RU2153785C1 - Method of evaluation of shielding properties of radiation protective clothing - Google Patents

Abstract

FIELD: radiation protection. SUBSTANCE: method of evaluation of shielding properties of radiation protective clothing consists in measurement of value of decrease of intensity of electromagnetic radiation in fixed points of space under clothing and in computation of average arithmetic mean of shielding efficiency and index of its variation. Configuration of shielding shell of radiation protective clothing close to each chosen point of space under clothing is changed at random before each next measurement. EFFECT: increased accuracy, authenticity and stability of evaluation of protective properties of radiation protective clothing. 2 tbl

Description

 The invention relates to the field of monitoring the protective parameters of special clothing that protects people professionally associated with intense electromagnetic fields from microwave irradiation.

 Known methods for measuring the protective parameter of radiation protective clothing (RO) - shielding efficiency (EE) - a value that shows the degree of attenuation of the intensity of electromagnetic fields through the use of PO [1-3]. However, these methods implement the principles that are characteristic of working with quasistationary fields, and therefore they are not suitable for monitoring the effectiveness of shielding microwave radiation with special clothing.

 Known methods for measuring energy efficiency at radio frequency frequencies [4-6]. However, they are designed to control technical devices and engineering structures and, due to their specificity, cannot be used to assess the protective effectiveness of RO.

 The sources of scientific information [7-11] describe the methods used to assess the properties of PO. In all of them, EE is defined as the magnitude of the decrease in the intensity of microwave radiation at fixed points in the suit space due to the use of RO.

 As a prototype adopted the method [7], in which the measurement of EE is as follows. After appropriate adjustment of the measuring circuit, microwave radiation intensity sensors — sub-suit antenna probes (AZ) —are placed at selected points on a mannequin that models the human body both in shape and in electromagnetic parameters. Then, microwave irradiation is turned on and the first countdown of the generator power is performed. At the same time, the response values from each of the sensors are recorded. After dressing the RO sample on the mannequin of the test sample, the generator is turned on again, and by changing the power supplied to the irradiator, the initially recorded responses from each of the sensors are sequentially obtained, making secondary readings of the power value. The power supplied to the irradiator is adjusted by a calibrated attenuator calibrated in decibels. Therefore, the difference in the readings on the attenuator scale (with and without a dressed PO) is taken as an EE in that region of the PO where the corresponding AZ is placed. Despite the fact that such a procedure is called the measurement of EE by the authors of [6, 7], it is not such, since it allows one to only determine the magnitude of the decrease in the radiation intensity for the shape of the shielding sheath RO fixed for a particular observation. Studies [12] showed that even for the same point in the undersuit space, the amount of attenuation of the field intensity, determined in this way, is random and, depending on variations in the shape of the shell in the vicinity of the AZ, can vary by tens or hundreds of times. The physical reason for such changes lies in the laws of the distribution of electromagnetic field energy in the undersuit space, that is, in the dependence of the measured field intensity on the position of the AZ relative to the shielding. Therefore, this procedure makes it possible to assess the EE in this particular observation, but does not allow to obtain any objective characteristic of the protective properties provided in the process of using RO. To objectify intentions, it is necessary to repeat this procedure several times with various random configurations of the shielding, followed by statistical processing of the results. The number of repetitions (at least 10) is specified during the measurements, depending on the variability and the required (permissible) variance of the result.

Thus, the process of controlling the shielding properties of the RO in the prototype method consists of the following steps:
1. Calibration of the measuring circuit, allowing to measure the relative magnitude of the intensity of electromagnetic radiation (EMP), irradiating the mannequin.

 2. The level of microwave power supplied to the irradiator is recorded, and at the same time the responses of the AZ placed on the manikin are recorded.

 3. The studied RO is put on the mannequin and successively for each of the AZs it is determined how much the irradiation power should be changed compared to the initially fixed level, so that the response of the corresponding sensor matches the previously recorded one.

 4. The value of the EE at each point of the RO is determined by the results of two corresponding readings of the power supplied to the irradiator.

 The purpose of the invention is to improve the quality (accuracy, reliability, stability) of the evaluation of the protective properties of PO by reducing the influence of a random factor due to changes in the configuration of the shielding shell on the energy distribution of the electromagnetic field.

 This goal is achieved by repeatedly repeating the process described above, in which the relative magnitude of the reduction in radiation intensity is determined with random changes in the configuration of the shielding sheath RO.

The proposed method for evaluating the shielding properties of RO includes the following sequence of actions (signs):
1. Calibration of the measuring circuit is performed, which allows to measure the relative magnitude of the intensity of the EMP irradiating the mannequin.

 2. The level of microwave power supplied to the irradiator is recorded, and at the same time the responses of the AZ placed on the manikin are recorded.

 3. The studied RO is put on the mannequin and successively for each of the AZs it is determined how much the irradiation power should be changed compared to the initially fixed level, so that the response of the corresponding probe matches the previously recorded one.

 4. Repeatedly (at least 10 times) randomly changes the configuration of the shielding shell RO in the vicinity of each of the probes and each time the measurements are performed again according to paragraph 3.

 5. The energy efficiency at the corresponding point of the RO is determined by statistical processing of the data obtained during the implementation of paragraphs. 2-4, as the arithmetic mean value and an indicator of its variation.

 The ability to achieve the objectives of the invention is proved by the following example.

 Example.

 To illustrate the invention, the following are the results of evaluating the effectiveness of shielding of one of the laboratory models of PO, which is a jumpsuit made of cotton fabric with a weft and a thin copper wire woven into it.

 Studies on the installation simulating the prototype method used, which included the G4-123 generator, modulation antenna parameters meter PK7-18, P6-23A irradiator, mannequin, antenna probes, at a frequency of 4 GHz in different series of experiments, allowed us to obtain the following estimates of the average attenuation presented in table. 1.

