JP6516192B2 - Simplified mixed gas diving unit and simplified mixed gas diving system including the same - Google Patents

Description

  The present invention relates to a diving system.

Conventionally, various proposals have been made for diving systems.
Patent Document 1 discloses a nitrogen / oxygen mixed gas production / supply system for air type diving, in which oxygen high partial pressure nitrogen / oxygen mixed gas of desired oxygen concentration is continuously produced from air at the diving site and supplied to divers. Has been proposed.

  As the diving depth increases, the pressure of about 80% of nitrogen contained in the breathing gas supplied to the diver increases. If the pressure of nitrogen exceeds a certain level, there is a risk that the symptoms of "nitrogen sickness" will appear to the diver by the anesthetic action of nitrogen.

  In order to prevent the above "nitrogen sickness", when performing diving work at a depth of 40 m or less, helium-oxygen mixed gas is used as a breathing gas.

  In this case, a mixed gas diving system 32 as shown in FIG. 13 is used as an example. The conventional mixed gas diving system 32 includes a control container 33 for instructing diving work, a control panel 34 for managing the supply of respiratory gas to the diver, a depth management panel 35 for managing the diving depth of the diver, a work conductor, A simultaneous communication system 36 capable of simultaneous and simultaneous communication with a diver and a deck member, an umbilical hose 37 including a breathing gas hose, a depth control hose, a communication cable, etc., and a medium pressure compressor 38 for supplying breathing gas to a diver , Air curd (air supply device) 39 for back-up of medium pressure compressor 38, high pressure compressor 40 for cylinder charge of air curd 39, repressure tank 41 for emergency treatment at the time of depressive disorder occurrence, materials and equipment are stored. Store container 42, generator 43, lifting equipment 44, mixed gas (helium / oxygen mixed gas) Dollar (mixed gas supplying device) 45 is built is a set-connection.

  The conventional mixed gas diving system 32 constructed in such a configuration is a large-scale equipment, and it takes time to build the system (transport and installation) regardless of the scale of the diving operation. It is unsuitable.

  Moreover, although a simple type diving system has been conventionally adopted, this is a dedicated air having only a gas control panel dedicated to air, and can not cope with the mixed gas required when performing diving work at a water depth of 40 m or more It was a thing.

JP, 2002-68081, A

  SUMMARY OF THE INVENTION An object of the present invention is to provide a simplified mixed gas diving unit having a simple configuration and suitable for diving work at a depth of 40 m or less and a simplified mixed gas diving system including the same.

[1]
The downstream side of the first gas supply path for supplying the first gas to the diving equipment mounted by the diver and the downstream side of the second gas supply path for supplying the second gas to the diving equipment A simplified mixed gas diving unit, comprising: a first gas supply control valve connected to the three-way valve configured to switch the supply of the first gas and the second gas to the diving apparatus. The first gas and the second gas may be supplied to a submersible.

[2]
The simplified mixed gas diving unit according to [1], wherein a first gas exhaust passage is connected to the first gas supply passage upstream of the first gas supply control valve via a first exhaust on-off valve.

[3]
The simplified mixed gas diving unit according to [1] or [2], wherein a second gas exhaust passage is connected to the second gas supply passage upstream of the first gas supply control valve via a second exhaust on-off valve.

[4]
The simplified mixed gas diving unit according to any one of [1] to [3], wherein the second gas is a mixed gas of oxygen and nitrogen.

[5]
The first gas is either a mixed gas of helium and oxygen or air, and is a mixture of helium and oxygen for the first gas supply path disposed upstream of the first gas supply path. A first gas supply switching device provided with a second gas supply control valve for switching between gas supply and air supply is connected upstream of the first gas supply passage [1] to [4] One of the simplified mixed gas diving units.

[6]
The simplified mixed gas diving unit according to [5], wherein the second gas supply control valve comprises a three-way valve.

[7]
The downstream side of the first gas supply path for supplying the first gas to the diving equipment mounted by the diver and the downstream side of the second gas supply path for supplying the second gas to the diving equipment A first gas supply control valve connected to the three-way valve for switching the supply of the first gas and the second gas to the diving apparatus;
A first gas exhaust passage connected to the first gas supply passage upstream of the first gas supply control valve via a first exhaust on-off valve;
A second gas exhaust passage connected to the second gas supply passage upstream of the first gas supply control valve via a second exhaust on-off valve;
Supply of a third gas, which is one of two types of gas constituting the first gas to the first gas supply passage, disposed upstream of the first gas supply passage, and the first gas A second gas supply control valve for switching the supply of the fourth gas, which is the other of the two gases constituting the first gas supply switch, connected to the upstream side of the first gas supply passage A simplified mixed gas diving unit comprising:
A diving depth management means for measuring the diving depth where the diver is diving;
First and second gas supply switching means for switching the supply of the first gas and the second gas to the diving equipment by the first gas supply control valve according to the diving depth to be measured;
Third and fourth gas supply switching means for switching the supply of the third gas and the fourth gas to the first gas supply passage by the second gas supply control valve in accordance with the measured diving depth.
The first exhaust on-off valve or the first exhaust valve provided in the first gas supply passage or the second gas supply passage through which the first gas or the second gas is supplied to the diving equipment. two exhaust-off valve is closed, the walk said second gas supply passage supplying is not performed in the second gas or said first gas to the diving equipment is deployed prior Symbol first gas supply passage A simplified mixed gas diving system, comprising: exhaust on-off valve control means for opening the second exhaust on-off valve or the first exhaust on-off valve.

[8]
The simplified mixed gas diving system of [7], wherein the second gas is a mixed gas of oxygen and nitrogen.

[9]
The simplified mixed gas diving system according to [7] or [8], wherein the third gas is air, and the fourth gas is a mixed gas of helium and oxygen.

