RU2036704C1 - Multi-section, multi-chamber membrane module for separation of liquid mediums; method of its preparation - Google Patents

Abstract

FIELD: chemical industry. SUBSTANCE: module has groups of alternated cross- directed slit chambers for separation of mediums and permeate. These chambers are made of sets of semi-permeable membranes and seals and provided with separation and drainage members. Seals are made in the form of racks located following the direction of movement of mediums and permeate. Chambers are also provided with additional racks to divide them into compartments with equal number of sections each. EFFECT: higher efficiency. 2 cl, 6 cl, 11 dwg, 1 tbl

Description

 The invention relates to medical equipment, in particular to devices for carrying out blood separation processes, for example, for plasmapheresis, and can also be used in the manufacture of membrane devices for the separation of liquid and gaseous media in chemical, biotechnological and other industries.

Various multi-chamber membrane devices based on flat semipermeable membranes are known, containing several parallel chambers into which the flow of the shared mixture is pressurized, and several parallel permeate chambers separated by semipermeable membranes from the chambers of the shared mixture [1, 2]
A disadvantage of the known multi-chamber apparatuses with laminar flows of a separable mixture directed along the surface of the membranes is their insufficient efficiency due to the formation of stagnant zones and a decrease in the specific productivity of the membrane along its length. This drop is due to the phenomenon of concentration polarization, i.e. with an increase in the concentration of particles near the membrane surface under the influence of a permeate flow directed in the chambers of the shared medium perpendicular to the membrane surface. Particles that accumulate at the membrane surface overlap its pores and thereby prevent the passage of permeate through it [1, 2]
Known multi-chamber membrane filter [3] containing chambers of the separable mixture separated by semipermeable flat membranes from the permeate chambers, an inlet distributor for parallel supply of the separable mixture along the surface of the membranes of the chambers of the separable mixture, an output collector of concentrate in communication with parallel exits of the chambers of the shared mixture and a permeate collector communicating with the outputs of the permeate chambers. Membrane 0.22 m long is used in this plasmaphereser; therefore, the phenomenon of concentration polarization is manifested very significantly in it. An increase in the influence of concentration polarization, i.e., an additional decrease in the specific productivity, is caused in the known plasma filter by a decrease in the flow rate of the separated mixture (due to a decrease in the volume of the flow of the separated mixture during separation of the permeate) along the length of the membranes in the direction from the inlet of the filter to its outlet, leading to a weakening of the effect flow to particles deposited on the membrane and their removal from the membrane surface. To reduce the effect of concentration polarization, it is proposed to carry out chambers of a shared medium with a height that decreases in the direction of flow. This device is difficult to manufacture and also not efficient enough to operate.

The closest in technical essence and achieved by using the result technical solution (prototype) is a multi-chamber membrane module for separating liquid media, containing groups of alternating cross-directional media streams of chambers for shared media and permeate, formed from a tape membrane by folds of flat semipermeable membranes and means sealing, as well as a set of separation and drainage elements placed in the chambers [4]
The disadvantages of this membrane module is the formation of stagnant zones, which significantly reduces the specific productivity of the module and necessitates an increased consumption of materials. In addition, the design of this module does not allow the organization of automated large-scale production of membrane filters.

 Thus, an inventive task arises (i.e., a task aimed at resolving a technical contradiction) to create a technical solution that improves the efficiency of the membrane module of a multi-chamber plasma filter by reducing the effect of concentration polarization in the section chambers and eliminating stagnant zones while increasing the manufacturability of multi-chamber multisectional membrane modules needed to enable mass industrial on the production of cheap disposable membrane apparatus, which is especially important in connection with the impending pandemic of AIDS and acute shortage of efficient equipment for processing and cleaning the blood.

A known method of manufacturing membrane devices for blood processing, including the manufacture of flat (with a raised surface) blanks of support elements and semipermeable membranes, assembling them in the foot with alternating layers and ensuring the sealing of the chambers of the shared medium and permeate by screed through coaxial holes [5]
The disadvantage of this method is the high complexity of the manufacture of membrane devices, as well as the inability to use nuclear membranes as the membrane material, since they are damaged when the apparatus is sealed by compression.

