UA69539A - Method of accelerated aging tests of polymer workpieces - Google Patents

Abstract

The proposed method of accelerated aging tests of polymer workpieces consists in holding the samples of the workpiece material at temperatures within the range from a minimal temperature that is possible in the use of the workpieces to a maximal temperature when the physical and chemical properties of the material begin to change and determining the material characteristics that are used for estimating the state of the workpieces in storage and determining the allowable conditions and the period of the storage. For testing, at least two groups of the workpieces are selected. The samples of one of the groups are tested for determining the sensitivity of the material characteristics to parameters that characterize the storage conditions and the stability of these characteristics in storage. The samples of the other groups are held within the period that is equivalent to the storage period, at the minimal temperature that is possible in the use of the workpieces if the workpieces are made of material with increased activation energy or at the minimal temperature when the physical and chemical properties of the material begin to change if the workpieces are made of material with decreased activation energy. Than these samples are held at a normal temperature and tested according to the test procedure provided for the samples of the first group.

Description

Description of the invention

The invention relates to testing equipment, namely to methods of accelerated aging tests of 2 products containing polymeric explosive materials, which may change their properties (characteristics) during long-term storage (operation) under the influence of temperature. Such products are, for example, artillery and aviation ammunition, projectiles, small arms bullets, solid fuel rocket engines (RDTP), etc. ware.

Explosive products, as a rule, are designed and manufactured with a specified warranty period of 70 years of operation. After the expiration of the established warranty period for such products, the task may be to assess the possibility of establishing (extending) an additional period of safe storage and operation, or to dispose of products with past warranty periods. Utilization of explosive products can be carried out both by their destruction (for example, detonation or burning), and by their processing with the subsequent production of new products with different material properties (for example, 72 processing of solid rocket fuel into explosive materials for use in the mining industry).

However, both for the first and for the second method of disposal of products, it is necessary to determine possible changes in the properties of explosive materials when establishing an additional period of storage of products before their disposal or during further operation.

There are well-known methods of accelerated tests of RDTS and their storage charges, which are based on the principle of temperature-time equivalence to ensure the conditions for natural and accelerated aging of the product materials (Construktion and development of RDTT. Edited by A.M. Vinitsky, Moscow, Mashinostroenie, 1982. Section 15.3

Assessment of the warranty period of RDTT storage, p. 214-222). For such methods of research, there is a practice of selecting for testing several road accidents from batches stored under normal operating conditions. In some cases, this is preceded by a period of additional accelerated storage in moderately harsh conditions or at a temperature higher than the maximum operating temperature of the products. A similar method of research followed by fire tests of road accidents with positive test results allows to guarantee the reliable functioning of the remaining products (see ibid., p. 221).

The disadvantage of the method is that when implementing the mentioned research method, the possibility of fuel processing during the disposal of road accidents is excluded, as it will be used during fire tests. at

The method of accelerated testing of polymer materials for aging according to the author's certificate is the closest in technical essence to the proposed invention and chosen in this connection as its co-prototype

USSR for 1985 Mo1133507 (application Mo3402112/25-28 dated February 16, 1982, class IPC-SO1 M 17/00). The testing method o includes exposure of material samples for a given time in the temperature range from the maximum operating (storage) temperature to the minimum temperature of the beginning of physico-chemical transformations 3o (phase, structural or chemical transformation) in the materials of the product sample, and then determination of ee, properties of materials, according to which the condition of products during storage is evaluated. This method with sufficient accuracy while simultaneously reducing the time of tests allows to draw a conclusion about the handling of materials in conditions of long-term operation or during storage based on the results of research. "

The disadvantage of the prototype is that the implementation of the specified method of testing products, which are supposed to be disposed of in order to obtain new materials with defined properties, does not allow obtaining more reliable information about changes or preservation of the characteristics of materials after accelerated aging. This is due to the fact that the tests are carried out at temperatures close to the temperatures of the beginning of physical and chemical transformations in the product materials, which for polymer materials reach up to 1007 and more. In real conditions of storage and operation for products with explosive materials, the maximum temperature can be in the range from 357C to (70-80)"0. b The invention is based on the task of improving the method of accelerated tests of polymer (se) materials of products for aging, in which increasing the probability of research results when determining the additional term of storage of products before their disposal (or when assessing the possibility of further exploitation of products) is ensured by conducting tests of pre-made groups of samples of 20 materials from products according to certain modes, which are assigned depending on the energy characteristics of the materials and the required the shelf life of products, which allows the process of accelerated tests to be brought closer to the process of natural storage of products.