[10]
The simplified mixed gas diving system according to any one of [7] to [9], wherein the second gas supply control valve comprises a three-way valve.

  According to the present invention, it is possible to provide a simple mixed gas diving unit suitable for diving work at a water depth of 40 m or less and a simple mixed gas diving system including the same with a simple configuration.

It is a figure showing an example of the composition of the simple type mixed gas diving unit of the present invention. It is an enlarged view of the structure of the 1st and 2nd gas supply switching apparatus with which the simple type mixed gas diving unit of this invention is equipped. It is an enlarged view of the structure of the 1st gas supply switching apparatus with which the simple type mixed gas diving unit of this invention is provided. It is a figure showing an example of the composition of the control means with which the simple type mixed gas diving system of the present invention is provided. It is a figure showing an example of the state of the first gas supply switching device in the case of supplying air using a simple type mixed gas diving unit of the present invention. It is a figure showing an example of the state of the first gas supply switching device in the case of supplying helium and oxygen mixed gas using a simple type mixed gas diving unit of the present invention. It is a figure showing an example of the state of the 1st and 2nd gas supply switching device in the case of supplying air or helium and oxygen mixed gas using a simple type mixed gas diving unit of the present invention. It is a figure showing an example of the state of the 1st gas supply switching device in, when a diver is pressure-reducing near water surface. It is a figure showing an example of the state of the 1st and 2nd gas supply switching device in, when a diver is pressure-reducing with oxygen and nitrogen mixed gas near water surface. It is a figure showing an example of the state of the 1st and 2nd gas supply switching device in, when a diver is pressure-reducing with air near water surface. It is a figure showing an example of a diving pattern. BRIEF DESCRIPTION OF THE DRAWINGS It is a figure showing an example of schematic structure of the simple type mixed gas diving system of this invention combined with mixed gas curdling, Comprising: (a) is a front view, (b) is a side view. It is a figure showing an example of the composition of the conventional mixed gas diving system.

  Hereinafter, an example of an embodiment of the present invention will be described with reference to the attached drawings.

[Mixed gas diving unit]
The simplified type mixed gas diving unit 1 of this embodiment includes a first and second gas supply switching device 2 and a first gas supply switching device 13 as shown in FIGS. 1 to 3.

  The first and second gas supply switching devices 2 are provided with a first gas supply control valve 5 that switches the supply of the first gas and the second gas to the diving equipment 12 worn by the diver.

  The first gas supply control valve 5 is a downstream side of the first gas supply path 3 for supplying the first gas to the diving equipment 12 and a second gas supply for supplying the second gas to the diving equipment 12 It is connected to the downstream side of the passage 4.

In this embodiment, the first gas supply control valve 5 is a three-way valve.

A first gas supply switching device 13 is connected upstream of the first gas supply passage 3 for supplying the first gas to the diving equipment 12.

  A second gas supply device 21 is connected to the upstream side of the second gas supply path 4 for supplying the second gas to the diving equipment 12.

In this embodiment, the first gas is a mixed gas of helium (concentration 79.5% to 83.5%) and oxygen (concentration 16.5% to 20.5%) or air. . The air is comprised of a ratio of 79% nitrogen and 21% oxygen. Hereinafter, in the present specification, the air may be described as a third gas, and the mixed gas of helium and oxygen may be described as a fourth gas.

The first gas is, according to a control instruction from the first and second gas supply switching means 24 to be described later, a submersible who is diving at a depth up to a predetermined depth, for example, a diving operation at a depth of 40 m or less It is supplied via the first gas supply path 3 to the diving equipment 12 worn by the diver.

In this embodiment, the second gas is a mixed gas of oxygen (90% concentration) and nitrogen (10% concentration).

The second gas is installed by the diver who has finished the diving operation, for example, a diver whose pressure is reduced between the water depth of 9 m and the water surface, in accordance with a control instruction from the first and second gas supply switching means 24 described later. The submersible equipment 12 is supplied via the second gas supply passage 4.

The first gas supply passage 3 is connected to the first gas inlet 5 b of the first gas supply control valve 5. In addition, the second gas supply passage 4 is connected to the second gas inlet 5 c of the first gas supply control valve 5.

In the first gas supply passage 3 between the first gas supply switching device 13 and the first gas supply control valve 5, a first gas supply for controlling the supply of the first gas to the first gas supply control valve 5 is performed. A gas on-off valve 10 is provided.

A first gas exhaust passage 7 is connected to the first gas supply passage 3 between the first gas supply on-off valve 10 and the first gas supply control valve 5 via the first gas exhaust on-off valve 6.

In the second gas supply passage 4 between the second gas supply device 21 and the first gas supply control valve 5, a second gas supply that controls the supply of the second gas to the first gas supply control valve 5 An on-off valve 11 is provided.

In this embodiment, the second gas supply on / off valve 11 is a ball valve 11a and a needle valve 111b.

A second gas exhaust passage 9 is connected to the second gas supply passage 4 between the second gas supply on-off valve 11 and the first gas supply control valve 5 via a second gas exhaust on-off valve 8.

The first gas supply switching device 13 is connected to the upstream side of the first gas supply passage 3.

The first gas supply switching device 13 includes a second gas supply control valve 16 that switches the supply of the mixed gas of the helium and the oxygen to the first gas supply path 3 and the air.

The second gas supply control valve 16 is disposed upstream of the first gas supply passage 3 on the downstream side of the air supply passage 14 supplying the air to the first gas supply passage 3 and on the first gas supply passage 3. On the other hand, it is connected to the downstream side of a helium oxygen mixed gas supply passage 15 for supplying a mixed gas of the helium and the oxygen.

In this embodiment, the second gas supply control valve 16 is a three-way valve.

An air supply device 19 is connected to the upstream side of the air supply passage 14 that supplies the air to the first gas supply passage 3.