A known method of manufacturing a membrane apparatus for blood purification (dialysis), including the formation of a tape membrane of a large number of folds closely spaced to each other, installation between the folds on one side of the separation elements, fixing the position of the spacer elements using a special tool with pins, filling the end faces of the folds fluid synthetic material for the purpose of sealing and installing the membrane module in the housing [4]
The disadvantage of this method is its low manufacturability and the principal unsuitability of the method for mass production of membrane devices due to technological operations with single blanks.

 The closest in technical essence and the achieved result with respect to the claimed method (prototype) is a method of manufacturing membrane modules [6] comprising forming folds from a tape of membrane material, installing separating elements between adjacent folds, sealing the chambers of the shared medium and permeate in the housing by filling end parts of folds with sealant. A feature of the method is the use of a tape of membrane material with a width suitable for the manufacture of only one device. Moreover, to ensure the flowing motion of the shared medium inside the chambers of the shared medium of adjacent sections, an additional sealing zone is made, which requires additional labor costs and contributes to the formation of peripheral stagnant zones in the shared medium chamber.

 The aim of the group of inventions (the required technical result) is to increase the efficiency of the multi-chamber membrane module by providing the possibility of sequentially reducing the total cross-sectional area of the chambers of the shared mixture in accordance with a decrease in the volume of the shared mixture due to the separation of permeate and the possibility of using nuclear membranes while increasing the manufacturability of multi-chamber membrane manufacturing modules for separating liquid media.

 The goal is achieved in that in a multi-sectional multi-chamber membrane module for separating liquid media, containing into groups of alternating, cross-directed along the flow of media, slotted chambers for shared media and permeate, formed by a set of flat semi-permeable membranes and sealing means, as well as a set of separation and drainage elements placed in the chambers, according to the invention, the means of sealing the chambers are made in the form of strips located along the direction of movement of the media and permeate, the chambers are equipped with placed inside them in the direction of movement of the media and permeate with additional slats dividing the chambers into compartments with the formation of sections containing the same number of compartments, while in adjacent sections the compartments of the chambers for the shared medium are connected in series along the movement of the media, the compartments of each of the sections are made with the same length, and the compartments of the chambers for the shared medium in adjacent sections are made with a width successively decreasing in the direction of flow of the shared medium.

 In addition, the strips are made of a material containing a thermoplastic and are permanently connected to the membranes with the formation in the places of contact with them of supporting elements in the form of a column.

 In addition, additional slats in the chambers of the shared medium of the module are located at an angle to the direction of movement of the shared medium.

 In addition, nuclear membranes were used as membranes.

 In addition, the planks are made of polymer melt adhesive based on silactan.

 In addition, the separation and drainage elements are made of microporous material.

 In addition, the trims are made of fiber reinforced material.

 The goal (the required technical result) is also achieved by the fact that according to the method of manufacturing multi-sectional membrane modules, including the operation of forming a block of blanks of modules from layers of membranes, separation and drainage elements and sealing means according to the invention, after forming the block of blanks is heated to the softening temperature of the material of the sealing means, withstand under a fixed load, they are cooled and a block of membrane modules is obtained, and then the block is divided into separate e modules.

 Moreover, according to the proposed method, the operation of holding the block of the billet of the membrane modules under a fixed value of the load includes a fixed value of the deformation of the block of the billet of the membrane modules with compressive force in the direction perpendicular to the plane of the nuclear membranes, and the deformation of the block of the billet is not more than 20% of the initial thickness of the block at dense laying of layers of membrane material based on semi-permeable polymer nuclear membranes, separation and drainage elements and tools in sealing chambers of a shared medium and permeate.

 The combination of general and private essential features of the group of inventions provides the opportunity to achieve the goal of inventions (the required technical result).

 The proposed group of inventions allows not only at the same time significantly simplifying the design of the membrane module to increase the efficiency of its operation by ensuring the constancy of the main parameters of the separation process (the speed of movement of the shared mixture) by ensuring that the total cross-sectional area of the chambers corresponds to the volume of the shared mixture, which decreases during the separation of permeate, and by providing the ability to use nuclear membranes, but also significantly increase the manufacturability of mas ovogo producing relatively cheap disposable membrane modules.

