel bearing, and the second screw is connected to the outer ring of the swivel bearing.
In one aspect, the plurality of teeth are fixed to the inner ring of the swivel bearing, and the second screw is connected to the inner ring of the swivel bearing.

In one aspect, a filter cylinder into which the liquid-containing material is charged, and a first screw and a second screw which are arranged concentrically with the filter cylinder in the filter cylinder and transfer the liquid-containing material in a predetermined transfer direction. A first rotation mechanism for rotating the first screw and a second rotation mechanism for rotating the second screw independently of the first screw are provided, and the second screw is said to have the same in the transfer direction. The first rotating mechanism is arranged on the downstream side of the first screw, and includes a swivel bearing that rotatably supports the first screw, a drive mechanism that rotates the first screw via the swivel bearing, and a drive mechanism that rotates the first screw. A screw press equipped with is provided.

In one aspect, the drive mechanism comprises a rotary gear, and the swivel bearing comprises a plurality of teeth that mesh with the rotary gear.
In one aspect, the plurality of teeth are fixed to the outer ring of the swivel bearing, and the first screw is connected to the outer ring of the swivel bearing.
In one aspect, the plurality of teeth are fixed to the inner ring of the swivel bearing, and the first screw is connected to the inner ring of the swivel bearing.

According to the present invention, at least one of the first screw and the second screw is supported by a swivel bearing. Since the swivel bearing has a structure in which the gear and the bearing are integrated, it is simpler than the bearing and torque transmission mechanism (for example, a combination of a chain and a sprocket) that are separately provided in a conventional screw press. And a compact structure can be provided. As a result, a screw press with swivel bearings can achieve cost savings and installation space savings.

It is a schematic diagram which shows one Embodiment of a screw press. FIG. 3 is a schematic cross-sectional view of the second screw, the swivel bearing, and the rotary gear shown in FIG. It is a figure which looked at the swing bearing shown in FIG. 2 from the axial direction. It is a figure which shows the other embodiment of the 2nd rotation mechanism. It is a figure which looked at the swing bearing shown in FIG. 4 from the axial direction. It is a figure which shows the other embodiment of a screw press. FIG. 6 is a schematic cross-sectional view of the first screw, the swivel bearing, and the rotary gear shown in FIG. It is a figure which looked at the swing bearing shown in FIG. 7 from the axial direction. It is a figure which shows still another embodiment of a screw press. It is a figure for demonstrating the operation of the screw press shown in FIG. It is a figure for demonstrating the operation of the screw press shown in FIG. It is a figure for demonstrating the operation of the screw press shown in FIG.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic view showing an embodiment of a screw press. The screw press shown in FIG. 1 is arranged concentrically with the cylindrical screen casing (filtration cylinder) 1 and the screen casing 1 in the screen casing 1, and sludge (liquid content) is transferred in a predetermined transfer direction D. The first screw 3 and the second screw 4 to be transferred to the casing, the first rotation mechanism 7 for rotating the first screw 3, and the second rotation mechanism 20 for rotating the second screw 4 independently of the first screw 3. It has.

The screen casing 1 is formed of a screen (perforated plate) such as punching metal. The screen casing 1 has a sludge inlet 2 at its upstream end. The sludge charged into the screen casing 1 from the charging port 2 is transferred in the screen casing 1 in a predetermined transfer direction D by the rotating first screw 3 and the second screw 4. The screw press has a control unit 6 that controls the operation of the first rotation mechanism 7 and the second rotation mechanism 20.

The second screw 4 is connected to the first screw 3 so that it can rotate independently of the first screw 3. The first screw 3 and the second screw 4 extend through the screen casing 1 and the discharge chamber 33, respectively. The discharge chamber 33 is connected to the screen casing 1. A plug cake, which will be described later, is discharged from the screen casing 1 into the discharge chamber 33.

The axial length of the second screw 4 is shorter than the axial length of the first screw. The first screw 3 is fixed to the outer surface of the first screw shaft 3A having a truncated cone shape (tapered shape) and the first screw shaft 3A whose diameter gradually increases toward the downstream side in the sludge transfer direction D. It has a first screw blade 3B. The second screw 4 has a cylindrical second screw shaft 4A, a second screw blade 4B fixed to the outer surface of the second screw shaft 4A, and a flange 5 fixed to the end of the second screw shaft 4A. is doing. The flange 5 and the second screw shaft 4A may be integrally formed.

The second screw shaft 4A of the second screw 4 is arranged concentrically with the first screw shaft 3A. The outer diameter of the second screw shaft 4A is the same as the maximum diameter of the first screw shaft 3A. The second screw shaft 4A extends through the discharge chamber 33.

