KR100571579B1 - Floating Portable Air Supply Unit - Google Patents

Abstract

The present invention relates to a floating portable air supply device, and in particular, to provide a portable portable air supply device for automatically supplying the air (Air) required for human breathing during diving activities at a relatively deep depth.

Floating type portable air supply device of the present invention having the above object, with a cover which is fixed to the upper end of the lower floating body to form an air inlet space having a lower floating body and a plurality of air communication holes to provide a floating force on the water surface An air supply buoy configured; An air supply pipe extending through the center of the lower floating body after the plurality of air inlet holes positioned at the top thereof communicate with the air inlet space of the air supply buoy; A scuba mouthpiece in communication with the air supply pipe; It includes, but the inner or outer side of the air supply buoy is further provided with an air compression pump for supplying compressed air to the scuba mouthpiece side through the air supply pipe, the compressed air as well as the external air communicated with the atmosphere underwater automatically As it can be supplied, it can be used safely in relatively deep water.

Floating portable air supply, air supply buoy, floating body, air supply pipe, mouthpiece for scuba, air compression pump, float, center of gravity, compressed air storage room, one-way valve

Description

Portable Air Supplying Apparatus Type Buoy on the Water}             

1 is a front sectional view showing a configuration of a conventional portable underwater air supply device.

Figure 2 is a schematic diagram schematically showing the configuration of the air supply pipe and the respiratory ejector of the configuration of a conventional portable underwater air supply device

3 is an external perspective view showing the overall appearance of the floating portable air supply apparatus of the present invention.

4 is an overall cross-sectional view showing a floating portable air supply apparatus of the present invention.

Fig. 5A is a partially cutaway exploded perspective view showing the inside of the floating portable air supply device of the present invention.

5B is a partially cutaway perspective view showing the inside of the floating portable air supply apparatus of the present invention.

Figure 6 is a schematic diagram showing the installation relationship of the valves for controlling the air flow of the floating portable air supply of the present invention

7 is an external air supply state diagram illustrating a state in which atmospheric air is supplied to a scuba mouthpiece through the floating portable air supply device of the present invention.

8 is a compressed air supply state diagram illustrating a state in which compressed air is supplied to a scuba mouthpiece through the floating portable air supply device of the present invention.

Fig. 9 is an operational state diagram of the float showing a state of preventing water penetration into the air supply pipe of the floating portable air supply device of the present invention.

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

100: air supply buoy 110: lower float

112: compressed air storage chamber 121: float

122: rubber pad 130: cover

135: air inlet space 150: upper floating body

170: center of gravity 180: air compression pump

200: supply pipe 201: first one-way valve

203: second one-way valve 205: third one-way valve

207: fourth one-way valve 209: directional control valve

210: branch pipe 300: scuba mouthpiece

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a floating portable air supply device, and more particularly to human breathing during diving activities at a relatively deep depth as well as at shallow depths. Provided with a portable floating portable air supply device for supplying the air required for the air, the air compression pump to generate air supply buoy (floating) and compressed air floating on the water surface and is formed in the internal space of the air supply buoy By constructing a compressed air storage room to automatically supply the compressed air in the compressed air storage room underwater and at the same time to prevent water penetration into the air passage when using a snorkel on the water surface, as well as a certain depth Breathing of the user can be made naturally even in the water having a conventional compressed air and the filling device for filling the compressed air Compared with the conventional submersible air supply system, it is lighter in weight and easier to use and carry. Also, by simplifying the construction, the manufacturing cost of the device can be reduced, and the maintenance and storage of the device is easy and the buoy The present invention relates to a floating portable air supply device capable of preventing diving to a certain depth or less due to the floating force, and thus preventing safety accidents during underwater activities such as swimming.

In recent years, people have invested a lot of money and time in order to effectively spend their time away from their normal life, such as work or school, in order to better their own lives or to relieve stress from everyday life. It is true.

There are many kinds of recreational activities as above, but among them, there are many recreational activities related to the sea in summer, due to the special topographical conditions of Korea. There is a growing trend for skin scuba activities to enjoy the mysterious underwater world.

