KR102220656B1 - Dive system with fuction for component anaysis of high-pressured gas - Google Patents

Abstract

The present invention relates to a diving system having a high-pressure gas component analysis function, according to one example, a gas supply tank for supplying a compressor body having a high pressure above atmospheric pressure; Doedoe worn by the underwater diver, a wearing member including a breathing apparatus for providing the diver with a compressor body supplied from the gas supply tank; A gas supply pipe connecting the gas supply tank and the breathing apparatus; And a component analysis sensor that is replaceably installed on the gas supply pipe and detects the ratio of harmful components contained in the compressor body output from the gas supply tank to the harmful component ratio in the compressor body. A diving system equipped with is proposed.

Description

Diving system with high-pressure gas component analysis function {DIVE SYSTEM WITH FUCTION FOR COMPONENT ANAYSIS OF HIGH-PRESSURED GAS}

The present invention relates to a diving system with a high-pressure gas component analysis function. Specifically, it relates to a diving system equipped with a high-pressure gas component analysis function capable of detecting or analyzing harmful component substances or harmful component ratios contained in breathing gas.

In general, compressed air is used as a breathing gas for underwater diving. In general, a personal compressed air container is provided, and the compressed air is used as a breathing gas and diving is performed. In the case of industrial diving, since it is necessary to stay in the water longer than in the case of general diving, a method of supplying breathing gas from the surface rather than using a personal compressed air tank is taken. This method is called surface-fed diving.

In diving systems, breathing gas is supplied by varying the pressure of the supply gas according to the depth of the water or using a mixed gas. In diving, while submerging from the surface to the surface or ascending from the water to the surface, it is necessary to supply the breathing gas at an appropriate pressure with an appropriate respiratory gas. Since the pressure of the gas supplied from each depth is different, the person handling the diving device requires a high level of skill, and the diving system equipped with the high-pressure gas component analysis function is prepared for some failures of the parts used and various safety devices. need.

The diving system requires a gas supply tank and a breathing device to supply breathing gas to the underwater diver, a gas supply pipe connecting the gas supply tank and the breathing device, and equipment worn by divers. At this time, the compressor body supplied from the gas supply tank stores the air compressed by the compressor in advance in the case of scuba diving, and in the case of surface-supply diving, the compressor compresses the gas in real time and supplies it to the gas supply tank. In the case of divers, the compressed body is supplied through a respirator to breathe. However, if the compressed body contains pollutants such as harmful substances or the component ratio is harmful, it can cause a significant risk to health. There is a concern that harmful components from outside are included in the process of compressing the compressor body supplied from the gas supply tank in advance or compressing it in real time.

Conventionally, in the case of scuba diving, risk was prevented by checking whether the compressed air is stored in the gas supply tank or before diving to check whether or not harmful components are included in the compressed air, but when diving is conducted by overlooking the harmful component check, the aforementioned problem Can occur. In addition, even in the case of conventional surface-supplied diving, the above-described problem may be caused because it is not possible to confirm whether or not harmful components are included in the compressed body or whether harmful components generated during compression or discharge are included.

US Patent Publication No. US 5865877 (announced on February 2, 1999) Korean Registered Patent Publication No. 10-1018653 (announced on March 4, 2011) Republic of Korea Utility Model Publication No. 20-0397869 (announced on Oct. 10, 2005)

In order to solve such a conventional problem, the present invention installs a replaceable component analysis sensor on the gas supply pipe of the diver to detect or analyze the harmful component substances or the harmful component ratio contained in the breathing gas supplied to the breathing apparatus. This is to propose a diving system equipped with a high-pressure gas component analysis function that can supply suitable breathing gas to divers by judging whether there is an abnormality in the supply gas provided to divers.

In order to solve the above-described problem, according to one aspect of the present invention, there is provided a diving system, comprising: a gas supply tank for supplying a compressor body having a high pressure above atmospheric pressure; Doedoe worn by the underwater diver, a wearing member including a breathing apparatus for providing the diver with a compressor body supplied from the gas supply tank; A gas supply pipe connecting the gas supply tank and the breathing apparatus; And a component analysis sensor that is replaceably installed on the gas supply pipe and detects the ratio of harmful components contained in the compressor body output from the gas supply tank to the harmful component ratio in the compressor body. A diving system equipped with is proposed.

