RU151772U1 - LABORATORY INSTALLATION FOR TESTING OF SAMPLES OF BUILDING MATERIALS FOR BIOSTABILITY IN MODEL ENVIRONMENTS - Google Patents

Abstract

1. Laboratory installation for testing samples of building materials for biostability in model environments, including a test container made of a material resistant to microorganisms with samples installed in the bottom of the installation immersed in a model environment, characterized in that the test container is made with heat-protective casing and is equipped with a cassette installed in its bottom and made in the form of a tank with a double bottom, the upper of which has openings, the upper and lower bottom of the cassette connected by strips with the formation of a meander-like channel, in one corner of the cassette there is a flow heater of the model medium having a nozzle for entering the model medium and openings communicating with the channel of the cartridge for supplying a heated model medium to it, a polymer mesh is fixed in the upper part of the cartridge for fixing samples; a temperature sensor and a pH electrode are installed in the test vessel, immersed in a model environment; in the lower part of the test container is a pipe connected to a drain tank with a polyvinyl chloride hose passing through an electromagnetic valve; the installation is equipped with a pump, the suction pipe of which is connected to the pipe of the test container, the discharge pipe of the pump is connected to the pipe of the heater; the installation is also equipped with a make-up container located above the test vessel and having an electromagnetic valve on the supply line of the model medium to the test vessel; the unit is equipped with an electronic control unit that records and regulates the basic parameters of the environment and communication�

Description

The utility model relates to the field of testing building materials: in particular, to devices for testing, in model environments, samples of building materials of standard sizes for biostability.

A device for testing samples of building materials in aeration tanks, which is a polymer network with patch pockets of the same material, for placing samples. The device is immersed in an aqueous, biologically active environment of the aeration tank and the network is fixed in it with the help of cables and carabiners on fences (RF patent No. 115076, B No. 11, 04/20/12).

The disadvantage of this device are: inconvenience and the complexity of placing and securing samples, the irrational use of the capabilities of the aeration tank: not full use of the entire width of its corridor, different load of activated sludge depending on the installation location along the length of the corridor.

It is also known a device for fixing samples of test materials, installed in a water treatment plant (aeration tank), made in the form of blocks consisting of U-shaped guides in which frames are installed to accommodate inset frames in which polymer nets with patch pockets are fixed (RF patent No. 126142, B No. 8, 03.20.13).

The disadvantage of this device is a possible violation of the hydrodynamic mode of operation of the aeration tank, when setting the maximum number of samples, due to the high hydrodynamic resistance, which is determined both by the design and the position of the device in the water treatment plant (across the corridor of the aeration tank).

In addition, the main disadvantage of the proposed devices is that when testing samples it is impossible to change the parameters of the biologically active medium of the aeration tank - the temperature and pH of the medium, i.e. carry out a comprehensive study of the processes of biocorrosion of building materials in full.

As a prototype, the device used in the method of testing samples of building materials for biostability according to the patent of the Russian Federation No. 2471188, No. 36, 12/27/12 was chosen. The device is a hermetically sealed container made of a material resistant to microorganisms, at the bottom of which samples of the studied products are placed, immersed in a model of slightly aggressive medium (pH <7) so that the upper edge of the medium is higher than the upper edge of the samples.

Significant disadvantages of the prototype is that the temperature of the model environment is unstable and depends on the ambient temperature, in addition, it is impossible to maintain the pH of the medium at a given level, and to carry out the mixing of the medium. All this significantly affects the results of assessing the degree of biostability of building materials and does not allow a comprehensive study of biocorrosion processes, i.e. the prototype does not allow to evaluate the kinetic parameters of the biodeterioration processes of building materials.

The objective of the utility model is to create a device for researching the processes of biodeterioration of building materials, which allows maintaining the pH of the model medium and its temperature at a given level and allows for constant concentrations of the components of the model environment due to constant mixing. The device should automatically record in time the main kinetic parameters - pH and ambient temperature.

The utility model is aimed at creating the possibility of conducting kinetic studies of the processes of biocorrosion of building materials under constant pH and temperature of the model environment, the possibility of calculating kinetic parameters from the experimental data of the installation and the possibility of creating a mathematical model of the processes of biocorrosion of building materials, which fundamentally distinguishes this device from previously created ones.

The technical result is to increase the accuracy of studying the processes of biodeterioration of building materials and the possibility of creating a mathematical model of biocorrosion processes.

