FI57885B - FOERBAETTRINGAR I ROERTRYCKFILTER ELLER I ANSLUTNING TILL DYLIKA - Google Patents

Description

155 ^ 1 [B] (11) ANNOUNCEMENT ςπ oor flSjft L J 1; UTLÄGGNINGSSKAIFT O 'O O 0 C. Paterit ti granted 10 11 1980 'Patent ecddelat ^ (51) K * .ik.Wa.3 B 01 D 29/02 ENGLISH —Ff N LAN D (21) Pwnttlh «fctnu« - P »tt <ttmn« a> uMnf 1505/71 (22) Hakemltptiyi — An * eknlnpd «f 01.06.71 ^ ^ (23) AlkupUvi — Glltl | K« t * d «f 01.06.71 (41) Come] outside * ktl - BIMt offtncllg 71 ** *** U i * register h * IHtU * NlhOriluip ^ is,. moonLull year date.-

Patents and registries' 7 AraBkan tithed och utukrifun pubiicond 31.07.80 (32) (33) (31) Pyydetty «uolkMS — Begird prlorltec 03.06.70

England-England (GB) 26902/70 (71) English Clays Lovering Pochin & Company Limited, John Keay House,

St. Austell, Cornwall, England-England (GB) (72) Ralph Derek Gwilliam, St. Austell, Cornwall, England-England (GB) (7 * 0 Oy Kolster Ab (5 * 0 Improvements in tube pressure filters or related improvements - Förbättringar This invention relates to a tubular pressure filter having a pair of substantially coaxial cylindrical tubular bodies nested and adapted to be supported in a substantially vertical position, and a resilient impermeable sleeve disposed therein and disposed in the outer tube. supported by an inner tubular body, removal means for removing a filter which has passed through the filter element and through the openings in the inner tubular body from the interior of the inner tubular body, and means for moving the tubular bodies axially relative to each other between the first and second positions. n such that in the first position of said tubular bodies they work together to define a closed annular chamber divided into substantially coaxial inner and outer compartments not connected to each other by said impermeable flexible sleeve, the inner compartment having an inlet for a moist finely divided solid the outer compartment has an inlet for hydraulic pressurized fluid and in the second position of said tubular bodies said annular chamber is open to allow fine solids to discharge from the inner compartment.

For example, British Patent Specification No. 907,485 and Canadian Patent Specification No. 2,574,465 disclose the earliest tube pressure filters suitable for reducing the liquid content of aqueous clay or other mixtures / containing liquids and finely divided solids. These tubular pressure filters consist of a substantially vertical, annular chamber formed between two coaxially arranged tubular bodies, the waterproof, flexible sleeve attached to the second tubular body dividing the annular chamber into inner and outer compartments which are not in communication with each other. The tubular bodies are axially displaceable between the first and second positions, the arrangement being such that from said positions of the tubular bodies in the first position a pressurized material can be fed into a compartment formed between the second side of the waterproof, flexible sleeve and the second tubular body. when the body supports the filter element. The hydraulic fluid can be fed into the compartment formed between the second side of the flexible sleeve and the second tubular body to press the substance to be filtered under pressure against the filter element. The removal of the hydraulic fluid and the transfer of the tubular bodies to their second position then make it possible to discharge the solid from which the fluid has been compressed. The filter elements used in such tubular pressure filters may include a filter cloth in the form of a filter media sleeve, the filter cloth preferably being supported by a wadding mesh sleeve, which in turn is supported by another tubular body.

The tubular pressure filter generally has a structure such that the inner tubular body supports the filter element and the waterproof flexible sleeve is attached at its ends to the outer tubular body. With this arrangement, the pressure-filterable material is fed from the inner part 5. The hydraulic pressure fluid is fed to the outer compartment to stretch the flexible sleeve and thus compress the material in the inner compartment and form a cake from the solid by the filter element, the filter being extruded through the filter element and passing out. through the openings formed in the piece. One method of discharging a filter press cake formed by a filter element involves directing one or more blows of gas, usually air, to a side below the flow of the filter element. When pressure-filtration of aqueous clay or other mixtures of liquids or solids in which the solid is non-fibrous, e.g., clays, calcium carbonates, etc., the filter-press cake easily cracks under the action of gas blows, and thus the discharge of the filter-press cake is easily achieved. When pressure filtering mixtures of liquids and solids in which the solid contains fibrous 3,578,85 substances, e.g. sewage sludge or paper pulp, the solid tends to form a filter press cake which does not easily crack and therefore cannot fall off the filter cloth because different parts of the inner tubular body prevent the.

It is an object of the present invention to provide a tubular pressure filter suitable for use in the treatment of mixtures of liquids and solids in which the solid contains a fibrous substance and in which the filter has a filter element which facilitates the removal of a fibrous solid filter cake from the filter.

The pipe pressure filter according to the invention is characterized in that the filter element has alternately permeable and impermeable compartments, each of which extends over the entire length of the effective filtration area of the filter element or substantially over its entire length.