In one example, a diving system having a high-pressure gas component analysis function includes: a gas auxiliary supply means for temporarily or partially storing an auxiliary gas for breathing at a preset pressure or a compressed body supplied from a gas supply tank; A valve system for blocking continuous supply of gas from the gas supply tank to the breathing apparatus according to the control and starting a temporary supply of gas from the gas auxiliary supply means to the breathing apparatus; And it may further include a control unit for controlling the valve system according to the setting by receiving the detection or analysis result of the harmful component substance or the harmful component ratio from the component analysis sensor.

At this time, in one example, the valve system is any one of a first check valve, a switching valve, and a three-way valve at the connection part between the gas supply pipe and the pipe connected to the gas auxiliary supply means for storing the auxiliary gas for breathing at a preset pressure. Or a second check valve installed at the front end of the gas auxiliary supply means for temporarily or partially storing the compressor body supplied from the gas supply tank, and shutting off the continuous supply of gas and starting the temporary supply of gas according to the control. I can.

In addition, in one example, the diving system having a high-pressure gas component analysis function may further include an alarm display unit that displays an alarm display signal according to the detection or analysis result of the component analysis sensor.

At this time, in one example, the alarm display unit displays the alarm display signal so that the diver or others can recognize it, but the display on the viewing window of the helmet among the wearing members, the audio signal output into the helmet, and the diver's viewing range of the wearing member other than the helmet The alarm display signal may be displayed in at least one of a warning lamp display, a warning lamp or an audio signal display around the component analysis sensor or around the gas supply pipe.

In another example, the component analysis sensor is fastened between the male and female connectors on the gas supply line, and has an object that chemically reacts or physically couples with harmful constituent substances on the flow path to generate a signal according to the chemical reaction or physical bonding, and The female connector provided on the supply tank side has a valve body that is pushed backward by contacting one projection of the component analysis sensor, which has the same structure as the connecting projection of the male connector, to open the pipeline, and an elastic body that elastically supports the valve body. can do.

In this case, in one example, the object performing a chemical reaction or physical coupling is provided in a mesh structure provided on the inner flow path of the component analysis sensor, and the object reacting or combining with harmful component substances is different for each division area of the mesh structure. can do.

In addition, according to an example, the harmful component material is at least one of fine dust, nitric oxide, sulfur oxide, carbon monoxide, and carcinogen, and the harmful component ratio may be a component ratio that exceeds or falls short of the normal component ratio or the set component ratio of oxygen or carbon dioxide. have.

At this time, in one example, the diving system equipped with the high-pressure gas component analysis function is installed interchangeably in the front side of the component analysis sensor or in the component analysis sensor, or when continuous supply of the compressed body to the gas supply tank is made, the gas It is installed in the direction of the supply side of the supply tank and may further include a filter member for filtering harmful component substances, harmful component substances, and moisture.

According to another example, the pressure of the compressor body supplied from the gas supply tank may be in the range of at least one of 2 to 300 bar, 2 to 50 bar, and 5 to 15 bar.

In addition, in one example, the diving system having a high-pressure gas component analysis function may be a scuba diving system in which a diver wears a gas supply tank or a surface-supply diving system in which a gas supply tank is installed on a water structure.

At this time, in one example, the surface-supply diving system is installed on the aquatic structure and further includes a compressor that sucks external air and compresses it at high pressure, and the gas supply pipe allows communication between the communication device on the wearing member and the equipment on the floating structure. A connection pipe is formed by being tied together with the communication path to be performed, and the component analysis sensor may be installed interchangeably at the water-exposed portion of the gas supply pipe or the output side of the gas supply tank.

In addition, in this case, in an example, when the diving system includes a gas auxiliary supply means for temporarily or partially storing a breathing auxiliary gas at a preset pressure or a compressor body supplied from a gas supply tank, the gas auxiliary supply means The auxiliary tank for storing the auxiliary gas for breathing at a preset pressure is worn by the diver or installed on the aquatic structure, and the auxiliary storage for temporarily or partially storing the compressed body as a gas auxiliary supply means is provided on the connection side of the breathing apparatus of the gas supply pipe. To the respirator connection side and branched may be provided on the wearing member.

According to an embodiment of the present invention, a replaceable component analysis sensor is installed on the gas supply pipe to the diver to enable detection or analysis of harmful component substances or harmful component ratios contained in the breathing gas supplied to the breathing apparatus. By doing so, it is possible to supply suitable breathing gas to the diver by judging whether there is an abnormality in the supply gas provided to the diver.

In one example, it is possible to identify harmful components contained in external air or generated during compression or discharge, and further block them to protect the health of the diver.

Even if the effect is not directly mentioned in the specification of the present invention, various characteristic effects within the understanding of those of ordinary skill in the art from the features of the configuration to the various configurations included in various embodiments and modifications of the present invention It is obvious that it can be derived.

