Patent Description:
Aerosol sampling based on the collection of aerosol particles on a filtering substrate is among the most commonly used methods. The filtering substrates are grouped to types of fibrous matrixes, membranes, and foams.

Membrane filters are mainly distinguished to two groups:.

Membrane filters possess high stability and capture efficiency. However, they provide a high pressure drop within the thickness of the filtering membrane layer.

Foam filters are constructed as a volume mesh of large pores, providing capture of coarse (respirable) particles. These filters are fabricated either of polymer (polypropylene), or stainless steel.

Fibrous matrixes are constructed as deep mesh of fibres with random orientations. They collect aerosol sample within a depth of the filtering layer, providing high filtration efficiency with a relatively low pressure drop. Fibrous matrixes are usually fabricated of mineral materials (glass, quartz) or natural materials (cellulose). Although fibrous filters are among the most common aerosol sampling substrates, they suffer from several drawbacks: a) due to the large surface area of filters, compounds of higher volatility (e. some PAHs or organometallic compounds) contained in the sampled particles evaporate from the filter during prolonged storage; b) blank values of mineral fibres can affect the subsequent chemical analysis (such as metals in aerosol particles); c) some formulations of pure mineral fibres (such as quartz) are mechanically unstable and disintegrate during handling.

The number of fibrous aerosol sampling filter options are limited based on their chemical composition and fibre morphology (porosity, fibre size, pore size). At the same time, the broad variety of chemical analysis methods as well as emerging new methods for chemical analysis techniques of collected particles requires the creation of bespoke filters having unique composition. No single filter medium is appropriate for all desired chemical analyses, and it is often necessary to sample on multiple substrates when chemical characterization is desired.

The present invention allows the fabrication of bespoke aerosol sample collection filters using several techniques of electrohydrodynamic polymer processing from the plurality of polymers (benefiting the selection for subsequent chemical analysis of collected particles) and obtaining plurality of surface morphologies (benefiting the selection for sampling particles of various sizes and shapes).

The closest inventions to the proposed are the following:
US Patent <CIT> describes the fibre sampler for recovery of bioaerosols and particles: a bioparticle collection device and an aerosol collection system. The bioparticle collection device includes a collection medium including a plurality of fibres formed into a fibre mat and configured to collect bioparticles thereon and includes a viability enhancing material provider disposed in a vicinity of the plurality of fibres and configured to provide a viability enhancing material to the collected bioparticles to maintain viability of the bioparticles collected by the fibre mat. The patent covers collection of viable bioaerosol particles which are of limited size range. The patent presents a modification of fibres aiming to sustain bioaerosol particle viability, which is a limited modification specific to this type of particles.

The Chinese patent <CIT>discloses "Preparation method of detection filter membrane used for bacteria and virus sampling in air". The invention provides a composite membrane suitable for sampling of air microorganisms, providing beneficial combination of action on microorganisms and retention efficiency. The composite membrane is made from a porous membrane coated with a solution of a macromolecular substance. The macromolecular substances in the composite membrane can maintain the activity of trapped microorganisms to a certain extent. The patent covers collection of viable bioaerosol particles which are of limited size range. The patent presents a modification of fibres aiming to sustain bioaerosol particle viability, which is a limited modification specific to this type of particles.

Another Chinese patent <CIT>discloses "Reinforced microporous filter membrane and method and device for preparing the same". The invention relates to a filtering material, in particular to an enhanced microporous filter membrane for radioactive aerosol sampling monitoring and a method and device for preparing the product. The invention adopts the following technical solutions: an enhanced microporous filter membrane, which includes a non-woven fabric as a substrate, using a cast-scraped film method, scraping the casting solution on the front and back of the non-woven fabric. The patent focuses on sampling of radioactive aerosol particles, which is a narrow and specific subdivision of aerosol particles, thus cannot be applied to a general environmental aerosol.

The UK patent application <CIT> discloses "Aerosol sampling filter". The invention presents a sampler for collecting aerosol particles from a flow of gas comprises a plurality of collection regions of a porous medium. The collection media is comprised of mesh screens of varying openings. The nets are Nylon Net Filters (Nylon PA <NUM>,<NUM>; polyamide <NUM>,<NUM>), supplied by Millipore UK. Such classification is based on the selective particle penetration through the mesh orifices, thus of different working mechanism than the presented invention in this patent.

