KR102235760B1 - Air quality measuring device of air tank for diving breathing - Google Patents

Abstract

The present invention relates to an air quality measuring device of an air tank for breathing while diving. More specifically, the present invention relates to a technology which is able to measure hazardous substances in the air filling an air tank applied to diving equipment in real time, to prevent various accidents due to the inhalation of polluted air, and to improve the measurement accuracy because of an efficient structure of the measuring device. That is, according to the present invention, the air quality measuring device of the air tank for breathing while diving comprises: a mainframe unit which includes an air inlet formed on a lower side, an air outlet formed on an upper side to have a measuring space formed between the air inlet and the air outlet, and a measuring space placed on one side to be opened; a cover unit engaged with the opened part of the mainframe unit to cover a measuring space, having a sensor engagement unit which has a plurality of sensor holes formed by penetrating toward the measuring space; air quality sensors respectively engaged with the sensor holes of the cover unit to measure the air quality in the measuring space; and a PCB substrate engaged with a cover unit from outside the air quality sensors.

Description

Air quality measuring device of air tank for diving breathing

The present invention relates to a device for measuring air quality of a reservoir for diving and breathing, and more specifically, it is possible to measure in real time the harmful components of the air charged in the reservoir applied to the diving equipment. It relates to a technology that can prevent safety accidents and improve measurement accuracy due to the efficient structure of the measurement device.

In general, diving breathing tanks (respirators) are used for diving-related sports called skin scuba, scuba diving, skin diving, snorkling, etc., or in the sea. It means equipment worn by divers for fishing, broadcasting, research, military, etc.

However, accidents due to inert gas, oxygen partial pressure, carbon monoxide and carbon dioxide have been raised as serious problems due to the problem of air quality in the breathing reservoir used for diving activities. In particular, the concentration of carboxyhemoglobin in the blood increases depending on the carbon monoxide concentration, and as the concentration increases, it causes relatively mild physical symptoms such as headache, dizziness, and vomiting. Leads to

According to the 2017 Occupational Safety and Health Research Institute's report on "cause analysis and system improvement plan" from 2003 to 2016, there were 14 serious accidents and more than 100 cases of polluted air gas when charging regular air every year. It states that an accident will occur.

The reason why a problem occurs in the reservoir that the diver breathes in this way is that, in charging the air in the breathing reservoir, the general air is using a device such as a compressor, and the charging process of the air due to the charging environment or the problem of the compressor. Noxious gas is introduced into the reservoir.

To list representative examples of air pollution caused by the compressor (air compressor): 1. Inflow of exhaust gas discharged from the engine exhaust system of the air compressor, 2. Inflow of compressor oil due to wear inside the compressor cylinder, 3. High humidity environment (marine, Corrosion and pollution inside the air tank due to condensation of compressed air in the rainy season, indoor facilities, etc.), 4. Inflow of impurities due to non-compliance with the exchange cycle of consumable filters of the air compressor, 5. Internal combustion/incomplete combustion of compressor oil due to overheating of the compressor There are reasons such as oil carbonization and denaturation due to, 6. Unlicensed filling facilities.

As a general air quality measuring device used in other fields has an inherent limitation in that it cannot measure the air quality of the high-pressure air of a compressor, there is a problem of being exposed to safety accidents due to inhalation of contaminated air.

As a related prior art, Registration Patent No. 10-0841598 (a bio-signal measuring device for underwater) is for measuring a bio-signal of an aquatic activator active in the water, and is mounted on the head of the underwater activator, and the eyes of the underwater activator A water goggle for protecting the water goggles, a light volume pulse wave sensor that is detachably coupled to the water goggles, and is attached to the earlobe of the aquatic activator to measure a pulse wave of the aquatic activator and output a signal corresponding thereto, and the light volume pulse wave sensor A technology including a control unit configured to receive the signal from and calculate at least one of a heart rate, respiration, and oxygen saturation of the aquatic activator, and a display device that displays a value calculated by the control unit.

