CS217148B1 - A method for determining the properties of solid, especially textile, absorbent materials in dynamic interaction with a liquid - Google Patents

Abstract

The invention concerns the testing of textile materials, especially dressing materials, for their absorbency and suction power. The absorbent material can be at least partially soaked with a liquid containing a radioactive nuclide and then the distribution of radioactive nuclides in it is determined by measuring the value of the response magnitude of the radioactive capture with both a surface probe and a hollow probe and the pair of thus measured values of the magnitudes of the radioactive responses, characterizing the material under test, is compared with the values of the reference material.

Description

(54) Method for determining the properties of solid, especially textile absorbent materials during dynamic interaction with a liquid

The invention deals with testing textile materials, especially dressing materials, for their absorbency and suction power.

The absorbent material can be at least partially soaked with a liquid containing a radioactive nuclide and then the distribution of radioactive nuclides in it is determined by measuring the value of the response magnitude of radioactive capture with both a surface probe and a hollow probe, and the pair of thus measured values of the magnitudes of radioactive responses, characterizing the material under examination, is compared with the values of the reference material.

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The invention relates to a method for determining the properties of solid, especially textile absorbent materials during dynamic interaction with a liquid.

For the study of textile absorbent materials, especially dressing materials, there is still no suitable test analytical method that would monitor the properties of these materials during their dynamic interaction with a liquid, i.e. liquid absorption, in connection with the type and composition, method of reinforcement and treatment of the material used. It is therefore difficult, if not impossible, to objectively characterize individual types of absorbent materials, compare them with each other and prepare or select materials with optimal properties.»

The absorbency of textile materials is still determined not by an analytical method, but by a weighing method, which indicates the amount of liquid absorbed by a given amount of material over a specified period of time. Although a weighing method is known, which, when testing dressing materials, cleverly imitates the conditions manifested during the application of the dressing material to a bleeding wound, it must be stated that the purpose of this known weighing method is to determine whether the tested dressing material is absorbent and whether this absorbency is also manifested during the practical application of the dressing material) and it has succeeded in this, while other known weighing methods are often unreliable in this respect. The known weighing method, which consists in constantly feeding liquid into the examined textile in an amount corresponding to the amount absorbed, does not give an accurate answer to the question of what happens inside the dressing material during its absorption by the liquid, and this is its disadvantage. It is true that, by using a colored test liquid, it is possible to visually determine the path along which the liquid has progressed during absorption when the dressing material is divided into several layers after the test, but this visual observation is not sufficiently objective for study purposes, although it is useful for practical purposes. Therefore, there has been an increasingly urgent need to propose an analytical method which, in combination with the well-known weighing method just mentioned, would enable an objective evaluation of textile absorbent materials when assessing the suitability of the examined textiles for dressing, surgical and medical material meeting the requirements of medical therapy.

This need is met and the above-mentioned disadvantage is eliminated by the method of determining the properties of solid, especially textile absorbent materials during dynamic interaction with a liquid, and its essence, according to the invention, lies in the fact that the absorbent material can be at least partially soaked with a liquid containing a radioactive nuclide and then the distribution of radioactive nuclides is determined in it by measuring the value of the response magnitude of radioactive capture with both a flat probe and a hollow probe, and the pair of thus measured values of the magnitudes of radioactive responses, characterizing the absorbent material under investigation, is compared with the values of the reference, i.e. suitably selected standard material. For the absorbent material under investigation, the so-called characteristic number of the distribution of radioactive nuclides is determined, i.e. difference between the values of the response magnitude of radioactive capture, measured by a hollow probe for the standard material and the investigated absorbent material and corresponding to the measured value of the response magnitude of the surface probe), it is possible, however, to proceed in the opposite way when determining the characteristic number of the distribution of radioactive nuclides:

the difference between the values measured by the surface probe for the standard material and the absorbent material under investigation and the corresponding measured value of the response magnitude of the hollow probe is determined.

