RU223138U1 - Installation for studying the performance properties of fire-resistant liquids - Google Patents

Abstract

The utility model refers to devices designed to study, analyze or evaluate the performance properties of fire-resistant turbine oils (liquids) and their mixtures used in control systems of steam turbines and in lubrication systems of various equipment by determining their chemical and/or physical properties. The installation contains a reactor 1 with a lid 19 and a stirrer 2. The lid 19 is equipped with a port for installing a copper plate 16, which is made in the form of a hole in the lid with a side around the perimeter of this hole. The flange of the port opening 16 can be made, for example, as a flange, in the form of a hollow welded boss or in the form of a fitting. On the outer surface of the side of the hole in port 16, a copper wire is fixed at one end. The second end of the copper wire through the opening of port 16 is placed inside the reactor 1, while a copper plate 15 is fixed to it. The technical result consists in accelerated aging of fire-resistant turbine fluids, reducing the duration of the study.

Description

The utility model refers to devices designed to study, analyze or evaluate the performance properties of fire-resistant turbine oils (liquids) and their mixtures used in control systems of steam turbines and in lubrication systems of various equipment by determining their chemical and/or physical properties.

A device for studying the performance properties of motor oils is known from the prior art, described in the patent for the invention “Method and installation for studying the aging processes of motor oils” (patent RU No. 2542470, IPC G01N33/30, published 02.20.2015, bulletin No. 5) , containing a thermostat tank with a mechanical stirrer, thermometers, pressure gauges, control valves, heaters, coolers, oil lines, oil pumps, centrifuges, control valves, hydraulic accumulators, high-pressure nozzles, gasoline blowtorches, compressors, storage tanks, receivers and valves, which allow the processes of hydromechanical, thermodynamic and thermochemical destruction to be carried out during cyclic tests carried out under certain modes.

The disadvantage of this device is its complexity, as well as the inability to use it for fire-resistant liquids.

The closest in technical essence to the claimed utility model is a device for implementing a method for studying the physical state of lubricants (RU 2285918, IPC G01N 33/30, IPC G01N 7/14, published on October 20, 2006, Bulletin No. 29), which contains an oil thermostat tank with mechanical stirrer, thermal heater and thermometer and pipeline with valve. It is also additionally equipped with a pump, a throttling valve and a degassing device. In this case, the transition valve, pump and throttling valve are connected in series to each other by sections of the pipeline. The pipeline sections containing the throttling valve and degassing device are made of heat-resistant transparent material and are equipped with temperature and pressure sensors and digital video cameras connected to a computer.

The disadvantage of this technical device is the limited functionality of its use for fire-resistant liquids and the duration of the study.

The technical problem solved by the claimed utility model is to expand the functionality of the device, aimed at studying fire-resistant liquids.

The technical result achieved when using the utility model is the accelerated aging of fire-resistant turbine fluids, reducing the duration of the study.

This is achieved by the fact that an installation for studying the operational properties of fire-resistant liquids, containing a reactor with a lid and a stirrer, connected to a thermostat, equipped with sensors and a control panel for operating parameters, a port for supplying a fire-resistant liquid and a drain port; according to the utility model, the lid is equipped with a port for installing a copper plate , which is made in the form of a hole in the cover with a side around the perimeter of this hole, on the outer surface of the side of the hole of the copper plate installation port, a copper wire is fixed at one end, the second end of the copper wire is placed inside the reactor through the hole of the copper plate installation port, while a copper wire is fixed to it plate.

Also, the side of the port opening can be flanged.

In addition, the side of the port opening can be made in the form of a hollow welded boss or fitting.

Additionally, the side of the port opening is made in the form of a fitting.

The essence of the utility model is illustrated by a drawing, which shows a schematic diagram of an installation for studying the operational properties of fire-resistant liquids and the following notations are adopted:

1 - reactor,

2 - stirrer,

3 - shirt,

4 - engine,

5 - support,

6 - rod bearing,

7 - thermometer,

8 - port for supplying fire-resistant liquid,

9 - mechanical vacuum sensor,

10 - drain port,

11- coolant input,

12 - coolant outlet,

13 - capacitor,

14 - control panel,

15 - copper plate,

16 - copper plate installation port,

17-tube with venting,

18 - thermostat,

19 - reactor cover.