A helium oxygen mixed gas supply device 20 is connected to the upstream side of the helium oxygen mixed gas supply passage 15 for supplying the mixed gas of helium and oxygen to the first gas supply passage 3.

The air is supplied to the first gas supply passage 3 via the air supply passage 14 in accordance with a control instruction from the third and fourth gas supply switching means 25 described later.

The helium oxygen mixed gas is supplied to the first gas supply passage 3 through the helium oxygen mixed gas supply passage 15 in accordance with a control instruction from the third and fourth gas supply switching means 25 described later.

The air supply passage 14 is connected to the air inlet 16 b of the second gas supply control valve 16. Further, the helium-oxygen mixed gas supply passage 15 is connected to the helium-oxygen mixed gas inlet 16 c of the second gas supply control valve 16.

The air supply passage 14 between the air supply device 19 and the second gas supply control valve 16 is provided with an air supply on-off valve 17 for controlling the supply of the air to the first gas supply passage 3.

Helium-oxygen mixed gas supply path 15 between the helium-oxygen mixed gas supply device 20 and the second gas supply control valve 16 controls the supply of the helium-oxygen mixed gas to the first gas supply path 3 A gas supply on-off valve 18 is provided.

[Mixed gas supply process]
The mixed gas supply process in a certain diving pattern will be described with reference to FIGS.

(First gas supply process)
In the diving operation section from depth A to depth C in Fig. 11 and in the decompression section from depth C to depth E, depth F to depth G, and depth H to depth I, the diving equipment 12 worn by the diver is illustrated The first gas is supplied.

  When diving from the start of diving shown in FIG. 11 (water depth A) to a predetermined water depth, for example, water depth 30 m (water depth B), according to an instruction from the third and fourth gas supply switching means 25 described later, FIG. As described above, the air supply on / off valve 17 of the first gas supply switching device 13 is opened, the air inlet 16b of the second gas supply control valve 16 and the first gas outlet side outlet 16a are opened, and the helium oxygen mixed gas inlet 16c is closed, and the helium oxygen mixed gas air supply on-off valve 18 is closed.

  Thus, the air is supplied from the air supply device 19 to the first gas supply path 3 via the second gas supply control valve 16.

  In the first and second gas supply switching devices 2, in response to an instruction from the first and second gas supply switching means 24 described later, as shown in FIG. 7, the first gas feed on / off valve 10 is opened, The first gas inlet 5b and the diver side outlet 5a of the first gas supply control valve 5 are opened, the second gas inlet 5c is closed, and the second gas feed on-off valve 11 is closed.

Further, the first gas exhaust on-off valve 6 is closed and the second gas exhaust on-off valve 8 is opened in accordance with an instruction from the exhaust on-off valve control unit 26 described later.

  As a result, the air among the first gas is supplied to the diving equipment 12 worn by the diver who is diving from the start of diving to, for example, a depth of 30 m.

  When diving from the water depth 30 m (water depth B) shown in FIG. 11 to the water depth 40 m (water depth C), as shown in FIG. 6 according to an instruction from the third and fourth gas supply switching means 25 described later. When the helium oxygen mixed gas air supply on-off valve 18 and the first gas supply passage side outlet 16a of the first gas supply switching device 13 are closed, the helium oxygen mixed gas inlet 16c of the second gas supply control valve 16 is opened. The inlet 16b is closed, and the air supply on-off valve 17 is closed.

  Thus, the helium oxygen mixed gas is supplied from the helium oxygen mixed gas supply device 20 to the first gas supply path 3 via the second gas supply control valve 16.

In the first and second gas supply switching devices 2, the first gas feed on / off valve 10 shown in FIG. 7 is opened, and the first gas inlet 5b and the diver's side outlet 5a of the first gas supply control valve 5 are opened. The second gas inlet 5c is closed, the second gas feed on / off valve 11 is closed, the first gas exhaust on / off valve 6 is closed, and the second gas on / off valve 8 is maintained open.

Thus, the helium-oxygen mixed gas of the first gas is supplied to the diving equipment 12 worn by a diver who is diving to a depth of more than 30 m, for example, 40 m.

  After the completion of the diving operation shown in FIG. 11, in the case of rising from a depth of 40 m (depth C) to a predetermined decompression stop depth, for example, a depth 16 m (depth D), the helium oxygen mixed gas of the first gas continues to be a dive It is supplied to the device 12. The helium-oxygen mixed gas performs depressurization to discharge nitrogen accumulated in the diver from the body.

  When raising from the decompression stop water depth (water depth D) shown in FIG. 11 to, for example, water depth 9 m (water depth E), as shown in FIG. 5 according to an instruction from third and fourth gas supply switching means 25 described later. The air supply on-off valve 17 of the first gas supply switching device 13 is opened, the air inlet 16b of the second gas supply control valve 16 is opened, and the helium oxygen mixed gas inlet 16c and the first gas supply side outlet 16a are When closed, the helium oxygen mixed gas air supply on-off valve 18 is closed.

  Thus, the air is supplied from the air supply device 19 to the first gas supply path 3 via the second gas supply control valve 16.

In the first and second gas supply switching devices 2, the first gas feed on / off valve 10 shown in FIG. 7 is opened, and the first gas inlet 5b and the diver's side outlet 5a of the first gas supply control valve 5 are opened. The second gas inlet 5c is closed, the second gas feed on / off valve 11 is closed, the first gas exhaust on / off valve 6 is closed, and the second gas on / off valve 8 is maintained open.

Thus, the air is supplied to the diving equipment 12 among the first gas. The air is subsequently depressurized to discharge nitrogen accumulated in the diver from the body.