The upstream end of the screen casing 1 is sealed by a closing wall 8. One end of the first screw shaft 3A (upstream end in the transfer direction D) extends through the closing wall 8. A water sealing device 10 for sealing the gap between the closing wall 8 and the first screw shaft 3A is installed on the closing wall 8. The upstream end of the first screw shaft 3A extending through the closing wall 8 is rotatably supported by bearings 11 and 12 installed on the base (not shown) while restraining axial movement. .. One of the bearings 11 and 12 can be omitted.

The upstream end of the first screw shaft 3A is connected to a first rotation mechanism 7 for rotating the first screw 3. In the present embodiment, the first rotation mechanism 7 includes a first drive (for example, an electric motor) 14, a sprocket 15 fixed to the rotation shaft of the first drive 14, and a sprocket fixed to the first screw shaft 3A. A 16 and a chain 17 wound around these sprockets 15 and 16 are provided. The sprocket 16 is located between the bearings 11 and 12.

When the first drive machine 14 of the first rotation mechanism 7 is driven, the sprocket 15 fixed to the rotation shaft of the first drive machine 14 rotates, and the sprocket 16 fixed to the first screw shaft 3A via the chain 17 To rotate. As a result, the first screw 3 is rotated by the first rotation mechanism 7. The first drive unit 14 is connected to the control unit 6, and the control unit 6 is configured to be able to control the operation of the first drive unit 14.

The second rotating mechanism 20 includes a swivel bearing 21 that rotatably supports the second screw 4 and a drive mechanism 22 that rotates the second screw 4 via the swivel bearing 21. The second screw 4 is connected to the swivel bearing 21. Specifically, the flange 5 of the second screw 4 is fixed to the swivel bearing 21. The swivel bearing 21 can receive both a thrust load and a radial load. In one example, the swivel bearing 21 has an angular contact ball bearing configuration.

The drive mechanism 22 includes a second drive (for example, an electric motor) 25 and a rotation gear 23 fixed to the rotation shaft of the second drive 25. The swivel bearing 21 and the second drive 25 are held by the support base 28. The swivel bearing 21 has a plurality of teeth 21A, and the rotary gear 23 has a plurality of teeth 23A. The teeth 21A of the swivel bearing 21 mesh with the teeth 23A of the rotary gear 23. When the second drive machine 25 is driven, the rotary gear 23 fixed to the rotary shaft of the second drive machine 25 rotates, and the swivel bearing 21 that meshes with the rotary gear 23 rotates. As a result, the second screw 4 connected to the swivel bearing 21 is rotated by the second rotation mechanism 20.

The second drive 25 is connected to the control unit 6. The second drive machine 25 has a built-in inverter (not shown), and the control unit 6 is configured to be able to control the operation of the second drive machine 25 via the inverter. That is, the control unit 6 can control the rotation speed and the rotation direction of the second drive machine 25 via the inverter. The second drive machine 25 can rotate the second screw 4 independently of the first screw 3. It is preferable that the first drive machine 14 also has a built-in inverter capable of changing the rotation speed and the rotation direction of the first drive machine 14.

The first screw blade 3B extends spirally along the axial direction of the first screw shaft 3A, and the second screw blade 4B spirally extends along the axial direction of the second screw shaft 4A. The total length of the portion of the first screw 3 to which the first screw blade 3B is fixed and the portion of the second screw 4 to which the second screw blade 4B is fixed is the axial length of the screen casing 1. Same or longer.

A minute gap is formed between the inner surface of the screen casing 1 and the first screw blade 3B so that the first screw blade 3B can rotate without contacting the screen casing 1. Similarly, a minute gap is formed between the inner surface of the screen casing 1 and the second screw blade 4B, so that the second screw blade 4B can rotate without contacting the screen casing 1. ing. The sludge charged into the screen casing 1 from the inlet 2 formed at the upstream end of the screen casing 1 is transferred toward the discharge chamber 33 by the rotating first screw blades 3B and the second screw blades 4B (that is, transferred). Can be transferred (in direction D).

In the present embodiment, the winding direction of the second screw blade 4B (that is, the spiral direction) is opposite to the winding direction of the first screw blade 3B. Therefore, when the sludge charged from the charging port 2 is sent out to the discharge chamber 33, the second screw 4 is rotated in the direction opposite to that of the first screw 3 as shown in FIG.

The winding direction of the second screw blade 4B may be the same as the winding direction of the first screw blade 3B. In this case, when the sludge charged from the charging port 2 is sent out to the discharge chamber 33, the second screw 4 is rotated in the same direction as the first screw 3.