The task is solved by the fact that according to the method of accelerated testing of polymer materials, which includes exposure of samples from product materials in the temperature range from the maximum operating temperature to the minimum temperature of the beginning of physicochemical transformations in the sample materials. during the time set depending on the energy of activation of the materials of the product and the temperature-temporal equivalence of ensuring the conditions of natural and accelerated aging, and determining the properties of the materials of the samples, according to which the condition of the products during the storage process is evaluated, no less than two groups of the products are previously selected and made material samples, then one group of samples is subjected to testing to determine 60 sensitivity and stability of material characteristics to possible conditions of additional storage, and other groups of samples are kept at accelerated aging temperatures for a time equivalent to the required storage period, while material samples with a higher activation energy are kept at a temperature close to the maximum temperature of operation, and samples of materials with a lower activation energy are kept at a temperature below the minimum temperature of the beginning of physicochemical transformations in the materials of the samples, after which these groups of samples are kept and normal temperatures and are subjected to the same testing as the first group of samples, and the obtained test results of the sample groups are compared with each other and the properties of the materials are determined based on it and the storage conditions of the products are assigned before their use (before disposal or during further operation).

Other distinctive features of the invention are that: - samples of materials from products are made and tested in an amount equal to at least two samples for each test to determine the characteristics of materials under possible conditions of additional storage; - accelerated aging of groups of samples is carried out at several temperatures, differing from each other by (5-10376. 70) To prove the cause-and-effect relationship between the set of essential features of the claimed invention and the technical result, the following data are provided.

Preliminary selection and production of groups of product material samples, and then testing of one group of material samples to determine the properties of the materials, allows you to determine the properties of the materials for the time being, after a long period of operation or storage of the products in 7/5 natural conditions, based on the test results. Exposure of the second group of product material samples at accelerated aging temperatures for a time equivalent to the required additional storage period allows, after testing similar to that of the first group of material samples, to obtain information about possible changes or preservation of material properties after accelerated aging.

Testing of product materials that have a sufficiently higher activation energy at a temperature close to 2o of the maximum operating temperature of products, as well as testing of product materials that have a sufficiently low activation energy at a temperature below the minimum temperature of the beginning of physicochemical transformations in the materials of product samples , allows you to prevent the removal of negative phenomena from the aging process of materials, which cannot be present in the conditions of natural storage of products.

The production and testing of samples in the amount of two or more for each test to determine the characteristics of the materials allows to increase the reliability of the experiment for testing the materials of the product. "

Accelerated aging of groups of material samples at several temperatures (from the range of thermal aging temperatures) that differ by (5-10)"С, as well as exposure of samples at certain temperatures depending on the activation energy of the materials, approximates the conditions of accelerated Ge from tests to storage of products in natural conditions.

The method is implemented as follows. at

In advance, samples of explosive materials, such as solid rocket fuel or ammunition charges, are taken and made from products that are supposed to be stored for some time after the expiration of the established warranty period and then disposed of. Samples of the products are made in the amount necessary for me) c5 testing and for accelerated tests by thermal aging. Depending on the type of test, to determine the sensitivity and stability of material characteristics to possible storage conditions, fuel samples (charge) are made in the form of tablets, shavings, columns, blades, etc. Work on testing material samples is carried out according to special methods that determine the conditions, procedure, safety measures, test regimes, processing and analysis of research results. Characteristics of materials are determined, for example, by "tests: sensitivity to impact, friction and explosion propagation, thermal stability, speed of burning in open air or in a confined space, physical and mechanical characteristics (tensile and compressive strength). Other parameters can be selected as tests to determine the characteristics of materials. One is subjected to testing;" from manufactured groups of samples of materials from products.

Other groups of material samples (for example, the second and third groups) are kept at accelerated aging temperatures for a time equivalent to the required additional storage period. Test temperatures

Ge" is prescribed in the range between the maximum operating (storage) temperatures and those temperatures at which the identity of the flow of physico-chemical processes in the sample materials is ensured at and, natural and accelerated operating temperatures of the products. Such temperatures can be, for example, the minimum temperature of the beginning of phase, structural or chemical transformation in the materials of the product. 5. The duration of the sample tests is determined taking into account the expected storage conditions of the products and the energy characteristics (activation energy) of the product materials. For polymeric materials, the activation energy (value,

Ge) which determines the rate of chemical reaction in the material at a given temperature) is in the range of 15000-3000Ocal/mol and more.

In order to bring the test conditions closer to the natural storage conditions of products, samples of materials with a higher value of activation energy are kept at a lower temperature of thermal aging, and samples of materials with a lower value of activation energy are kept at a higher temperature of thermal aging.

P It should be noted that a specific polymer material can have both one value of activation energy and several values, for example, according to thermal decomposition and material strength.

