KR20100019012A - Equipment breathe in the water - Google Patents

Abstract

PURPOSE: Low pressure diving equipment is provided to enable a diver under the water to breath naturally at normal pressure. CONSTITUTION: An intake pipe part(20) is installed in a float(10) to provide a diver under the water with external air. A discharge pipe part(30) discharges the air provided with the intake pipe part to outside. A mouth part(40) is connected between the intake and the discharge pipe part to feed air to the diver. An air drive part(50) compulsorily supplies the air of the intake pipe part. A controller(60) controls the air drive part according to the water pressure. The intake pipe part comprises an air control valve controlling the air supply between upper and lower branch pipes.

Description

Low pressure diving device {Equipment breathe in the water}

The present invention relates to a low pressure diving device. More particularly, the present invention relates to a low pressure diving device capable of forcibly supplying air to a diver according to the water pressure generated according to the depth of the water.

Conventional aquatic respirators were able to breathe heavy equipment (oxygen tanks, etc.) on the back of divers and enter the water to breathe with oxygen supplied from the tank.

However, the conventional respirator was not inconvenient for breathing or activity, but was expensive and unsuitable for easy purchase and use by the general public, and the oxygen storage in the tank was limited. There is a problem.

Therefore, there is an increasing demand for the development of a low pressure diving device that overcomes the problems of the respirator.

As one of the proposed diving devices to overcome this problem, "aquatic respirator" (application number: 1989-0000558) was filed on January 18, 1989.

In this way, the conventional aquatic respirator drills the air inlet hole in the outer periphery of the mold and puts a vent pipe in the center of the weight body of the inner bottom, while the upper side of the partition plate and the lower side of the partition plate and a waterproof partition plate of the lower side are in the proper position. It is formed in the buoyancy holding space section and the space section, and the ventilating pipe of the space section is connected to the monitor valve with a through hole, and the intake valve with a suction valve is connected between the mask connected to the air inlet hose.

However, the conventional respirator has a structural problem that does not naturally inhale and discharge the outside air to the normal pressure by the water pressure increases as the diver is placed in deep water.

The present invention has been made to solve the above problems, an object of the present invention is to provide a low-pressure diving device that the diver can breathe at normal pressure underwater.

Embodiments of the present invention proposed in order to achieve the above object, in the low pressure diving device, a float, a suction pipe portion installed in the float supplying the outside air to the diver, and the air supplied by the suction pipe portion to the outside A discharge part connected to the discharge pipe part, a mouth part connected to the suction pipe part and the discharge pipe part to supply air to the diver, an air driving part forcibly supplying air to the suction pipe part, and a control part controlling the air driving part according to the water pressure. .

According to the present invention, since the outside air can be naturally breathed or forced to breathe depending on the underwater position of the diver, there is an advantage that the diver can always breathe at normal pressure.

In addition, the present invention has the advantage of being able to breathe air naturally or forcibly according to the diver's intention.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 1, an embodiment of the present invention is provided by a buoy 10 and a suction pipe 20 which is installed at the buckle 10 to supply external air to the diver, and the suction pipe 20. Discharge pipe portion 30 for discharging the air to the outside, the suction pipe portion 20 and the discharge pipe portion 30 is connected between the mouth portion 40 to provide air to the diver and the air of the suction pipe portion 30 Air control unit 50 forcibly supplying the control unit 60 for controlling the air driving unit 50 according to the water pressure.

Here, the float 10 may be made of a material floating in water, it may be implemented in a tube, styrofoam, wood and the like.

One end of each of the suction pipe part 20 and the discharge pipe part 30 may be installed in the mouth 10 so as to be exposed to the outside of the water. The other end of each of the suction pipe part 20 and the discharge pipe part 30 may be connected to the mouth part 40. In this case, each of the suction pipe part 20 and the discharge pipe part 30 may be implemented to include a hose (pipe) through which air can flow.

In addition, the air driving unit 50 may be connected to the suction pipe unit 30 to forcibly supply air supplied to the suction pipe unit 30 to the mouth unit 40. In this case, the air driver 50 may be driven by a power source of a battery (not shown) provided in the sub-ball 10. In addition, the air driver 50 may be implemented as an air compressor 52 capable of compressing and supplying air by driving the motor 51 and the motor 51.

In addition, the control unit 60 is connected to the air driving unit 50 by a wire (not shown) having a predetermined length, the diving unit can be gripped, the switching operation by the water pressure in the water air driving unit 50 is to be driven Can be. At this time, the length of the wire is preferably equal to or longer than the length of the suction pipe portion (30).

In addition, the suction pipe 21 may be used by installing an expansion unit 80 for temporarily storing the outside air.

Here, the expansion unit 80 is stored in the outside air, even if the diver is located deep in the water can be easily inhaled air.