1A is a block diagram schematically showing a diving system having a high-pressure gas component analysis function according to an embodiment of the present invention.
1B is a block diagram schematically showing a diving system having a high-pressure gas component analysis function according to another embodiment of the present invention.
1C is a block diagram schematically showing a diving system equipped with a high-pressure gas component analysis function according to another embodiment of the present invention.
Figure 2a is a block diagram schematically showing a diving system with a high-pressure gas component analysis function according to another embodiment of the present invention.
Figure 2b is a block diagram schematically showing a diving system having a high-pressure gas component analysis function according to another embodiment of the present invention.
Figure 2c is a block diagram schematically showing a diving system with a high-pressure gas component analysis function according to another embodiment of the present invention.
3A is a diagram schematically showing a diving system having a high-pressure gas component analysis function according to another embodiment of the present invention.
3B is a diagram schematically showing a diving system having a high-pressure gas component analysis function according to another embodiment of the present invention.
3C is a diagram schematically showing a diving system having a high-pressure gas component analysis function according to another embodiment of the present invention.

Embodiments of the present invention for achieving the above object will be described with reference to the accompanying drawings. In the present description, the same reference numerals mean the same configuration, and a secondary description may be omitted in order to promote understanding of the present invention to those of ordinary skill in the art.

In the present specification, when one component forms a coupling relationship such as connection or coupling in a relationship with another component, or a transmission relationship such as transmission or transfer, unless there is a limitation of'direct', a'direct' coupling relationship Not only in the form of a transmission relationship, but also in the form of a coupling relationship by a medium or a transmission relationship through a transmission relationship, as another component is related therebetween. In addition, the same applies when terms that can imply the meaning of'contact' such as'top','top','bottom', and'bottom' are included. In addition, terms indicating direction should be interpreted as a relative concept to the element on which they are referenced.

In addition, it should be noted that in the present specification, even though the configuration is expressed in the singular, it may be used as a concept representing the entire plurality of configurations unless interpreted contrary to or contradictory to the concept of the invention.

In addition, in this specification, the description of words such as'comprise' and'comprising' and terms derived therefrom may indicate the possibility of addition, combination, or combination of one or more other elements to the original element or elements. It is not excluded, and further, the description of words having meanings such as'to have','to be composed', and terms derived from them are also the addition, combination, or combination of one or more other elements to the original element or elements. The possibility of addition or combination of one or more other components should not be excluded if the original element or elements are not lost in their features, functions, and/or properties.

The drawings referred to in the present specification are examples for explaining an embodiment of the present invention, and the shape, size, thickness, etc. may be exaggerated for effective description of technical features.

[Diving system with high pressure gas component analysis function]

A diving system equipped with a high-pressure gas component analysis function according to an aspect of the present invention will be described in detail with reference to the drawings. In this case, reference numerals not described in the referenced drawings may be reference numerals in other drawings representing the same configuration. In this case, it should be noted that the configurations disclosed in each drawing may be partially omitted or modified according to the modification of the embodiment.

1A is a block diagram schematically showing a diving system having a high-pressure gas component analysis function according to an embodiment of the present invention, and FIG. 1B is a diving system having a high-pressure gas component analysis function according to another embodiment of the present invention. A block diagram schematically showing the system, and FIG. 1C is a block diagram schematically showing a diving system having a high-pressure gas component analysis function according to another embodiment of the present invention, and FIG. 2A is another embodiment of the present invention. A block diagram schematically showing a diving system having a high-pressure gas component analysis function according to an example, and FIG. 2B is a block diagram schematically showing a diving system having a high-pressure gas component analysis function according to another embodiment of the present invention. , Figure 2c is a block diagram schematically showing a diving system with a high-pressure gas component analysis function according to another embodiment of the present invention. 3A is a diagram schematically showing a diving system having a high-pressure gas component analysis function according to another embodiment of the present invention, and FIG. 3B is a diving system having a high-pressure gas component analysis function according to another embodiment of the present invention. FIG. 3C is a schematic diagram of a system, and FIG. 3C is a diagram schematically illustrating a diving system having a high-pressure gas component analysis function according to another embodiment of the present invention.