In the method according to the invention, the difference between the characteristic number of the distribution of the radioactive nuclide in the material under investigation, partially soaked with liquid, and the characteristic number of the distribution of the radioactive nuclide in the material under investigation, soaked in the entire volume with liquid, is also determined. The value of the magnitude of the response of the radioactive capture can be measured with a hollow probe on layers taken from the thickness of the material under investigation.

It follows from the above that the method according to the invention consists in determining the distribution of radioactive nuclides in the material under investigation by measuring the capture of emitted radiation using a surface probe and subsequent measurement using a hollow probe. The radioactive nuclide is introduced into the material under investigation by dissolving or dispersing it in the test liquid, which is then absorbed by the material under investigation. For example, the textile is placed on the suction outlet from a storage container, in which the level of the test liquid is constantly maintained at the level of the suction outlet

217 148 by dripping liquid, e.g. from a burette.

Measurement with an area probe provides information about the areal distribution of a radioactive nuclide in the material under investigation. This measurement usually involves measuring the radioactive response of an area sample of standard size and placed at a suitable distance from the probe.

Measurement with a hollow probe gives the actual magnitude of the response of the emitted radiation regardless of the areal or spatial distribution of the radioactive nuclide in the material or the spatial arrangement of the measured strut and the probe. Measurement with a hollow probe, whose usable space is limited, usually assumes the division of the examined material into smaller parts and the gradual accumulation of the response values of the separately measured parts inserted into the cavity of the usable space of the hollow probe.

The pair of both values of the magnitudes of the radioactive responses measured by the surface probe and the hollow probe is characteristic of the type of material under investigation. Therefore, one type of material with certain properties can be chosen as the standard material. For example, for a group of materials consisting of pure cotton, pure viscose staple, a mixture of cotton and viscose and these materials reinforced with a binder, viscose staple reinforced with a binder is chosen as the reference or standard material.

The selected calibration dependence of the pair of responses of the surface probe and the hollow probe for a variable concentration of the radioactive nuclide in the test liquid is decisive for determining the characteristic number of the material, which is given by the difference between the responses detected by the hollow probe for the standard material and the material under investigation and corresponding to one measured value of the surface probe.

The absorption of the test liquid into the material under investigation is measured in two ways. In the first method, expressing the so-called relative characteristic number of the distribution of the radioactive nuclide in the material, only such an amount of test liquid is absorbed into the material under investigation that the material is only partially wetted; the liquid is absorbed mainly into the area, which in the thickness of the material under investigation can be located at different heights, most often in the contact surface part, but sometimes also in the inner part of the material thickness, while the remaining part of the material thickness remains unabsorbed. The amount of absorbed liquid varies depending on the type of material mainly in the range from 17.5 ml to 26.0 ml. In the second method, expressing the so-called absolute characteristic number of the distribution of the radioactive nuclide in the material, the test liquid is absorbed into the entire volume of the material under investigation in an amount corresponding to the absorbent properties of the respective material and usually ranging from 28.0 ml to 42.0 ml. The amount of absorbed liquid for both the absolute and relative characteristic numbers refer to samples of the material under investigation weighing around 7 g. For both of these methods of absorbing the test liquid into the material under investigation, a corresponding characteristic number can be found that describes the monitored properties of this material. The difference between the relative characteristic number and the corresponding absolute characteristic number determines the total characteristic number that best determines the monitored properties of the absorbent materials under investigation and which is the desired resulting value. Relative characteristic numbers are usually larger than absolute characteristic numbers for various types of textile materials. The relative characteristic number of the distribution of the radioactive nuclide represents the largest possible dispersion of the radioactive nuclide in the minimum thick layer of the wetted material under investigation. The absolute characteristic number of the distribution of the radioactive nuclide represents the simultaneous accumulation of the distribution of the radioactive nuclide both over the area and into the thickness of the material under investigation. However, the thickness distribution reduces the effect of the previously created area distribution.

As already mentioned, the total characteristic number of the distribution of a radioactive nuclide is the desired resulting value that best describes the desired property of the material under investigation, i.e. its behavior during dynamic interaction with a liquid. This property, and thus the total characteristic number, are influenced in various ways by the composition, type and treatment of the material, as well as the nature of the interweaving of the material, i.e. whether it is woven or non-woven.