As shown in FIG. 1, the screen casing 1 is divided into a dehydration region 1A in which the first screw 3 is arranged and a plug forming region 1B in which the second screw 4 is arranged. The space to which sludge is transferred in the dehydration region 1A is formed by the inner surface of the screen casing 1, the first screw blade 3B, and the first screw shaft 3A. As shown in FIG. 1, the cross-sectional area of this transfer space gradually decreases along the sludge transfer direction D. Therefore, as the sludge charged from the charging port 2 is transferred through this transfer space by the first screw blade 3B, the sludge is squeezed and dehydrated. The filtrate that has passed through the screen (perforated plate) of the screen casing 1 is collected by the filtrate receiver 38 arranged below the screen casing 1. A drain 39 is connected to the filtrate receiver 38, and the filtrate collected by the filtrate receiver 38 is discharged from the screw press via the drain 39.

The space to which sludge is transferred in the plug forming region 1B is formed by the inner surface of the screen casing 1, the second screw blade 4B, and the second screw shaft 4A. As shown in FIG. 1, the cross-sectional area of this transfer space is constant. In the plug forming region 1B, the plug cake is formed by the sludge (that is, the cake) dehydrated in the dehydrating region 1A. The method of forming the plug cake will be described later.

FIG. 2 is a schematic cross-sectional view of the second screw 4, the swivel bearing 21, and the rotary gear 23 shown in FIG. 1, and FIG. 3 is a view of the swivel bearing 21 shown in FIG. 2 as viewed from the axial direction thereof. .. The second screw shaft 4A has a hollow structure. The swivel bearing 21 includes an outer ring 21B, an inner ring 21C, and a plurality of balls 21D. The plurality of balls 21D are sandwiched between the inner ring 21C and the outer ring 21B and held inside the swivel bearing 21, and are arranged in a row along the circumferential direction of the inner ring 21C and the outer ring 21B. The plurality of balls 21D roll and contact the outer surface of the inner ring 21C and the inner surface of the outer ring 21B. The swivel bearing 21 has a plurality of teeth 21A. The rotary gear 23 fixed to the rotary shaft of the second drive 25 has a plurality of teeth 23A that mesh with the teeth 21A. The plurality of teeth 21A are fixed to the outer ring 21B and can rotate integrally with the outer ring 21B. The rotary gear 23 is arranged outside the outer ring 21B.

The inner ring 21C and the outer ring 21B are arranged so as to be offset in the axial direction of the second screw shaft 4A. Specifically, the outer ring 21B is arranged on the upstream side (hereinafter, may be simply referred to as the upstream side) of the inner ring 21C in the sludge transfer direction. The inner ring 21C of the swivel bearing 21 is fixed to the support base 28, while the outer ring 21B is in non-contact with the support base 28. Therefore, the inner ring 21C does not rotate, but the outer ring 21B can rotate relative to the inner ring 21C.

The flange 5 of the second screw 4 is connected to the outer ring 21B of the swivel bearing 21. Therefore, the second screw 4 can rotate integrally with the outer ring 21B of the swivel bearing 21. In the present embodiment, the flange 5 of the second screw 4 is fixed to the outer ring 21B of the swivel bearing 21. In one embodiment, the second screw 4 may be connected to the outer ring 21B via a shaft joint. When the second drive machine 25 operates, the rotary gear 23 fixed to the rotation shaft of the second drive machine 25 rotates. The outer ring 21B that meshes with the rotary gear 23 rotates around the axis of the second screw 4 while contacting the ball 21D. As a result, the second screw 4 connected to the outer ring 21B is rotated.

In this way, the drive mechanism 22 rotates the second screw 4 via the swivel bearing 21. The combination of the drive mechanism 22 and the swivel bearing 21 can rotate the second screw 4 without the sprocket or the chain wound around the sprocket. As a result, the size of the screw press can be reduced. Furthermore, the number of parts can be reduced, and cost reduction can be achieved.

As shown in FIG. 2, a reduced diameter portion 3C to be inserted into the cylindrical second screw shaft 4A is formed at the other end portion (downstream side end portion in the transfer direction D) of the first screw shaft 3A. ing. By forming the reduced diameter portion 3C on the first screw shaft 3A, a wall surface 3D perpendicular to the axial direction is formed on the first screw shaft 3A. The reduced diameter portion 3C is inserted into the cylindrical second screw shaft 4A and is rotatably supported by the slide bearings 30 and 31 fixed to the inner wall 4C of the second screw shaft 4A. With such a configuration, the first screw 3 is rotatably connected to the second screw 4. The upstream end of the second screw shaft 4A is rotatably supported by the first screw shaft 3A via the slide bearings 30 and 31.

