RU9201U1 - DIVER WORK CAMERA - Google Patents

Abstract

1. A pressure chamber for diving operations, comprising a gas medium supply system comprising pipelines with valves connected to an air or oxygen source, a gas medium exhaust system from a pressure chamber and a gas medium withdrawal channel from a pressure chamber connected to a carbon dioxide gas analyzer, characterized in that it is provided placed inside the pressure chamber by an emergency breathing system, a system for cleaning the gas environment of the pressure chamber from carbon dioxide and harmful substances and a sensor for monitoring the oxygen content in the pressure chamber. 2. The pressure chamber according to claim 1, characterized in that the emergency breathing system is made in the form of breathing masks connected by inlet pipelines with valves with air and oxygen sources and a discharge pipe through a pressure regulator with the external environment. The pressure chamber according to claim 1 or 2, characterized in that the system for cleaning the pressure medium of the pressure chamber from carbon dioxide and harmful substances contains breathable cartridges with a substance that absorbs carbon dioxide and harmful substances, and an electric fan installed under them, and the outlet of the pipeline supplying oxygen to the pressure chamber placed above the cassettes in the stream created by the electric fan. 4. The pressure chamber according to one of claims 1 to 3, characterized in that the sensor of the oxygen analyzer of oxygen control is connected by a cable to the voltage converter through a pressure seal installed on the pressure chamber housing.

Description

Pressure chamber for diving

The utility model relates to the field of diving technology, in particular to pressure chambers with a gaseous medium of overpressure, a circular circulator in a closed cycle inside a pressure chamber, designed to provide habitability in a closed volume.

A pressure chamber is known comprising a system for supplying air and rock to a pressure chamber, and a system for discharging a gaseous medium from a pressure chamber. The oxygen supply system contains an electromagnetic valve with a rock distributor in a metering unit made in the form of a bubbler. This design of the oxygen supply system reduces the explosiveness of the mixture in the pressure chamber.

RU, 2051068, B 63 C 11/00, 1995.

However, the known design of the pressure chamber does not allow coit | polish the composition of the gaseous medium with carbon dioxide and oxygen.

The closest technical solution to the declared utility and model is a pressure chamber for diving operations including a gas medium supply system containing piping with valves connected to air and oxygen sources, a gas medium exhaust system from a pressure chamber and a piping; an air sampling system from a pressure chamber connecting to a gas analyzer .

SIJ, 152391, B 63B 11/00, 1965.

A disadvantage of the known design is the lack of control over the oxygen content in the pressure chamber, as well as the need for names of a large air supply for ventilation of the pressure chamber with an increased content of carbon dioxide and harmful substances.

The objective of the utility model is to create a design that maintains at the required level vital parameters of gases and the medium in a closed chamber of a pressure chamber for carbon dioxide, harmful eeiiiecTBaM and oxygen, and also creates a design that provides for the failure of systems and units of the main operating mode of the pressure chamber

 B 63 C 11/00

The technical result achieved by solving the ix tasks is the ability to:

-a significant reduction in air reserves in cylinders, necessary;: those to ensure the operation of the pressure chamber;

 if necessary, isolate the respiratory system during an emergency in the pressure chamber;

- ensuring the maintenance of vital parameters of the gas environment in pressure chambers having a small internal volume and small a (:. 1 rits, without compromising the comfort of people staying in them.

The indicated problem is solved in a pressure chamber for diving operations, which includes a gas medium supply system containing pipelines with valves connected to an air and oxygen source, a gas exhaust system; 1edocameras from a pressure chamber and a gas medium extraction pipeline from a pressure chamber connected to a carbon dioxide gas analyzer due to the fact that it is equipped with an emergency breathing system located inside the pressure chamber, a system for cleaning the gas environment of the pressure chamber from carbon dioxide and other harmful substances, and a monitoring sensor contains I oxygen in a hyperbaric chamber.

The emergency respiratory system can be made in the form of: i, iinative masks connected by supply pipelines with valves with oxygen or air coils and a discharge pipe through a regulator; 1 phenomena with the external environment.

The system for cleaning the gas medium of the pressure chamber from carbon dioxide and harmful substances can be made in the form of oxygen installed under stream i, which flows through the pipeline into the pressure chamber of breathable cartridges with a substance that cleans the gas medium from carbon dioxide and harmful substances with an electric fan installed under them.

The oxygen control sensor can be connected by cable to npeoOp; i the voltage analyzer of the gas analyzer through a pressure seal installed neither in the pressure chamber housing.

The pressure chamber 1 for diving operations contains a pipeline. oxygen supply connected to a cylinder 3 for dosed supply of ki rock and a cylinder 4 for oxygen supply.

The pipeline 2 has a valve 5 (valves) and a flow meter 6.

Inside the pressure chamber 1 is a gas purification system o; carbon dioxide and harmful substances. The system includes an electric fan 7 installed under a re-breathable air box: shea 8 with a substance that absorbs carbon dioxide, or harmful substances, for example, a chemical absorbent KhPI or cartridge FKB - 25.