After the thermal aging is completed, the material samples are subjected to the same testing and under the same conditions as the first group of samples that were not tested at accelerated temperatures, the test results are compared for the sample groups, and the material properties are determined based on them, and the storage conditions of the products are assigned before disposal.

It should be noted that this method of accelerated testing of polymer materials of products for aging can also be used when assessing the possibility of extending the service life of the remaining products for further operation (beyond the previously established warranty period). At the same time, products from which samples of materials for testing and accelerated tests were selected and made must be disposed of in the future.

To prove the possibility of industrial use of the invention, the following example of its use is given.

Example. It is necessary to evaluate the possibility of additional safe storage of products with a warranty period of service (operation) that is passing (or has already passed). Products are expected to be disposed of within the next 5 years after the established service life. The average (equivalent) storage temperature is 20°C, and the maximum operating temperature is 507°C.

Choose the temperature of thermal aging of samples of product materials above the maximum temperature / about operation. The test temperatures are set so that during the aging process in the materials of the product does not take place, which is not characteristic of the processes that occur in the materials during the operation of the products in natural conditions. For the product material in question, this temperature can be equal to, for example, 707С (343ЗК).

Calculation of the duration of accelerated aging tests at test temperatures equivalent to simulating an additional 5 years of product storage (operation) is carried out according to the formula:

E(Te Te tre VI tue pr/'e

De tro Taro duration (day) and temperature (K) in accelerated tests, respectively;

Te» Te 7 duration (days) and temperature (K) of operation (storage) in natural conditions, respectively; Er. the base of natural logarithms is equal to 2.718...;

E is the universal gas constant, equal to 1.987 cal/mol degrees;

E is the activation energy of the tested material of the product, equal to 20,000 and 25,000 cal/mol in this example.

The specified formula is reduced to a form convenient for calculating the duration of thermal aging, and which was used when calculating the time of accelerated tests of polymer materials according to the test method specified in the author's certificate Mo1133507 (prototype). "

The duration of accelerated tests of material samples in the general case for simulating 5 years (1825 days) of additional storage depending on the activation energy of the materials is given in the table. The temperature range of accelerated aging is taken as equal to 507C (323K) to 70"7C (343K). F

Tv" doba E, salimot tur doba, at that so vo |v5 (vo vv (t yu

M is jealous F (Se)

It can be seen from the table that when samples of materials with a higher activation energy (25,000 cal/mol) are kept at temperatures (50-553"C, the duration of thermal aging will be from 33.8 to 18.7 days. When samples of materials with a lower activation energy (2,000Ocal) are kept /mol) at temperatures (65-70)"C, the duration of thermal aging will be from 18.8 to 12.2 days. "20 The above-described technological process of conducting tests and the presented set of distinctive features 73 of this invention allows: - to increase the probability of test results when determining the additional period of storage of products before their disposal; - to carry out an assessment when determining the possibility of additional exploitation of products after the expiration of the established warranty periods; b - to ensure the rational use of products remaining after the production of samples of materials from products for testing, thanks to their further utilization for obtaining new products with other ise) properties of materials. 1 at 70

Claims (3)

Formula of the invention 3e) 1. The method of accelerated tests of polymer materials of products for aging, which includes exposure of samples from product materials in the temperature range from the maximum operating temperature to the minimum temperature of the beginning of physical and chemical transformations in the sample materials during the time set depending on the activation energy of the product materials and temperature -temporary equivalence of natural and accelerated aging conditions, and determination of the material properties of the samples used to assess the condition of the products during the storage process, which differs in that at least two groups of material samples are first selected and made from the products, then one group of samples are subjected to testing to determine the sensitivity and stability of material characteristics to possible conditions of additional storage, and other groups of samples are kept at accelerated aging temperatures for a time equivalent to the required storage period, while samples of materials with more with the highest activation energy are kept at a temperature close to the maximum operating temperature, and samples of materials with a lower activation energy are kept at a temperature below the minimum temperature of the beginning of physicochemical transformations in the sample materials, after which these groups of samples are kept at normal temperatures and subjected to the same testing , as well as the first group of samples, and then, based on the results of testing groups of samples, determine the properties of the materials and assign the storage conditions of the products before their use. 2. The test method according to claim 1, which differs in that samples of product materials are made and tested in an amount equal to at least two samples for each test to determine the characteristics of materials under possible conditions of additional storage. 3. The test method according to claims 1, 2, which differs in that the accelerated aging of groups of samples is carried out at several temperatures that differ from each other by 5-1070. Official bulletin "Industrial Property". Book 1 "Inventions, useful models, topographies of integrated microcircuits", 2004, M 9, 15.09.2004. State Department of Intellectual Property of the Ministry of Education and Science of Ukraine. « (o) (ze) iv) (o) (Se) - with . and? (o) se) 1 (95) 3e) 60 b5