The US patent application <CIT> discloses "Method for producing a filter intended to filter nanoparticles, obtained filter and associated method for the collection and quantitative analysis (specifically X-Ray fluorescence) of nanoparticles". The invention relates to a method for impregnating a filter having pores suitable for retaining particles within them that may be present in a flow of air suitable for passing through the filter, according to which the filter made up of a polymer membrane (polymer of the membrane being chosen from saturated polyesters, such as polycarbonate) is impregnated with one or more organometallic salts by applying a treatment using supercritical CO<NUM>, the metal M of each salt being chosen from among the group of rare earths, yttrium, scandium, chromium, or a combination. This invention is based on a modification of a commercial (non-fibrous) membrane thus not presenting a method for the fabrication of membrane.

One more Chinese patent <CIT>discloses "Sampling film and method for detection and analysis of iron ore sintering flue gas ultrafine particles by using sampling film". The invention relates to a method for sampling and analysing ultrafine particle pollutants of iron ore sintering flue gas, in particular to an ultrafine particle sampling membrane for iron ore sintering flue gas and a method for analysing ultrafine particles of iron ore sintering flue gas based on membrane detection, belongs to the field of steel metallurgy. The invention provides sampling film, which comprises a polytetrafluoroethylene base film, and a high temperature resistant tape or a conductive tape adhered to the surface of the base film. Such substrate is designed to collect particles by impaction, as opposed to filtration, thus does not represent similar collection mechanism as in this invention.

<NPL> discloses a novel approach towards tackling the balance between filter efficiency and pressure drop by layering micro and nano fibres using melt and solution electrospinning. Polyamide fibre mats were fabricated by a prototype fibre printing apparatus, based on a combination of melt and solution electrospinning. Fibrous mats with favorable filtration performance characteristics were developed by optimizing the process parameters. The measurements were performed at a face velocity of <NUM>/s. High filtration quality factors (such as <NUM>-<NUM> Pa-<NUM> for PN<NUM> fraction) were reached due to low values of pressure drop (<NUM>-<NUM> Pa). The filtration efficiencies ranged from <NUM> (PN<NUM>) to <NUM>% (PN<NUM>). Higher ratios of nano-sub micrometer (<<NUM>) to super micrometer (≥<NUM>) fibres in the fibrous matrix were associated with the higher filtration quality factors.

The Korean patent application <CIT> discloses an electrospining apparatus, where only a certain nozzle from nozzles, arranged and installed on a nozzle block of a unit located on a front end portion, sprays a hot-melt material on a base material to form the hot-melt material to be in the shape of a dot; a nozzle, arranged and installed on a nozzle block of a unit located on a rear end portion, electrospins a polymer spinning solution. Therefore, the electrospinning apparatus can easily attach nanofiber web on the base material. The electrospinning apparatus comprises: a hot-melt unit that has at least one solution main tank which is filled with the hot-melt material, and the nozzle blocks which are installed in the case to spray the hot-melt material filled in the solution main tank and include a plurality of nozzles arranged and installed in the shape of a pin and independently controlled in order to spray the hot-melt material on the base material supplied from the outside; a spinning solution unit that has at least one solution main tank which is filled with the spinning solution, and the nozzle blocks which are installed in the case to spray the polymer spinning solution filled in the solution main tank and include a plurality of nozzles arranged in the shape of a pin to spray the polymer spinning solution on the base material supplied from the outside; collectors which are installed in each unit and are placed apart from the nozzles at a certain distance to collect the hot-melt material and the polymer spinning solution sprayed from the nozzles arranged on the nozzle blocks; a voltage generator which generates voltages on the collectors; and a subsidiary transferring device for transferring the base material. At least one hot-melt unit and at least one spinning solution unit are alternately arranged.