Skin scuba refers to skin diving and scuba diving. Skin diving refers to skin diving, masking, snorkel, and flippers. For example, dive until you can hold your breath and hold your breath. Scuba diving means that a diver can use a combination of air glasses, snorkels, flippers, etc. It means that you can dive up to 30 ~ 40m under the sea by breathing by yourself.

That is, the above-mentioned skin diving or scuba diving is a leisure to swim or dive in the water, and the depth or time of diving according to the degree of equipment, the skin diving is oxygen tank (compressed air cylinder) While scuba diving refers to being able to float on water and see underwater, scuba diving involves taking oxygen tanks and diving deep into the water to observe the scenery in deep water.

The skin diving and the scuba diving are both provided with an air supply device, the air supply in the skin diving is a snorkel, the air supply in the scuba diving, in addition to the snorkel to reduce the pressure of the compressed air and the compressed air cylinder This includes automatic respiration regulators.

There are advantages and disadvantages to skin diving and scuba diving using the air supply as described above. First, skin diving using only the snorkel as the air supply has the advantage of low equipment purchase cost, but as mentioned above, the snorkel alone The disadvantage is that you can't breathe deeply, so you can't observe the scenery in the water, and scuba diving using the snorkel, compressed air and automatic respirator as an air supply can breathe underwater as well. While there is an advantage that can be observed even in the depths of the water, while the cost of equipment is expensive, and the compressed air to be worn on the back of the diver is heavy because the weight of the compressed air to sleep after wearing the There is a problem to be restricted when moving outside In addition, the configuration and use of the equipment including the automatic breathing regulator is complicated, and due to its use in air-free water, it is difficult to rent the above-mentioned equipment only after having obtained thorough training for safety. Restrictions have been recognized as equipment and leisure that are not readily available to the public.

In addition, when the air in the compressed air is exhausted, there is a troublesome problem such as having to refill the air in the compressed air for a long time.

Accordingly, in order to improve the above-mentioned various problems, the Korean Utility Model Registration No. 0317210 (Application No. 2003-10720, Designed by the applicant of the present invention jointly filed and determined to maintain technology evaluation of December 16, 2003) Name: a portable underwater air supply device), which is a first floating material (1) that provides a primary floating force in the underwater air supply device for supplying air to the water, as shown in Figs. ), The floating metal (1a) in close contact with the bottom center of the first floating water (1) as the central axis of the floating force by the first floating material (1), and the first floating material (1) When the second float (2) to provide a secondary floating force to prevent the ingress of external water, the first to fourth air passage (10, 11, 12, 13), which is a moving space of the air, and the external water Go to the surface to prevent entering into the second and third air passages 11 and 12 The first surface of the air passage 10 is opened at the lower end thereof, and the first air passage 10 is opened in a circular shape at regular intervals, and the second air cylinder is moved up and down with the second float 2. A rubber plate 7 which blocks or opens the inlet of the furnace 11, a movable table 6 which is integrally coupled to the rubber plate 7 and the second float 2 to perform an integral movement, and the second float Boss 3, which is the lowest support of (2), and a third float (8) bonded to the upper surface and both sides of the waterproof plate (5) to provide a floating force to balance and maintain the posture on the water surface Floating air buoys;

The second through fourth air passages (11, 12, 13) are formed by sequentially passing through the floating metal (1a), the first floating material (1), the second floating material (2), and the rubber plate (7). An air supply pipe 15 for guiding water supplied from the buoy into water;

One-way inhaler 17 to flow only from the fourth air passage 13 in the direction of the breathing passage 16 (shown in Figure 2) and prevent the flow in the opposite direction, to prevent the infiltration of water in the water by increasing the internal pressure after breathing A respirator composed of one-way ejectors 18 and 19 installed outside and inside the chair, and an ejector body 20; It is characterized by what was included.

