KR20190026242A - Pressure filter - Google Patents

Abstract

The present invention relates to a compression filter device. Contaminants, which are a mixture of a liquid and a solid, are introduced through a contaminant inlet pipe and injected into a cylindrical filter. A piston is moved up and down by a connection link connected to the piston according to rotation of a driving rotary shaft and sludge deposited on an inner surface of the cylindrical filter is swept downward by a downward movement of the piston to deposit the sludge to maintain filter holes, and the deposited sludge is compressed and discharged to the outside. The yield of a filtrate is increased and the volume of the sludge, which is a filtration waste, is reduced. The device can be applied to high viscosity sludge and, treat contaminants mixed with low density suspensions and sludge, and can increase the separation efficiency of the filtrate.

Description

[0001] PRESSURE FILTER [0002]

More particularly, the present invention relates to a compression filter device, and more particularly, to a method for introducing a contaminant, which is a liquid and a solid mixture, into a contaminant inlet tube and injecting the same into a cylindrical filter, The sludge immersed in the inner circumferential surface of the cylindrical filter is swept downward by the downward motion of the piston to deposit a filter hole of the cylindrical filter and sinter the precipitated sludge The present invention relates to a compression-filtration device capable of discharging it to the outside.

In general, a squeeze filter (also called a filter press) which is a squeeze filtration and dehydrator effectively pressurizes and dehydrates slurry or sludge from wastewater generated in industry or households and forms and separates into a cake having a low water content .

In particular, recently, it is impossible to dump or fill the slurry generated in the wastewater treatment process to the ocean, and thus interest in the development of a solid-liquid separation and dewatering device such as a compression filter is increasing.

The squeeze filter is passed through the wastewater treatment system, and the slurry discharged therefrom is introduced between the pressurized and adhered filter plates, whereby the filtration is performed by the filter plate provided on the filter plate. Therefore, the filtrate after filtration is discharged to the outside, and the sludge deposited in the filtration cloth is subjected to a pressure and dehydration process to form a cake, and then treated separately.

On the other hand, in the conventional compression filter using a conventional filter, the filtration particles are deposited on the filter filtration surface to block the filter hole, thereby increasing the pressure difference between the downstream and downstream sides of the filter.

In order to solve such a problem, a method of spraying a high-pressure fluid in the opposite direction by using a back-washing method after dust filtration using a filter for a certain period of time is used to remove dust particles deposited on the filtration surface of the filter .

The backwashing method by spraying the fluid can exhibit the effect in the case of the solid dust having a low viscosity, but in the case of the sludge having a high viscosity, the desorption efficiency is drastically lowered. Therefore, the backwashing cycle is accelerated due to the decrease of the backwashing efficiency, and frequent backwashing lowers the filtration speed and causes a problem that the power consumption for the fluid supply is greatly increased.

The centrifugal sludge treatment method can be used for highly viscous sludge. However, when the sludge having low dewatering efficiency and low density is contained, the separation efficiency of the floating sludge is low, which is not suitable.

Korean Patent Publication No. 10-2014-0024596

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to solve the above-mentioned problems by supplying contaminants as a mixture of liquid and solid into a contaminant intake pipe, injecting the contaminants into a cylindrical filter, The sludge deposited on the inner circumferential surface of the cylindrical filter is swept downward by the downward motion of the piston to deposit the sludge down to hold the filter hole and to squeeze out the precipitated sludge to discharge the sludge to the outside, The present invention provides a squeeze filter device capable of reducing the volume of filtration waste, applying to a high viscosity sludge, treating pollutants mixed with suspended solids of low density and sludge, and increasing the separation efficiency of the filtrate. There is a purpose.