The prior art is a technology that detects a diver's human body information (heart rate, respiration, oxygen saturation) in a measuring device and gives a warning, and there is an inconvenience that a diver must always wear the equipment, and the diver wears it in connection with the present invention. The air quality information of the reservoir is a technology that cannot be grasped at all.

As another prior art, Registration Patent No. 10-2080975 (a filling device for a breathing reservoir and a filling method using the same) contains a compressor that compresses gas, and a chamber that stores the gas compressed by the compressor and has a plurality of gas outlets. And, a filling pipe connected to the gas outlet of the chamber and connected to the air cylinder; including, a gas analyzer connected to the chamber and analyzing component gases of the gas, and reading whether the content of each component gas is appropriate, and a gas analyzer A configuration including a; management server for receiving and monitoring the data of the wired or wireless is disclosed.

The gas analyzer of the prior art merely describes that it analyzes oxygen, carbon dioxide, carbon monoxide, etc. contained in compressed air, and does not mention any content intended to improve the measurement accuracy of the substances. The structure is also not shown at all.

The present invention has been devised to solve the above problems, and measures harmful substances that may be contained in the air filled in the diving breathing reservoir, but by providing a measuring device having a structure optimized for air quality measurement, measurement accuracy is improved. It is an object of the present invention to provide an air quality measuring device for a diving breathing reservoir having a structure that is easy to replace parts and expand sensors, and is easy to clean inside.

In the present invention, in the air quality measuring apparatus of a reservoir for diving breathing, an air inlet is formed at one side of the lower part, an air outlet port is formed at the upper part, and a measuring space is formed between the air inlet and the air outlet, and the measuring space is opened to one side. The main body part and the cover part having a sensor coupling part formed therein to cover the measurement space in the open part of the main body part, and a plurality of sensor holes penetrated into the measurement space, and the sensor hole of the cover part It characterized in that it consists of an air quality sensor that is respectively coupled to measure the air quality inside the measurement space, and a PCB substrate coupled to the cover from the outside of the air quality sensor.

In addition, a regulator is coupled to one side of the air inlet of the main body to adjust the pressure of air flowing into the measurement space.

In addition, a guide wall is formed at one side of the regulator so that the air introduced by the pressure is reduced in a direction in which the air quality is measured.

In addition, a partition wall member having a porous characteristic is coupled to the measurement space of the main body to form an analysis region for a portion to which the air quality sensor is coupled.

In addition, a pressure sensor for measuring the pressure in the analysis area is installed in the main body.

In addition, a moisture sensor for measuring moisture in air flowing into the measurement space is installed in the main body.

In addition, the air quality sensor is characterized in that it is composed of a module-type O2 sensor, a CO sensor, and a VOC sensor.
In addition, in the present invention, in the air quality measuring apparatus of a reservoir for diving breathing, an air inlet is formed on one side of the lower side, an air outlet is formed on the upper side, and a measurement space is formed between the air inlet and the air outlet, and a measuring space is formed on one side. The open body part and the cover part formed in the form of covering the measurement space in the open part of the body part, and a sensor coupling part formed therein through which a plurality of sensor holes are formed through the measurement space, and a sensor of the cover part Consists of an air quality sensor that is respectively coupled to the hole to measure the air quality inside the measurement space, and a PCB substrate coupled to the cover from the outside of the air quality sensor, and a regulator is coupled to one side of the air inlet of the main body to the inside of the measurement space. The pressure of the incoming air is adjusted to 2 ~ 3 bar, and a partition member 600 having a porous characteristic is coupled to the measuring space of the main body, and a pair of the partition member is installed adjacent to the air inlet and the air outlet. An analysis area is formed for the part where the air quality sensor is coupled between a pair of barrier members, and the flow of air flowing into the analysis area through the barrier member is kept constant, and the air flow can be evenly distributed throughout the analysis area. By doing so, it improves the accuracy of air quality measurement, and provides an air quality measuring device for a diving and breathing reservoir, characterized in that the air that has become higher than atmospheric pressure through a regulator is secondarily decompressed to a pressure corresponding to the atmospheric pressure level.