The use of semi-permeable nuclear membranes in the proposed module allows, compared with other currently used membranes (for example, membranes based on cellulose derivatives), to significantly increase the efficiency of plasma separation and reduce the trauma of blood cells, which has been experimentally proven in determining the comparative efficiency of using various types of membrane materials [ nineteen]
The implementation of the separation elements and sealing means in the form of strips based on thermoplastic materials, for example, from hot melt adhesive based on silactan, allows not only to increase the efficiency of mass transfer by eliminating stagnant zones during the movement of blood and plasma, but also to increase the sealing efficiency, since the hot melt adhesive when the module is deformed, it is pressed into the pores of the nuclear membranes under the influence of temperature and pressure and it adheres more reliably. At the same time, high manufacturability of mass production of modules and reliable sealing of module chambers are simultaneously ensured.

 In addition, the use of microporous material for the manufacture of separation and drainage elements in plasma chambers allows not only to increase transmembrane pressure during blood separation, but also to retain blood cells accidentally entering the plasma due to possible membrane defects, which significantly increases the reliability of the functioning of membrane modules.

 In addition, the proposed module design allows the automation of serial production of membrane modules and almost completely eliminates manual labor during the assembly of membrane devices.

 Thus, it can be argued that the group of inventions meets the requirements of the criterion of "inventive step", as it allows to obtain a combination of new technical results and the criterion of "industrial applicability", and the analysis also shows that all the general and particular features of the group of inventions are essential , since each of them is necessary, and all together they are sufficient to achieve the goal of inventions to increase the efficiency of the membrane module while increasing increase the manufacturability of modules.

 In addition, the analysis of the set of essential features of the inventions of the group and the result achieved by using them shows the presence of a single inventive concept, the close and inextricable connection between the inventions of the group and the purpose of the method directly for the manufacture of membrane modules of the claimed design.

 In FIG. 1, 2, 3 shows a general view of the multi-chamber membrane module; 4, 5 a scheme of alternating layers of flat semipermeable membranes and separation and drainage elements with means for sealing the chambers in the form of strip strips of material containing a thermoplastic, for example, hot melt adhesive based on silactan; Fig.6 is a diagram of the design of composite support elements-columns formed by the alternation of permanently connected to each other layers of membranes and separation-sealing strip strips; 7 is a diagram of the manufacture of a block of blanks of membrane modules; on Fig, 9 blocks of blanks of membrane modules; figure 10, 11 is a General view of a section of membrane apparatus with multi-chamber modules of various designs.

 The multi-chamber membrane module for the separation of blood (1, 2, 3) contains a set of flat nuclear membranes 1 and separation and drainage elements of the plasma chambers 2 and plasma chambers 3 with sealing means in the form of strips 4, 5 made of a material based on thermoplastic and / or containing thermoplastic, for example, from polymeric hot melt adhesive based on lavsan or impregnated into separation and drainage elements. Blood chambers and plasma chambers in the membrane module are made in the form of slotted flat open channels on both sides of the inlet and outlet of the media, providing mutually cross-movement of blood and plasma in the chambers. In this case, the blood chambers (Figs. 10, 11) communicate with the blood distributor and the blood collector, communicating with the supply pipes 8 and 9 of the blood outlet, and the plasma chambers communicate respectively with the plasma collectors and the plasma discharge pipes 10. The cross-directed strips 4, 5 form in the corners or on the sides of the membrane module, vertical support composite elements-columns 7 (6, 8, 9), obtained by permanently connected to each other layers of membranes 1 and strips 4, 5.