According to an aspect of the present invention, there is provided a squeeze filter device comprising: a filtrate tank containing a filtrate and having a sludge discharge hole formed at a center of a bottom thereof; A cylindrical filter installed in the filtrate tank and having a plurality of filter holes formed on an outer peripheral surface thereof and a lower end coupled to the sludge discharge hole; A contaminant inlet pipe into which a lower end is inserted into an opening formed at an upper end of the cylindrical filter so as to inject contaminants to be filtered into the cylindrical filter; A sludge discharge cover installed at a lower portion of the filtrate tank to discharge sludge accumulated in a lower end portion of the cylindrical filter; A level tank for storing the filtrate in the filtrate tank; A filtrate discharge pipe formed at a lower portion of the level tank for transferring the filtrate in the filtrate tank to the level tank; An arm extending from the sludge discharge cover to control opening and closing of the sludge discharge cover; A buoyant body installed at an end of the arm and floating on top of the filtrate stored in the level tank to provide a force to the sludge discharge cover in a direction to close the sludge discharge hole; A piston installed in the cylindrical filter to allow the pollutant intake pipe to rise and down in the cylindrical filter, and to sweep the sludge deposited on the inner peripheral surface of the cylindrical filter downward; And a sludge removing unit for lowering the piston so that sludge deposited on the inner circumferential surface of the cylindrical filter can be swept downward and opening the sludge discharge cover for discharging the sludge loaded on the lower end of the cylindrical filter, Means.

Wherein the sludge removing means comprises: a support installed on an upper portion of the filtrate tank; A rotary drive shaft rotatably supported by the support; And a plurality of connection links connecting the rotary drive shaft and the piston to convert the rotational force of the rotary drive shaft into a vertical reciprocating motion of the piston.

A sludge discharge guide for preventing the sludge from entering the level tank may be installed at a lower portion of the sludge discharge cover.

A piston rod having a contaminant passage formed therein; A link connecting portion formed on an upper portion of the piston rod; A piston head formed at a lower portion of the piston rod and closely attached to an inner peripheral surface of the cylindrical filter; And a seal member that is vertically movable in the pollutant passage below the piston rod to selectively open and close the pollutant passage.

A seal member guide groove is formed in a lower side of the piston rod, and the seal member can be moved up and down along the seal member guide groove. When the seal member is filtered, the seal member opens the pollutant passage, The seal member is configured to close the contaminant passage.

The connection link includes a drive connection link connected to the rotation drive shaft; And a driven connection link connecting the drive connection link and the piston.

When the lowering pressure of the piston generated by the sludge removing means is relatively larger than the buoyancy generated by the buoyant body, the sludge discharge cover is opened and the sludge loaded on the lower end of the cylindrical filter is discharged .

As described above, as the piston moves downward, the sludge deposited (adhered) to the inner circumferential surface of the cylindrical filter is swept off and removed to hold the filter hole, and the deposited sludge can be compressed and discharged to the outside, It is possible to apply the present invention to a high viscosity sludge which can not be removed by the reverse washing of the sludge, and it is also possible to treat contaminants mixed with low density suspensions and sludge.

In addition, since the sludge can be physically squeezed and automatically discharged to the outside using the pressure difference, the efficiency of separation of the filtrate can be increased and the volume of the sludge as a filtration waste can be reduced.

Also, it can be used as a single product, and when using two or more units, continuous sludge removal and squeeze discharge are possible.

1 is a perspective view showing a compression filter device of the present invention.
2 is a bottom perspective view showing a compression filter device of the present invention.
3 is a perspective view showing a piston installed in a cylindrical filter and a perspective view showing a sludge removing means.
4 is a view for explaining the upward and downward movement of the piston by the sludge removing means;
FIG. 5 is a perspective view showing the inside of the compression filter device of FIG. 1, showing the closure of the sludge discharge cover
Fig. 6 is an enlarged view of the main part of Fig. 5
Fig. 7 is a perspective view showing the contaminant passage opening of the seal member; Fig.
FIG. 8 is a perspective view showing the inside of the compression filter device shown in FIG. 1 and showing the opening of the sludge discharge cover
9 is an enlarged view of the main part of Fig. 8
10 is a perspective view showing the seal member closing the pollutant passage

Hereinafter, a compression filter device according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a bottom perspective view showing a compression filter device of the present invention, Fig. 3 is a perspective view showing a piston installed in a cylindrical filter, and sludge removing means, Fig. 4 Fig. 5 is a perspective view showing the interior of the squeeze filter device shown in Fig. 1 by cutting the sludge discharge cover, and Fig. 6 is a cross- FIG. 8 is a perspective view showing the inside of the squeeze filter device of FIG. 1 by cutting the sludge discharge cover, and FIG. 9 is a view showing the opening of the sludge discharge cover. Fig. 10 is a perspective view showing the seal member closing the pollutant passage. Fig.