1A to 3C, a diving system having a high-pressure gas component analysis function according to an example includes a gas supply tank 20, a wearing member 100, a gas supply pipe 40a, and a component analysis sensor 30. Include. In addition, referring to Figs. 1b, 1c, 2b, 2c, 3b and/or 3c, in one example, a diving system having a high-pressure gas component analysis function includes a gas auxiliary supply means 25, a valve system 50, and a control unit ( 70) may be further included. Referring to FIGS. 1C and 2C, in another example, a diving system having a high-pressure gas component analysis function may further include an alarm display unit 60. In addition, referring to FIGS. 1C and 2C, in another example, the diving system having a high-pressure gas component analysis function may further include a filter member 80. Referring to FIGS. 2A to 3C, in another example, the diving system having a high-pressure gas component analysis function may be a surface-supplied diving system further including a compressor 10.

First, the gas supply tank 20 supplies a breathing compressor body having a high pressure above atmospheric pressure. The wearing member 100 is worn by the underwater diver, and includes a breathing apparatus that provides the compressed body supplied from the gas supply tank 20 to the diver. The gas supply pipe 40a connects the gas supply tank 20 and the breathing apparatus. The component analysis sensor 30 is replaceably installed on the gas supply line 40a and detects the harmful component substances contained in the output compressor body or the harmful component ratio of the compressor body.

In addition, in one example, the gas auxiliary supply means 25 stores auxiliary gas for breathing at a preset pressure or temporarily or partially stores the compressor body supplied from the gas supply tank 20. The valve system 50 blocks the continuous supply of gas from the gas supply tank 20 to the breathing apparatus according to the control, and starts the temporary supply of gas from the gas auxiliary supply means 25 to the breathing apparatus. The control unit 70 controls the valve system 50 according to the setting by receiving the detection or analysis result of the harmful component substance or the harmful component ratio from the component analysis sensor 30.

In another example, the alarm display unit 60 displays an alarm display signal under the control of the control unit 70 according to the detection or analysis of the component analysis sensor 30.

In addition, in another example, the filter member 80 is installed interchangeably on the front side of the component analysis sensor 30 or installed within the component analysis sensor 30, or of a continuous compressor body to the gas supply tank 20. When the supply is made, it is installed in the direction of the supply side to the gas supply tank 20 and filters harmful constituent substances, harmful constituent substances and moisture.

In one example, the diving system with a high-pressure gas component analysis function is a surface-supplied diving system and may further include a compressor 10 at this time. The compressor 10 is installed on the water-phase structure 1 and compresses it at high pressure by sucking external air.

For example, in one example, the diving system having a high-pressure gas component analysis function may be a scuba diving system in which a diver wears a gas supply tank or a surface-supply diving system in which a gas supply tank is installed on a water structure.

Hereinafter, each configuration will be described in more detail with reference to the drawings.

Gas supply tank (20)

1A to 3C, the gas supply tank 20 supplies a breathing compressor body having a high pressure above atmospheric pressure.

For example, in one example, the pressure of the compressor body supplied from the gas supply tank 20 may range from 2 to 300 bar. In a diving system, the pressure of the breathing compressor varies depending on the depth of diving. The deeper the diving depth, the more a pressure of 100 bar or more may be required. If the dive depth is shallow, relatively low pressure is sufficient. In another example, the pressure of the compressor body supplied from the gas supply tank 20 may range from 2 to 50 bar. The range of 2 to 50 bar may be the pressure applied in diving at depths of around 30 m or surface-supplied diving. In another example, the pressure of the compressor body supplied from the gas supply tank 20 may range from 5 to 15 bar. The pressure range of 5 to 15 bar can be applied to surface-supplied diving systems within or outside of 30 m.

For example, in one example, when the diving system is scuba diving, the gas supply tank 20 may be an air tank for scuba.

Referring to Figures 2a to 3c, in another example, when the diving system is a surface-supplied diving system, the gas supply tank 20 is installed on the aquatic structure 1, and a breathing compressor body having a high pressure of atmospheric pressure or higher from the compressor 10 It can be provided and supplied as a respiratory device. For example, the water structure 1 may be floating on the water such as a ship or fixed on the water. For example, the water structure 1 may be a ship or a barge.

For example, when the diving system is a scuba diving, in the process of inhaling and compressing external air in advance to obtain a compressed body supplied from the gas supply tank 20 or in the process of storing the compressed gas in the gas supply tank 20 As pollutants are introduced or composed of a component ratio that is outside the set component ratio, it is supplied to the diver 3 and may cause problems in the health or activities of the diver 3. In addition, as in the case where the diving system is a surface-supply diving system, the compressed gas is sucked in and compressed by the compressor 10, which provides the compressor body supplied from the gas supply tank 20. In the process of providing to (20), pollutants are introduced or are supplied to divers (3) by being composed of component ratios outside the set component ratio, which may cause problems in the health or activities of the diver (3). For example, in the case of a surface-supplied diving system, the work environment depends on the natural environment and is difficult to control, so inflow problems such as pollutants may occur. Therefore, as in the embodiment of the present invention, prior detection is required before supplying to the diver 3 by providing the component analysis sensor 30 to be described later. Depending on the embodiment, a filter member 80 for filtering contaminated gas may be added.