<NPL> discloses development embossed nanofiber membranes (ENMs) using 3D patterns for use in air mask filtration and compares this structure with a planar nanofibrous materials (PNMs). The embossed nanofiber membrane (ENM) was prepared using a combination of 3D printing and electrospinning technologies to increase the surface area of the ENM compared to that of planar structures. The surface area of the ENM was three times higher (<NUM><NUM> g-<NUM>) than that of the PNM (<NUM><NUM> g-<NUM>). The embossing structure depended on hole size and height of the grid in the 3D pattern. The pore size of the nanofiber membranes (NMs) was controlled to <NUM> to enable robust filtration of ultrafine airborne particle and smog pollutants. The polyamide <NUM> ENM achieved excellent filtration efficiency via corona surface ionic modification with (---CH<NUM>CHCONH<NUM>+) or anion (---NHCH<NUM>COO-). Ion-modification generated an electrostatic attraction or van der Waals force/repulsive force between pollutant particles and the NM surface. The dynamic particle barrier efficiency of ionic ENMs was evaluated by dynamic particle removal efficiency (%), penetration (%), resistance (mmH<NUM>O), and air permeability (m<NUM>/m<NUM>/min) tests. Well-developed pore structures and large surface area of the NM were enhanced by the embossed structure compared to that of PNM.

The closest prior art is the Chinese patent application <CIT>, relating to a polyurethane-polyacrylonitrile super air filter disc and a preparation method thereof. The composite fiber comprises a three-layer fiber composite structure, wherein the first layer is an electro-spinning polyurethane and polyacrylonitrile composite fiber strong supporting layer, the thickness of the first layer is <NUM>-<NUM> mu m, and the fiber diameter is <NUM>-<NUM> mu m; the second layer is a functional support layer of electrospun superfine polyurethane and polyacrylonitrile composite fibers, the thickness of the second layer is <NUM>-<NUM> mu m, and the fiber diameter is <NUM>-<NUM> mu m; the third layer is an electro-spinning polyurethane nanofiber filtering functional layer, the thickness of the third layer is <NUM>-<NUM> mu m, and the fiber diameter is <NUM>-<NUM> mu m. The polyurethane-polyacrylonitrile super air filter disc disclosed by the invention has excellent thermal stability and mechanical properties, and the specific thermal decomposition temperature is more than <NUM>; the softening temperature is higher than <NUM>; washing resistance and friction resistance; porosity about <NUM>%; the average pore diameter of the functional layer is <NUM> micron, and the pressure difference is about 186Pa under the air flow rate of <NUM>/min; the interception rate of the mask for the particles with the particle size of more than <NUM> micron is more than <NUM> percent and is far better than that of an N95 mask (the interception rate is <NUM> percent). The <CIT>purpose product is filters for masks with specific thickness, by the above defined maximum thickness of layers <NUM>, <NUM>, and <NUM>, which in total sums up to <NUM> thickness. However, for aerosol sampling applications, the practical thickness of an aerosol sampling filter is above <NUM>-<NUM> micrometers.

The present invention discloses a novel method for the fabrication of a fibrous aerosol particle collection filters from a plurality of polymers, providing a platform for aerosol sampling for numerous post-sampling physico-chemical or toxicological analysis.

The present invention relates to a method of producing a nano/micro fibrous filter substrate for sampling aerosol particles comprising at least three fibrous layers according to the subject-matter of claim <NUM>. Additionally, the present invention also relates to a 2D composite filter disc according to the subject -matter of claim <NUM>.

Technical problem. The presented invention solves a technical problem of an efficient aerosol particle sampling. Currently, the selection of fibrous aerosol sampling filters is limited to several materials (such as quartz or cellulose), preventing the usage of these materials for the application in subsequent chemical analyses that require specific composition of filter material not interfering with the specific method of chemical analysis. While fibrous filters are advantageous in terms of favourable efficiency and relatively low pressure drop, the fabrication methods are limited thus not allowing the production of bespoke sampling substrates necessary for a specific sampling methods and subsequent physico-chemical/toxicological treatment.

The invention presents a new method for the fabrication of a fibrous aerosol particle collection filters from the plurality of polymers providing a platform for aerosol sampling for numerous post-sampling analysis. The fibrous sampling media developed by this method will have controlled chemical composition, fibre and pore diameters, pressure drop, and filtration efficiency. The fibrous particle sampling filter will have high particle retention efficiency, a superior mechanical stability and bespoke chemical composition for post-processing by a plurality of chemical analysis techniques.