The result is achieved in that in a laboratory installation for testing samples of building materials for biostability in model environments, which includes a test container made of a material resistant to microorganisms with samples installed in the bottom of the installation immersed in a model environment, according to a utility model, a test the tank is made with a heat-protective casing and is equipped with a cassette installed in its bottom and made in the form of a tank with a double bottom, the upper of which has an Stia, upper and lower bottom tape strips are joined to form a meandering channel; in one corner of the cassette, an in-line model medium heater is installed, having a nozzle for entering the model medium and openings communicating with the cassette channel for supplying a heated model medium to it; a polymer mesh is fixed in the upper part of the cassette for fixing samples; a temperature sensor and a pH electrode are installed in the test vessel, immersed in a model environment; in the lower part of the test container is a pipe connected to a drain tank with a polyvinyl chloride hose passing through an electromagnetic valve; the installation is equipped with a pump, the suction pipe of which is connected to the pipe of the test container, the discharge pipe of the pump is connected to the pipe of the heater; the installation is also equipped with a make-up container located above the test vessel and having an electromagnetic valve on the supply line of the model medium to the test vessel; the unit is equipped with an electronic control unit that records and regulates the basic parameters of the medium and is connected with a temperature sensor, a pH electrode, an electric heater of a model medium, and electromagnetic valves.

The result is also achieved by the fact that, all the units of the installation are made of corrosion-resistant materials, and all containers are made of sheet polymethyl methacrylate.

In FIG. 1 schematically shows the proposed installation for testing samples of building materials for biostability (side view).

In FIG. Figure 2 schematically shows a cassette for placing test samples (top view).

Laboratory installation for testing samples of building materials for biostability consists of a test container 1 of rectangular cross section made of a material resistant to microorganisms, for example, sheet polymethylmethacrylate. In the bottom of the test container 1 is a cassette 2 for placement of the test samples. Cassette 2 is a container of rectangular cross section, made, for example, of sheet polymethylmethacrylate, in the upper part of which (parallel to the bottom) a polymer mesh 3 is fixed, which serves to fix samples of building materials 4 in its cells in a vertical position. Cassette 2 has a double bottom, the upper bottom has openings 5. The upper and lower bottom of the cassette 2 are connected by strips, for example, of sheet polymethylmethacrylate 6, forming a square-shaped meander channel through which a heated model medium is supplied to update and mix the medium around samples 4 and maintain set temperature of the medium. In one of the corners of the cassette 2, there is a flow heater of medium 7, which is a rectangular container, for example, of polymethyl methacrylate, with an electric heater installed in it 8. The flow heater 7 has an inlet pipe 9 for receiving a model medium and a rectangular hole (not shown in the diagram ) for supplying heated medium to the meander-like channel of the cartridge 2. To the nozzle 9 of the flow heater 7, a discharge nozzle 10 of the centrifugal pump 11 is connected using a polyvinyl chloride hose 11. Suction nozzle 1 2 of the pump 11 is connected with a polyvinyl chloride hose to the pipe 13 of the test container 1. The pipe 13 is made of a corrosion-resistant material, for example, stainless steel. A pH electrode 14 and a temperature sensor 15 are also installed in the test container 1, immersed in a model medium to a depth of 30 mm. Test container 1 has a heat-shielding casing made of expanded polystyrene foam, providing minimal heat exchange with the environment (not shown in the diagram).

The installation also includes an electronic control unit 16, which records and regulates the main parameters of the medium: pH and temperature, by measuring the pH and temperature of the medium using the connected pH electrode 14 and temperature sensor 15 connected to the electric heater 8, which serves for heating model environment to the set temperature value.

The test tank 1 and the drain tank 17 are interconnected by a polyvinyl chloride hose through an electromagnetic valve 18 located at the bottom of the test tank 1 to allow gravity to drain the spent model medium.

The make-up tank 19 is made, for example, of sheet polymethyl methacrylate and has a rectangular cross-section. In its lower part there is a pipe to which the solenoid valve 20 is connected using a polyvinyl chloride hose 20. A polyvinyl chloride hose is connected to the solenoid valve 20, which is immersed in the model medium of test vessel 1 to supply fresh medium. The make-up tank 19 is located above the test tank 1, to ensure the draining of the fresh model environment by gravity. Solenoid valves 18 and 20 associated with the electronic control unit 16 ensure that the pH of the medium is maintained at a predetermined level by periodically adding fresh model medium and draining the waste.

The circuit diagram of the electronic control unit 16 consists of three parts: a measuring unit, a power supply and a charger (not shown in the diagram).

