RU199096U1 - DEVICE FOR RESEARCHING THE CAVITATION STRENGTH OF MATERIALS - Google Patents

Abstract

The utility model relates to the field of testing equipment, machines and mechanisms, namely, devices for studying the intensity of erosional destruction of structural materials under cavitation conditions. The technical result from the use of the utility model is to increase the reliability of the research results. The device, as well as the prototype, includes a generator of electrical oscillations of ultrasonic frequency and an ultrasonic oscillatory system with a concentrator of mechanical vibrations, a working container with liquid and placed in it, a holder with a sample of material under study and a concentrator of mechanical vibrations, unlike the prototype, the working container is made with the ability hermetically sealed, equipped in the upper part with a neck for filling with liquid and a drain valve for draining it, connected through a non-return valve to the compressor, equipped with a heater for the test sample, a liquid cooler and a thermostat. 2 wp f-ly, 1 dwg

Description

The utility model relates to the means of testing equipment, machines and mechanisms, namely, to the stands for studying the intensity of erosional destruction of structural materials under cavitation conditions. The advantage of the proposed device is to ensure the study of the processes of wear of equipment in a wide range of temperatures and pressures of a cavitating working fluid of various physicochemical composition, as well as a different composition of gases above its free surface, the temperature of the samples under study, and identifying their effect on the erosion resistance of structural materials.

It is known that a large number of elements of equipment, machines and mechanisms (parts of the cylinder-piston group of internal combustion engines, impellers of pumps and hydraulic turbines, propellers, tube bundles of heat exchangers, etc.) are operated under conditions of erosion of working surfaces by flows of cavitating working fluids Tuzov L.V., Bezyukov O.K., Afanasyeva O.V. Vibration of ship internal combustion engines. - SPB .: Publishing house of polytechnic. University, 2012. p. 183-188; Khmelev S.S., Khmelev V.N., Golykh R.N., Kuzovnikov Yu.M. Development of a stand for experimental studies of cavitation acoustic phenomena / Scientific and technical bulletin of the Volga region, 2015, No. 3, p. 231-234; Almametov N.K., Goncharov V.K., Gorshkov A.S. Gultsev A.D. Stand for the study of the cavitation properties of sea water. Auth. St. USSR No. 457906, 1975; ASTM G32-16, Standard Test Method for Cavitation Erosion Using Vibratory Apparatus, ASTM International, West Conshohocken, PA, 2016, www.astm.org).

The impact of cavitation leads to intense erosional destruction of equipment, machines and mechanisms. In this case, the intensity of erosional destruction is determined both by the properties of structural materials and by the parameters and properties of cavitating liquids, the composition of the gases absorbed by them (Bezyukov O.K., Zhukov V.A. Cooling liquids of transport internal combustion engines. SPb .: SPGUVK, 2009. - 263p. ).

To determine the service life of equipment, units of machines and mechanisms, it is necessary to have information on the intensity of erosion-corrosion destruction of structural materials. For this purpose, cavitation stands are used that simulate various operating conditions of the equipment.

There is a known method for determining cavitation wear resistance (RF patent No. 2359245, publ. 2009), which consists in the action of cavitation on the investigated area, characterized in that the cavitation field is created using ultrasound in a liquid medium, where there is a uniform effect on the surface of the microsection of the test material. The disadvantage of the device implementing the method is the limited scope of research due to the inability to change the temperature and pressure of the working fluid, the composition of the gas above its free surface due to leaks in the working chamber.

Known stand for studies of cavitation destruction of the components of the cooling system of a ship internal combustion engine along.with. SU No. 1511618, publ. 1989, containing a hydraulic circuit including a cavitation chamber equipped with a magnetostrictive vibrator, and fluid flow regulators, characterized in that in order to improve accuracy, the hydraulic circuit is connected to the internal combustion engine through the first of the regulators, and the cavitation chamber ( working capacity) is connected to the circuit in parallel through the second and third regulators connected, respectively, before and after the first regulator.

The known technical solution has a limited field of application, since it is included in the cooling system of a specific engine, with a set of physical and chemical properties and parameters of the coolant inherent only for it. To expand the field of investigation of erosion and corrosion damage, it is necessary to use other types of engines by installing an additional circuit on it.