1 to 10, the compression bonding apparatus 100 of the present invention includes a filtrate tank T1 for containing a filtrate, a cylindrical filter (not shown) having a plurality of filter holes 111 formed on the outer periphery thereof, A contaminant intake pipe 120 capable of injecting contaminants (a mixture of liquid and solid) into the cylindrical filter 110, a sludge discharge cover 130 installed at the bottom of the filtrate tank T1 to be openable and closable, A level tank T2 for storing the filtrate, an arm 140 for controlling opening and closing of the sludge discharge cover 130, a buoyant body 150 for providing buoyancy to the sludge discharge cover 130, and a sludge removing unit 160 for sweeping the sludge deposited on the inner circumferential surface of the cylindrical filter 110 downward and discharging the sludge accumulated on the lower end of the cylindrical filter 110, (170).

The configuration of the compression filter device 100 of the present invention will be described in more detail.

First, the filtrate tank T 1 can receive filtrate filtered by the cylindrical filter 110, and can be installed at a predetermined height from the bottom surface by a support structure (not shown) or a bracket.

The upper portion of the filtrate tank T1 can be opened, and the upper portion of the filtrate can be blocked by a cover or a lid (not shown). A sludge discharge hole H for discharging sludge generated during filtration is formed at the lower center of the filtrate tank T1.

The cylindrical filter 110 is installed in the filtrate tank T1 in the longitudinal direction and a plurality of filter holes 111 for filtration are formed on the outer circumferential surface.

The lower end of the cylindrical filter 110 can be fitted into the sludge discharge hole H to be engaged. The lower end of the cylindrical filter 110 may be fixed by welding or the like, and the filtrate tank T1 and the cylindrical filter 110 may be configured such that the center lines coincide with each other.

The contaminant inlet pipe 120 is inserted into an opening formed at the upper end of the cylindrical filter 110 so that contaminants to be filtered can be injected into the cylindrical filter 110. The contaminant inlet pipe 120 is fixed in position by a holder (not shown).

The sludge discharge cover 130 is installed at a lower portion of the filtrate tank T 1 to discharge the sludge accumulated at the lower end of the cylindrical filter 110. That is, the sludge discharge cover 130 includes a hinge 131, And is configured to be able to open and close the sludge discharge hole H. A seal ring or a seal sheet (not shown) for sealing the sludge discharge hole H is installed on the upper periphery of the sludge discharge cover 130 .

A sludge discharge guide 132 may be installed in the lower portion of the filtrate tank T1 to prevent sludge from entering into the level tank T2 when the sludge discharge cover 130 is opened, . The sludge discharge guide 132 is formed in a curved shape, that is, a round shape, to facilitate sludge discharge.

The level tank T2 is a storage tank for storing filtrate in the filtrate tank T1, and a discharge pipe P2 may be formed on the upper side.

The filtrate discharge pipe P1 may be formed at the lower portion of the level tank T2 to transfer the filtrate in the filtrate tank T1 to the level tank T2. The filtrate in the filtrate tank T1 is conveyed to the level tank T2 through the filtrate discharge pipe P1 by its own load.

The arm 140 is extended from the sludge discharge cover 130 to control the opening and closing of the sludge discharge cover 130.

The arm 140 may be formed in a "B" shape or a "B" shape so as not to interfere with the sludge discharge guide 132.

The buoyant body 150 is installed at the end of the arm 140 and is floated on top of the filtrate stored in the level tank T2 so as to apply force to the arm 140 in a direction to close the sludge discharge hole H. [ . The arm 140 causes the sludge discharge cover 130 to close the sludge discharge hole H.

That is, the floating body 150 is floating in the level tank T2 at a high water level of the filtrate, so that the arm 140 connected to the buoyant body 150 is discharged to the sludge discharge cover 130), that is, temporarily closes the sludge discharge hole (H).

The sludge discharge cover 130 is configured to be opened by the lowering pressure of the piston 160, that is, the buoyancy difference between the sludge compression resistance and the buoyancy member 150.

