CZ36119U1 - Equipment for determining the transport properties of non-porous polymeric materials for gases - Google Patents

Description

CZ 36119 Ul

Device for determining the transport properties of non-porous polymer materials for gases

Field of technology

The technical solution concerns a device - a permeation cell of a specific design - for determining the transport properties of non-porous polymer materials in the form of membranes and films during the passage of gas in order to quickly evaluate the applicability of a given polymer material for the separation of gaseous mixtures.

Current state of the art

Gas transport in polymer membranes, or films, is described by the solubility-diffusion mechanism, where the permeability, i.e. permeability, of the gas through the membrane is determined by its diffusivity and solubility in the material of the polymer film. Knowledge of these quantities is essential when assessing the suitability of a given polymer membrane when using it for the separation of gas mixtures. Individual material transport parameters for a given gas are usually determined on the basis of independent measurements on different devices.

Permeability is usually determined from permeation experiments performed on a permeation cell. Standard permeation methods enable the determination of permeability and the evaluation of the gas diffusion coefficient in the membrane material from the time dependence of the increasing gas pressure in the closed space under the membrane. In the case of a permeation cell of classical construction, the dimensions of the closed internal volumes below and above the membrane are in the order of tens to hundreds of milliliters. However, information on gas sorption in the membrane material is not provided by these commonly used permeation procedures, and sorption is usually determined using sorption apparatus based on gravimetric, i.e. monitoring the increase in material weight after gas sorption, or more often using volumetric measurements, i.e. monitoring the drop in gas pressure in a closed calibrated volume caused by gas sorption in the material. Solubility values can also be obtained indirectly, by calculating from the measured permeability and diffusivity values from the relationship: Permeability (P) = Diffusivity (D) x Solubility (S). However, these values are usually burdened with a large error.

To date, no devices have been described that would enable the simultaneous determination of the transport properties, i.e. permeability, diffusivity and sorption, of non-porous polymer membranes during the passage of gas from a single measurement and thus easily and quickly obtain information about the mechanism of gas transport and the selectivity of the polymer membrane for a given gaseous mixture.

The essence of the technical solution

The above-mentioned shortcomings are largely eliminated by the device for determining the transport properties of non-porous polymer materials for gases, according to this technical solution. Its essence is that it contains a cylinder-shaped cell composed of a cell body with an internal cavity and a cell lid with an internal cavity, while a membrane-shaped polymeric material is placed near the cavities. The internal volume of the cavity above the membrane and below the membrane corresponds to the volume of the tested polymeric material, while the body of the cell is equipped with a pressure sensor and a capillary for gas removal from the lower volume of the cell, and the lid of the cell is equipped with another pressure sensor and another capillary for gas removal from the upper volume of the cell, and yet another capillary for gas supply from the gas reservoir with yet another pressure sensor. A pressure sensor, another pressure sensor, and yet another pressure sensor are connected to the control system.

The cavity in the body of the cell and the cavity in the lid of the cell preferably have a volume in the range of 100 to 2000 pl.

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A metal capillary and another metal capillary are connected to vacuum pumps in an advantageous embodiment.

The cell and the gas reservoir are preferably located in a thermostatic environment.

A/D converters can be placed between a pressure sensor, another pressure sensor, and yet another pressure sensor and the control system.

The essence of the presented technical solution is a device for fast and reliable determination of the transport properties of non-porous polymer membranes, i.e. permeability, diffusivity and sorption of a given gas in a non-porous membrane at the same time.

The device provides important parameters of polymeric thin-film materials for their effective application in the field of membrane separation of mixtures. Membrane materials with such determined parameters, thanks to the presented technical solution, can be effectively applied for the separation of various mixtures of gases and vapors, i.e. removing an unwanted component from a gas mixture or, conversely, enriching the mixture with a desirable component.

The subject of the presented technical solution is a device for very fast characterization of thin-film polymeric material, in the sense of its use for the separation of mixtures of gases and vapors. The device, according to the technical solution, includes a permeation cell in the shape of a cylinder with an internal cavity consisting of two parts, between which a thin layer of polymer material - a membrane - is inserted and sealed. The sealed membrane thus divides the inner cavity of the cylinder-shaped cell into two hermetically separated parts. The upper part of the cell of the device is equipped with a capillary for gas supply and a pressure sensor for sensing the gas pressure above the membrane, from the lower part of the cell comes a capillary for gas removal under the membrane, the pressure of which is also sensed by a pressure sensor. The essence of the technical solution is that the internal volumes of the cell are comparable to the volume of the tested material and thus it is possible to determine the solubility of the gas in the membrane material on the basis of the permeation measurement. Thanks to this design of the device, it is possible to determine with advantage three basic characteristics of the membrane, namely permeability, gas diffusion coefficient and gas sorption. The devices known so far allow only the permeability to be evaluated from the measurement, i.e. the gas flow and the gas diffusion coefficient in the membrane under the given conditions given by the pressure pl above the membrane, below the membrane p2 and the temperature T. However, the sorption measurement must be performed separately on another device.

In a preferred embodiment, the cell is constructed as a cylinder with an internal cavity with approximately equal volumes above and below the membrane, which are comparable to the volume of the tested membrane. With this arrangement, the amount of gas sorbed in the tested membrane during its transport through the membrane is comparable to the amount of gas above and below the membrane and can thus be determined. The internal volumes above and below the membrane are preferably in the range from 100 to 2000 pl.