The pressure chamber 1 has an emergency breathing system containing a wire () wire 9 connected to an oxygen source, a pipe 10 connected to an i air scraper, shut-off valves 11. Pipelines 9 and 10 serve as a supply of oxygen and air to breathing chambers inside, respectively. masks 12, which are connected by a pipe 13 to a pressure regulator 14 located outside the pressure chamber. , For sampling the gases ui of the pressure chamber medium, a pipe 15 is used, with a shut-off valve 16 and a voltage converter 17 of the carbon dioxide monitoring gas analyzer. Barocam; i 1 has a sensor 18 installed inside it, for monitoring the oxygen content in the gas environment. The sensor 18 is connected by a cable 19 through a pressure seal 20 located on the pressure chamber housing with a voltage converter 21 of the oxygen monitoring gas analyzer.

Inside the pressure chamber 1, people are placed, after which, using a socially provided air supply system, the pressure necessary to perform the work is created. The electric fans of the 7 units are switched on. which mix the gas in the pressure chamber to obtain its uniformity. At the same time, the fans pump the gaseous medium through the c.osets 8 with absorbers of carbon dioxide or harmful substances, thereby purifying the gaseous medium from these substances. The carbon dioxide content is monitored by means of a gas analyzer to which npof v of the gaseous medium is supplied from the pressure chamber through the pipe 15. The necessary gas flow rate is regulated by valve 16. When the content of harmful substances reaches the maximum permissible concentrations, reloading of the cartridges of 8 units

cleaning for new ones. While people are in the pressure chamber, they i-absorb oxygen, which is replenished using the system in a dosed manner; filing. Oxygen from the cylinder 4, where it is stored initially, is supplied to.-Fill the dosing cylinder 3, after which the oxygen from this cylinder, 1, is fed through the pipe 2 to the pressure chamber into the gas flow created by the vent 7 of the cleaning unit. A single supply of oxygen is carried out in the amount i necessary for breathing of all people in the pressure chamber for 1 hour. In case of failure of the dosed supply system, oxygen is supplied to the pressure chamber ni through a pipe) from the cylinder 4 through the flow meter 6, the flow rate of which is established from the same calculation as the volume of the dosing cylinder. Oxygen content in the gaseous medium is monitored using an oxygen sensor 18 located inside the pressure chamber, the electric signal from which fio dies through cable 19 and through the pressure inlet 20 in the pressure chamber housing to the oxygen detector analyzer 21 mounted outside the pressure chamber. Carbon dioxide and oxygen gas shock absorbers carry out automatic continuous monitoring of the gaseous medium. If the content of the monitored parameters is exceeded above the established standards, they provide alarming sound sampling, which leads to the need to adjust the working conditions of the cleaning units (reduce the gap between cartridge changes) and the frequency of the dosed oxygen supply or to reduce the oxygen flow through the flow meter

In case of malfunctioning of the cleaning units, the system for supplying kitty, the rock to the pressure chamber, and if necessary, isolate the human respiratory system, for example, when smoke is inside the pressure chamber, in fasting the content of carbon dioxide and harmful substances is higher than the maximum available concentrations, an individual breathing system is used through m. 12, into which, depending on the situation, either air is supplied through line 10 or pure oxygen through line 9. Exhalation from the masks is carried out into line 13, and from it to atmosphere. The pressure in the exhalation pipe 13 in comparison with the inspiratory pipelines 9, 10 is provided by means of a pressure relief regulator 14 located outside the pressure chamber.

Using the 8 pressure chamber described system designs and, lo people can be in it in comfortable conditions for quite a long time several days).

Claims (4)

1. A pressure chamber for diving operations, comprising a gas medium supply system comprising pipelines with valves connected to an air or oxygen source, a gas medium exhaust system from a pressure chamber, and a gas medium withdrawal channel from a pressure chamber connected to a carbon dioxide gas analyzer, characterized in that it is provided placed inside the pressure chamber by an emergency breathing system, a system for cleaning the gas environment of the pressure chamber from carbon dioxide and harmful substances and a sensor for monitoring the oxygen content in the pressure chamber.  2. The pressure chamber according to claim 1, characterized in that the emergency breathing system is made in the form of breathing masks connected by inlet pipelines with valves with air and oxygen sources and a discharge pipe through a pressure regulator with the external environment.  3. The pressure chamber according to claim 1 or 2, characterized in that the system for cleaning the pressure medium of the pressure chamber from carbon dioxide and harmful substances contains breathable cartridges with a substance that absorbs carbon dioxide and harmful substances, and an electric fan installed under them, and the outlet of the pipeline supplying oxygen in the pressure chamber, placed above the cassettes in the stream created by the electric fan. 4. The pressure chamber according to one of claims 1 to 3, characterized in that the sensor of the oxygen analyzer for oxygen control is connected by a cable to the voltage transducer through a pressure seal installed on the pressure chamber body.