That is, when the sludge compression resistance is relatively larger than the buoyancy generated by the buoyant body 150 when the piston 160 descends due to the operation of the sludge removal means 170, the sludge discharge cover 130 is opened, And to discharge the sludge loaded on the lower end of the filter 110 to the outside. With the sludge discharge cover 130 open, the buoyant body 150 is implanted deep into the level tank T2 (see also).

The piston 160 is installed up and down in the cylindrical filter 110 with the pollutant intake pipe 120 therein and sweeps down the sludge deposited on the inner peripheral surface of the cylindrical filter 110 You can kick it out.

The piston 160 includes a piston rod 161 in which a contaminant passage 160a is formed, a link connecting portion 162 formed in an upper portion of the piston rod 161, A piston head 163 which is in close contact with the inner circumferential surface of the filter 110 for sweeping the sludge and a piston head 163 which is vertically movable on the contaminant passage 160a below the piston rod to selectively open and close the lower portion of the contaminant passage 160a And a seal member (164).

The seal member 164 may be made of a soft material such as silicone or rubber and the seal member 164 may move up and down by a pressure difference to selectively close the lower portion of the pollutant passage 160a do.

A seal member guide groove 161a is formed in the lower side of the piston rod 161 and the seal member 164 can be moved up and down along the seal member guide groove 161a. When the piston 160 rises, the seal member 164 descends to open the lower portion of the contaminant passage 160a. On the contrary, when the piston 160 descends, the seal member 164 rises to close the lower portion of the contaminant passage 160a .

That is, before the operation of the sludge removing means 170, the piston rod 161 is lifted upward and the seal member 164 is lowered by the pressure of the polluted liquid flowing in the pollutant intake pipe 120, 160a. At this time, the contaminant introduced through the contaminant inlet pipe 120 is introduced (injected) into the cylindrical filter 110.

The piston rod 161 moves downward by the operation of the sludge removing means 170 and the piston head 163 sweeps out the sludge deposited on the inner peripheral surface of the cylindrical filter 110, As the compression resistance of the loaded sludge gradually increases, the seal member 164 rises along the seal member guide groove 161a.

When the seal member 164 rises along the seal member guide groove 161a, the seal member 164 closes the lower portion of the pollutant passage 160a. The contamination does not flow back to the pollutant intake pipe 120 due to the closure of the pollutant passage 160a and the sludge does not flow into the piston 160. [

The sludge removing means 170 can descend the piston 160 to sweep down the sludge deposited on the inner circumferential surface of the cylindrical filter 110 and to remove the sludge accumulated on the lower end of the cylindrical filter 110 The sludge discharge cover 130 is opened for discharging.

The sludge removing means 170 includes a support 171 installed on the upper portion of the filtrate tank T1, a rotary drive shaft 172 rotatably supported by the support 171, And a plurality of connection links 173 and 174 connecting the rotary drive shaft 172 and the piston 160 to switch the upper and lower linear reciprocating motion of the piston 160.

The connection links 173 and 174 include a drive connection link 173 connected to the rotary drive shaft 172 and a driven connection link 174 connecting the drive connection link 173 and the piston 160. Here, although only two connection links 173 and 174 are illustrated, they may be manufactured in accordance with design conditions. Furthermore, although not shown in the drawings, the piston may be configured to be elastically lifted up and down by an eccentric cam that is not a connecting link structure.

When the rotary drive shaft 172 connected to the motor (not shown) rotates in the structure of the sludge removing means 170, the drive connection link 173 and the driven connection link 174 connected to the rotary drive shaft 172 are driven, (160) reciprocates up and down. At this time, the piston head 163 of the piston 160 sweeps the sludge deposited on the inner peripheral surface of the cylindrical filter 110. The swept sludge is loaded on the bottom of the cylindrical filter 110, that is, on the sludge discharge cover 130. A large amount of sludge is loaded on the sludge discharge cover 130 by the sludge removing means 170.