In a preferred embodiment, the upper part of the cavity, i.e. the space above the membrane, and the bottom of the lower part of the cavity, i.e. the space below the membrane, are roughened to ensure sufficient gas mixing.

In an advantageous design, the cell is made of stainless steel AISI 304 and AISI 316 in pressure class PN 10.

In an advantageous embodiment, the device can be placed in a thermostated space, i.e. a box for measurements at constant temperatures.

Clarification of drawings

The device for determining the transport properties of non-porous polymer materials for gases according to this technical solution will be explained in more detail on a specific example of the design with the help of the attached Fig. 1, which shows a schematic drawing of the device - cells for determining the transport properties of non-porous polymeric membranes.

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An example of the implementation of a technical solution

A device was constructed - a cell for determining the transport properties of non-porous polymer membranes 2, which is schematically shown in Fig. 1. The cell in the shape of a cylinder consists of a cell body 1 with an internal cavity, where the tested membrane 2 with an effective diameter of 36.4 mm is placed - the effective area of the membrane A = 1.041 x 10-3 m ² and the lid 3 of the cell with an internal cavity, by means of which the membrane 2 is sealed via a sealing ring, which is not shown. The body 1 of the cell is equipped with a metal capillary 4 with a valve 5 for gas removal from the lower part, and a pressure sensor 6 for sensing the pressure under the membrane 2. The lid 3 of the cell is also equipped with another metal capillary 7 with another valve 8 for evacuating the inner cavity of the lid 3 of the cell and another pressure sensor 9 for sensing the gas pressure above the membrane 2. The gas is supplied to the upper volume VI of the cell above the membrane 2 by yet another metal capillary 10 through yet another valve 11 from the reservoir 12 with a volume of V0 equipped with yet another pressure sensor 13, into which gas is passed from the main gas reservoir 14 through the pressure regulator 15. The gas pressures in the volumes V0, VI and V2 are sensed by A/D converters 16 and recorded by the control system 17. The outputs from the cell volumes above and below the membrane 2 are equipped with vacuum pumps 18 for evacuating the internal volumes of the cell body 1 and the cell lid 3. The constant temperature of the cell is ensured by its placement in a thermostatic environment 19.

The function of the device according to the technical solution is as follows, see Fig.l. Before measuring the gas transport through the tested polymer material, the internal volumes VI, V2 of the body 1 and the lid 3 of the permeation cell with an inserted membrane 2 are properly evacuated by means of vacuum pumps 18. The gas reservoir 12 with a volume V0, which is an order of magnitude larger than the volume VI, is separated by yet another valve 11 from the upper closable volume VI of the lid 3 of the cell above the membrane 2 is filled with measured gas from the main reservoir 14 through the gas regulator 15 to the required pressure monitored by yet another pressure sensor 13. At time t = 0 this yet another valve 11 is quickly opened and closed again and the initial pressure is set. At the same time, the valve 5 also closes the volume V2 under the membrane 2, in which the gas pressure increases due to transport through the polymer membrane 2. During the actual experiment, the changing pressures p1 and p2 are measured over time in both closed volumes V1 above and V2 below the membrane 2 using a pressure sensor 6 and another pressure sensor 9, processed by A/D converters 16 and recorded by the control system 17. The transport process is ended when the pressures on both sides of the membrane 2 reach the same pressure value, which is measured by the pressure sensor 6 and another pressure sensor 9. From the time course of the pressures above and below the membrane 2 and from the knowledge of the thickness of the membrane 2, all the required transport parameters of the tested membrane 2 can be evaluated - permeability, diffusivity and sorption of the measured gas in the given polymer membrane 2.

Industrial applicability

Knowledge of transport quantities is essential when assessing the suitability of a given membrane when using it for the separation of gas mixtures. The device according to the presented technical solution ensures a quick assessment of the applicability of the given polymeric material for the separation of gaseous mixtures. An example of the application of a characterized membrane can be the removal of carbon dioxide to increase the concentration of methane in biogas, which is obtained during the processing of plant waste in biogas stations.

Claims (5)

PROTECTION CLAIMS 1. Device for determining the transport properties of non-porous polymer materials for gases, characterized by the fact that it contains a cylinder-shaped cell composed of a body (1) of a cell with an internal cavity and a lid (3) of a cell with an internal cavity, wherein the polymer material is placed near the cavities in the shape of a membrane (2) and the internal volume of the cavity above the membrane (2) and below the membrane (2) corresponds to the volume of the tested polymer material, while the body (1) of the cell is equipped with a pressure sensor (6) and a capillary (4) for gas removal from the lower of the volume V2 of the cell and the lid (3) of the cell is equipped with another pressure sensor (9) and another capillary (7) for the removal of gas from the upper volume of the VI cell and yet another capillary (10) for gas supply from the gas reservoir (12) with yet another by a pressure sensor (13), and a pressure sensor (6), another pressure sensor (9) and yet another pressure sensor (13) are connected to the control system (17). 2. Device according to claim 1, characterized in that the cavity in the body (1) of the cell and the cavity in the lid (3) of the cell has a volume in the range of 100 to 2000 pl. 3. Device according to claim 1 or 2, characterized in that the metal capillary (4) and another metal capillary (7) are connected to the vacuum pumps (18). 4. The device according to any one of claims 1 to 3, characterized in that the cell and the gas reservoir (12) are located in a thermostatic environment (19). 5. A device according to any one of claims 1 to 4, characterized in that A/D converters are placed between the pressure sensor (6), another pressure sensor (9) and yet another pressure sensor (13) and the control system (17).