  In the depressurizing work section shown in FIG. 11, in the water depth 9 m to the water surface (water depth F to water depth G to water depth H to water depth I to water depth I to water depth K), instructions from third and fourth gas supply switching means 25 described later Accordingly, as shown in FIG. 8, the air supply on / off valve 17 of the first gas supply switching device 13 is opened, and the air inlet 16 b of the second gas supply control valve 16 and the first gas supply passage outlet 16 a are opened. The helium oxygen mixed gas inlet 16c is closed, and the helium oxygen mixed gas air supply on-off valve 18 is closed.

  Thus, the air is supplied from the air supply device 19 to the first gas supply path 3 via the second gas supply control valve 16.

  In the first and second gas supply switching devices 2, in response to an instruction from the first and second gas supply switching means 24 described later, as shown in FIG. 10, the first gas feed on / off valve 10 is opened, The first gas inlet 5b and the diver side outlet 5a of the first gas supply control valve 5 are opened, the second gas inlet 5c is closed, and the ball valve 11a of the second gas feed on / off valve 11 is closed, the needle The valve 11b is opened.

Further, the first gas exhaust on-off valve 6 is closed and the second gas exhaust on-off valve 8 is opened in accordance with an instruction from the exhaust on-off valve control unit 26 described later.

Thereby, the state in which the second gas is supplied to the diving equipment 12 by the second gas supply process described later is switched to the state in which the air among the first gas is supplied to the diving equipment 12.

(Second gas supply process)
In the depressurization work section shown in FIG. 11, in the water depth 9 m to the water surface (water depth E to water depth F to water depth G to water depth H to water depth I to water depth K) Accordingly, as shown in FIG. 8, the air supply on / off valve 17 of the first gas supply switching device 13 is opened, and the air inlet 16 b of the second gas supply control valve 16 and the first gas supply passage outlet 16 a are opened. The helium oxygen mixed gas inlet 16c is closed, and the helium oxygen mixed gas air supply on-off valve 18 is closed.

  As a result, the air constituting the first gas is supplied to the first gas supply passage 3 via the second gas supply control valve 16.

In the first and second gas supply switching devices 2, the second gas supply on-off valve 11 is opened as shown in FIG. 9 according to an instruction from the first and second gas supply switching means 24 described later. The second gas inlet 5c and the submersible outlet 5a of the first gas supply control valve 5 are opened, the first gas inlet 5b is closed, and the first gas feed on-off valve 10 is closed.

Further, the second gas exhaust on-off valve 8 is closed and the first gas exhaust on-off valve 6 is opened in accordance with an instruction from the exhaust on-off valve control unit 26 described later.

That is, the second gas exhaust on-off valve 8 is closed, the second gas supply on-off valve 11 is opened, the second gas inlet 5c of the first gas supply control valve 5 and the diver outlet 5a are opened, and the first gas flow The operation sequence is as follows: the inlet 5 b is closed, the first gas feed on / off valve 10 is closed, and the first gas exhaust on / off valve 6 is opened.

The second gas is supplied from the second gas supply device 21 to the submersible equipment 12 of the diver who is decompressing via the second gas supply passage 4.

  As a result, the state in which the first gas is supplied to the diving equipment 12 in the first gas supply process described above is switched to the state in which the second gas is supplied to the diving equipment 12.

  Moreover, although the helium oxygen mixed gas which comprises the said 1st gas is not supplied to the 1st gas supply path 3 via the 2nd gas supply control valve 16, the said 2nd gas (mixed gas of oxygen and nitrogen) under pressure reduction is carried out The air constituting the first gas is supplied to the first gas supply passage 3 via the second gas supply control valve 16 so that air can be breathed out when oxygen poisoning occurs due to the above.

  In this embodiment, the first gas (air or helium oxygen mixed gas) is supplied via the first gas supply path 3 to the diving equipment 12 of the diver who is diving or reducing the pressure within the depth of 40 m. The air supply passage 14 for supplying air to the first gas supply passage 3 and the helium oxygen mixed gas supply passage 15 for supplying helium oxygen mixed gas are the mixture of air and helium oxygen to the first gas supply passage 3. It is connected to a second gas supply control valve 16 consisting of a three-way valve that switches the supply of gas.

Therefore, only by switching control of the second gas supply control valve 16 consisting of a three-way valve, supply of air to the diving equipment 12 of the diver working or reducing pressure at a predetermined water depth, and helium oxygen mixed gas It can be easily switched with the supply of

  In this embodiment, air of the first gas is supplied to the submersible equipment 12 of the diver whose pressure is reduced within the depth of 40 m via the first gas supply passage 3 or the second gas supply passage 4 is The second gas (a mixed gas of oxygen and nitrogen) is supplied via the first gas supply passage 3 and the second gas supply passage 4 to the first gas and the second gas to the diving equipment 12. It is connected to a first gas supply control valve 5 consisting of a three-way valve which switches the supply of two gases.

  Therefore, only by switching control of the first gas supply control valve 5 consisting of a three-way valve, supply of the first gas (air) to the diving equipment 12 of the diver whose pressure is reduced at a predetermined water depth, and It can be easily switched with the supply of gas (mixed gas of oxygen and nitrogen).

  This eliminates the need to prepare large-scale equipment as in the conventional mixed gas diving system 32 as described with reference to FIG.

  Further, in this embodiment, when the first gas (air or a mixed gas of helium and oxygen) is supplied to the diving equipment 12 worn by the diver, the second gas supply passage 4 is interposed. Not only the second gas supply on-off valve 11 is closed, and the second gas inlet 5c of the first gas supply control valve 5 is closed, but also the second gas on-off valve 11 and the first gas supply control The second gas exhaust on-off valve 8 interposed between the second gas supply passage 4 and the second gas exhaust passage 9 between the valve 5 is opened.

  As a result, even if the second gas (mixed gas of oxygen and nitrogen) is mixed in the second gas supply passage 4 on the first gas supply control valve 5 side, even if the second gas supply on-off valve 11 is closed. Even if it leaks, the leaked second gas never flows out to the second gas inlet 5c of the first gas supply control valve 5, and the second gas exhaust on-off valve is opened. It is discharged through 8 and the second gas exhaust passage 9.