Wearing member (100)

1A to 3C, the wearing member 100 is worn on the underwater diver 3. The wearing member 100 includes a breathing apparatus that provides a compressor body supplied from the gas supply tank 20 to the diver 3.

For example, the wearing member 100 may include a helmet 110, and the breathing apparatus may be provided on the helmet 110 worn by the diver 3. For example, the breathing apparatus is a breathing regulator, and may be integrally provided with the helmet 110. For example, in the case of a surface-supplied diving system, a breathing device may be integrally provided with the helmet 110. For example, according to the embodiment, the breathing apparatus may be worn by the diver 3 without the helmet 110. For example, in the case of a scuba diving system, a regulator, which is a breathing device, can be directly worn by the diver 3 without a helmet 110.

For example, the wearing member 100 may include a wetsuit 130 in addition to the helmet 110 worn by the diver 3. Depending on the embodiment, the portion connected to the connector 40 to be described later may be a respirator of the helmet 110 or a temporary scissor space in the wetsuit 130.

For example, an alarm display unit 60 to be described later may be provided on the wearing member 100. For example, an alarm display unit 60 may be provided on the helmet 110 or the wetsuit 130.

Gas supply pipe (40a) to connection pipe (40)

1A to 3C, the gas supply pipe 40a connects the gas supply tank 20 and the breathing apparatus.

For example, in one example, although not shown, a male and female connector may be provided on the gas supply line 40a. At this time, a component analysis sensor 30 may be installed between the male and female connectors. At this time, the female connector (not shown) provided on the side of the gas supply tank 20 is in contact with one protrusion of the component analysis sensor 30 having the same structure as the connecting protrusion of the male connector (not shown), A valve body (not shown) that is pushed to open the conduit and an elastic body (not shown) that elastically supports the valve body, such as a spring, may be provided therein.

For example, in one example, referring to FIGS. 2A to 3C, when the diving system is a surface-supplied diving system, the gas supply pipe 40a may be bound together with the communication path 40b to form the connection pipe 40 . The connection pipe 40 includes a gas supply pipe path 40a and a communication path 40b. The gas supply pipe 40a connects the gas supply tank 20 and the breathing apparatus. The communication path 40b performs communication between the communication device on the wearing member 100 and the equipment on the waterborne structure 1.

Component Analysis Sensor(30)

Referring to Figures 1a to 3c, the component analysis sensor 30 is installed to be replaced on the gas supply pipe (40a). The component analysis sensor 30 detects the harmful component substances contained in the compressor body output from the gas supply tank 20 or the harmful component ratio of the compressor body.

For example, in one example, the harmful component material may be at least one or more of fine dust, nitric oxide, sulfur oxide, carbon monoxide, and carcinogen. In addition, the harmful component ratio may be a component ratio that exceeds or falls below the normal component ratio or the set component ratio of oxygen or carbon dioxide. For example, the normal component ratio of oxygen or carbon dioxide refers to the normal component ratio at atmospheric pressure, and the set component ratio of oxygen or carbon dioxide refers to the component ratio required according to the depth of diving because high concentration oxygen is required in the case of deep diving.

For example, in one example, although not shown, the component analysis sensor 30 is fastened between the male and female connectors on the gas supply line 40a, and includes an object that chemically reacts or physically couples with harmful constituents on the flow path. It is possible to generate a signal according to the combination.

Although not shown, in one example, an object that performs a chemical reaction or a physical combination is provided in a mesh structure provided on the inner flow path of the component analysis sensor 30, and reacts with harmful constituents for each division area of the mesh structure. The objects to be combined can be different.

For example, in one example, when the diving system is a surface-supplied diving system, the component analysis sensor 30 may be installed interchangeably on the water exposed portion of the gas supply pipe 40a or on the output side of the gas supply tank 20. I can.

Next, with reference to FIGS. 1b, 1c, 2b, 2c, 3b, and/or 3c, a diving system having a high-pressure gas component analysis function according to an example will be described. In one example, the diving system with a high-pressure gas component analysis function may further include a gas auxiliary supply means 25, a valve system 50, and a control unit 70.