As shown in FIG. 2, with the reduced diameter portion 3C of the first screw shaft 3A inserted inside the second screw shaft 4, the upstream end of the second screw shaft 4A is the first screw shaft 3A. It is in contact with the wall surface 3D. In one embodiment, a slight gap may be formed between the upstream end of the second screw shaft 4A and the wall surface 3D of the first screw shaft 3A. In this case, the sliding bearing 30 and / or the reduced diameter portion 3C is provided with a seal structure (for example, a labyrinth structure) that prevents sludge in the screen casing 1 from passing through the gap between the sliding bearing 30 and the reduced diameter portion 3C. It may be provided in.

As shown in FIG. 2, the pitch P1 of the second screw blade 4B is smaller than the pitch P2 of the first screw blade 3B (that is, P1 <P2). Further, the number of turns of the second screw blade 4B is less than three. The number of turns of the second screw blade 4B shown in FIG. 1 is two.

FIG. 4 is a diagram showing another embodiment of the second rotation mechanism 20, and FIG. 5 is a view of the swing bearing 21 shown in FIG. 4 as viewed from the axial direction thereof. Since the configuration of the present embodiment, which is not particularly described, is the same as that of the embodiment described with reference to FIGS. 1 to 3, the duplicate description thereof will be omitted.

The swivel bearing 21 has a plurality of teeth 21A fixed to the inner ring 21C. The rotary gear 23 is arranged inside the inner ring 21C, and the teeth 21A of the swivel bearing 21 mesh with the teeth 23A of the rotary gear 23. The inner ring 21C and the outer ring 21B are arranged so as to be offset in the axial direction of the second screw shaft 4A. Specifically, the inner ring 21C is arranged on the upstream side of the outer ring 21B in the sludge transfer direction. The outer ring 21B of the swivel bearing 21 is fixed to the support 28, while the inner ring 21C is non-contact with the support 28. Therefore, the outer ring 21B does not rotate, but the inner ring 21C can rotate relative to the outer ring 21B.

The flange 5 of the second screw 4 is connected to the inner ring 21C of the swivel bearing 21. Therefore, the second screw 4 can rotate integrally with the inner ring 21C of the swivel bearing 21. In the present embodiment, the flange 5 of the second screw 4 is fixed to the inner ring 21C of the swivel bearing 21. In one embodiment, the second screw 4 may be connected to the inner ring 21C via a shaft joint. When the second drive machine 25 operates, the rotary gear 23 fixed to the rotation shaft of the second drive machine 25 rotates. The inner ring 21C that meshes with the rotary gear 23 rotates around the axis of the second screw 4 while contacting the ball 21D. As a result, the second screw 4 connected to the inner ring 21C is rotated.

Also in this embodiment, the same effect as that of the embodiment shown in FIGS. 1 to 3 can be obtained. In particular, according to the present embodiment, since the rotary gear 23 is arranged inside the swivel bearing 21, the width of the second rotary mechanism 20 can be reduced.

FIG. 6 is a diagram showing another embodiment of the screw press. Since the configuration of the present embodiment, which is not particularly described, is the same as that of the embodiment described with reference to FIGS. 1 to 3, the duplicate description thereof will be omitted. In the present embodiment, the swivel bearing 41 is adopted in the first rotating mechanism 7 instead of the second rotating mechanism 20.

The first rotating mechanism 7 includes a swivel bearing 41 that rotatably supports the first screw 3 and a drive mechanism 42 that rotates the first screw 3 via the swivel bearing 41. The first screw 3 is connected to the swivel bearing 41. Specifically, the flange 9 of the first screw 3 is fixed to the swivel bearing 41. The swivel bearing 41 can receive both a thrust load and a radial load. In one example, the swivel bearing 41 has an angular contact ball bearing configuration.

The drive mechanism 42 includes a first drive (for example, an electric motor) 45 and a rotation gear 43 fixed to the rotation shaft of the first drive 45. The swivel bearing 41 and the first drive 45 are held by the support base 48. The swivel bearing 41 has a plurality of teeth 41A, and the rotary gear 43 has a plurality of teeth 43A. The teeth 41A of the swivel bearing 41 mesh with the teeth 43A of the rotary gear 43. When the first drive 45 is driven, the rotary gear 43 fixed to the rotary shaft of the first drive 45 rotates, and the swivel bearing 41 that meshes with the rotary gear 43 rotates. As a result, the first screw 3 connected to the swivel bearing 41 is rotated by the first rotation mechanism 7.