  Therefore, while the first gas (air or a mixed gas of helium and oxygen) is being supplied to the diving equipment 12 worn by the diver, the second gas (mixed gas of oxygen and nitrogen) is supplied There is no risk of mixing in the first gas being treated.

  Further, in this embodiment, when the second gas (mixed gas of oxygen and nitrogen) is supplied to the diving equipment 12 worn by the diver, the first gas interposed in the first gas supply passage 3 Not only the air supply on-off valve 10 is closed and the first gas inlet 5 b of the first gas supply control valve 5 is closed, but also the first gas on-off valve 10 and the first gas supply control valve 5 The first gas exhaust on-off valve 6 interposed between the first gas supply passage 3 and the first gas exhaust passage 7 is opened.

  As a result, even if the first gas supply passage 3 is closed, the first gas supply passage 3 on the first gas supply control valve 5 side is mixed with the first gas (air or helium and oxygen). Even if the gas) leaks out, the leaked first gas never flows into the first gas inlet 5b of the first gas supply control valve 5, and the first gas is opened. It is discharged through the exhaust on-off valve 6 and the first gas exhaust passage 7.

  Therefore, while the second gas (mixed gas of oxygen and nitrogen) is supplied to the diving equipment 12 worn by the diver, the first gas (air or mixed gas of helium and oxygen) is supplied There is no risk of mixing in the second gas being treated.

  When the diver is diving at a predetermined depth, for example, within 40 m, one mixed gas of the first gas (air or mixed gas of helium and oxygen) is the diving equipment of the diver 12 is supplied to the diving equipment 12 when, at this time, even if only a small amount of the other mixed gas of the first gas and the second gas (mixed gas of oxygen and nitrogen) are mixed, Because gas is directly breathed by divers, even small amounts of gas can lead to serious accidents.

  Similarly, the second gas (mixed gas of oxygen and nitrogen) is supplied to the diving equipment 12 of the diver when the diver is depressurizing at a predetermined depth, for example, a depth of water near 9 m, but At this time, if only the first gas (air or a mixed gas of helium and oxygen) is mixed, the gas supplied to the diving equipment 12 is a small amount because the diver breathes directly. Gas contamination also leads to serious accidents.

  In this embodiment, by adopting the above-described configuration, it is possible to prevent such an accident from occurring.

[Mixed gas diving system]
The simplified mixed gas diving system of this embodiment includes the simplified mixed gas diving unit 1 shown in FIG. 1 and the control means 22 shown in FIG.

The control means 22 is, as shown in FIG. 4, the diving depth management means 23, the first and second gas supply switching means 24, the third and fourth gas supply switching means 25, and the exhaust on / off valve control means 26. And.

FIG. 12 illustrates a schematic configuration of a simplified mixed gas diving system 27 integrally combined with the mixed gas curd 28. A mixed gas curd 28 is configured by combining two gas cylinders of air constituting the first gas, two gas cylinders of helium oxygen mixed gas, and two gas cylinders of second gas (mixed gas of oxygen and nitrogen). .

A gas control panel configured of the two left and right first and second gas supply switching devices 2 and the first gas supply switching device 13 indicated by reference numeral 29 is mounted on the upper part of the mixed gas cardlet 28. The gas control panel 29 constitutes the control means 22 and functions of the diving depth management means 23, the first and second gas supply switching means 24, the third and fourth gas supply switching means 25, and the exhaust on-off valve control means 26. Demonstrate. Further, each of the gas control panels 29 plays the role of the supply of the first gas and the supply of the second gas described in the simplified mixed gas diving unit 1 described above.

  The mixed gas curd 28 and the two left and right gas control panels 29 are integrated and transported to the site where the diving operation is performed and used. A belt spring 31 is hung on a suspended piece 30 disposed at a portion of the mixed gas cardle 28 and the whole is lifted, and mounted on a ship where a diver or a worker gets to a diving site on the sea.

  The simplified mixed gas diving system 27 shown in FIG. 12 requires only 810 kg in total weight even if the weight of an umbilical hose or the like connected to the diving equipment 12 of two divers is included. In addition, the size is about 1.8 m in width, which is the horizontal length in FIG. 12 (a), and about 0.6 m in depth, which is the horizontal length in FIG. 12 (b), The height, which is the direction length, can be made compact at about 1.4 m.

  Therefore, when using the simplified mixed gas diving system 27 of this embodiment, in the case of a slight diving operation, it is not necessary to transport large-scale equipment like the conventional mixed gas diving system, and for diving operation Without preparing a large ship, it is possible to load the above-mentioned compact-sized system with a small total weight into a relatively small ship and proceed to the diving operation, and shorten the preparation for transportation (shipping and outfitting). It can be done easily in time.

  In the illustrated embodiment, the simplified mixed gas diving unit 1 is a system capable of supplying mixed gas to each of two divers.

  The diving depth management means 23 measures the diving depth in which the diver is diving.

  The first and second gas supply switching means 24 controls the first gas and the second gas to the diving equipment 12 by the first gas supply control valve 5 according to the diving depth measured by the diving depth management means 23. Switch the supply of

The third and fourth gas supply switching means 25 controls the third gas and the fourth gas to the first gas supply passage 3 by the second gas supply control valve 16 according to the diving depth measured by the diving depth management means 23. Switch the supply of

The exhaust on-off valve control means 26 is a first gas exhaust on-off valve 6 disposed between the first gas supply passage 3 of the first gas to be supplied to the submersible 12 and the first gas exhaust passage 7. And opening and closing of the second gas exhaust on-off valve 8 disposed between the second gas supply passage 4 and the second gas exhaust passage 9 of the second gas not supplied to the submersible 12. Control.