Gas auxiliary supply means (25)

Referring to Figures 1b, 1c, 2b, 2c, 3b and/or 3c, the gas auxiliary supply means 25 stores the auxiliary gas for breathing at a preset pressure or the compressor body supplied from the gas supply tank 20 Save temporary or partial. For example, the gas auxiliary supply means 25 is an auxiliary tank 25a for storing auxiliary gas for breathing at a preset pressure or an auxiliary storage 25b for temporarily or partially storing the compressed body supplied from the gas supply tank 20. I can.

For example, in one example, the auxiliary tank 25a for storing the auxiliary gas for breathing at a preset pressure as the gas auxiliary supply means 25 may be worn on the diver 3 or installed on the aquatic structure 1, Or the auxiliary storage (25b) for temporarily or partially storing the compressed body as the gas auxiliary supply means (25) is provided on the connection side of the breathing apparatus or the connection side of the breathing apparatus of the gas supply pipe (40a) Can be provided in.

For example, when the diving system is a scuba diving system, the auxiliary tank 25a may be worn by the diver 3, and the auxiliary reservoir 25b may be provided on the gas supply pipe 40a or the wearing member 100. If the diving system is a surface-supplied diving system, the auxiliary tank 25a can be installed on the aquatic structure 1 or worn on the diver 3, and the auxiliary storage 25b is a gas supply pipe 40a exposed to the water. It may be provided on or on the breathing apparatus and the connection side gas supply pipe 40a or the wearing member 100 of the underwater diver (3).

Valve system(50)

1b, 1c, 2b, 2c, 3b and/or 3c, the valve system 50 cuts off the continuous supply of gas from the gas supply tank 20 to the breathing apparatus according to the control, and the gas auxiliary supply means 25 Start the temporary supply of gas from the to the respiratory device. The continuous supply of gas refers to the continuous supply of breathing gas from the gas supply tank 20 to the breathing apparatus, and the temporary supply of gas is the supply of breathing gas to the breathing apparatus from the gas auxiliary supply means 25, not the gas supply tank 20. Says that this is done.

For example, in one example, the valve system 50 is a first check valve at a connection portion between the gas supply pipe 40a and the pipe connected to the gas auxiliary supply means 25 for storing the auxiliary gas for breathing at a preset pressure. 51b), a switching valve, and a three-way valve may be provided. For example, when the first check valve 51b is provided at the connection part between the gas supply pipe 40a and the pipe connected to the gas auxiliary supply unit 25, the side of the pipe connected to the gas auxiliary supply unit 25 and the gas supply pipe ( The first check valve 51b may be provided in two places on 40a). For example, when a switching valve or a three-way valve is provided at a connection portion between the gas auxiliary supply means 25 and the gas supply pipe 40a, the gas supply path is changed or changed according to the control.

Or in another example, the valve system 50 includes a second check valve 51a installed at the front end of the gas auxiliary supply means 25 for temporarily or partially storing the compressor body supplied from the gas supply tank 20. Can be equipped. In each example, the valve system 50 may cut off the continuous supply of gas and initiate a temporary supply of gas according to the control. For example, the gas auxiliary supply means 25 is an auxiliary storage 25b that temporarily or partially stores the compressed body supplied from the gas supply tank 20, and the auxiliary storage 25b is branched from the connection side of the respirator to partially separate the compressed body. In the case of providing a respiratory device according to control after storage, the valve system 50 is installed at the rear end of the auxiliary storage 25b and is opened when the second check valve 51a is shut off according to the control to supply respiratory gas to the breathing device. It may further include a valve.

For example, in one example, the gas auxiliary supply means 25 is an auxiliary tank, and the valve system 50 is provided with or is connected to a connector and a connecting valve connecting the gas supply pipe 40a and the pipe connected to the auxiliary tank. Each of the branch pipes is provided and may include a check valve to block gas flow according to the control.

Control unit 70

Referring to FIGS. 1b, 1c, 2b, 2c, 3b and/or 3c, the control unit 70 receives the detection or analysis result of the harmful component substance or the harmful component ratio from the component analysis sensor 30, and the valve system ( 50).

For example, in one example, the control unit 70 may receive the result of the component analysis sensor 30 and control the alarm display unit 60.

For example, when the diving system is a surface-supplied diving system, the control unit 70 may be installed on the aquatic structure 1 or may be provided on land that is connected to communication equipment of the aquatic structure 1. Alternatively, when the diving system is scuba diving, the control unit 70 may be installed on the wearing member 100.

Alarm display (60)

Referring to FIGS. 1C and/or 2C, in one example, the diving system equipped with a high-pressure gas component analysis function may further include an alarm display unit 60.

The alarm display unit 60 displays an alarm display signal under the control of the control unit 70 according to the detection or analysis of the component analysis sensor 30.