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In addition to the relative, absolute and total characteristic number of the distribution of the radioactive nuclide in the material, determined by the above procedure, it may be useful to determine only the absolute characteristic thin layers, which either form the material under investigation or are taken in sufficient number from the thickness of this material under investigation. The individual layers, taken gradually from the lower contact layer towards the outer layer of the material under investigation, have different, continuously changing absolute characteristic numbers when compared with each other, for example if the protein albumin is labeled with a radioactive nuclide, the distribution of which in the textile is measured. The absolute characteristic numbers of these individual layers are, with regard to both the size of these numbers for individual layers and the size of these numbers for layers of the same order, dependent on the type and/or composition and/or treatment of the textiles.

The relative, absolute or total characteristic numbers thus determined, or the characteristic numbers of individual layers in the absolute overall distribution, can be used for various materials for the expected determination of the suitability of the given material for practical applications or for the preparation of a material with suitable utility properties, e.g. by a combination of influencing aspects, which are in particular the type of fibers, the mixture ratio of fibers, the method of fiber connection. It is expected that this method will be used for monitoring changes in the structure of the above materials influenced, e.g. by thermal or chemical energy, high-energy ionizing radiation, ultrasound or the like, and thus determine materials with suitable utility properties.

Example.

When determining the characteristic numbers of textile materials by measuring the distribution of the radioactive nuclide in the test liquid, four types of material were used, namely pure cotton, pure viscose, a mixture of cotton and viscose and viscose staple bonded with a latex binder. The area of the examined samples was 10 x 10 cm and the weight was 7.0 - 0.5 g. - The test liquid was horse serum diluted with isotonic solution in a ratio of 3.75 » 1.25 parts by volume, in which the radioactive nuclide ¹² ^J in the form of potassium iodide of known activity was dissolved. The test liquid was sucked into the individual examined samples by placing the sample on the suction mouth from a storage container, in which the level of the test liquid was constantly maintained at the level of the suction mouth by dripping from a burette.

The measurement results of the individual materials tested and the corresponding amount of absorbed liquid are shown in the table »

Type of distribution of the nuclide: I-.....— + Monitored parameter» -.Π 1 1 ......... III e·............ ....... Type of fiber material under investigation cotton viscose cotton/viscose blend 60/40 viscose + BRNON binder (20%) Absolute A 42.0 42.0 35.0 28.5 B 6.2 9.5 8.7 ........ 14.3......... Relative A 25.5 26.0 21.5 17.5 B 18.0 14.3 20.7 12.2 Total B 11.8 4.8 12.0 - 2.1

A « amount of test liquid sucked in ml,

B and the corresponding characteristic number, i.e. absolute, relative, total

Claims (5)

SUBJECT OF THE INVENTION Method for determining the properties of solid, in particular textile absorbent materials, in danymiocal interaction with a liquid, characterized in that the absorbent material can be at least partially soaked in a liquid containing radioactive scavenging and then detecting the distribution of radioactive nuclides by measuring the magnitude of as well as the hollow probe and a pair of measured values of the radioactive response magnitudes characterizing the examined material are compared with the values of the reference, the so-called standard material. 2. Method according to claim 1, characterized in that the so-called absorbent material distribution is characterized by the so-called characteristic number of the radioactive nuclide distribution, i.e. the difference between the radioactivity response value measured by the hollow probe of the standard material and the absorbent material and correspondingly measured. the response value of the area probe. 3. Method according to claim 1, characterized in that the absorbent material to be examined is determined by the so-called characteristic characteristic of the distribution of radioactive nuclides, i.e. the difference between the radioactive capture response values measured by the probe and the corresponding hollow response value. probes. 4. A method according to claim 1, characterized in that the difference between the radioactive nuclide distribution characteristic number of the material partially soaked in liquid and the radioactive nuclide distribution number of the material soaked in its liquid volume is determined. Method according to claim 1, characterized in that the value of the radioactive capture response is measured by a hollow probe on layers taken from the thickness of the material to be examined.