Known device for cavitation wear of materials according to RF patent No. 2309401, publ. 2007, containing a magnetostrictive transducer, an oscillation concentrator installed with the ability to change the gap between it and the test sample, a container with a liquid and a fixing mandrel for the sample, characterized in that it additionally contains cylindrical brackets with an impeller that fix the position of the wear surface, made with the possibility of rotation around its axis and rolling over the wear surface of the test specimen, the base for fastening the brackets is rigidly connected to the housing of the magnetostrictive transducer, the fastening mandrel contains a cavity with a spring and a valve made with the possibility of ensuring constant contact of the test specimen with the brackets.

However, this technical solution also has a narrow field of application, since it does not provide the ability to change the parameters of the coolant and gas in a leaky working chamber.

Of the known analogs, the closest to the claimed technical solution is a device for studying the cavitation strength of materials according to the RF patent for a useful model No. 163845, IPC G01N 3/56, 2016, selected as a prototype.

The specified device consists of a generator of electrical oscillations of ultrasonic frequency and an ultrasonic vibrating system with a replaceable working tool placed in a leaky working vessel. The prototype uses an electromechanical transducer (piezoelectric or magnetostrictive) and a replaceable working tool, which can be made of various metals that are subjected to research for cavitation strength. It is also possible to study the cavitation wear of samples placed at a certain distance in front of the radiating surface of the instrument.

This technical solution has several disadvantages. Due to the use of a leaking working container in this device, it is impossible:

conducting research on cavitation destruction of materials at various pressures and temperatures of the liquid;

research of erosional damage at temperatures of material samples other than the temperature of the cavitating liquid;

research on the effect of the composition and properties of gases above the surface of the cavitating working fluid on the intensity of erosion damage;

ensuring control and regulation of the temperature of the test sample, in order to determine its effect on the intensity of cavitation damage.

The revealed shortcomings of the prototype are the reason for the impossibility of obtaining reliable results of the study of erosion processes under conditions corresponding to the real operating conditions of power equipment, namely, under conditions of: elevated temperatures and pressures, different physicochemical composition of the gas above the free surface of the cavitating liquid. This, in turn, reduces the accuracy of estimating the maximum service life of power equipment elements, machines and mechanisms (internal combustion engines, pumps, heat exchangers, etc.).

The claimed utility model makes it possible to increase the reliability of the results of investigating the intensity of erosional destruction of structural materials under cavitation conditions.

To solve the problem, the following set of essential features is used: in a device for studying the cavitation strength of materials, including, as well as a prototype, a working container with a liquid, a generator of electric oscillations of ultrasonic frequency with an ultrasonic oscillatory system and a concentrator of mechanical vibrations placed in the liquid, and a holder with the sample under study, also placed in a liquid, including a prototype, the working container is made sealed, with the ability to connect through a non-return valve to a source of both high and low pressure and is equipped with in the upper part with a neck for filling with liquid and a drain valve for draining it, while a heater is placed inside the container, made with the possibility of placing a test sample in it, and a heat exchanger that ensures the constancy of the specified temperature of the liquid.

The essence of the utility model consists in making a working container closed on all sides and sealed for air and liquid in the assembled form of the device. In turn, during the installation or removal of the test material, the container can be depressurized and opened. This makes it possible to create conditions inside the tank that correspond to the real operating conditions of power equipment when conducting research on the cavitation strength of structural materials.

Comparison of the proposed device for the study of the cavitation strength of materials and the prototype showed that the task posed is to increase the reliability of the results of the study of the intensity of erosional destruction of structural materials under cavitation conditions by creating conditions corresponding to the real operating conditions of power equipment is solved as a result of a new set of features, which proves the compliance with the proposed utility model to the criterion "novelty".

The essence of the proposed technical solution is illustrated by graphic materials, where (figure 1) presents a schematic representation of a device for studying the cavitation strength of materials.