For example, the alarm display unit 60 may be installed on at least one of the waterborne structure 1 and the wearing member 100. For example, in the case of a scuba diving system, the alarm display unit 60 may be installed on the wearing member 100, and in the case of a surface-supplied diving system, the alarm display unit 60 is among the aquatic structures 1 and the wearing member 100 It may be installed on at least one or more.

For example, in one example, the alarm display unit 60 displays an alarm display signal so that the diver 3 or others can recognize it. At this time, the alarm display unit 60 is a display on the viewing window of the helmet 110 of the wearing member 100, an audio signal output into the helmet 110, the view of the diver 3 of the wearing member 100 other than the helmet 110 The alarm display signal may be displayed in at least one of a warning lamp display on a range, a warning lamp or an audio signal display around the component analysis sensor 30 or around the gas supply line 40a. For example, in the case of a surface-supplied diving system, the alarm display unit 60 may be installed around the component analysis sensor 30 or around the gas supply pipe 40a.

Filter member (80)

Referring to FIGS. 1C and/or 2C, in one example, the diving system having a high-pressure gas component analysis function may further include a filter member 80. The filter member 80 filters harmful component substances, harmful component substances, and moisture.

The filter member 80 may be installed interchangeably on the front side of the component analysis sensor 30 or installed in the component analysis sensor 30. Alternatively, when a continuous supply of the compressor body to the gas supply tank 20 is made, that is, in the case of a surface supply type diving system, the filter member 80 may be installed in the supply side direction to the gas supply tank 20. For example, in the case of a surface-supplied submersible system, the filter member 80 includes the external air inlet side of the compressor 10, the outlet side of the compressor 10, the inlet side of the gas supply tank 20, the compressor 10 and the It can be installed interchangeably on the pipeline between the gas supply tanks 20.

<Surface-supplied diving system>

Referring to Figures 2a to 3c, in one example, a diving system equipped with a high-pressure gas component analysis function is a surface-supply diving system in which a gas supply tank 20 is installed on an aquatic structure (1) where a diver wears a gas supply tank. Can be

For example, in one example, the surface-supplied diving system further includes a compressor 10, and the gas supply line 40a is tied together with the communication line 40b to form a connection pipe 40. The component analysis sensor 30 may be installed to be replaceable at the exposed portion of the gas supply pipe 40a or at the output side of the gas supply tank 20.

At this time, the compressor 10 is installed on the waterborne structure 1 and compresses it by sucking external air. The water structure 1 may be a floating or fixed object on a ship or other water. For example, the water structure 1 may be a ship or a barge.

When external air is sucked and compressed by the compressor 10, when the external air contains a pollutant, the pollutant is supplied to the diver 3, which may cause problems in the health or activities of the diver 3. Therefore, as in the embodiment of the present invention, prior detection is required before supplying to the diver 3 by providing the component analysis sensor 30 to be described later. Depending on the embodiment, a filter member 80 for filtering contaminated gas may be added.

In the above, the above-described embodiments and the accompanying drawings are not limited to the scope of the present invention, but are illustratively described to help those of ordinary skill in the art understand the present invention. That is, various embodiments of the present invention may be implemented in various modified forms according to various combinations of the above-described components without departing from the essential characteristics of the present invention. Accordingly, the scope of the present invention should be interpreted according to the invention described in the claims, and includes not only the above-described embodiments, but also various modifications, alternatives, and equivalent embodiments by those of ordinary skill in the art.

1: water structure 3: diver
10: compressor 20: gas supply tank
25: gas auxiliary supply means 25a: auxiliary tank
25b: auxiliary storage 30: component analysis sensor
40: connector 40a: gas supply pipe
50: valve system 51a, 51b: check valve
60: notification display unit 70: control unit
80: filter member 100: wearing member
110: helmet 130: wetsuit

Claims (13)