The present invention includes a decompression configuration in the device itself, and an environment capable of measuring the air charged in an air container that could not be measured before is provided, and is optimized for air quality measurement due to the combination of the body part, the cover part, and various air quality sensors. It has the effect of improving the measurement accuracy by providing a structured structure.

In addition, the present invention is composed of a structure in which the measurement space is formed open on the main body and the measurement space is sealed by a cover portion to which the air quality sensor is coupled, so that cleaning inside the measurement space is easy, and sensor replacement and sensor type expansion are possible. There is an easy effect.

1 is a perspective view showing an air quality measuring apparatus for a diving breathing reservoir of the present invention
Figure 2 is an exploded perspective view showing the configuration of the air quality measuring apparatus of the reservoir for diving breathing of the present invention
3 is a perspective view showing a state in which the partition member and the cover part are separated from the main body of the present invention
Figure 4 is a cross-sectional view showing the internal structure of the air quality measuring apparatus for a diving breathing reservoir of the present invention
5 is a perspective view showing a state in which the air quality sensor coupled to the cover part of the present invention is separated

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted.

The present invention relates to an apparatus for measuring air quality in a reservoir for diving breathing, the configuration of which is formed with an air inlet 110 on one side of the lower side, and an air outlet 120 on the upper side, as shown in Figs. A measurement space (S) is formed between the inlet (110) and the air outlet (120), and the body portion (100) in which the measurement space (S) is open to one side, and an open portion of the body portion (100) Doedoe coupled in a form covering the measurement space (S), a plurality of sensor holes 220 is formed through the measurement space (S) a sensor coupling portion 210 is formed, the cover portion 200 is formed, and the cover An air quality sensor 300 coupled to the sensor hole 220 of the part 200 to measure the air quality inside the measurement space S, and a PCB coupled to the cover part 200 from the outside of the air quality sensor 300 It characterized in that it consists of; a substrate 400.

The air quality measuring apparatus of the present invention is a configuration that is mounted inside an air analyzer (not shown), and the case is coupled so that it is not exposed to the outside, and a separate direct reading type detection tube is installed in the case through a valve that distributes gas to prevent oil. Make it possible to measure the mist. In addition, a display may be installed in the case, which is connected to the PCB substrate 400 by an electrical signal to display the air quality measurement state.

The present invention is largely composed of a main body portion 100, a cover portion 200, a PCB substrate 400, as shown in Figure 2, the cover portion 200 is coupled to the body portion 100, and the cover portion ( It is sequentially combined in the form of coupling the PCB substrate 400 to 200). And the air quality sensor 300 is a configuration that is coupled to the cover portion 200, but when actually coupled, the PCB substrate 400 to the cover portion 200 in a state in which the air quality sensor 300 is coupled to the PCB substrate 400. Will be combined. And it is preferable to first combine the sealing O-ring (O-ring) before combining the PCB substrate 400 for the airtightness of the cover portion 200.

The body part 100 of the present invention has a measuring space S formed inside, and an air inlet 110 through which the air to be measured is introduced into the measuring space S is formed on one lower side of the body part 100 And, an air outlet 120 through which the air measured in the measurement space S is discharged to the outside is formed on the upper part of the main body 100.

In addition, the air to be measured is not directly introduced into the air inlet 110, and a regulator 500 is coupled to one side of the air inlet 110 to control the pressure of the air introduced into the measurement space (S). In general, since the pressure of the incoming air during air measurement is a high pressure, air quality is measured by reducing the pressure to atmospheric pressure in order to increase the accuracy of air quality measurement. Here, it is preferable that the pressure of the air regulated through the regulator 500 is at a level of 2 bar to 3 bar.

And the main body part 100 of the present invention is formed with a measuring space (S), the measuring space (S) has a structure in which the entire one side is open, and the cover part 200 is coupled to the open surface. The measurement space (S) is sealed. When configured in this way, when foreign matters are adsorbed into the measurement space (S) due to long-term use, only the cover portion 200 can be separated and cleaned easily.