The installation contains a reactor 1 installed in a single housing on a support 5 with a glass platform and rollers, with a lid 19 and a stirrer 2, while the reactor 1 is surrounded by a jacket 3. The lid 19 is equipped with a port for installing a copper plate 16, which is made in the form of a hole in the lid with a side along the perimeter of this hole. The flange of the port opening 16 can be made, for example, as a flange, in the form of a hollow welded boss or in the form of a fitting. On the outer surface of the side of the port hole 16, a copper wire is fixed at one end, for example, welded or tightened in a loop. The second end of the copper wire through the hole in port 16 is placed inside the reactor 1, while a copper plate 15 is fixed to it, for example, with a welded joint.

Reactor 1 is configured to carry out mixing, dissolution, extraction, heating, crystallization, degradation and other manipulations with fire-resistant liquids and is equipped with sensors for operating parameters (temperature, pressure, rotation speed). Thus, the temperature of the fire-resistant liquid and the temperature of the coolant can be measured using a thermometer 7, pressure - with a mechanical vacuum sensor 9. The rotation speed of the mixer 2 can be measured using, for example, a tachometer .

A motor 4 is connected to the mixer 2 to drive it. The engine 4 is mounted on a support 5 and contains a rod bearing 6.

Port 8 is used to supply fire-resistant liquid, drain port 10 is for draining.

On jacket 3 of reactor 1 there is a coolant inlet 11 and outlet 12 for cooling and heating the walls of the reactor 1.

Input 11, jacket 3 of reactor 1, output 12 and thermostat 18, which maintains the temperature of the coolant, form a cooling and heating circuit for the walls of reactor 1.

The installation contains a control panel 14 with a display, which is configured to control the temperature of the coolant supplied to the inlet 11, the rotation speed of the mixer 2, display the operating temperature of the fire-resistant liquid and the coolant supplied through the inlet 11.

In this case, reactor 1 and jacket 3 are made transparent. This allows you to monitor the processes taking place in reactor 1 without any special equipment. High-strength tempered glass was chosen as the material for the reactor and jacket, which can withstand temperature changes without destruction.

Water accumulates in condenser 13, which evaporates during the reaction process.

Thus, when conducting research, the results can be read not only by the control panel 14, but also by laboratory equipment, which can be additionally installed around the stand; in addition, this equipment can produce photo or video documentation, which in turn is achievable by transparency of the main elements of the stand.

A copper plate 15 on a copper wire is placed inside the reactor 1 to increase the reaction rate. Copper plate 15 acts as a catalyst, i.e. helps accelerate the aging of fire-resistant turbine fluids. In this case, regulation of the position of the copper plate inside the reactor 1 is possible by winding fewer or more turns around the side of the hole in port 16.

Tube 17 acts as a prompter, equalizes the pressure in reactor 1 with atmospheric pressure, and provides an air supply for the reaction.

It was experimentally confirmed by the example of a study of oil of the Reolube brand that using an installation for studying the operational properties of fire-resistant liquids, in 6 days, oil characteristics are obtained that are similar to approximately 3 years of operation of this oil on the equipment of automatic control systems of steam turbines of thermal power plants.

Thus, the use of a utility model makes it possible to accelerate the aging of fire-resistant turbine fluids and reduce the duration of research.

Claims (4)

1. An installation for studying the operational properties of fire-resistant liquids, containing a reactor with a lid and a stirrer connected to a thermostat, equipped with sensors and a control panel for operating parameters, a port for supplying fire-resistant liquid and a drain port, characterized in that the lid is equipped with a port for installing a copper plate, which is made in the form of a hole in the cover with a side around the perimeter of this hole, on the outer surface of the side of the hole of the copper plate installation port, a copper wire is fixed at one end, the second end of the copper wire is placed inside the reactor through the hole of the copper plate installation port, and a copper plate is fixed to it. 2. Installation according to claim 1, characterized in that the side of the port opening is flanged. 3. Installation according to claim 1, characterized in that the side of the port opening is made in the form of a hollow welded boss. 4. Installation according to claim 1, characterized in that the side of the port opening is made in the form of a fitting.