The downstream end of the second screw shaft 4A is rotatably supported by bearings 52 and 53 installed on a base (not shown) while restraining axial movement. The bearing 53 can be omitted. The downstream end of the second screw shaft 4A is connected to a second rotation mechanism 20 for rotating the second screw 4. In the present embodiment, the second rotation mechanism 20 includes a second drive machine (for example, an electric motor) 54, a sprocket 55 fixed to the rotation shaft of the second drive machine 54, and a sprocket fixed to the second screw shaft 4A. 56 and a chain 57 wound around these sprockets 55 and 56 are provided. The sprocket 56 is located between the bearings 52 and 53. When the second drive 54 of the second rotation mechanism 20 is driven, the sprocket 55 fixed to the rotation shaft of the second drive 54 rotates, and the sprocket 56 fixed to the second screw shaft 4A via the chain 57 is moved. Rotate. As a result, the second screw 4 is rotated by the second rotation mechanism 20.

FIG. 7 is a schematic cross-sectional view of the first screw 3, the swivel bearing 41, and the rotary gear 43 shown in FIG. 6, and FIG. 8 is a view of the swivel bearing 41 shown in FIG. 7 as viewed from the axial direction thereof. .. The first screw shaft 3A has a hollow structure. The swivel bearing 41 includes an outer ring 41B, an inner ring 41C, and a plurality of balls 41D. The plurality of balls 41D are sandwiched between the inner ring 41C and the outer ring 41B and held inside the swivel bearing 41, and are arranged in a row along the circumferential direction of the inner ring 41C and the outer ring 41B. The plurality of balls 41D roll into contact with the outer surface of the inner ring 41C and the inner surface of the outer ring 41B. The swivel bearing 41 has a plurality of teeth 41A. The rotary gear 43 fixed to the rotary shaft of the first drive 45 has a plurality of teeth 43A that mesh with the teeth 41A. The plurality of teeth 41A are fixed to the outer ring 41B and can rotate integrally with the outer ring 41B. The rotary gear 43 is arranged outside the outer ring 41B.

The inner ring 41C and the outer ring 41B are arranged so as to be offset in the axial direction of the first screw shaft 3A. Specifically, the outer ring 41B is arranged on the downstream side (hereinafter, may be simply referred to as the downstream side) in the sludge transfer direction with respect to the inner ring 41C. The inner ring 41C of the swivel bearing 41 is fixed to the support 48, while the outer ring 41B is non-contact with the support 48. Therefore, the inner ring 41C does not rotate, but the outer ring 41B can rotate relative to the inner ring 41C.

The flange 9 of the first screw 3 is connected to the outer ring 41B of the swivel bearing 41. Therefore, the first screw 3 can rotate integrally with the outer ring 41B of the swivel bearing 41. In the present embodiment, the flange 9 of the first screw 3 is fixed to the outer ring 41B of the swivel bearing 41. In one embodiment, the first screw 3 may be connected to the outer ring 41B via a shaft joint. When the first drive machine 45 operates, the rotation gear 43 fixed to the rotation shaft of the first drive machine 45 rotates. The outer ring 41B that meshes with the rotary gear 43 rotates around the axis of the first screw 3 while contacting the ball 41D. As a result, the first screw 3 connected to the outer ring 41B is rotated.

In this way, the drive mechanism 42 rotates the first screw 3 via the swivel bearing 41. The combination of the drive mechanism 42 and the swivel bearing 41 can rotate the first screw 3 without the sprocket or the chain wound around the sprocket. As a result, the size of the screw press can be reduced. Furthermore, the number of parts can be reduced, and cost reduction can be achieved.

FIG. 9 is a diagram showing still another embodiment of the screw press. Since the configuration of the present embodiment, which is not particularly described, is the same as that of the embodiment described with reference to FIGS. 1 to 3 and 6 to 8, the duplicate description thereof will be omitted. In this embodiment, swivel bearings 41 and 21 are adopted for the first rotating mechanism 7 and the second rotating mechanism 20, respectively. According to this embodiment, the entire installation space of the screw press can be minimized.

The embodiment of the swing bearing 21 described with reference to FIGS. 4 and 5 includes the embodiment of the swing bearing 41 described with reference to FIGS. 6 to 8 and the swing bearings 21 and 41 shown in FIG. It can also be applied to.

Next, the operation method of the screw press shown in FIG. 1 will be described with reference to FIGS. 10 to 12. 10 to 12 are diagrams for explaining the operation of the screw press shown in FIG. The following description is the operation method of the screw press according to the embodiment shown in FIG. 1, but the same can be applied to the operation method of the screw press according to the other embodiment described above.