In addition, the expansion portion 80 is preferably a corrugated pipe having a diameter larger than twice the diameter of the suction pipe 21.

Here, the expansion portion 80 is preferably formed in a corrugated pipe shape so that it can easily withstand water pressure. At this time, the corrugated pipe is preferably made larger than the diameter of the suction pipe 21 so that the outside air can be stored.

2 and 3, the suction pipe part 20 is a suction pipe 21 through which external air is sucked, and an upper portion branched from the upper portion of the suction pipe 21 and connected to the air driving part 50. The suction pipe is located between the engine 22, the lower part engine 23 connected to the air driving part 50 and connected to the lower part of the suction pipe 21, and the upper branch pipe 22 and the lower part engine 23. It may be configured to include an air control valve 24 installed in the control air supply.

Here, when the air driving unit 50 is not driven, external air may be supplied to the diving unit through the suction pipe 21 and through the air control valve 24.

When the air driving unit 50 is driven, external air passes through the upper part of the suction pipe 21, through the upper branch pipe 22, and the lower part engine 23, and is transferred to the diver through the lower part of the suction pipe 21. Can be. At this time, since the air supplied by the air driving unit 50 operates the air control valve 24 in the lower part engine 23, the external air is blocked by the air control valve 24 so that the upper portion of the suction pipe 21 is closed. It can be supplied to divers without being discharged.

On the other hand, the upper end of the suction pipe 21 is preferably a net 25 is installed to prevent the introduction of foreign matter. In addition, the suction pipe 20 and the discharge pipe 30 is preferably formed so that the upper end is bent to prevent the input of substances other than air.

In addition, the air control valve 24 is installed between the suction pipes 21 and separated and coupled to the upper and lower parts, the case 24a, the cylindrical member 24b installed inside the case 24a, and the cylindrical member 24b. ), A plurality of through-holes (24d) formed to be spaced apart at intervals set at the upper and lower portions of the cylindrical member (24b) and the piston (24c) moved by the pressure of the air, and a plurality of inside the cylindrical member (24b) A cover member which covers the engaging jaw 24e formed between the through holes 24d and the upper portion of the cylindrical member 24b, and has an air hole 24f through which the air is moved by the operation of the piston 24c. 24g).

Here, the case 24a is preferably divided into upper and lower screws. Then, when the air driving unit 50 is driven, the air is supplied from the lower portion of the suction pipe 21, so that the piston 24c is raised. At this time, the piston 24c covers the air hole 24f to prevent the air driven by the air driving unit 50 from being discharged through the upper portion of the suction pipe 21 to the outside. And, the piston 24c can be elastically supported by a compression spring (not shown) installed in the lower portion, the piston 24c can be easily raised by the air pressure because it can reduce the weight by digging.

In addition, when the air driving unit 50 is not driven, the piston 24c is lowered by the weight of the piston 24c and is caught by the locking jaw 24e, so that the plurality of through holes 24d are opened. It can be supplied to the diver through the suction pipe (21).

At this time, since the air driving unit 50 is not driven when the plurality of through holes 24d are opened, the diver must directly inhale and discharge external air.

Therefore, the air control valve 24 may be automatically operated by the driving of the air driving unit 50 to forcibly or naturally supply external air to the diver.

And, it is preferable to further include a coupling portion 70 for coupling the float 10 and the suction pipe portion 20 and the discharge pipe portion (30).

Here, since the coupler 10, the suction pipe portion 20 and the discharge pipe portion 30 can be coupled to and separated from each other by the coupling portion 70, it may be easy to store and carry.

In addition, the coupling part 70 includes a sub-plate 71 integrally coupled to the sub-ball 10, a hole 72 formed to penetrate the sub-plate 71, and a male coupling penetrated through the hole 72. The member 73, the female coupling member 74 connected to the male coupling member 73, and the plurality of holes formed so that the suction pipe portion 20 and the discharge pipe portion 30 penetrate the male coupling member 73 It can be configured to include (75).

Here, the suction pipe part 20 and the discharge pipe part 30 are installed to penetrate through the plurality of holes 75 of the male coupling member 73, respectively. At this time, the suction pipe portion 20 and the discharge pipe portion 30 may be formed on the upper portion of the water coupling member 73 protruding jaw (73a) so as not to be separated from the plurality of holes (75).

In addition, male threads are formed on the outer side of the male coupling member 73, and the female coupling member 74 may be mutually coupled using a nut-shaped member in which female threads are formed.