The proposed device consists of a generator of electrical oscillations of ultrasonic frequency with an ultrasonic vibrational system and a concentrator of mechanical vibrations 1, a working vessel 2 with the test liquid 3. The concentrator 1 creates the effect of ultrasonic vibrations in a liquid 3 filling the working vessel 2. In the upper part of the vessel 2 there is a neck 4 for filling with liquid; a controlled valve 5 serves to drain the liquid. The tank also provides: a viewing window 6, through which the processes occurring in the tank 2 are monitored, and a non-return valve 7. To ensure constant pressure during testing and the safety of the installation, the device is equipped with a safety (regulating) valve 8. Inside the container 2 is placed the holder 9 of the test sample 10. A source of high or low pressure (compressor, vacuum pump or gas cylinder) is used to supply air to the container. The pressure source, for which a non-return valve 7 is provided in the device, provides a pressure change in the working vessel 2. Inside the vessel 2 there is also a heater 11 (for example, thermoelectric), which serves to heat the test samples 10 and liquid 3, a heat exchanger (coil) 12 , performing the function of a cooler (heater) of liquid 3, and ensuring the constancy of the set temperature

due to circulating running water, and a thermostat 13, which ensures automatic maintenance of the set temperature. To measure the temperatures of liquid 3 and test sample 10, a pyrometer or thermal imager installed in container 2 is used.

The device works as follows.

The test sample 10, made of cast iron, steel or other metal, with a holder 9 is fixed in a thermoelectric heater 11 and placed in a working container 2. The container is closed and its gas tightness is ensured

and liquids, after which liquid 3 is poured into it through the neck 4 (for example, fresh or sea water, gasoline or diesel fuel, alcohol or water-fuel emulsion). The filling control is carried out using the viewing window 6. Then the volume of the container remaining from the liquid 3 is filled with air or another gas and, using a high or low pressure source, its specified pressure is provided. Using the coil of the heat exchanger 12 with running water, the flow of which during the tests is regulated depending on the set temperature of the liquid 3, the thermoelectric heater 11 and the thermostat 13 with automatic control, they provide heating and maintenance of the set temperatures of the sample 10 and the liquid 3. An ultrasonic generator is turned on, which creates vibrations of the concentrator 1, which leads to the appearance of a cavitation "cloud" above the surface of the sample 10. The closure of cavitation bubbles causes erosional destruction of the sample 10, the magnitude of which depends on the strength of the material, its temperature, physicochemical properties, pressure and temperature of the liquid 3 and the physical chemical properties and concentration of gas dissolved in it. Periodic weighing of the sample 10 after removing it from the working container 2 makes it possible to determine the dynamics of destruction and to predict the erosion resistance of equipment parts that are made of the same material.

Thus, in the claimed utility model, it is possible to study the intensity of erosional destruction of structural materials in real conditions of operation of power equipment. This, in turn, allows you to determine the resource indicators of the equipment and its individual units. The advantages of the proposed technical solution are the possibility of conducting studies of cavitation destruction of materials:

in a wide range of pressures and temperatures;

at temperatures of samples made of various materials and having a temperature different from the temperature of the cavitating liquid;

with different composition of gases above the surface of the cavitating working fluid on the intensity of erosion damage.

Carrying out research on the proposed installation will allow to determine the influence of a wide range of factors on the intensity of cavitation destruction of elements of power equipment, machines and mechanisms.

The described device was developed by specialists of the Department of Theory and Design of Marine Internal Combustion Engines of the Federal State Budgetary Educational Institution of Higher Education "State University of Maritime and River Fleet named after Admiral S.O. Makarov" in the process of performing research work "Improving design methods, technical operation of diesel engines, ship power and heat exchange equipment." The utility model was implemented for conditions typical for cooling systems of high-speed diesel engines. The tests of the product gave a positive result, which confirmed the possibility of using the device for carrying out a complex of studies of the erosion resistance of cast irons, steels during cavitation in fresh water with additives and in antifreezes.

The foregoing allows us to conclude that the claimed utility model meets the criterion of "industrial applicability".

Claims (1)

A device for studying the cavitation strength of materials, including a working container with a liquid, a generator of electric oscillations of ultrasonic frequency with an ultrasonic vibrating system and a concentrator of mechanical vibrations placed in the liquid, and a holder with a test sample also placed in the liquid, characterized in that the working container is made with the possibility of hermetically closing and connecting through a non-return valve to a source of both high and low pressure and is equipped in the upper part with a neck for filling with liquid and a drain valve for draining it, while a heater is placed inside the working container, made with the possibility of placing a test sample in it, and a heat exchanger that ensures the constant temperature of the liquid.

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