The sludge deposited on the inner circumferential surface of the cylindrical filter 110 is removed at an appropriate point of time by the sludge removing means 170 and at the point when the loaded sludge compression resistance becomes larger than the buoyancy of the buoyant body 150, So that the loaded sludge can be automatically discharged. Here, the sludge compression resistor sweeps down the sludge deposited on the inner circumferential surface of the cylindrical filter 110 by the sludge removing means 170, and when the piston 160 moves downward in a state where the sludge is heavily loaded, The contaminants are not filtered through the filter 111 and the pressure inside the cylindrical filter 110 is increased.

The function and effect of the compressed filter device of the present invention having such a structure will be described.

The level tank T2 is filled with the filtrate so that the arm 140 connected to the buoyant body 150 by the floating of the buoyant body 150 temporarily closes the sludge discharge cover 130 do.

Initially, the piston 160 is at the top. Contaminants are introduced into the cylindrical filter 110 through the contaminant inlet pipe 120. The contaminants introduced through the contaminant inlet pipe 120 are introduced into the cylindrical filter 110 through the contaminant passage 160a of the piston 160.

At this time, the seal member 164 maintains a state in which the lower portion of the pollutant passage 160a is opened in the lowered state. The filtrate filtered through the filter holes 111 of the cylindrical filter 110 is temporarily stored in the filtrate tank T 1 temporarily and the solid sludge as the filtration waste is filtered in the cylindrical filter 110.

The filtrate temporarily stored in the filtrate tank T1 is again conveyed to the level tank T2 through the filtrate discharge pipe P1 by its own weight. In the level tank (T2), the filtrate always maintains full water, and the filtrate flowing in more than that is discharged (supplied) to the outside through the discharge pipe (P2).

The piston 160 moves upward and downward linearly by the operation of the sludge removing means 170. At this time, the piston head 163 of the piston 160 moves the sludge deposited on the inner peripheral surface of the cylindrical filter 110 downward Sweep down. The swept sludge is loaded on the bottom of the cylindrical filter 110, that is, on the sludge discharge cover 130.

The precipitated sludge is squeezed by the compression action of the piston 160. The sludge compression resistance is gradually increased due to repeated sludge removal and compression.

The operation period of the sludge removal means 170 can be appropriately set in accordance with the design conditions in consideration of the polluted liquid and the filter performance.

If the sludge compression resistance is smaller than the buoyancy force of the buoyant body 150, the sludge discharge cover 130 remains closed.

However, when the sludge compression resistance becomes relatively larger than the buoyancy generated by the buoyant body 150, the sludge discharge cover 130 is opened to discharge the entire sludge loaded on the lower end of the cylindrical filter 110 to the outside.

In other words, when the sludge compressing force (the piston downward pressure) becomes relatively larger than the buoyancy force of the buoyant body 150, the sludge compressing force presses the sludge discharge cover 130 downward, So that the buoyant body 150 floated on top of the filtrate stored in the level tank T2 is deeply embedded in the filtrate. At this time, the sludge discharge cover 130 is opened to discharge the entire sludge loaded on the lower end of the cylindrical filter 110 to the outside.

As described above, since the piston moves downward, the sludge deposited on the inner circumferential surface of the cylindrical filter is swept away to remove the filter hole, and the deposited sludge can be compressed and discharged to the outside, It is possible to treat high-viscosity sludge that can not be removed by the conventional method. Also, it is possible to treat contaminants mixed with suspended matter of low density and sludge, so that it can be used for general purpose.

In addition, since the loaded sludge is physically compressed and can be automatically discharged to the outside using the pressure difference, the efficiency of separation of the filtrate can be increased and the volume of the sludge waste can be reduced.

Also, it can be used as a single product, and it is advantageous that continuous sludge removal and squeeze discharge can be performed when two or more sludge are used.