The principle of operation of the installation is as follows: insert a cartridge 2 into the test container 1, in which samples of building materials 4 are vertically mounted using a polymer net 3. The test medium 1 is poured into the test medium so that the upper edge of the medium is 10-15 above the upper face of the samples see. The model medium from the test tank 1 enters the suction nozzle 12 of the pump 11, which operates in a constant mode and provides continuous mixing of the model medium in the test tank 1. Model medium two from the discharge pipe 10 are fed into the flow heater 7 and heated by the electric heater 8. The heated model fluid stream enters the meander-like channel of the cartridge 2 and passes through the holes 5 in the perforated upper bottom of the cartridge 2, thereby mixing the model medium around the samples of building materials 4 and maintaining the specified level of temperature and pH of the medium through the electronic control unit 16.

The installation can operate in two kinetic modes. In the main operating mode of the installation, the pH values and the ambient temperature are automatically maintained constant over time, which can be set in the range from 25 to 50 ° C with an accuracy of 0.01 ° C.

In the main operating mode of the installation in order to maintain the pH and temperature of the medium at a predetermined level, in test vessel 1, these parameters are measured using a pH electrode 14 and a temperature sensor 15. An electrical signal from both sensors is sent to the electronic control unit 16. If the medium temperature according to the readings of the temperature sensor is lower than the set value, the electronic control unit 16 will automatically turn on the electric heater 7 and turn it off at the moment when the temperature of the medium reaches the set value. If the pH of the model medium rises (pH> 7), the electronic control unit 16 will turn on the solenoid valve 18 and the set amount of spent model medium will merge into the drain tank 17, after which the electromagnetic valve 18 will automatically turn off. Next, the solenoid valve 20 will automatically turn on and a predetermined amount of fresh model medium from the feed tank 19 will merge into the test tank 1. After that, the pH of the model medium is re-measured, and if the pH of the medium does not reach the set value, the operation will be repeated again.

In an additional operating mode of the installation, in the manner described above, the set temperature of the model medium is maintained with its mixing and registration of the temperature of the medium in time. Registration and recording in time of the pH of the medium on the memory card is performed without draining the waste and without adding a fresh model environment. After a specified period of testing the samples of building materials for biostability, the electronic control unit 16 includes a solenoid valve 18 and the entire volume of the model medium from the test container 1 is automatically discharged into the drain tank 17, after which the samples of building materials 4 are removed for further testing.

The model media used are both aqueous solutions of mono-, dibasic, and tribasic carboxylic acids (acetic, oxalic, citric, etc.) with different concentrations, and their possible combinations.

Biostability of building materials samples is determined by their chemical resistance coefficient characterizing the change in compressive and bending strength of samples before and after exposure in model environments.

The laboratory setup allows to increase the accuracy of studying the biodeterioration processes of building materials samples by maintaining the temperature and pH of the environment at a given level and to create a mathematical model for describing biocorrosion processes based on experimental data and the coefficient of chemical resistance of samples determined at different temperatures. Due to the possibility of increasing the temperature of the model environment, the use of the proposed utility model allows not only to determine the kinetic parameters of the biocorrosion process of building materials, but also significantly reduce the test time (2-4 times) against existing methods, since when the temperature of the environment is increased by 10 degrees, according to the Van Goff rule, the rate of biocorrosion processes doubles.

Claims (2)

1. Laboratory installation for testing samples of building materials for biostability in model environments, including a test container made of a material resistant to microorganisms with samples installed in the bottom of the installation immersed in a model environment, characterized in that the test container is made with heat-protective casing and is equipped with a cassette installed in its bottom and made in the form of a tank with a double bottom, the upper of which has openings, the upper and lower bottom of the cassette connected by strips with the formation of a meander-like channel, in one corner of the cassette there is a flow heater of the model medium having a nozzle for entering the model medium and openings communicating with the channel of the cartridge for supplying a heated model medium to it, a polymer mesh is fixed in the upper part of the cartridge for fixing samples; a temperature sensor and a pH electrode are installed in the test vessel, immersed in a model environment; in the lower part of the test container is a pipe connected to a drain tank with a polyvinyl chloride hose passing through an electromagnetic valve; the installation is equipped with a pump, the suction pipe of which is connected to the pipe of the test container, the discharge pipe of the pump is connected to the pipe of the heater; the installation is also equipped with a make-up container located above the test vessel and having an electromagnetic valve on the supply line of the model medium to the test vessel; the unit is equipped with an electronic control unit that records and regulates the basic parameters of the medium and is connected with a temperature sensor, a pH electrode, an electric heater of a model medium, and electromagnetic valves. 2. Installation according to claim 1, characterized in that all the components of the installation are made of corrosion-resistant materials, including all containers and the cartridge is made of sheet polymethyl methacrylate.

Images