As shown in FIG. 10, the control unit 6 drives the first rotation mechanism 7 to rotate the first screw 3 with the second screw 4 stopped. Next, sludge (liquid-containing material) is charged into the screen casing 1 from the charging port 2. The sludge charged from the charging port 2 is transferred toward the second screw 4 (that is, in the transfer direction D) by the rotating first screw blade 3B.

In the dehydration region 1A where the first screw 3 is arranged, the cross-sectional area of the space where the sludge is transferred gradually decreases along the transfer direction D. Therefore, the sludge is squeezed as it is transferred to the dehydration region 1A, and the water contained in the sludge is filtered by the screen casing 1. Since the sludge layer accumulated on the inner surface of the screen casing 1 is scraped off by the rotating first screw blade 3B, the inner surface (filtration surface) of the screen casing 1 in the dehydration region 1A is always maintained in a good state.

While the sludge is transferred through the dehydration region 1A of the screen casing 1, the sludge is dehydrated into a cake and sent to the plug forming region 1B where the second screw 4 is arranged. As shown in FIG. 10, since the second screw 4 is not rotating (that is, stopped) at the beginning of operation, the cake in the plug forming region 1B is not discharged to the discharge chamber 33, and the plug is formed. It stays in the region 1B. The cake is gradually accumulated on the second screw 4 and pressed against the second screw blade 4B by sludge (hereinafter referred to as “subsequent cake”) transferred from the dehydration region 1A to the plug forming region 1B. The cake in the plug forming region 1B is squeezed by being hindered from moving by the second screw blade 4B, and becomes a cake having a low water content. This low moisture content cake forms a plug cake that impedes subsequent cake movement. Back pressure is applied to the subsequent cake by the plug cake formed around the second screw shaft 4A, and the subsequent cake is further squeezed. The water separated from the plug cake in the plug forming region 1B is received by the filtrate receiver 38 and discharged from the screw press via the drain 39.

As the operation of the screw press is continued, the plug cake is uniformly formed over the entire circumference of the second screw shaft 4A. As a result, as shown in FIG. 10, a plug cake that reliably dams the subsequent cake is formed around the second screw shaft 4A. Therefore, even when the water content of the subsequent cake is high, the plug cake formed in the plug forming region 1B can reliably block the subsequent cake, so that one-sided flow of the subsequent cake can be prevented. This "one-sided flow" means that a subsequent cake having a higher water content than the plug cake passes through the plug forming region 1B as it is and is discharged to the discharge chamber 33.

As shown in FIG. 11, after the plug cake is formed, the control unit 6 rotates the second screw 4 in the direction opposite to the rotation direction of the first screw 3, and the second screw blade 4B makes the plug cake. It is gradually sent out to the discharge chamber 33 (that is, discharged). In this way, since the plug cake is formed and the plug cake is discharged continuously, the screw press can be operated with the plug cake always present in the plug forming region 1B.

The plug cake on the second screw 4 is discharged to the discharge chamber 33 by the second screw blade 4B of the second screw 4 rotated by the second rotation mechanism 20 while applying back pressure to the subsequent cake. The control unit 6 can adjust the amount of plug cake discharged into the discharge chamber 33 by changing the rotation speed of the second screw 4. More specifically, when the control unit 6 reduces the rotation speed of the second screw 4, the discharge amount of the plug cake decreases, and when the control unit 6 increases the rotation speed of the second screw 4, the plug cake Emissions increase. When the discharge amount of the plug cake decreases, the subsequent cake stays in the dehydration region 1A, and the back pressure applied to the subsequent cake increases. Therefore, the control unit 6 can reduce the rotational speed of the second screw 4 to reduce the water content of the subsequent cake. In one embodiment, the back pressure applied to the subsequent cake may be adjusted by performing an intermittent operation in which the rotation and the stop of the second screw 4 are alternately repeated.

As described above, in the present embodiment, the plug cake having a low water content can be removed from the screen casing 1 by rotating the second screw 4 in the direction opposite to the rotation direction of the first screw 3. Further, according to the present embodiment, it is not necessary to provide a resistor such as a back pressure plate at the discharge side end of the screen casing 1. Therefore, the plug cake can be smoothly discharged from the screen casing 1 to the discharge chamber 33. Further, since the back pressure plate and the operation mechanism of the back pressure plate are not required, the screw press can be manufactured at low cost.