The proposed fabrication method relies on a electrohydrodynamic processing of polymer melts and solutions, resulting in a non-woven plurality of randomly oriented fibres ranging from 1E-<NUM> to 1E-<NUM> meters in diameter, and pores 1E-<NUM> to 1E-<NUM> in diameter. The range of polymers and the fibrous morphologies presented in the invention provide an opportunity for air quality scientists and professionals to select sampling substrates for the bespoke needs of their research, considering further processing of collected aerosol particles. The fibrous filter is meant to be utilized in filter-based aerosol samplers, where it is inserted into a holder and exposed to the sampled air flow for a defined period of time. Aerosol particles are retained from the air flow on the top layer and may be transferred for a further analysis, such as gravimetric, spectroscopical, chemical, or toxicological.

Advantageous technical effects. The method for the fabrication of fibrous aerosol sampling filters presents the following advantageous technical effects:.

The drawings are provided as a reference to possible embodiments and are not intended and should not limit the scope of the invention.

Composite filter. The presented aerosol sampling filter is constructed as a 2D composite filter disc comprising at least three layers of non-woven fibrous matrixes. The cross-section of such composite filter is presented in <FIG>.

The three-layer composition ensures key operational parameters of the sampling filter, namely, good mechanical stability, high-efficiency of particle collection, and optimum pressure drop across the filter layer.

Layer <NUM> (the bottom layer) comprises a microfibre network and serves as a mechanically robust support for the upper nanofibre layers.

Layer <NUM> (the middle layer) comprises larger nanofibres and ensures a binding between the top and the bottom layer, as well as the adequate mechanical support for the fragile upper layer.

Layer <NUM> (the top layer) acts as the working layer which provides a nanofibre network for the collection of aerosol particles on the surface.

The thickness of such composite layered filter varies between <NUM> and <NUM> micrometres, depending on the materials that the layer is comprised of.

Due to a small fibre and pore size as well as high packing density of nanofibre network of the top layer, the entire composite works primarily as a surface filter where particles are collected above the fibres (as opposed to volume filters, where particles penetrate deeply into the filtering matrix). The prevailing particle capture mechanisms include impaction, interception, and diffusion.

This filter is sized accordingly to the sampling device that the filter is hosted in. The standard diameters of such sampling filter discs include, but are not limited to <NUM>, <NUM>, and <NUM>. The final size may be decided by the user, since the filter composites are first fabricated in larger rectangular sheets (for example, <NUM> x <NUM>). A round disc shape of the final product is obtained using mechanical hole puncher, computerized numerical control based cutter or similar technique.

The three-layered structure of such composite filter is unique and superior to just nanofibre membrane in terms of higher mechanical stability and lower pressure drop.

Production method. The production method of the composite three-layer aerosol sampling filter involves electrohydrodynamic method of polymer processing, i.e., electrospinning. This method relies on the property of the polymer solution or melt to elongate in the environment of strong electric field between two electrodes, forming thin fibres. Such fibres are emitted from a dispenser (a needle, or a hot-end nozzle) and collected on an oppositely charged electrode (drum or flat collector).

The presented invention introduces a novel production method by combining two modifications of the electrohydrodynamic polymer processing, namely, melt electrospinning and liquid-solution electrospinning.

The workflow, stages and steps of production method of the three-layer aerosol sampling filter are presented in <FIG>.

Materials used for fabrication. As polymer materials for fibre production are used the following ones:.

As polymer blending solvents for Layers <NUM> and <NUM> are used the following ones:.

The particle sampling filter is fabricated as a three-layered structure, presented in <FIG>. Layer <NUM> (the base layer at the bottom of the three-layer composite) is a mechanical support for the fragile upper layers. Layer <NUM> (the middle layer) functions as a binding layer between micro fibrous layer <NUM> and nanofibrous top-layer (Layer <NUM>), ensuring optimal adhesion and preventing breakdown of nanofibrous Layer <NUM> in high pressure environments. Layer <NUM> (the top-layer) functions as a 2D aerosol particle collection surface.

Production of Layer <NUM>. The fabrication setup is based on the method for the formation of polymer fibre matrixes by the combined fused deposition model and electrospinning. This method of producing Layer <NUM> is disclosed in the Lithuanian patent application <CIT>. The method of <CIT> includes a process of forming polymeric fibre matrices (for Layer <NUM>) by a combined fused deposition modelling and electrospinning process. The raw material, a polymer material in the form of the filament with a thickness of <NUM>,<NUM> ± <NUM>,<NUM> (or for some embodiments, may be different types of polymeric materials and their mixtures) is pushed into a variable diameter heated electrospinning head for melting the polymer using a mechanical dosing device (dispenser). The operation of the polymer mechanical dispenser and the flow rate of the polymer supply, are controlled by computer software. Using a high-voltage source to generate an electric field, when the heated electrospinning head is positively charged, the formed polymeric fibres fly in the formed electric field and then are deposited on a grounded substrate. The heating head acts as a positively charged high-voltage electrode, and the base is grounded, thereby forming an electric field between them both, which moves the polymer melt.

