SU783604A1 - Method of diagnosing object state by heat degree - Google Patents

Description

The invention relates to means ’monitoring the state of objects during operation by heating them and can be used in power plants to detect 5 and prevent accidents.

A known method of studying the properties of materials by acoustic emission arising from their heating G1]. 10

However, this method does not provide the ability to control the state of heated objects during their operation, since the intensity of their acoustic emission is practically insufficient for its measurement.

Also known is the closest to the proposed method for diagnosing 20 state of objects by their heating, which consists in the fact that during the operation of the object, acoustic emission from heated sections of the object is recorded and, according to its parameters, they judge the state of the object [21.

However, the performance in controlling extended sections of an object in this way is insufficient, since only local 30 overheating zones are recorded in an object containing a friction pair.

The purpose of the invention is to increase productivity in the control of extended sections of the object.

This is achieved by the fact that the latter are covered with layers of substances that intensify acoustic emission.

It is recommended that the composition of the substances be selected according to the permissible operating temperature in intensity, acoustic emission predominantly selenium up to 1500С, tin up to 232 ° С.

It is advisable to apply a layer of the substance in the form of a liquid, followed by drying, and use a compound based on ammonium carbonate dissolved in a gel of polyvinyl alcohol with a salt concentration of 5 to 10 g / l as a liquid.

The drawing shows a block diagram of a device for detecting acoustic emission from a controlled object.

The device contains a transducer 1 and 2 of acoustic emission into electrical signals located in section 3 of the controlled object with zone 4 overheating, section 3 is covered with a layer 5 of a substance that intensifies acoustic emission.

The device operates as follows,

During the operation of the object in its section 3, a zone 4 _ overheating occurs, which excites acoustic ³ emission of a part of layer 5 adjacent to the overheating zone,

As the substance of layer 5, it is selected for reasons of permissible operating temperature and maximum intensity of acoustic emission of selenium up to 150 ° C or tin up to 232 ° C,

For a temperature range from 60 to 115 * C, it is advisable to use a compound based on carbon dioxide, dissolved in a gel of polyvinyl alcohol with a salt concentration of from 5 to 10 g / l,

The layer of selenium and tin give practically good results with their thickness-JQ not from 0.05 to 0.15 mm

The compound is applied in liquid form, followed by drying at i-2 5 ° C.

A cadmium-zinc eutectic layer may also be used. 25

Coatings of selenium, tin and cadmium-zinc alloy can be used repeatedly. In relation to the specific operating conditions for the operation of the controlled objects, other coating compositions can be selected, including 30 such coatings that would simultaneously perform the functions of anticorrosion and would also prevent diffusion saturation of the base material with hydrogen and other gases, worsening the operating conditions of the process equipment in chemistry, energy, oil refining, etc.

Using the method of indicating 40 temperatures provides a simple and quick fixation of zones of local overheating of products, structures and structures that arise in the operation mode of various technological units and vehicles.

Claims (2)

The invention relates to means of monitoring the state of objects during operation by heating them and can be used in power plants for detecting and preventing accidents. There is a known method for studying the properties of materials by acoustic emission, which occurs during their heating with Tl. However, this method does not provide the possibility of monitoring the state of heated objects during their operation, since even the intensity of their acoustic emission is practically insufficient for its measurement. Also known is the closest to the proposed method of diagnosing the state of objects by heating them, which consists in the fact that during the operation of an object acoustic emissions are recorded from heated participants of the object and its parameters judge the state of object 2. However, the performance at monitoring There are insufficient areas of an object in this way, since they only register local overheating zones in an object containing a pair of friction. The purpose of the invention is to increase productivity while controlling extended areas of an object. This is achieved by the fact that the latter are covered with layers of substances, the intensity (;) of their akuaticheskoy essssnya. It is recommended to choose the composition of substances according to the permissible operating temperature in intensiveness, acoustic emission predominantly selenium up to 1500s, tin up to 23,200. It is advisable to apply a layer of the substance as a liquid with subsequent drying, and use liquid carbonate based on polyvinyl gel alcohol with a salt concentration of 5 to 10 g / l. The drawing shows a block diagram of a device for detecting acoustic emission from a test object. The device contains a transducer 1 and 2 of acoustic emission into electrical signals located in section 3 of the object under test with overheating zone 4, section 3 is covered with a layer 3 and is susceptible to acoustic emission. The device functions as follows 1HNM, During operation of the object, section 3 arises overheating zone 4, which excites acoustic emission of a part of layer 5 adjacent to the overheating zone. As a substance of layer 5, choose procuoT due to considerations of permissible operating temperature and maximum intensity of carrying acoustic emission selenium to or tin up to 232 ° C. For a temperature range from 60 to, it is advisable to use a compound based on ammonium carbonate dissolved in a gel of polyvinyl alcohol with salt concentration from 5 to 10 g / l. A layer of selenium and tin give practically good results when their thicknesses are not from 0.05 to 0.15 mm. The compound is applied in a liquid form, followed by drying at i-25 ° C. You can also use a layer of cadmium-zinc eutectic composition. Selenium, tin and cadmium-zinc alloys can be reused many times. In relation to the specific operating conditions of the controlled objects, other coating compositions can be selected, including such coatings that would simultaneously perform anti-corrosion functions as well as prevent diffusion saturation of the base material with hydrogen and other gases, worsening the operating conditions. technological equipment in energy, power engineering, oil refining, etc. Using the temperature indication method ensures fast and fast fixation of local heating of products 3Oij, structures and structures arising in the mode of operation of various technological units and vehicles. Claim 1, a method for diagnosing the state of objects by heating them, concludes that during the operation of an object, acoustic emission from heated areas of the object and PS is recorded, its parameters judge the state of the object, characterized in that control of extended areas of objects, the latter are covered with layers of substances that intensify acoustic emission, 2. A method for diagnosing the condition of objects according to claim 1, characterized in that the composition of the substances is chosen by the allowable working temperature and intensity of acoustic emission, the advantages of salts up to, tin 2320s, 3 1, that is, that the layer of the substance is applied in the form of a liquid, followed by drying, and a compound based on ammonium carbonate dissolved in a polyvinyl alcohol gel with a solc concentration of 5 to 10 g / l Sources of information taken into account in the examination 1, Sinnikov V.L., et al. Acoustic emission, M., Standards Publishing House, 1976, p. 152. 2, USSR Author's Certificate No. 116847 G 01 K 11/22, 1958 (prototype).