When using the filter element according to the present invention, the filter cannot pass through the impermeable parts of the filter element, so that these parts form either a poorly adhered filter cake or no cake at all, and when air or other gas blows are applied to the filter

In one embodiment of the invention, the filter element includes a filter fabric in the form of a filter media sleeve divided into longitudinally alternating, permeable and impermeable compartments. The impermeable compartments can be formed, for example, by applying a sealant or an impermeable, adhesive tape to parts of the sleeve or filter medium. A suitable adhesive tape may be formed of either natural rubber or artificial rubber or a plastic material in the form of a sheet or film or in a textile material impregnated with a binder which also closes the pores of the textile material. The impermeable compartments may alternatively be formed of metal strips or rigid or semi-rigid strips of plastic material which are attached to the filter cloth by hooks, rivets or other such attachment means. It is advantageous to support the filter media sleeve with a cotton mesh sleeve,

Il 57885, which preferably has a structure as described in Finnish patent application No. 1700/70. Alternatively, a coarsely woven backing fabric can be placed between the filter media sleeve and the anun mesh sleeve.

In another embodiment of the invention, the tubular filter element is provided with impermeable compartments by attaching metal strips or rigid or semi-rigid plastic strips to a wadding netting sleeve or a coarsely woven backing fabric with cages, rivets or similar fastening means and coating the wadding netting fabric. Alternatively or in addition, metal strips or plastic strips may be secured in place by annular strips disposed at least one at each end of the tubular filter element and preferably also at suitable intervals along the tubular filter element.

The filter element according to the present invention should generally be divided into at least three permeable compartments separated by three impermeable compartments. The width of the impermeable compartments should preferably be at least twice the thickness of the filter press cake, which cake is designed to form with the permeable compartments. The width of the impermeable compartments is usually at least 10 mm.

The inner wall of the inner tubular body preferably forms a substantially closed chamber and the tube pressure filter is provided with means for providing a plurality of short, discrete air blows inside said substantially closed chamber, with air blows passing through openings in the inner tubular body to the flow of the filter element below the substance can be discharged from the surface of the filter element.

It is preferred to construct a tube pressure filter and use it approximately as described in Canadian Patent Specification No. 85-655. In these types of tube pressure filters, the inlet of the tube pressure filter internals includes an inlet means designed to feed the moist, finely divided solid to be pressure filtered to the bottom of the inner compartment and distribute it substantially evenly in the first vertical position when the tubular bodies are

In order to facilitate an understanding of the invention and to illustrate its embodiment, reference will now be made, by way of example, to the accompanying drawings, in which: Figures 1 and 3 show two embodiments of a filter element according to the invention; and Figure 2 shows a pipe pressure filter incorporating a filter element according to the invention.

5 57885

According to Figures 1 and 2, the tubular pressure filter comprises an inner tubular body 1a and an outer tubular body Ib which, in their first operating position (according to Figure 2), form an annular chamber (le and lf) sealed at both ends by sealing means le mounted for tubular body la. The impermeable, flexible sleeve Id is placed inside the outer tubular body Ib and fixed to it at its ends and forms with the tubular bodies the inner and outer compartments le and lf, respectively, which are not in contact with each other. The inner tubular body 1a has an inlet 15a by means of which the slurry can be supplied under pressure through the chamber 151 »and a plurality of lines 15c to the inner compartment le, the slurry pressure expanding the elastomer ring 15d which normally closes the ends of the lines 15c. The filter element Ig is placed around the inner tubular body 1a supporting it. The outer compartment 1f has an inlet 16 for pressurized hydraulic fluid. The inner tubular body is also provided with openings through which the filter passes, an inlet 17 from which compressed air is supplied inside the inner tubular body and downstream of the flow of the filter element, a flap tube 18 which removes the filter from inside the inner tubular body and a lifting device (not shown), which moves the tubular bodies axially relative to each other between their first and second positions.

The filter element Ig includes a filter media sleeve 11, a coarsely woven backing fabric lk and a wadding mesh sleeve 13. The filter media sleeve has three impermeable compartments 12. The filter media sleeve 11 is shown schematically in Figure 1 and is made of three 125 denier, continuous, monofilament poly (ethylene) tere . The fibers were woven into a sleeve having a circumference of 5 ^ 5 cm and a weight of 3 ^ 0 grams per square meter. The filter media sleeve was divided lengthwise into three compartments at a distance of 18.17 cm from the centers, and at these centers the filter cloth was impermeable to a width of 16 mm by impregnating the filaments with a sealant containing a solvent-based elastomeric binder. The impermeable portions terminate approximately 5.08 cm (2 ") from each end of the filtration sleeve as this is covered at its ends with shaped plates.

In use, a tank containing finely divided solids to be treated is connected to the inlet 15a of the tubular pressure filter by a pump which supplies the substance to be filtered under pressure to the inner compartment le. The inlet 16 formed in the outer tubular body of the tube pressure filter is connected to a high pressure pump and a reversible low pressure / vacuum pump. High-pressure pumps 6 57885 and low-pressure pumps draw hydraulic fluid from the storage tank and supply it to the outer compartment lf. The inlet 16 is also connected directly to the storage tank. The hydraulic fluid can be removed from the outer compartment lf and returned to the storage tank by means of a reversible low pressure / vacuum pump, whereby the flexible sleeve Id stretches against the wall of the outer tubular body. The cables connecting the different parts of the device are equipped with valves that allow the auxiliary devices to operate at the right time.