An electric field is generated between the heating-melting head and the matrix-forming-base. Since the heating-melting head of the polymer filament must be connected to a high-voltage source at one of the poles where the polymer melt contacts with the heating element, with the temperature sensor and also with polymer dosing medium, these elements may be easily damaged due to the high-voltage. In the invention, the high voltage is separated from the power supply of the polymer heating-melting head, thus avoiding the undesired negative effect of the high voltage on the electrical parts of the forming device. A low voltage is supplied from the low-voltage source to the heating element of the heating-melting head and to means of measuring the head temperature.

The polymer is melted and conditioned after extrusion by an electric field, thus formed into micrometrically-sized fibres flying from the positively charged polymer melting-head towards the grounded base. The small volume of the heating head ensures a short storage time of the polymer melt in the head until the filaments are formed, thus avoiding thermal degradation of the polymer during melting. The polymer melt is bundled vertically from bottom to top in an electric field, thus avoiding unwanted fibre defects and a smoother electrospinning process.

The 3D-positioning module allows for controling the structural properties of the produced matrices (Layer <NUM>), such as the overall fibre shape, filament layout, etc., in the 2D and 3D dimensions, unlike conventional methods where the process is chaotic and uncontrolled. Fibrous matrices (Layer <NUM>) of polymeric materials made from a polymer melt have low cytotoxicity because no harmful and toxic solvents are used during production.

A porous, non-woven fibre micrometer filament polymer matrix is obtained, with a high filament-specific-surface area, that in the present invention is used for Layer <NUM>.

<FIG> presents a schematic diagram of a polymeric fibre matrix (Layer <NUM>) forming apparatus. The most preferred embodiments of the invention are described below with reference to this drawing. An apparatus is used to implement the method of forming polymeric fibre matrix (Layer <NUM>), comprising: a heating and melting head (<NUM>) of a polymer melt with a short path in the molten travel head in the molten state and at a high temperature; a polymer filament extruder (<NUM>); supplying a polymer filament (<NUM>); a polymer filament reel (<NUM>); a base for forming polymeric fibre matrices (<NUM>) (Layer <NUM>); a voltage source (<NUM>) comprising isolated high voltage supply and low voltage supply portions, wherein the high voltage portion is for supplying a high voltage for generating an electric field between the heating and melting head (<NUM>) of the polymer melt and the base (<NUM>); the voltage portion is for supplying voltage to the heating and melting head (<NUM>) of the polymer melt, heating and melting the polymer melt, and measuring the temperature of the head (<NUM>); a controller comprising of an ambient temperature control module and an ambient humidity control; a controller (<NUM>) for positioning of the heating and melting head (<NUM>) and the base (<NUM>) relative to each other to control the base of the polymeric fibre matrices (Layer <NUM>) on the y-axis and the heating and melting head (<NUM>) of the polymer melt on the x-z axes; a controlled climate chamber (<NUM>) in which the polymeric fibre matrices (Layer <NUM>) are formed.

At least one heating-melting head (<NUM>) of the polymer melt is housed inside the controlled climate chamber (<NUM>), which is a sealed chamber; a polymer filament extruder (<NUM>); supplying polymer filament (<NUM>); a polymer filament coil (<NUM>); the base of polymeric fibre matrices.

The operation of the polymeric-fibre-matrix-forming apparatus is controlled by conventional computer microprocessors. Control includes: controlling the power supply (<NUM>); controlling the basic operating environmental parameters by a controller comprising an ambient temperature control module for forming the polymeric fibre matrices and an ambient humidity control module; controlling the process of forming polymeric fibre matrices (Layer <NUM>) on the x-, y-, z- axes using the x, y, z-axis controller (<NUM>) used in conventional fused deposition modelling 3D-printers.