The pitch P1 of the second screw blade 4B of the second screw 4 (see FIG. 2) is smaller than the pitch P2 of the first screw blade 3B of the first screw 3 (that is, P1 <P2). In this way, when the pitch P1 of the second screw blade 4B is made smaller than the pitch P2 of the first screw blade 3B, the transfer distance of the plug cake discharged to the discharge chamber 33 during one rotation of the second screw 4 is short. Therefore, the back pressure applied to the cake in the dehydration region 1A can be finely adjusted.

In a general uniaxial screw press, if the cylindrically squeezed plug cake becomes too hard, the hardened plug cake blocks the screen casing and cannot be discharged from the screen casing. Furthermore, this hardened plug cake goes around with the screw. As a result, the operation of the screw press cannot be continued. In the biaxial screw press of the present embodiment, the winding direction of the second screw blade 4B of the second screw 4 is opposite to the winding direction of the first screw blade 3B of the first screw 3. Therefore, when the plug cake formed in the plug forming region 1B is discharged to the discharge chamber 33, the second screw 4 is rotated in the direction opposite to the rotation direction of the first screw 3, as shown in FIG. When the cake is pressed against the plug cake by the first screw 3 that rotates in the direction opposite to that of the second screw 4, a force in the direction opposite to the rotation direction of the second screw 4 is applied to the plug cake. As a result, the rotation of the plug cake and the second screw 4 in the plug forming region 1B and / or the rotation of the cake and the first screw 3 in the dehydration region 1A are prevented, so that the back pressure is high against sludge. It becomes possible to operate the screw press while adding.

When the number of turns of the second screw blade 4B is 3 or more, the time for transferring the plug cake formed in the plug forming region 1B to the discharge chamber 33 becomes long. If the plug cake has a high viscosity, the plug cake may rotate with the second screw 4. In the present embodiment, since the number of turns of the second screw blade 4B is less than 3, the plug cake can be discharged from the screen casing 1 in a short time. Therefore, even when the sludge dehydrated by the screw press has a high viscosity, the plug cake can be discharged from the screen casing 1 before the plug cake rotates together with the second screw 4. When the number of turns of the second screw blade 4B is one, the plug cake may be pushed out to the discharge chamber 33 by the subsequent cake, and back pressure may not be effectively applied to the subsequent cake. Therefore, the number of turns of the second screw blade 4B is preferably 2 or more and less than 3 turns.

As shown in FIG. 12, the second screw 4 may be rotated in the same direction as the first screw 3. When the second screw 4 is rotated in the same direction as the first screw 3, the plug cake formed in the plug forming region 1B is pushed out toward the dehydration region 1A, and a larger back pressure can be applied to the cake in the dehydration region 1A. can. As a result, the dewatering efficiency of sludge can be improved.

If the second screw 4 is rotated in the same direction as the first screw 3 for a long time, the cake in the dehydration region 1A may rotate with the first screw 3. Therefore, after rotating the second screw 4 in the same direction as the first screw 3 for a certain period of time, the rotation direction of the second screw 4 is returned to the direction opposite to the rotation direction of the first screw 3 (FIG. 11). reference). Since the screw press of the present embodiment does not have a resistor such as a back pressure plate that prevents the plug cake from being discharged, the second screw 4 smoothly discharges the plug cake into the discharge chamber 33 like a screw conveyor. can do. By changing the rotation direction of the second screw 4 in this way, the control unit 6 can adjust the back pressure applied to the sludge squeezed by the first screw 3 in the dehydration region 1A. In order to reliably discharge the plug cake to the discharge chamber 33, the rear end of the second screw blade 4B of the second screw 4 may be configured to slightly protrude from the open end of the screen casing 1.

By changing the rotation speed and rotation direction of the second screw 4, the control unit 6 can dehydrate the sludge to a low water content that cannot be achieved by a conventional screw press. That is, with the second screw 4 stopped, the first screw 3 is rotated to form a plug cake around the second screw shaft 4A. Next, the sludge in the screen casing 1 is squeezed and dehydrated while the second screw 4 is rotated in the forward direction (the direction opposite to the rotation direction of the first screw 3) to discharge the plug cake into the discharge chamber 33. conduct. During the dewatering treatment of sludge, the second screw 4 is rotated in the opposite direction (the same direction as the rotation direction of the first screw 3) to dehydrate the cake in the dehydration region 1A to a lower water content, and then the first screw. 2 The screw 4 may be rotated in the forward direction to discharge the plug cake having a low water content into the discharge chamber 33. It is preferable that the operation of changing the rotation direction of the second screw 4 is performed periodically at intervals according to the properties of the sludge.