In addition, it is preferable that a guide wall 510 is formed at one side of the regulator 500 so that the air introduced after being depressurized is guided in the direction in which the air quality is measured.

It is preferable that the guide wall 510 is configured in a plurality as shown in the drawing so that it can be guided in a direction in which air quality is measured, and formed in a form bent in the guide direction. It is capable of performing a function of distributing and diffusing gas and preventing eddy currents through the guide wall 510.

The guide wall 510 is formed in the same shape on the body part 100 and the cover part 200, respectively, as shown in the drawing, and when the cover part 200 is coupled to the body part 100, the flow of fluid It is desirable to be configured to be able to control.

In addition, in the measurement space S of the main body 100, as shown in Figs. 3 to 4, the partition wall member 600 having a porous characteristic is coupled to the analysis area for the portion to which the air quality sensor 300 is coupled. It has a structure in which (A) is formed. The reason for partitioning the analysis area (A) through the partition member 600 is to make the flow of air flowing into the analysis area (A) through the partition member 600 constant, and the flow of air is the analysis area (A) By allowing it to be evenly distributed throughout, the accuracy of air quality measurement can be improved.

The partition wall member 600 performs not only a diffusion effect of air flow, but also a decompression function and a flow rate reduction function due to resistance to fluid flow. Therefore, after the first decompression is achieved through the regulator 500 to about 2 bar to 3 bar, which is slightly higher than the atmospheric pressure, in the analysis area (A) in which the air quality is measured substantially, 1.2 corresponding to the atmospheric pressure level through the partition member 600 The pressure is reduced to about bar to 1.3 bar.

And the partition wall member 600 is each coupled to the lower end and the upper end of the analysis region (A) as shown in the figure, it is preferable that the analysis region (A) is formed between a pair of the partition member (600). That is, they are respectively installed on the side where air flows into the analysis area (A) and the side from which the air escapes from the analysis area (A) to form a complete analysis area (A) by a pair of partition wall members (600).

The partition wall member 600 is preferably applied with a metal material, a porosity of 30%, and a pore size of 10 μm (micrometer). In addition, the partition wall member 600 is formed in a block shape as shown in the figure and is coupled to the measurement space S of the main body 100. For smooth coupling of the partition wall member 600, the measurement space S of the main body 100 ) It is preferable that a fixing groove 130 is formed in one position so that the partition member 600 can be fitted inside, and both sides of the partition wall member 600 are inserted into the fixing groove 130 to be fixed.

In addition, a pressure sensor 700 for measuring the pressure on the analysis area A may be further installed in the main body 100. By measuring the pressure in the analysis area A in which air quality is measured through the pressure sensor 700, the air quality measurement environment is checked together, and it is possible to determine whether the decompression through the regulator 500 and the partition member 600 has been properly performed. There will be.

In addition, a moisture sensor 800 for measuring moisture in air flowing into the measurement space S is installed in the main body 100. The moisture sensor 800 is installed in the measurement space (S), and as shown in the drawing, it is preferable that the moisture sensor 800 is installed in a space where air is initially introduced, not in the analysis area (A). Since the moisture measurement by the moisture sensor 800 does not react sensitively according to the distribution of incoming air and there is almost no measurement error, it may be installed in a different location from the pressure sensor 700 and the air quality sensor 300. There is.

The cover portion 200 of the present invention is coupled to the open portion of the body portion 100, and a sensor coupling portion 210 having a plurality of sensor holes 220 penetrating through the measurement space S is formed. . The sensor coupling part 210 is formed in a shape protruding outward of the cover part 200 according to the size of the air quality sensor 300, so that interference with the PCB substrate 400 coupled to the outside of the cover part 200 Make sure it doesn't happen.