According to one example of the formation of the polymeric fibre matrix, the polymer filament (<NUM>) is dosed from the reel (<NUM>) into the heating-melting head (<NUM>) of the polymer melt by the filament extruder (<NUM>). The temperature of the polymer melt heating head (<NUM>) is controlled by a temperature controller which is part of the power supply (<NUM>). The heating element of the heating-melting head (<NUM>) is connected to the low-voltage circuit of the power supply (<NUM>). The melting head (<NUM>) is connected to the high voltage supply circuit of the power supply (<NUM>). The matrix forming base (<NUM>) on which the polymeric fibre matrix is formed is grounded. In a closed climate-controlled chamber (<NUM>), the ambient temperature is controlled by the temperature control module of the controller, and the humidity is controlled by the humidity control module of the controller. The positioning of the formed matrix in space is controlled by the x, y, z axis controller (<NUM>), controlling the position between the heating-melting head (<NUM>) and the base (<NUM>) in the space defined by the x, y, z axes, where x, y, z axes are the axes of the three-dimensional Cartesian coordinate system. The heating-melting head (<NUM>) is positioned in the space on the x- and z-axis by the controller (<NUM>), while the base (<NUM>) is positioned on the y-axis. The polymer melted in the heating-melting head (<NUM>) enters directly from the head into a high-voltage electric field formed between the heating-melting head (<NUM>) and the die-forming base (<NUM>). The formation of a polymer filament matrix with controlled characteristics is started by collecting the polymer melt fibres travelling to the surface of the substrate (<NUM>) in an electric field from the bottom upwards. The high voltage generated between the heating-melting head (<NUM>) and the base (<NUM>) creates an electric field where the voltage is in the range of <NUM> kV to <NUM> kV. The distance between the heating-melting head (<NUM>) and the base (<NUM>) can be varied between <NUM> and <NUM>.

A controller comprising temperature and humidity control modules with integrated corresponding sensors controls the temperature and humidity of the climate chamber (<NUM>). The controller modules perform the following functions: heating, cooling, humidifying, dehumidifying. Using a user interface of the controller comprising a data output device such as an LCD display and a data input device such as a keyboard, the controller sets the desired temperature and humidity to be maintained in the climate chamber (<NUM>). The controller monitors the current ambient conditions at a frequency of <NUM> and, accordingly, selects the combinations of temperature and humidity values suitable for forming the polymer fibre matrix in the controlled climate chamber (<NUM>). The controller also controls the polymer filament extruder (<NUM>), said control comprising controlling the polymer feed rate in the range of <NUM> to <NUM> / min. The control of the supply of polymer to the heating-melting head (<NUM>) of the polymer melt is performed manually or according to a data file used by the polymeric fibre matrix forming apparatus, which may be the same as the data file used in conventional fused deposition modelling 3D printers.

The voltage supplied by the high voltage portion of the power supply (<NUM>) is determined via a user interface of the controller that is part of the power supply (<NUM>), including a data output means such as an LCD display and a data input means such as a keyboard. The high-voltage selection range is <NUM> - <NUM> kV. The power supply (<NUM>) automatically maintains the set voltage level at a constant frequency of <NUM> by measuring the current voltage and selecting the power of the high voltage converter. Safety functions can be selected, for example, the voltage is switched-off by opening the door of the climate chamber (<NUM>) in the event of current surges, etc..

Depending on the operating parameters used, a microfibre matrix with a filament diameter of <NUM> ± <NUM> to <NUM> ± <NUM> and a surface pore size of <NUM> ± <NUM> to <NUM> ± <NUM> is formed as described.

In one embodiment, the polymer heating-melting head (<NUM>) is connected to a power supply (<NUM>), a <NUM> - <NUM> kV insulated high voltage portion. This is the voltage between the heating-melting head (<NUM>) and the matrix forming base (<NUM>). Depending on the polymer and its properties, the temperature of the heating-melting head (<NUM>) can be varied from <NUM> to <NUM>. The optimum processing temperature for a melt of a polymer, such as polycaprolactone (PCL), is <NUM>. The diameter of the polymer filament to the melting head (<NUM>) is <NUM> ± <NUM>.

In all embodiments, the heating-melting head (<NUM>) is given a positive charge and acts as a positive charge electrode. The polymeric fibre matrix is deposited on a negative charge electrode which is formed as a matrix deposition substrate (<NUM>).