In one embodiment, the winding direction of the second screw blade 4B may be the same as the winding direction of the first screw blade 3B. In this case, when the sludge charged from the charging port 2 is sent out to the discharge chamber 33, the second screw 4 is rotated in the same direction as the first screw 3. The number of turns of the second screw blade 4B is less than 3 in order to eject the plug cake from the screen casing 1 in a short time. Further, the number of turns of the second screw blade 4B is preferably two or more in order to effectively apply back pressure to the subsequent cake.

The screw press of the above-described embodiment is used to separate liquid water from sludge, which is an example of liquid-containing material, but this screw press is used to separate liquid from liquid-containing material other than sludge. You may use it. For example, the screw press according to the above-described embodiment can also be used for processing foods such as fruits and oils, and processing industrial products such as recycled paper. In food processing, a screw press is used to squeeze raw materials (liquid-containing substances) such as fruits and seeds and separate liquids such as fruit juice and oil from the raw materials. In the recycling process of used paper, the used paper is mixed with water and liquids such as chemicals to loosen the used paper into fibrous substances. A screw press is used to squeeze a mixture of fibrous material and liquid (liquid content) to separate the fibrous material from the mixture.

The above-described embodiment is described for the purpose of enabling a person having ordinary knowledge in the technical field to which the present invention belongs to carry out the present invention. Various modifications of the above embodiment can be naturally made by those skilled in the art, and the technical idea of the present invention can be applied to other embodiments. Therefore, the present invention is not limited to the described embodiments, but is construed in the broadest range according to the technical idea defined by the claims.

1 Screen casing (filter tube)
1A Dehydration area 1B Plug formation area 2 Input port 3 1st screw 3A 1st screw shaft 3B 1st screw blade 3C Reduced diameter part 3D wall surface 4 2nd screw 4A 2nd screw shaft 4B 2nd screw blade 6 Control unit 7 1st Rotating mechanism 8 Blocking wall 10 Water sealing device 11, 12 Bearing 14 1st drive machine 15, 16 Sprocket 17 Chain 20 2nd rotating mechanism 21 Swivel bearing 21A teeth 21B Outer ring 21C Inner ring 21D ball 22 Drive mechanism 23 Rotating gear 23A Tooth 25th 2 Drive 28 Support 33 Drain chamber 38 Strain receiver 39 Drain 41 Swivel bearing 41A Tooth 41B Outer ring 41C Inner ring 41D Ball 42 Drive mechanism 43 Rotating gear 43A Tooth 45 1st drive 48 Support

Claims (8)

The filter tube into which the liquid content is charged and
In the filter tube, the first screw and the second screw, which are arranged concentrically with the filter tube and transfer the liquid-containing material in a predetermined transfer direction,
The first rotation mechanism for rotating the first screw and
A second rotation mechanism for rotating the second screw independently of the first screw is provided.
The second screw is arranged on the downstream side of the first screw in the transfer direction.
The second rotation mechanism is
A swivel bearing that rotatably supports the second screw,
A screw press including a drive mechanism for rotating the second screw via the swivel bearing. The drive mechanism includes a rotary gear and
The screw press according to claim 1, wherein the swivel bearing includes a plurality of teeth that mesh with the rotary gear. The plurality of teeth are fixed to the outer ring of the swivel bearing, and the plurality of teeth are fixed to the outer ring of the swivel bearing.
The screw press according to claim 2, wherein the second screw is connected to an outer ring of the swivel bearing. The plurality of teeth are fixed to the inner ring of the swivel bearing, and the plurality of teeth are fixed to the inner ring of the swivel bearing.
The screw press according to claim 2, wherein the second screw is connected to an inner ring of the swivel bearing. The filter tube into which the liquid content is charged and
In the filter tube, the first screw and the second screw, which are arranged concentrically with the filter tube and transfer the liquid-containing material in a predetermined transfer direction,
The first rotation mechanism for rotating the first screw and
A second rotation mechanism that rotates the second screw independently of the first screw is provided.
The second screw is arranged on the downstream side of the first screw in the transfer direction.
The first rotation mechanism is
A swivel bearing that rotatably supports the first screw and
A screw press including a drive mechanism for rotating the first screw via the swivel bearing. The drive mechanism includes a rotary gear and
The screw press according to claim 5, wherein the swivel bearing includes a plurality of teeth that mesh with the rotary gear. The plurality of teeth are fixed to the outer ring of the swivel bearing, and the plurality of teeth are fixed to the outer ring of the swivel bearing.
The screw press according to claim 6, wherein the first screw is connected to an outer ring of the swivel bearing. The plurality of teeth are fixed to the inner ring of the swivel bearing, and the plurality of teeth are fixed to the inner ring of the swivel bearing.
The screw press according to claim 6, wherein the first screw is connected to an inner ring of the swivel bearing.

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