At the same time, additional straps 6 are installed inside the blood chambers so that they form several closely spaced sections 15 with the same number of chamber chambers 16 of the same height and length, but decreasing in width in the direction of blood movement. Moreover, the most preferred design option of the membrane module is the option with additional intermediate strips 6 located at an angle to the direction of movement of the mixture to be separated (FIGS. 2, 3, 10, 11), since such a design reduces the total cross-sectional area of blood chambers in exact accordance with a decrease in the volume of the shared medium due to the separation of permeate (b ₁ > b ₂ > b ₃ >b4> b ₅ > b ₆ ) (Fig.2, 3).

 The manufacture of multi-sectional multi-chamber membrane modules is as follows.

 The tape of the nuclear membrane from roll 8 is unwound under tightness with the formation of folds (Fig. 7), between which the blocks of blanks of separation elements 2, 3 with a width of N˙A and a length of M˙B, where N, M are positive integers, and A, In, respectively, the width and length of an individual membrane module (Fig, 9). In the blocks of the blanks of the separation elements 2, 3, strip strips 4, 5 of material containing thermoplastic are located, and in adjacent (separated by a membrane) chambers of the strip strips are oriented mutually crosswise. After laying the required number of folds, a block of blanks of membrane modules (Figs. 8, 9) is obtained, which is heated to the softening temperature of the material of the strip strips (thermoplastic), and is held under a fixed load, which ensures the deformation of the blank block of the membrane modules is not more than 20% of the initial thickness block with a dense installation of membrane material and separation and drainage elements and the penetration of thermoplastics into the pores of the membranes. The preform is then cooled and a block of membrane modules 9 is obtained, which is divided into N˙M individual membrane modules.

 Ready-made modules (Figs. 10, 11) are installed in the housing 11, in the side walls of which there are wedge-shaped protrusions 12, which are pressed into the vertical sections 7 of the composite supporting column elements, which ensures reliable sealing of the module in the housing simultaneously with the formation of distributors 13 and collectors 14 which communicate with the corresponding nozzles of the supply and removal of blood 8, 9 and the discharge of plasma 10, ensuring the sealing of blood and plasma flows relative to each other. In this case, the sealing of the membrane module in the housing is carried out only by heating to the softening temperature of the thermoplastic and mechanically pressing the module into the housing without traditional filling with sealant.

A characteristic feature of the proposed membrane modules is the use of nuclear membranes as membrane material, which are thin (from 5 to 20 μm) polymer films (for example, from lavsan or kapron) in which through cylindrical pores with a diameter of 0.05-2 are made by special technological methods microns [7, 8] Nuclear membranes are distinguished from traditional, obtained by chemical technology, membranes with high uniformity of geometric dimensions and regularity of pore shapes, high selectivity in relation to the secreted component, very low adsorption of the components of the media shared by the membrane surface, biological inertness, full compatibility with blood components and low traumatic effect on blood cells [9]
However, along with high functional indicators, nuclear membranes are distinguished by small thickness (up to 10 μm), low mechanical strength (nuclear membranes do not withstand pressurization by pressing to the sealing contours and burst) due to their small thickness, high electrification, and low adhesion to traditional adhesives. This significantly limited the use of nuclear membranes in apparatuses of known designs, where the piece-laying of blanks of membrane material (the size of individual blanks is equal to the size of the membrane apparatus) between the separation elements and sealing by mechanical pressing of the membranes to the sealing contours is mainly carried out.

 The membrane module design and the manufacturing method of the invention make it possible to exploit the advantages of nuclear membranes and neutralize their inherent negative properties, since the membrane material tape in the proposed method fits into the folds of the membrane module blanks at the same time for several membrane modules, thereby eliminating manifestations undesirable electrostatic phenomena associated with electrifying, and eliminate the need to directly of common production staff with the membrane material in the manufacture of membrane modules.

 The use of thermoplastics, for example, hot melt adhesives based on silactan, ensures reliable adhesion of the membrane to the sealing zones due to heating and aging under load (in this case, part of the thermoplastic is pressed into the pores of the membranes) and at the same time provides reliable sealing of the module in the apparatus body.