Further, the exhaust on-off valve control means 26 is configured to open and close the second gas exhaust disposed between the second gas supply passage 4 for the second gas supplied to the submersible 12 and the second gas exhaust passage 9. A valve 8 and a first gas exhaust on-off valve 6 disposed between the first gas supply passage 3 and the first gas exhaust passage 7 of the first gas not supplied to the submersible 12. Control opening and closing.

When the third gas (air) constituting the first gas is supplied to the diving equipment 12 worn by a submersible who is diving or depressurizing at a depth of 40 m or less, as shown in FIG. The third and fourth gas supply switching means 25 open the air air supply on-off valve 17 of the first gas supply switching device 13 and set the air inlet 16b of the second gas supply control valve 16 and the first gas supply passage side outlet 16a. While opening the helium oxygen mixed gas inlet 16c and closing the helium oxygen mixed gas air supply on-off valve 18, the mixed gas to be supplied to the first gas supply passage 3 is the third gas constituting the first gas Set to (Air).

While the third and fourth gas supply switching means 25 are thus set, the first and second gas supply switching means 24 open the first gas supply on-off valve 10 as shown in FIG. The first gas inlet 5b and the diver side outlet 5a of the gas supply control valve 5 are opened, the second gas inlet 5c is closed, and the second gas feed on / off valve 11 is set to be closed. The gas to be supplied is set to the third gas (air) constituting the first gas.

Further, the exhaust on-off valve control means 26 is configured to open and close the first gas exhaust disposed between the first gas supply passage 3 for the first gas supplied to the submersible 12 and the first gas exhaust passage 7. The second gas exhaust opening / closing provided between the second gas supply passage 4 for the second gas and the second gas exhaust passage 9 with the valve 6 set to the closed state and the supply to the submersible 12 is not performed. Set valve 8 open.

  The air supply device 19 connected to the first gas supply switching device 13 supplies the third gas (air) to the diving equipment 12 according to the control instruction of the third and fourth gas supply switching means 25 and the air supply passage. 14 and through the first gas supply line 3.

  Although the second gas which is the oxygen-nitrogen mixed gas is not supplied to the second gas supply passage 4, in order to prevent the second gas from being mixed into the diving equipment 12 through the second gas supply passage 4, While the third gas (air) constituting the first gas is supplied to the diving equipment 12 by opening the second gas exhaust on-off valve 8 according to the setting from the exhaust on-off valve control means 26 The second gas remaining in the second gas supply passage 4 is exhausted.

When supplying the fourth gas (mixed gas of helium and oxygen) constituting the first gas to the diving equipment 12 worn by a diver who is diving at a depth of 40 m or less, the third and fourth gases As shown in FIG. 6, the supply switching means 25 opens the helium oxygen mixed gas air supply on-off valve 18 of the first gas supply switching device 13, and the helium oxygen mixed gas inlet 16 c of the second gas supply control valve 16. The first gas supply passage side outlet 16a is opened, the air inlet 16b is closed, and the air supply on-off valve 17 is set to be closed, and the mixed gas supplied to the first gas supply passage 3 is the first gas. Set to four gases (mixed gas of helium and oxygen).

While the third and fourth gas supply switching means 25 are thus set, the first and second gas supply switching means 24 open the first gas supply on-off valve 10 as shown in FIG. The first gas inlet 5b and the diver side outlet 5a of the gas supply control valve 5 are opened, the second gas inlet 5c is closed, and the second gas feed on / off valve 11 is set to be closed. The gas to be supplied is set to the fourth gas (mixed gas of helium and oxygen) constituting the first gas.

Further, the exhaust on-off valve control means 26 is configured to open and close the first gas exhaust disposed between the first gas supply passage 3 for the first gas supplied to the submersible 12 and the first gas exhaust passage 7. The second gas exhaust opening / closing provided between the second gas supply passage 4 for the second gas and the second gas exhaust passage 9 with the valve 6 set to the closed state and the supply to the submersible 12 is not performed. Set valve 8 open.

  The helium oxygen mixed gas supply device 20 connected to the first gas supply switching device 13 receives the fourth gas (helium and oxygen) in the diving equipment 12 according to the control instruction of the third and fourth gas supply switching means 25. Mixed gas) is supplied through the helium oxygen mixed gas supply passage 15 and the first gas supply passage 3.

  Although the second gas which is the oxygen-nitrogen mixed gas is not supplied to the second gas supply passage 4, in order to prevent the second gas from being mixed into the diving equipment 12 through the second gas supply passage 4, According to the above setting from the exhaust on-off valve control means 26, the second gas exhaust on-off valve 8 is opened, whereby the fourth gas (mixed gas of helium and oxygen) constituting the first gas in the diving equipment 12 While being supplied, the second gas remaining in the second gas supply passage 4 is exhausted.

When the second gas (mixed gas of oxygen and nitrogen) is supplied to the diving equipment 12 mounted by a diver whose pressure is reduced to a depth of 40 m or less, the third and fourth gas supply switching means 25 are As shown in FIG. 8, the air supply on-off valve 17 of the first gas supply switching device 13 is opened, the air inlet 16 b of the second gas supply control valve 16 and the first gas supply side outlet 16 a are opened, The mixed gas inlet 16c is closed, and the helium oxygen mixed gas air supply on-off valve 18 is set closed.

While the third and fourth gas supply switching means 25 are thus set, the first and second gas supply switching means 24 open the second gas supply on-off valve 11 as shown in FIG. The second gas inlet 5c and the diver side outlet 5a of the gas supply control valve 5 are opened, the first gas inlet 5b is closed, and the first gas feed on / off valve 10 is set to be closed. The gas to be supplied is set to the second gas (mixed gas of nitrogen and oxygen).