When the PCB substrate 400 is coupled to the protruding surface of the sensor coupling unit 210 through such a structure, the PCB substrate 400 becomes a structure supporting the air quality sensor 300 from the outside, and a separate air quality sensor ( Even if there is no means for fixing 300), the air quality sensor 300 is not separated by only the combination of the PCB substrate 400 and the combined state can be maintained.

And it is preferable that a gasket 230 is disposed between the cover part 200 and the body part 100 for a sealing effect, and the shape of the gasket 230 is also in the same shape as the drawing, taking into account the measurement space (S). It must be formed.

The air quality sensor 300 of the present invention corresponds to a configuration that is coupled to the sensor hole 220 of the cover part 200 to measure the air quality of the analysis area A in the measurement space S. The air quality sensor 300 is composed of a module-type O2 sensor 310, a CO sensor 320, and a VOC sensor 330. There may be various types of the air quality sensor 300 in addition to this, and the position and number of the sensor holes 220 of the cover part 200 may vary according to the type of the air quality sensor 300.

Exceptionally, when the air quality sensor 300 is not a modular sensor, it may be installed on one side of the main body 100 instead of the cover 200. The air quality sensor 300 installed on one side of the main body is a CO2 sensor 340 and measures the air quality in the analysis area A.

In the above, the present invention has been described with reference to the above embodiments, but it is of course possible to implement various modifications within the scope of the technical idea of the present invention.

S: Measurement space A: Analysis area
100: main body 110: air inlet
120: air outlet 130: fixed groove
200: cover part 210: sensor coupling part
220: sensor hole 230: gasket
300: air quality sensor 310: O2 sensor
320: CO sensor 330: VOC sensor
340: CO2 sensor 400: PCB substrate
500: regulator 510: guide wall
600: bulkhead member 700: pressure sensor
800: moisture sensor

Claims (7)

In the air quality measuring device for a diving breathing reservoir,
An air inlet 110 is formed in the lower one side, and an air outlet 120 is formed in the upper part, and a measurement space S is formed between the air inlet 110 and the air outlet 120, and a measurement space ( S) the body portion 100 is open, and
The sensor coupling part 210 is formed to cover the measurement space S in the open part of the main body 100, and a plurality of sensor holes 220 penetrate into the measurement space S. With the cover portion 200,
An air quality sensor 300 that is coupled to the sensor hole 220 of the cover part 200 to measure the air quality inside the measurement space S,
Consists of; a PCB substrate 400 coupled to the cover part 200 from the outside of the air quality sensor 300,
A regulator 500 is coupled to one side of the air inlet 110 of the main body 100 to adjust the pressure of air flowing into the measurement space S to 2 to 3 bar,
A partition member 600 having a porous characteristic is coupled to the measurement space S of the main body 100, and a pair of the partition member 600 is installed adjacent to the air inlet and the air outlet to form a pair of partition walls. An analysis area (A) is formed for the portion to which the air quality sensor 300 is coupled between the members 600,
Through the partition member 600, the flow of air flowing into the analysis area (A) is made constant, and the air flow is evenly distributed throughout the analysis area (A), thereby improving the accuracy of air quality measurement, and the regulator Air quality measuring device for a diving and breathing reservoir, characterized in that the air that has become higher than atmospheric pressure through 500 is secondarily decompressed to a pressure corresponding to the atmospheric pressure level.
delete The method of claim 1,
An air quality measuring apparatus for a diving breathing reservoir, characterized in that a guide wall 510 is formed at one side of the regulator 500 to guide the air introduced after being depressurized in a direction in which air quality is measured.
delete The method of claim 1,
An air quality measuring device for a diving breathing reservoir, characterized in that a pressure sensor 700 for measuring the pressure on the analysis area A is installed in the main body 100
The method of claim 1,
An air quality measuring apparatus for a diving breathing reservoir, characterized in that a moisture sensor 800 for measuring the moisture in the air flowing into the measuring space S is installed in the main body 100
The method of claim 1,
The air quality sensor 300 is an air quality measuring device of a reservoir for diving breathing, characterized in that consisting of a module-type O2 sensor 310, a CO sensor 320, and a VOC sensor 330

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