 The use of microporous material in plasma chambers makes it possible to uniformly distribute the contact zones of membranes with separation elements over the entire membrane surface, which significantly increases the resistance of the membranes to transmembrane pressure and makes it possible to increase functioning efficiency by increasing the pressure drop in the blood chambers and plasma chambers without fear of mechanical damage to the membranes . Moreover, even in the case of mechanical defects in the membranes, blood cells that accidentally enter the plasma will be retained by microporous material, which also increases the efficiency of the modules and their reliability.

 In addition, the proposed module design allows the automation of serial production of membrane modules and almost completely eliminates manual labor during the assembly of membrane devices. The membrane module in the membrane apparatus for separation of blood works as follows.

 Blood is supplied through the blood supply pipe 8 (Fig. 10, 11) to the blood distributor 13, in which the blood is distributed over the slotted blood chambers 3. Under the influence of external pressure, the blood passes through the blood chambers in successively connected sections, the blood concentrate is collected in the output collector blood and is discharged through the blood outlet 9. In this case, part of the plasma contained in the blood under the action of transmembrane pressure penetrates the pores of the nuclear membranes and enters the plasma chambers 2, from where it is collected in opposite dnyh plasma collectors and discharged through nozzles 10 of the plasma discharge.

To verify the principal operability and effectiveness of the membrane modules (industrial applicability of the invention), nuclear membranes were taken from lavsan (TU 95-1667-88) 320 mm wide, 10 μm thick, pore sizes 0.5 μm and 10% porosity. Nuclear membranes were obtained by bombarding lavsan films with heavy ions and processing the resulting tracks with an alkali etching solution [8, 9]
As blanks of separation elements in the blood chambers, kapron fabric for sieves of grade 14K4C (TU 17 RSFSR-11086-86) with a thickness of 270 μm was used. Silactan was used as hot melt adhesive (technical conditions are drawn up).

 Filter blankets for TF-61 blood transfusion devices (TU 17 RSFSR 62-11438-87) 120 microns thick were used as blanks for separation and drainage elements in plasma chambers, and silactan was used as hot melt adhesive.

 The specific design parameters of a multi-sectional membrane module are selected based on the fact that a decrease in the effective filtration area proportional to the effective width l of the membranes in the sections occurs according to a linear law. According to the invention, it is optimal to reduce the effective filtration area with increasing section number (N) of the membrane module. This decrease should be all the more dramatic, the greater the degree of filtration in the membrane module, numerically equal to the ratio of the amount of permeate (blood plasma) at the outlet of the apparatus and the amount of shared medium (blood) at the entrance to the apparatus.

(n-1)] 0,5 ≅ bn≅ b₁[1-

(n-1)] + 0,5 где b₁ эффективная ширина фильтрации в первой секции;
bn эффективная ширина фильтрации в секции n;
φ- степень фильтрации;
m число секций в модуле;
n номер секции;
Из двух полученных по данной формуле значений bn выбирают большее.Based on the foregoing, the effective width of the membranes b in the nth section with the total number of sections in the module equal to m can be determined from the relation
b ₁ [1-

(n-1)] 0.5 ≅ bn≅ b ₁ [1-

(n-1)] + 0.5 where b _{1 is the} effective filtering width in the first section;
bn effective filtering width in section n;
φ is the degree of filtration;
m is the number of sections in the module;
n section number;
Of the two bn values obtained using this formula, the larger one is chosen.

The total hydraulic length of the sections of the plasma filter is selected based on the fact that the blood pressure at the inlet should be within the acceptable range to avoid hemolysis. Thus, for a filtration coefficient of 0.5, we obtain the following parameters of a multi-section module: the number of blood chambers in each section 16, the number of plasma chambers, respectively 17, the width of the sealing field 7 mm, the number of sections of the module m 3, the length of sections of the module l 40 mm, total the hydraulic length of all sections is 120 mm, the effective width of the first section is b ₁ 45 mm, the second section is b ₂ 35 mm, the third section is b ₃ 25 mm, the effective area of the first section is 360 cm ² , the second section is 280 cm ² , the third section is 200 cm ² , the total effective area of the plasma filter is 840 cm ² .

 Membrane modules are made as follows (Fig. 7).

The preform separation and drainage chambers for blood cells and plasma chambers flush with the surface-impregnated strips of strap sealing means silaktana at 130 ° ^C.