Further, the exhaust on-off valve control means 26 is configured to open and close the second gas exhaust disposed between the second gas supply passage 4 for the second gas supplied to the submersible 12 and the second gas exhaust passage 9. The first gas exhaust opening / closing provided between the first gas supply passage 3 of the first gas and the first gas exhaust passage 7 with the valve 8 closed and not supplied to the submersible 12 Set valve 6 open. That is, the second gas exhaust on-off valve 8 is closed, the second gas supply on-off valve 11 is opened, the second gas inlet 5c of the first gas supply control valve 5 and the diver outlet 5a are opened, and the first gas flow The operation sequence is as follows: the inlet 5 b is closed, the first gas feed on / off valve 10 is closed, and the first gas exhaust on / off valve 6 is opened.

  The second gas supply device 21 connected to the first and second gas supply switching devices 2 transmits the second gas to the diving equipment 12 according to the control instruction of the first and second gas supply switching means 24. The gas is supplied through the second gas supply passage 4.

  The first gas supply path 3 is not supplied with the air or the first gas which is the helium oxygen mixed gas, but the first gas is mixed into the diving equipment 12 through the first gas supply path 3. According to the above setting from the exhaust on-off valve control unit 26, the first gas exhaust on-off valve 6 is opened to prevent the first gas supply passage while the second gas is being supplied to the diving equipment 12 The first gas remaining in 3 is exhausted.

In this embodiment, when the first gas (air or mixed gas of helium and oxygen) is supplied to the diving equipment 12 worn by the diver, the second gas supply passage 4 is interposed between Not only the gas supply on-off valve 11 is closed, and the second gas inlet 5 c of the first gas supply control valve 5 is closed, but also the second gas on-off valve 11 and the first gas supply control valve 5 The second gas exhaust on-off valve 8 interposed between the second gas supply passage 4 and the second gas exhaust passage 9 is opened.

  As a result, even if the second gas (mixed gas of oxygen and nitrogen) is mixed in the second gas supply passage 4 on the first gas supply control valve 5 side, even if the second gas supply on-off valve 11 is closed. Even if it leaks, the leaked second gas never flows out to the second gas inlet 5c of the first gas supply control valve 5, and the second gas exhaust on-off valve is opened. It is discharged through 8 and the second gas exhaust passage 9.

  Therefore, while the first gas (air or mixed gas of helium and oxygen) is supplied to the diving equipment 12 worn by the diver, the second gas (mixed gas of oxygen and nitrogen) is There is no risk of being mixed into the supplied first gas.

Further, in this embodiment, when the second gas (mixed gas of oxygen and nitrogen) is supplied to the diving equipment 12 worn by the diver, the first gas interposed in the first gas supply passage 3 Not only the air supply on-off valve 10 is closed and the first gas inlet 5 b of the first gas supply control valve 5 is closed, but also the first gas on-off valve 10 and the first gas supply control valve 5 The first gas exhaust on-off valve 6 interposed between the first gas supply passage 3 and the first gas exhaust passage 7 is opened.

  As a result, even if the first gas supply passage 3 is closed, the first gas supply passage 3 on the first gas supply control valve 5 side is mixed with the first gas (air or helium and oxygen). Even if the gas) leaks out, the leaked first gas never flows into the first gas inlet 5b of the first gas supply control valve 5, and the first gas is opened. It is discharged through the exhaust on-off valve 6 and the first gas exhaust passage 7.

  Therefore, while the second gas (mixed gas of oxygen and nitrogen) is supplied to the diving equipment 12 worn by the diver, the first gas (air or mixed gas of helium and oxygen) is supplied There is no risk of mixing in the second gas being treated.

  In this embodiment, the simplified mixed gas diving system 27 includes at least the simplified mixed gas diving unit 1 described above, the diving depth management means 23, the first and second gas supply switching means 24, and the third and fourth gas supply switching. Since the means 25 and the exhaust on-off valve control means 26 are provided, the structure can be simplified as compared with the conventional mixed gas diving system, and diving preparation can be performed in a short time.

In this embodiment, by controlling the opening and closing of the three-way valve employed as the first gas supply control valve 5, the supply of the mixed gas can be switched according to the predetermined water depth. Therefore, only by switching and controlling the first gas supply control valve 5 consisting of a three-way valve, the first gas (a mixture of air or helium and oxygen) is transmitted to the diving equipment 12 of the diver working at a predetermined water depth. The supply of the gas) and the supply of the second gas (mixed gas of oxygen and nitrogen) can be switched easily.

In addition, by controlling the opening and closing of the three-way valve employed as the second gas supply control valve 16, the supply of the third gas and the fourth gas constituting the first gas can be switched according to the predetermined water depth. it can. Therefore, the third gas (air) is supplied to the diving equipment 12 of the diver who is diving or depressurizing at a predetermined depth by merely switching and controlling the second gas supply control valve 16 consisting of a three-way valve. It can be easily switched with the supply of the four gases (mixed gas of helium and oxygen).

This eliminates the need to prepare large-scale equipment as in the conventional mixed gas diving system 32 as described with reference to FIG.

In this embodiment, while the submersible equipment 12 is being supplied with one of the first gas and the second gas via one gas supply passage, the other exhaust gas disposed in the other gas supply passage is provided. Since the on-off valve exhausts the other gas remaining in the other gas supply passage, it is possible to prevent the other gas from being mixed in the submers 12 with the one gas.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, the present invention is not limited to the above-described embodiments, and various modifications can be made within the technical scope understood from the description of the claims. It is.