In the diving system,
A gas supply tank for supplying a compressor body having a high pressure above atmospheric pressure;
A wearing member that is worn on an underwater diver and includes a breathing apparatus for providing the compressor body supplied from the gas supply tank to the diver;
A gas supply pipe connecting the gas supply tank and the breathing apparatus; And
A high-pressure gas, characterized in that it comprises a component analysis sensor that is replaceably installed on the gas supply line and detects the harmful component ratio in the compressor body and the harmful component substances contained in the compressor body output from the gas supply tank. Diving system with component analysis function.
In claim 1,
A gas auxiliary supply means for temporarily or partially storing the auxiliary gas for breathing at a preset pressure or the compressed body supplied from the gas supply tank;
A valve system for blocking continuous supply of gas from the gas supply tank to the breathing apparatus according to control and starting a temporary supply of gas from the gas auxiliary supply means to the breathing apparatus; And
A diving system with a high-pressure gas component analysis function, characterized in that it further comprises a control unit for receiving the detection or analysis result of the harmful component substance or the harmful component ratio from the component analysis sensor and controlling the valve system according to a setting.
In claim 2,
The valve system is provided with any one of a first check valve, a switching valve, and a three-way valve at a connection portion between the gas supply pipe and a pipe connected to the gas auxiliary supply means for storing the breathing auxiliary gas at a preset pressure, or Or a second check valve installed at a front end of the gas auxiliary supply means for temporarily or partially storing the compressor body supplied from the gas supply tank, and block the continuous supply of the gas and temporarily supply the gas according to the control. A diving system with a high-pressure gas component analysis function, characterized in that to initiate.
In claim 1,
A diving system with a high-pressure gas component analysis function, further comprising an alarm display unit for displaying an alarm display signal according to the detection or analysis result of the component analysis sensor.
In claim 4,
The alarm display unit displays the alarm display signal so that the diver or others can recognize it, and a display on the viewing window of the helmet among the wearing members, an audio signal output into the helmet, and the diver's viewing range of the wearing member other than the helmet A diving system with a high-pressure gas component analysis function, characterized in that the alarm display signal is displayed in at least one of a warning lamp display on the top, a warning lamp or an audio signal display around the component analysis sensor or around the gas supply pipe .
In claim 1,
The component analysis sensor is coupled between the male and female connectors on the gas supply line and includes an object that chemically reacts or physically couples with the harmful component material on the flow path to generate a signal according to the chemical reaction or physical combination,
The female connector provided on the side of the gas supply tank is pushed to the rear by contacting one protrusion of the component analysis sensor having the same protrusion as the connecting protrusion of the male connector, and elastically supports the valve body and the valve body to open the pipeline. A diving system with a high-pressure gas component analysis function, characterized in that it has an elastic body therein.
In claim 6,
The object performing the chemical reaction or physical coupling is provided in a mesh structure provided on the inner flow path of the component analysis sensor,
A diving system with a high-pressure gas component analysis function, characterized in that the object reacting or combining with the harmful component material is different for each division area of the mesh structure.
In claim 1,
The harmful component material is at least one or more of fine dust, nitric oxide, sulfur oxide, carbon monoxide, and carcinogen,
The harmful component ratio is a diving system with a high-pressure gas component analysis function, characterized in that the component ratio exceeds or falls below the normal component ratio or the set component ratio of oxygen or carbon dioxide.
In claim 8,
When the compressor body is continuously supplied to the gas supply tank or is installed interchangeably at the front side of the component analysis sensor, or is installed in the component analysis sensor, it is installed in the direction of the supply side to the gas supply tank and the harmful components Submersible system with a high-pressure gas component analysis function, characterized in that it further comprises a filter member for filtering the substances to the harmful substances and moisture.
In claim 1,
A diving system with a high-pressure gas component analysis function, characterized in that the pressure of the compressor body supplied from the gas supply tank is in the range of at least one of 2 to 300 bar, 2 to 50 bar, and 5 to 15 bar.
In any one of claims 1 to 10,
The diving system is a diving system with a high-pressure gas component analysis function, characterized in that the diving system is a scuba diving system in which the diver wears the gas supply tank or a surface-supply diving system in which the gas supply tank is installed on a water structure.
In claim 11,
The surface-supplied diving system is installed on the aquatic structure and further comprises a compressor that sucks external air and compresses it to the high pressure,
The gas supply pipe is tied together with a communication path for performing communication between the communication device on the wearing member and the equipment on the floating structure to form a connection pipe,
The component analysis sensor is a diving system with a high-pressure gas component analysis function, characterized in that installed to be replaceable at the water exposure portion of the gas supply pipe or the output side of the gas supply tank.
In claim 12,
When the diving system includes a gas auxiliary supply means for storing auxiliary gas for breathing at a preset pressure or temporarily or partially storing the compressed body supplied from the gas supply tank, the pressure preset as the gas auxiliary supply means The auxiliary tank for storing the auxiliary gas for breathing is worn by the diver or installed on the aquatic structure, and the auxiliary storage for temporarily or partially storing the compressor body as the gas auxiliary supply means is the breathing apparatus connection side of the gas supply pipe Diving system with a high-pressure gas component analysis function, characterized in that provided on the branch to the respirator connection side and provided on the wearing member.

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