And, as shown in Figure 4, the mouse portion 40 is the suction connection portion 41 is connected to the suction pipe portion 20, the discharge connection portion 42 connected to the discharge pipe portion 30, the suction connection portion 41 And the discharge connection portion 42 are connected to both sides, and the mouse body 43 through which air flows, and the suction valve 44 which supplies the air supplied to the suction connection portion 41 to the inside of the mouse body 43; Discharge valve 45 for discharging the air supplied to the mouse body 43 through the discharge connection portion 42, and the mouth hole 46 through which the diver part sucks and discharges air is formed through the mouse body 43; And a mouth member 47 formed at an outer side of the mouth hole 46 so that the diver can bite into the mouth, and a stopper member 48 installed in the mouse body 43 to open and close the mouth hole 46. Can be configured.

Here, a predetermined space is formed in the mouse body 43 so that air flows therein, and the suction connection part 41 and the discharge connection part 42 are connected to both sides of the mouse body 43. In addition, the mouth hole 46 and the mouse member 47 are formed at the center of the mouse body 43 so that the diver can breathe by sucking the mouth member 47 with the mouth.

At this time, the closure member 48 for opening and closing the mouth hole 46 is preferably installed in the mouse body 43 to be located in the direction corresponding to the mouth hole 46.

In addition, since the configuration of the suction connection 41 and the discharge connection 42 is the same as the air control valve 24, the description of the configuration will be omitted.

The plug member 48 is a female coupling member 48a coupled to the mouse body 43, a female screw hole 48b formed to penetrate the center of the female coupling member 48a, and a screw in the female screw hole 48b. It may be configured to include a knob 48d having a male thread 48c coupled thereto, and an opening and closing plate 48e formed at the other end of the knob 48d to open and close the mouth hole 46.

Here, the diver can close the mouth hole 46 by using the stopper member 48 when the mouth part is to be worn in the mouth while diving, so that the water can pass through the mouth hole 46. It can be prevented from flowing into the inside of the mouse body 43.

In addition, when the diver wants to breathe underwater, by opening the mouth hole 46 by rotating the stopper member 48 in the state of biting the mouth part 40 by the mouth, the outside air can be breathed.

As shown in FIG. 5, the control unit 60 includes a switch member 61 for driving the air driving unit 50, a rubber plate 62 for operating the switch member 61, and a rubber plate 62. And a lower case 63 in which the switch member 61 is built, and a lower pressure portion 64 coupled to the lower case 63, and formed with a pressure hole 64 formed to transmit water pressure to the rubber plate 62, and having a female thread. It may be configured to include an upper case 66, the hole 65 is formed, and an adjusting knob 67 having a male thread to be screwed into the knob hole 65.

Here, the switch member 61 may be implemented as a power terminal of '+', '-' to apply the power of the battery to the air drive unit 50. That is, one terminal is fixed to the lower case 63, and the other terminal is installed on the rubber plate 69 disposed in the center of the lower case 63 so as to move up and down by contraction of the rubber plate 62. At this time, since the water pressure increases when the diver moves deeper in the water, the rubber plate 62 is contracted, and the power terminals of the '+' and '-' are in contact with each other so that the air driving unit 50 may be driven.

In addition, when the upper case 66 and the lower case 63 are coupled, the rubber case 62 is coupled with the rubber case 62, so that the inside of the lower case 63 may be sealed by the rubber plate 62. At this time, a separate sealing member (not shown) may be further used.

In addition, since the adjusting knob 67 is screwed into the knob hole 65 of the upper case 66, when the adjusting knob 67 is rotated forward, the rubber plate 62 is contracted.

On the other hand, the outer case of the lower case 63 is provided with a clip (63a) is attached to the body of the diver is easy to carry and can be used conveniently.

In addition, the rubber plate 62 may further include an elastic member 68 that connects the adjustment knob 67.

Here, the elastic member 68 may be implemented with a bent leaf spring. Compression springs may also be used. That is, both ends of the leaf springs are respectively installed in the rubber plate 62 and the adjustment knob 67 to be idling, and when the user rotates the adjustment knob 67, the rubber plate 62 is compressed in advance by the elasticity of the plate spring, or It may be stretched in advance.

Therefore, when the diver rotates the adjustment knob 67 forward to compress the rubber plate 62 in advance, the controller 60 operates even at a relatively low water surface, so that the diver easily scoops external air supplied by the air driver 50. Inhalation is possible. This can be useful for beginners in diving.

In addition, when the diver rotates the adjustment knob 67 in the reverse direction and expands the rubber plate 62 in advance, the control unit 60 does not operate even in a relatively deep water surface, so that the outside air is supplied without passing through the air driving unit 50. Divers can inhale. This is a choice for experienced divers, allowing them to dive for longer periods of time without wasting battery power.

In the above, the Example of this invention was described. The technical configuration of the present invention will be understood by those skilled in the art that the present invention can be implemented in other specific forms without changing the technical spirit or essential features.