The rubber sleeve Id initially stretches against the inner wall of the outer tubular body and the compartment le is empty. A small amount of hydraulic fluid is then supplied to the outer compartment lf between the flexible sleeve Id and the inner wall of the outer tubular body. The batch of material to be filtered is then fed through the inlet 15a through the chamber 15b and the lines 15c to the inner compartment le between the flexible sleeve Id and the inner tubular body. This causes abrasion on the lower part of the filter element Ig by removing any solid left by the previous use of the pressure filter. During this rubbing operation, more hydraulic fluid is pumped at low pressure into compartment lf. This reduces the volume of the inner compartment le until it is completely filled with feed. Filtration may be continued at low pressure until the flow of the filter has substantially ceased, at which time the High Pressure Pump is started to supply hydraulic fluid to compartment lf under higher pressure, the filter inside the inner tubular body is removed through the paddle tube 18. When the filtration step is completed, the supply of hydraulic fluid is cut off and the compartment lf is emptied under vacuum. When the compartment 1f has been emptied and the flexible sleeve has been stretched against the inner wall of the outer tubular body, the inner tubular body is lowered by the lifting device so that the tubular bodies move to their second position where they do not work and the filter press cake formed by the filter element Ig is removed to the page below. Because the filter element is provided with impermeable compartments that extend the entire length of the inner compartment, the filter press cake made of fibrous materials also breaks into strips and disintegrates easily. When the discharge of the filter press cake is completed, the inner tubular body is raised to its former position and the cycle can start again. When using a tube tube filter, the amount of feed material fed to the inner compartment is such that the thickness of the filter press cake formed on the filter cloth is about 8 millimeters.

Figure 3 shows an alternative form of filter element in which the impermeable parts of the filter element are formed by attaching three rigid or semi-rigid metal strips 22 to the wadding mesh sleeve 23 by means of hooks 25. The wadding mesh sleeve is then covered with a coarsely woven backing and the filter media sleeve 21 is shown partially cut off for ease of understanding.

Claims (7)

8 57885 A tubular pressure filter having a pair of substantially coaxial cylindrical tubular bodies (1a, 1b) nested and adapted to be supported in a substantially vertical position, a flexible impermeable sleeve (1d) disposed inside and attached thereto to the outer tubular body (1b). , a filter element (1g) supported by the inner tubular body (1a), removal means (18) for removing a filter which has passed through the filter element and through the openings of the inner tubular body from inside the inner tubular body, and means for moving the tubular bodies axially relative to the first and second positions the system being such that, in the first position of said tubular bodies (1a, 1b), they work together to define a closed annular chamber divided into substantially coaxial inner and outer compartments (1e, 1f) which are not in communication with each other; by an impermeable flexible sleeve (1d), wherein the inner compartment (1c) has an inlet (15a-c) for a moist finely divided solid and the outer compartment (1f) has an inlet (16) for a hydraulic pressure fluid and in said second tubular body said annular chamber (1e, 1f) is open to allow the fine solid to discharge from the inner compartment (1e), characterized in that the filter element (1g) has alternately permeable and impermeable compartments (11,21) 12,22), each of which extends through the effective section of the filter element (1g). for the entire length of the filtration zone or substantially for its entire length. Pipe pressure filter according to Claim 1, characterized in that the filter element (1g) has a sleeve (11, 21) of filter material which is supported by a wadding mesh sleeve (13, 23). A pipe pressure filter according to claim 2, characterized in that said sleeve (11, 21) of filter material has alternating permeable and impermeable compartments (11) 12) formed by applying varnish or impermeable adhesive tape to spaced apart sleeves of filter media. sections (12). Pipe pressure filter according to Claim 2, characterized in that the impermeable compartments of the filter element are formed by attaching metal strips (22) or strips of rigid or semi-rigid plastic material to the wadding sleeve so as to extend in its longitudinal direction. Pipe pressure filter according to one of Claims 1 to 4, characterized in that it has at least three permeable compartments (11, 21) which are separated by a corresponding number of impermeable compartments. 9 5 7 8 8 5 Pipe pressure filter according to one of Claims 1 to 5, characterized in that the width of the impermeable compartments (12, 22) of each filter element is at least 10 mm, but substantially less than the width of the adjacent permeable compartments. Pipe pressure filter according to one of the preceding claims, characterized in that the inlet (15a-c) of the inner compartment (1e) of the pipe pressure filter is at the lower end of the inner compartment and is constructed and arranged so that the tubular bodies (1a, 1b) are supported in an approximately vertical position and in their first position. position, the wet finely pressurized filterable solid can be conveyed to the bottom of the inner compartment (1e) through said inlet and distributed by said inlet (15a-c) substantially uniformly to each side of the inner tubular body. 5 7 8 8 5 10