Unwind the interference roll of the nuclear membrane 8 and form folds, between which the blanks of the separation and drainage elements of the blood chambers 2 and the plasma chambers 3 are successively installed. The blank of the membrane module block obtained in this way is placed on the base of a special device with heat transfer means and compressed at a pressure of 6.1 kPa The device with the workpiece unit membrane modules for 1.5 hours and is kept heated at 130 ^{° C} for 1.5 hours, resulting in a reliable adhesion of membranes to the strip-sealing strips. In this example, with the parameters of the module block 150 x 40 mm, N 2 and M 5, the total compression force was 340 N. After cooling under the load of the block of blanks, a block of membrane modules 9 is obtained (Figs. 8, 9), which are separated by known methods (cut) on separate (M x N 10) membrane modules. Thus obtained membrane modules are placed in the housing 11 and close the lid under the action of mechanical stress. If necessary, heating, aging at a temperature and cooling of the apparatus are additionally carried out for more reliable sealing of the membrane module in the housing.

 Experimental studies of the functional properties of plasma filters made using the proposed membrane modules were carried out at the Leningrad Research Institute of Emergency Medicine. Jalelidze. The conformity of plasma filters to the world level was checked by comparing their functional characteristics with the characteristics of plasma filters of leading foreign companies. The tests were carried out on canned human blood citrate with a hematocrit of 0.42 at a blood flow rate of 60 ml / min. The test results are shown in the table.

 An analysis of the comparative data given in the table shows that, according to the functional characteristics, the tested plasma filters using the membrane module proposed according to the invention fully correspond to the world level.

 The biocompatibility of membrane modules is proved by tests on rabbits at the St. Petersburg Institute of Traumatology and Orthopedics. R.R. Vredena.

 The use of the inventive membrane modules and the method of their manufacture can significantly increase manufacturability and reduce the complexity of their manufacture by providing the possibility of complete mechanization and automation of production, which allows for large-scale production of currently severely deficient membrane plasma filters. At the same time, it becomes possible to exclude contact of production personnel with individual parts of the membrane modules, which increases the sterility of the membrane apparatus.

 The economic and social effect of using the invention can be achieved both through the organization of large-scale industrial production and the use of plasma filters, and by reducing the unit cost of production of membrane plasma filters.

Claims (8)

 1. A multi-section multi-chamber membrane module for separating liquid media, containing groups of alternating, cross-directed media and permeate, formed by a set of flat semipermeable membranes and means for sealing the chambers, a set of separation and drainage elements placed in the chambers, characterized in that the sealing means are made in the form of strips located along the direction of motion of the media and permeate, the chambers are equipped with additional by channels, dividing the chambers into compartments with the formation of sections containing the same number of compartments, while in adjacent sections the compartments of the chambers for the shared medium are connected in series along the movement of the media, the compartments of each of the sections are made of the same length, and the compartments of the chambers for the shared medium in the adjacent sections are made wide successively decreasing in the direction of flow of the shared medium.  2. The module according to claim 1, characterized in that the planks are made of a material containing a thermoplastic and are permanently connected to the membranes with the formation in the places of contact with them supporting elements in the form of columns.  3. The module according to claim 2, characterized in that the additional slats in the chambers of the shared medium are located at an angle to the direction of movement of the shared medium.  4. The module according to paragraphs. 1 and 2, characterized in that the nuclear membranes are used as membranes.  5. The module according to paragraphs. 1 to 4, characterized in that the planks are made of polymer melt adhesive based on silactan.  6. The module according to paragraphs. 1 to 5, characterized in that the separation and drainage elements are made in the form of gaskets of microporous material.  7. The module according to paragraphs. 1 to 6, characterized in that the planks are reinforced with fibrous material.  8. A method of manufacturing a multi-sectional multi-chamber membrane module, including the operation of forming a block of blanks of modules from layers of membranes, separation and drainage elements and sealing means, characterized in that after forming the block of blanks is heated to the softening temperature of the material of the sealing means, kept under a fixed load, cool and separate the unit into separate modules.

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