Therefore, the embodiments described above are to be understood in all respects as illustrative and not restrictive, the scope of the invention being indicated by the following claims rather than the foregoing description, and the meaning and scope of the claims and All changes or modifications derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

1 is a state of use of the low pressure diving device according to an embodiment of the present invention.

2 is a view showing the accessory of the present invention.

3 is a view showing an air control valve of the present invention.

4 is a view showing a mouse portion of the present invention.

5 is a view showing a control unit of the present invention.

<Explanation of symbols for the main parts of the drawings>

10: part 20: suction part

30: discharge pipe portion 40: the mouth portion

50: air drive unit 60: control unit

70 coupling portion 80 expansion portion

Claims (11)

In the low pressure diving device, Float 10; A suction pipe part 20 installed at the buckle 10 to supply external air to the diving part; A discharge pipe part 30 for discharging the air supplied by the suction pipe part 20 to the outside; A mouse part 40 connected between the suction pipe part 20 and the discharge pipe part 30 to provide air to the diver; An air driving unit 50 for forcibly supplying air of the suction pipe unit 30; Low pressure diving device including a control unit 60 for controlling the air drive unit 50 according to the water pressure. The method of claim 1, The suction pipe portion 20 A suction pipe 21 through which outside air is sucked; An upper branch pipe 22 branched from an upper portion of the suction pipe 21 and connected to the air driving unit 50; A lower engine 23 connected to the air driving unit 50 and connected to a lower portion of the suction pipe 21; Low pressure diving device comprising an air control valve (24) installed in the suction pipe so as to be located between the upper branch pipe (22) and the lower pipe (23) to control the air supply. 3. The method of claim 2, The air control valve 24 is A case 24a installed between the suction pipes 21 and separated and coupled to the upper and lower parts; A cylindrical member 24b installed inside the case 24a; A piston 24c that is moved by the pressure of air in the cylinder member 24b; A plurality of through holes 24d spaced apart at intervals set at upper and lower portions of the cylindrical member 24b; A latching jaw (24e) formed between the plurality of through holes (24d) in the cylindrical member (24b); And a cover member (24g) which covers the upper portion of the cylindrical member (24b) and has an air hole (24f) through which air is moved by the operation of the piston (24c). The method of claim 1, Low pressure diving device further comprises a coupling portion (70) for coupling the float (10) and the suction pipe portion 20 and the discharge pipe portion (30). The method of claim 4, wherein The coupling portion 70 A sub-plate 71 integrally coupled to the sub-ball 10; A hole 72 formed to penetrate the sub-plate 71; A male coupling member 73 inserted through the hole 72; A female coupling member 74 connected to the male coupling member 73; Low pressure diving device comprising a plurality of holes (75) formed so that the suction pipe portion 20 and the discharge pipe portion 30 is installed through the water coupling member (73). The method of claim 4, wherein The suction pipe 21 is Low pressure diving device further comprises an expansion unit 80 is temporarily stored outside air. The method of claim 6, The expansion unit 80 Low pressure diving device which is a corrugated pipe of diameter twice or more than the diameter of the suction pipe (21). The method of claim 1, The mouse portion 40 is A suction connection part 41 connected to the suction pipe part 20; A discharge connection part 42 connected to the discharge pipe part 30; A mouse body 43 in which air is flowed by connecting the suction connection part 41 and the discharge connection part 42 to both sides; A suction valve 44 for supplying air supplied to the suction connection part 41 to the inside of the mouse body 43; A discharge valve 45 for discharging the air supplied to the mouse body 43 through the discharge connection part 42; A mouth hole 46 formed to penetrate the mouse body 43 so that the diving part inhales and discharges air; A mouth member 47 formed outside the mouth hole 46 so that the diver can bite into the mouth; Low pressure diving device comprising a closure member (48) installed in the mouse body (43) to open and close the mouth hole (46). The method of claim 8, The closure member 48 is An arm coupling member 48a coupled to the mouse body 43; A female screw hole 48b formed to penetrate the center of the female coupling member 48a; A knob 48d having a male screw thread 48c screwed to the female screw hole 48b; Low pressure diving device including an opening and closing plate (48e) formed on the other end of the knob (48d) for opening and closing the mouth hole (46). The method of claim 1, The control unit 60 A switch member 61 for driving the air driver 50; A rubber plate 62 for operating the switch member 61; A lower case 63 in which the rubber plate 62 is covered and in which the switch member 61 is built; An upper case 66 coupled to the lower case 63 and formed with a pressure hole 64 formed to transmit water pressure to the rubber plate 62, and an adjustment hole 65 having a female thread; Low pressure diving device comprising an adjustment knob (67) having a male thread to be screwed into the knob hole (65). The method of claim 10, Low pressure diving device further comprises an elastic member (68) connecting the rubber plate (62) and the adjustment handle (67).

Images