1 simple type mixed gas diving unit 2 first and second gas supply switching device 3 first gas supply passage 4 second gas supply passage 5 first gas supply control valve 5a diver side outlet 5b first gas inlet 5c first Two gas inlet 6 first gas exhaust on-off valve 7 first gas exhaust passage 8 second gas exhaust on-off valve 9 second gas exhaust passage 10 first gas gas on-off valve 11 second gas gas on-off valve 11a ball valve 11b Needle valve 12 Diving device 13 First gas supply switching device 14 Air supply passage 15 Helium oxygen mixed gas supply passage 16 Second gas supply control valve 16a First gas supply passage side outlet 16b Air inlet 16c Helium oxygen mixed gas inlet 17 Air air on-off valve 18 Helium oxygen mixed gas air on-off valve 19 Air supply device 20 Helium oxygen mixed gas supply device 21 Second gas supply device 22 Control means 23 Submersible depth management means 24 First and second gas supply switching means 25 Third and fourth gas supply switching means 26 Exhaust on-off valve control means 27 Simplified mixed gas diving system 28 Mixed gas curd 29 Gas control panel 30 Suspension piece 31 Belt spring 32 Conventional mixing Gas diving system 33 Control container 34 Control panel 35 Depth control panel 36 Simultaneous call equipment 37 Umbilical hose 38 Medium pressure compressor 39 Air curd (air supply device)
40 High-Pressure Compressor 41 Repressure Tank 42 Store Container 43 Generator 44 Lifting Equipment 45 Mixed Gas Curdle (Mixed Gas Supply Device)

Claims (10)

A first gas downstream side of the first gas supply channel for supplying in diving against diving equipment diver is wearing, the second gas supply for supplying a second gas into a dive to the diving equipment A simplified mixed gas diving unit comprising a first gas supply control valve connected to the downstream side of a path and comprising a three-way valve switching the supply of the first gas and the second gas to the diving apparatus. The downstream side of the first gas supply path for supplying the first gas to the diving equipment mounted by the diver and the downstream side of the second gas supply path for supplying the second gas to the diving equipment A simplified mixed gas diving unit comprising: a first gas supply control valve connected to a first gas supply control valve comprising a three-way valve switching the supply of the first gas and the second gas to the diving apparatus;
A first gas exhaust passage is connected to the first gas supply passage upstream of the first gas supply control valve via a first exhaust on-off valve
A simple mixed gas diving unit characterized by The downstream side of the first gas supply path for supplying the first gas to the diving equipment mounted by the diver and the downstream side of the second gas supply path for supplying the second gas to the diving equipment A simplified mixed gas diving unit comprising: a first gas supply control valve connected to a first gas supply control valve comprising a three-way valve switching the supply of the first gas and the second gas to the diving apparatus;
A second gas exhaust passage is connected to the second gas supply passage upstream of the first gas supply control valve via a second exhaust on-off valve
A simple mixed gas diving unit characterized by The downstream side of the first gas supply path for supplying the first gas to the diving equipment mounted by the diver and the downstream side of the second gas supply path for supplying the second gas to the diving equipment A simplified mixed gas diving unit comprising: a first gas supply control valve connected to a first gas supply control valve comprising a three-way valve switching the supply of the first gas and the second gas to the diving apparatus;
The second gas is a mixed gas of oxygen and nitrogen
A simple mixed gas diving unit characterized by The downstream side of the first gas supply path for supplying the first gas to the diving equipment mounted by the diver and the downstream side of the second gas supply path for supplying the second gas to the diving equipment A simplified mixed gas diving unit comprising: a first gas supply control valve connected to a first gas supply control valve comprising a three-way valve switching the supply of the first gas and the second gas to the diving apparatus;
The first gas is either a mixed gas of helium and oxygen or air, and is a mixture of helium and oxygen for the first gas supply path disposed upstream of the first gas supply path. A first gas supply switching device provided with a second gas supply control valve for switching between gas supply and air supply is connected upstream of the first gas supply passage.
A simple mixed gas diving unit characterized by   The simplified mixed gas diving unit according to claim 5, wherein the second gas supply control valve comprises a three-way valve. The downstream side of the first gas supply path for supplying the first gas to the diving equipment mounted by the diver and the downstream side of the second gas supply path for supplying the second gas to the diving equipment A first gas supply control valve connected to the three-way valve for switching the supply of the first gas and the second gas to the diving apparatus;
A first gas exhaust passage connected to the first gas supply passage upstream of the first gas supply control valve via a first exhaust on-off valve;
A second gas exhaust passage connected to the second gas supply passage upstream of the first gas supply control valve via a second exhaust on-off valve;
Supply of a third gas, which is one of two types of gas constituting the first gas to the first gas supply passage, disposed upstream of the first gas supply passage, and the first gas A second gas supply control valve for switching the supply of the fourth gas, which is the other of the two gases constituting the first gas supply switch, connected to the upstream side of the first gas supply passage A simplified mixed gas diving unit comprising:
A diving depth management means for measuring the diving depth where the diver is diving;
First and second gas supply switching means for switching the supply of the first gas and the second gas to the diving equipment by the first gas supply control valve according to the diving depth to be measured;
Third and fourth gas supply switching means for switching the supply of the third gas and the fourth gas to the first gas supply passage by the second gas supply control valve in accordance with the measured diving depth.
The first exhaust on-off valve or the first exhaust valve provided in the first gas supply passage or the second gas supply passage through which the first gas or the second gas is supplied to the diving equipment. two exhaust-off valve is closed, the walk said second gas supply passage supplying is not performed in the second gas or said first gas to the diving equipment is deployed prior Symbol first gas supply passage A simplified mixed gas diving system, comprising: exhaust on-off valve control means for opening the second exhaust on-off valve or the first exhaust on-off valve.   The simplified mixed gas diving system according to claim 7, wherein the second gas is a mixed gas of oxygen and nitrogen.   9. The simplified mixed gas diving system according to claim 7, wherein the third gas is air, and the fourth gas is a mixed gas of helium and oxygen.   The simplified mixed gas diving system according to any one of claims 7 to 9, wherein the second gas supply control valve comprises a three-way valve.