RU2093254C1 - Method for manufacturing depth membrane filters - Google Patents

Abstract

FIELD: physico-chemical purification of substances. SUBSTANCE: method involves local radiation of films or plates with fluxes of high-energy particles, subsequent shrinking of films or plates and pickling. Shrinking may be conducted after pickling by thermomechanical or chemical treatment, by vacuum drying or by exposure to fluxes of super-high frequency, optical radiation or particle flux. Radiation may be effected through stencils. EFFECT: higher efficiency. 8 cl, 1 dwg

Description

 The invention relates to the field of physico-chemical purification of substances, and more particularly to methods for the manufacture of porous membrane filters. It can be used to solve the problems of filtration, ultrafiltration, dialysis.

 Known methods for the manufacture of filter membranes (see, for example, the book of S.-T. Hwang and K. Kammermeyer "Membrane separation processes" - M. Chemistry, 1981. - S. 367-394.). These methods make it possible to obtain filters with a random arrangement and configuration of pores and a wide spread in the distribution of pores along their diameter and length.

 Among the known methods of manufacturing filter membranes, the closest in technical essence to the proposed one is the method described in the work of G. N. Flerov and V. S. Barashenkov UFN, (1974), v. 114, no. 2, p. 361-369. This method consists in the fact that a film or plate of filter material is irradiated with a stream of high-energy particles (ions), thus exposing it to local effects. After exposure, the film is treated with an etchant that dissolves the filter substance in the places exposed to the particles and etches the channels in the direction of their propagation.

 This method imposes a fundamental limit on the minimum pore size, which is determined by the type and energy of the particles, the film material and the etching mode, as well as on the specific density of the pore distribution over the surface.

 The aim of the present invention is to reduce the size of pores and increase the surface density of their distribution.

 This goal is achieved by the fact that the film or plate of the filter material is subjected to local exposure to fluxes of high-energy particles of radiation quanta, electrons or ions, followed by etching, the filter is subjected to shrinkage after irradiation. Shrinkage can be carried out after etching. Shrinkage can be carried out by thermomechanical or chemical treatment, either by vacuum drying or irradiation with radiation fluxes from the short-wavelength to microwave ranges, or corpuscular streams.

 In order to obtain an ordered arrangement of pores, irradiation of the film or plate can be carried out through a stencil.

 The drawing schematically shows the sequence of operations in the manufacture of a porous membrane filter, where 1 film, 2 exposure zones on the film during irradiation (tracks), 3 particle flow, 4 exposure zones after shrinkage, 5 irradiator-desiccant, 6 etchant, 7 pores after shrinkage or etching; a) irradiation of the film; b) shrinkage; c) etching through channels along particle tracks; d) the membrane after shrinkage and etching.

 Due to shrinkage of the membrane material, the pore diameters and the distances between them decrease. The last two circumstances lead to an increase in the specific permeability of the membrane filter.

Claims (8)

 1. A method of manufacturing a porous membrane filter, including local irradiation of the original film or plate with streams of high-energy particles and subsequent treatment with an etchant, characterized in that the film or plate is subjected to shrinkage after irradiation.  2. The method according to claim 1, characterized in that the shrinkage of the film or plate is carried out after etching.  3. The method according to claim 1, characterized in that the shrinkage of the film or plate is produced by thermomechanical processing.  4. The method according to claim 1, characterized in that the shrinkage of the film or plate is produced by chemical treatment.  5. The method according to claim 1, characterized in that the shrinkage of the film or plate is carried out by vacuum drying.  6. The method according to claim 1, characterized in that the shrinkage of the film or plate is produced by irradiation with microwaves, optical, infrared radiation or corpuscular streams.  7. The method according to claim 1, characterized in that the irradiation of the film or plate is made through a stencil.  8. The method according to claim 1, characterized in that the radiation quanta, electrons or ions are used as high-energy particles.