The positioning of the heating-melting head (<NUM>) involves its control in the x-z axes at a speed of <NUM> to <NUM> / s. The diameter of the heating / melting head nozzle (<NUM>) can be changed from <NUM> to <NUM>. In order to form fibrous matrices of smaller diameter filaments, a heating-melting head with a smaller diameter is selected.

The distance from the heating-melting head (<NUM>) of the polymer filament to the base (<NUM>) for forming the polymeric fibre matrices can be varied from <NUM> to <NUM>, for example, in steps of <NUM>, <NUM>, <NUM>, and <NUM>. The polymer feed rate can be varied from <NUM> to <NUM> / min, for example in increments of <NUM> / min, <NUM> / min, and <NUM> / min. Depending on the distance between the heating-melting head (<NUM>) and the matrix forming base (<NUM>), the high-voltage values can be changed from <NUM> kV to <NUM> kV, for example, in steps of <NUM> kV, <NUM> kV, <NUM> kV, <NUM> kV, and <NUM> kV. For example, at a distance of <NUM> between the head (<NUM>) and the base (<NUM>), the maximum safe voltage is <NUM> kV.

The distance between the heating-melting head (<NUM>) and the base (<NUM>) substantially affects the structure of the fibrous matrix. For example, at a distance of up to <NUM> between the head (<NUM>) and the base (<NUM>), the fibres of the matrix fuse together because the molten PCL filament fails to cool before it hits already deposited fibres. For example, at a distance of <NUM> between the head (<NUM>) and the base (<NUM>), the PCL filaments already do not stick with each other.

Increasing the value of the high voltage between the heating-melting head (<NUM>) and the matrix forming base (<NUM>) decreases the diameter of the microfibre filaments of the matrix and the width of the surface pores of the matrix. At a temperature of <NUM> heating and melting head (<NUM>), a distance of <NUM> between the heating and melting head (<NUM>) and the base (<NUM>), at a PCL feed rate of <NUM> / min and changing the high voltage value, the diameter of the PCL matrix filaments as follows: for a voltage value of <NUM> kV, the filament diameter is <NUM> ± <NUM>; at a voltage of <NUM> kV, the filament diameter is <NUM> ± <NUM>; when the voltage value is <NUM> kV, the diameter of the wire is <NUM> ± <NUM>; when the voltage value is <NUM> kV, the wire diameter is <NUM> ± <NUM>.

Specifically for the present invention, the method stage and steps for producing Layer <NUM> are: <NUM> - fabrication of Layer <NUM> stage; <NUM>. <NUM> - filament extrusion; <NUM>. <NUM>-filament conditioning; <NUM>. <NUM> - fabrication of Layer <NUM> by 3D-fibre printing. Layer <NUM> is fabricated using a polymer filament made of either PCL, PLA, or PA6 under the following process conditions: voltage between electrodes of <NUM>. 0E+<NUM> - <NUM>. 0E+<NUM> V, filament feed rate <NUM>. 3E-<NUM> - <NUM>. 2E-<NUM>/s, hot end temperature <NUM>-<NUM>, and tip to collector distance <NUM>. 0E-<NUM> - <NUM>.

Production of Layer <NUM>. A liquid-solution electrospinning setup, depicted in <FIG>, is used to fabricate fibre samples. The fabrication setup consists of the following main parts: plastic syringe (<NUM>) filled with dissolved polymer (<NUM>), automatic pump (<NUM>) for extruding polymer from the syringe (<NUM>), metal needle (<NUM>) with blunt end (gauge <NUM>), vertical rotating metal collector (<NUM>), high voltage source (<NUM>), applied to metal needle (<NUM>) and rotating metal collector (<NUM>). The dissolved polymer is collected with a <NUM> syringe (<NUM>), which is then inserted into an automatic pump (<NUM>). A plastic tube (such as silicone) is connected to the syringe (<NUM>), the other end of which is attached to the needle (<NUM>). The needle (<NUM>) is connected to a high voltage source (<NUM>). The high voltage source (<NUM>) is also connected to a rotating collector (<NUM>), which is covered with layer one fiber matrix (<NUM>). Using an automatic pump (<NUM>), the silicone tube is filled with the polymer solution. Flow rates were adjusted accordingly for each layer and the high voltage source (<NUM>) is turned on as well as the collector (<NUM>) rotation (<NUM>). With controlled temperature, vacuum chamber (<NUM>) was used overnight for drying excess solvents from all electrospun membrane before proceeding further.