100: Compression filter device
110: cylindrical filter
111: Filter Ball
120: Contaminant inlet pipe
130: Sludge discharge cover
131: Hinge
132: Sludge discharge guide
140: arm
150: Buoyant body
160: Piston
160a: Contaminant passage
161: Piston rod
161a: seal member guide groove
162: Link connection part
163: Piston head
164: Seal member
170: sludge discharge means
171: Support
172:
173,174: Link to link
H: Sludge discharge hole
P1: filtrate discharge pipe
P2: discharge pipe
T1: filtrate tank
T2: Level tank

Claims (8)

A filtrate tank for containing the filtrate and having a sludge discharge hole formed at the center of the lower surface thereof;
A cylindrical filter installed in the filtrate tank and having a plurality of filter holes formed on an outer peripheral surface thereof and a lower end coupled to the sludge discharge hole;
A contaminant inlet pipe into which a lower end is inserted into an opening formed at an upper end of the cylindrical filter so as to inject contaminants to be filtered into the cylindrical filter;
A sludge discharge cover installed at a lower portion of the filtrate tank to discharge sludge accumulated in a lower end portion of the cylindrical filter;
A level tank for storing the filtrate in the filtrate tank;
A filtrate discharge pipe formed at a lower portion of the level tank for transferring the filtrate in the filtrate tank to the level tank;
An arm extending from the sludge discharge cover to control opening and closing of the sludge discharge cover;
A buoyant body installed at an end of the arm and floating on top of the filtrate stored in the level tank to provide a force to the sludge discharge cover in a direction to close the sludge discharge hole;
A piston installed in the cylindrical filter so as to be able to move up and down within the pollutant intake pipe and sweep down the sludge deposited on the inner peripheral surface of the cylindrical filter; And
A sludge removing means for lowering the piston so that the sludge deposited on the inner circumferential surface of the cylindrical filter can be swept downward and opening the sludge discharge cover for discharging the sludge loaded on the lower end of the cylindrical filter, ; . ≪ / RTI > The method according to claim 1,
The sludge removing means comprises:
A support installed at an upper portion of the filtrate tank;
A rotary drive shaft rotatably supported by the support; And
A plurality of connection links connecting the rotary drive shaft and the piston to convert the rotational force of the rotary drive shaft into a vertical reciprocating motion of the piston; . ≪ / RTI > The method according to claim 1,
And a sludge discharge guide for preventing sludge from entering the level tank is installed at a lower portion of the sludge discharge cover. The method according to claim 1,
The piston
A piston rod having a contaminant passage formed therein;
A link connecting portion formed on an upper portion of the piston rod;
A piston head formed at a lower portion of the piston rod and closely attached to an inner peripheral surface of the cylindrical filter; And
A seal member installed vertically movably in the pollutant passage below the piston rod to selectively open and close the pollutant passage; . ≪ / RTI > The method of claim 4,
A seal member guide groove is formed in a lower side of the piston rod, and the seal member is movable up and down along the seal member guide groove,
Wherein the sealing member opens the contaminant passage during filtration and the sealing member closes the contaminant passage when the sludge is discharged. The method according to claim 1,
The connection link
A drive connection link connected to the rotary drive shaft; And
A driven connection link connecting the drive connection link and the piston; . ≪ / RTI > The method according to claim 1,
And the sludge discharge cover is opened to discharge the sludge loaded on the lower end of the cylindrical filter when the lowering pressure of the piston generated by the sludge removing means is relatively larger than the buoyancy generated by the buoyant body . A filtrate tank;
A cylindrical filter coupled to the sludge discharge hole of the filtrate tank;
A contaminant inlet pipe for injecting contaminants into the cylindrical filter;
A sludge discharge cover installed at a lower portion of the filtrate tank to discharge sludge accumulated in a lower end portion of the cylindrical filter;
A level tank for storing the filtrate in the filtrate tank;
A filtrate discharge pipe formed at a lower portion of the level tank for transferring the filtrate in the filtrate tank to the level tank;
A buoyant body suspended above the filtrate stored in the level tank to provide a force to the sludge discharge cover in a direction to close the sludge discharge hole;
A piston installed in the cylindrical filter so as to be able to move up and down within the pollutant intake pipe and sweep down the sludge deposited on the inner peripheral surface of the cylindrical filter; And
A sludge removing means for lowering the piston so that the sludge deposited on the inner circumferential surface of the cylindrical filter can be swept downward and opening the sludge discharge cover for discharging the sludge loaded on the lower end of the cylindrical filter, ; ≪ / RTI >
Wherein the sludge is automatically discharged by the pressure difference at a time when the downward pressure of the piston becomes larger than the buoyancy of the buoyant body.

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