 Each of the tab. 1 values of EE was determined as the average of 3 measurements with an unchanged shape of the shielding shell of the RO. Since the observed scatter in each series was less than 0.1 dB, the confidence interval was determined by the instrumental error and amounted to 0.4 dB. Obviously, the extremely low stability of these estimates, only with great reservations, allows them to be used to characterize the protective properties of the investigated clothing option.

 Studies of the same object at the same frequency of 4 GHz, carried out using the proposed method on the installation "Dipole", which implements one of the methods of spectral analysis, led to the results presented in table. 2.

 Randomly changing the configuration of the shielding in the vicinity of the AZ was carried out during the research manually by the operator.

 As can be seen, obtained by using the proposed method of assessment are much more stable and more accurately characterize the protective properties of PO. The inventive method allows to improve the quality of the evaluation of the controlled parameter and to more fully characterize the shielding properties of PO.

 The claimed invention satisfies the criterion of "novelty", since the introduction of feature 4 is proposed for the first time, that is, randomly changing the configuration of the shielding in the vicinity of each probe, simulating the actual conditions for changing shielding properties during use of clothing, which improves the quality of determining its protective properties.

 The claimed invention satisfies the criterion of "inventive step", since from the sources of information on methods for assessing the protective properties of POs, the need to change the configuration of the shielding shell of the PO to provide a more complete and high-quality assessment of its protective properties during operation under high radiation doses does not follow clearly. The need for multiple measurements of the attenuation of the intensity of EMR in the undersuit space with a randomly deformed shielding in the vicinity of the AZ to obtain an estimate of the EE of the RO was identified as a result of fairly detailed studies of the laws governing the formation of the field structure in the protected volume. In the known methods-analogues and prototype method, the indicated step is absent.

 Compliance with the criterion of "suitability for industrial use" is proved by the above test results. In the simplest version, randomly changing the configuration of the shielding shell RO can be carried out manually by the operator making the measurements. The rest of the claimed method is identical to the prototype method.

Literature
1. A. p. 845121 USSR, MKI ³ G01R 31/02. A method for evaluating the protective properties of a shielding kit / M.D. Stolyarov (USSR). - N 2963451 / 18-21; Claimed on 07/14/80; Publ. 07.07.81, Bull. Discoveries. Inventions - 1981, - N 25; - from. 215.

2. A.S. 1196782 USSR, MKI ⁴ G01R 31/02. The method of monitoring the protective properties of the shielding kit (its options) / V.V. Smekalov, M.D. Stolyarov (USSR). - N 3593889 / 29-12; claimed March 25, 83; Publ. 12/07/85, Bull. Discoveries. Inventions - 1985, - N 25; - p. 215.

3. Pat. 2012004 Russia, MKI ⁵ G01R 31/02. The method of monitoring the protective properties of the shielding kit / V.N. Kuznetsov, M.D. Stolyarov (USSR). - N 4927619/21; claimed March 19, 91; Publ. 04/30/94, Bull. Inventions - 1994, - N 8; - p.136.

4. A. p. 1636859 USSR, MKI ⁵ G12B 17/00, G12B17 / 02, G01R33 / 00. Correlation method for assessing the effectiveness of shielding structures / V.S. Polyakov, V.P. Tregubov (USSR). - N 4702800/21; claimed 05/06/89; Publ. 03/23/91, Bull. Discoveries. Inventions - 1991, N 11; - p. 153.

5. Pat. 5153524 USA, MKI ⁵ G01R 31/02, Testing Electromagnetic Shielding Effectiveness of Shielded Enclosures / Ray G. McCormick, St. Joseph (USA); N 330247; Stated March 29, 89; Publ. 10/06/92, NKI 324-627. // Inventions of the countries of the world, 1994, 85, N 09. - p. 33.

6. Pat. 5345243 USA, MKI ⁵ G01S 7/10, Continuous - Wave Reflection on Transmissometer with Targets / Curt A. Levis (USA); N 49630; Stated April 19, 93; Publ. 09/06/94, NKI 342-173. // Inventions of the countries of the world, 1995, 85, N 22. - p.32.

 7. Guy A.W., Chou C-K, McDougall J.A. Measurement of shielding effectiveness of microwave protective suits // IEEE Trans. on MTT. - 1987, vol. 35, - N 11, pp. 984-994.

 8. Chou C-K, Guy A.W., McDougall J.A. Shielding effectiveness of improved microwave protective suits // IEEE Trans. on MTT, 1987, vol. 35, N 11, pp. 995-1001.

 9. Minin B.A. Microwave and human security. M .: Sov. Radio, 1974.- 354 p.

 10. Chubarova Z.S. Methods for assessing the quality of special clothing. M .: Legprombytizdat, 1988 .-- 160 p.

 11. Marchenko B.S., Stepanova T.I., Denisova L.V. Personal protective equipment against electromagnetic fields. Electronic equipment. Ser. <Microwave Electronics>. - 1980. Issue. 12 (324). - p. 37-39.

 12. Osipovich V.K., Spiridonov K.A. Efficiency of shielding of radio emissions with protective clothing // Proc. doc. int. symposium <Protection against electromagnetic pollution>. June 21-25, 1993 - St. Petersburg: Leningrad. Forestry Academy. 1993 p. 98.2

Claims (1)

 A method for evaluating the shielding properties of radiation protective clothing, which consists in measuring the magnitude of the decrease in the intensity of electromagnetic radiation at fixed points in the suit space and calculating the arithmetic mean of the shielding efficiency and its variation index, characterized in that before each subsequent measurement, the configuration of the shielding shell of the radiation protective clothing in the vicinity is changed randomly each selected point in the undersuit space.

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