The method stage and steps for producing Layer <NUM> are: <NUM> - fabrication of Layer <NUM> stage; <NUM>. <NUM> - application of Layer <NUM> onto the surface of a collector; <NUM>. <NUM>-preparation of polymer solution for Layer <NUM>; <NUM>. <NUM> - fabrication of Layer <NUM> by solution electrospinning onto Layer <NUM> surface.

Layer <NUM> is fabricated of CA, PCL, PMMA, or PLA under the following conditions:.

Production of Layer <NUM>. A liquid-solution electrospinning setup, similar to that of Layer <NUM>, was used to fabricate Layer <NUM>, except that the collector is covered with the composite of Layer <NUM> and Layer <NUM>.

The method stage and steps for producing Layer <NUM> are: <NUM> - fabrication of Layer <NUM> stage; <NUM>. <NUM> - preparation of polymer solution for Layer <NUM>; <NUM>. <NUM> - fabrication of Layer <NUM> by solution electrospinning onto Layer <NUM> surface.

Layer <NUM> fabricated of CA, PCL, PA6, PMMA, PAN, or PLA under following conditions:.

Postprocessing. The method stage and steps for postprocessing are: <NUM>-Postprocessing and Storage stage; <NUM>. <NUM> - drying the fabricated multi-layered substrate; <NUM>. <NUM> - static charge removal; <NUM>. <NUM> - sterilizing the fabricated multi-layered substrate (optional); <NUM>. <NUM> - storage until sampling.

Particle retention results by the sampling filter. The presented invention results in aerosol particle collection filters having high particle collection efficiency, quantitatively described as higher than <NUM>% at the most penetrating particle size range (<NUM>).

The collection efficiency of several composite filters as a function of particle size is presented in <FIG>, as obtained with the nebulized NaCl aerosol.

Industrial applications of the sampling filter and production method. The practical applications of the manufactured filter disc involve installations in aerosol sampling devices in indoor, occupation, and ambient environments by the operators of aerosol particle sampling devices. The highest quantities of such sampling filters are consumed in frameworks of governmental air monitoring campaigns. However, the opportunity for controlling particle collection surface morphology and precursor polymer makes the key application of such sampling filters in scientific studies, namely in the development of new aerosol particle analysis techniques.

Claim 1:
A method of producing a nano/micro fibrous filter substrate for sampling aerosol particles (<NUM>) comprising at least three fibrous layers (Layer <NUM>, <NUM>, <NUM>), the method comprising at least:
• stage (<NUM>) of producing the first layer (Layer <NUM>) as a structural microfibrous support layer (<NUM>), comprising steps of
∘ (<NUM>.<NUM>) extruding a polymer filament,
∘ (<NUM>.<NUM>) conditioning the extruded filament,
∘ (<NUM>.<NUM>) 3D-printing the first layer from the conditioned filament;
• stage (<NUM>) of producing the second layer (Layer <NUM>) as a micro/nano mesofibrous binding layer (<NUM>), comprising steps of
∘ (<NUM>.<NUM>) applying the produced first layer (Layer <NUM>) to a collector,
∘ (<NUM>.<NUM>) providing a polymer solution for the second layer (Layer <NUM>),
∘ (<NUM>.<NUM>) producing the second layer (Layer <NUM>) by electrospinning said polymer solution on the surface of the first layer (Layer <NUM>);
• stage (<NUM>) of producing the third layer (Layer <NUM>) as the nanofibrous surface layer (<NUM>) for the collection of aerosol particles (<NUM>), comprising steps of
∘ (<NUM>.<NUM>) providing a polymer solution for the third layer (Layer <NUM>),
∘ (<NUM>.<NUM>) producing the third layer (Layer <NUM>) by electrospinning said polymer solution on the surface of the second layer (Layer <NUM>);
• stage (<NUM>) of postprocessing the substrate, comprising steps of
∘ (<NUM>.<NUM>) drying the fabricated substrate;
∘ (<NUM>.<NUM>) removing static charge from the fabricated substrate;
∘ optionally, (<NUM>.<NUM>) sterilizing the fabricated multi-layered substrate.