Korean Utility Model Registration No. 0317210, which is a conventional technology characterized by the above-described technical configuration, is lighter in weight than the underwater air supply device made of a conventional compressed air cylinder and a filling device for filling compressed air, and can be easily used and carried. By simplifying the configuration as compared to the prior art, the manufacturing cost of the device can be reduced, and the maintenance and storage of the device are easy, and the buoyancy of the buoy can prevent diving below a certain depth, so that the water can be used underwater. Activities have the effect of preventing safety accidents. However, there is a problem that the air supplied from the air supply buoy located on the water surface cannot be supplied through the air supply pipe due to water pressure acting on the human body at a depth of about 1 m or less from the water surface. That is, in the water below the depth of about 1m from the surface of the water as the water pressure acts on the chest of the diver to press the chest of the diver, the diver can spout air, but from the air supply buoy located on the surface of the water There was a problem that can not breathe because it can not suck the air supplied. Therefore, there is a problem that the practical use of the equipment employing the prior art is weakened as it becomes almost impossible to breathe through the equipment of the prior art above a certain depth (about 1 m) from the surface of the water.

SUMMARY OF THE INVENTION The present invention has been made to improve the above-mentioned problems, and provides a portable floating underwater air supply device for supplying air for human breathing when diving at a relatively shallow depth, but with a buoy buoy floating on the water surface. An air compression pump for generating compressed air and a compressed air storage chamber formed in the internal space of the air supply buoy allow the compressed air in the compressed air storage chamber to be automatically supplied to the water, thereby having a predetermined depth as well as water surface. Among them, the user's breathing can be made naturally, thereby increasing the safety and practicality of the device of the present invention, and the weight is lighter than the underwater air supply device, which is composed of a compressed air container and a filling device for filling the compressed air, so that it is easy to use and carry. It is also possible to make the configuration Purification reduces the manufacturing cost of the device, facilitates maintenance and storage, and prevents diving below a certain depth due to the buoyancy of the buoy, preventing safety accidents during underwater activities such as playing in the water. An object of the present invention is to provide a floating portable air supply device capable of preventing the leakage.

Another object of the present invention is to provide a floating portable air supply device capable of reducing the risk of a safety accident in water by providing a buoyant buoyancy capable of simultaneously serving as a safety tube.

As a means for achieving the above object, the floating portable air supply device of the present invention, the lower floating body to provide a floating force on the water surface, and having a plurality of air communication holes to form an air inlet space while the upper end of the lower floating body An air supply buoy comprising a cover fixed to the air supply buoy;

An air supply pipe extending through the center of the lower floating body after the plurality of air inlet holes positioned at the top thereof communicate with the air inlet space of the air supply buoy;

A scuba mouthpiece in communication with the air supply pipe; It includes, but the inner or outer side of the air supply buoy is further provided with an air compression pump for supplying compressed air to the scuba mouthpiece side through the air supply pipe, the compressed air as well as the external air communicated with the atmosphere underwater automatically As it can be supplied, it can be used safely in relatively deep water.

In addition, the floating portable air supply apparatus of the present invention is characterized in that the gravity center body made of a material having a specific gravity that is heavier than water so as to maintain the balance of the apparatus of the present invention on the water surface at all times.

Further, the floating portable air supply device of the present invention is characterized in that a float capable of preventing water penetration into the air supply pipe is provided.

In addition, the floating portable air supply device of the present invention is characterized in that it has a structure that can be quickly discharged when the water penetrates.

In addition, the floating portable air supply apparatus of the present invention is characterized in that a compressed air storage chamber for storing compressed air by an air compression pump is formed so as to cope with when a large amount of compressed air is instantaneously required. .

In addition, the floating portable air supply apparatus of the present invention is characterized in that it is provided with a one-way valve having a function of opening and closing according to the change in air pressure when the air compression pump is driven.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. First, in adding reference numerals to the components of each drawing, it should be noted that the same components as possible, even if displayed on the other drawings have the same number as possible.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail.

Figure 3 is an external perspective view showing the overall appearance of the floating portable air supply apparatus of the present invention, Figure 4 is an overall cross-sectional view showing the floating portable air supply apparatus of the present invention, as shown in the figure, the floating portable air supply of the present invention The device is provided with a lower float 110 providing a primary floating force on the water surface, and a plurality of air communication holes 130a to form an air inlet space 135 at the top of the lower float 110 Hemisphere cover 130 is coupled and fixed, the upper float 150 is coupled to the top of the hemisphere-shaped cover 130 to provide a secondary floating force, and the lower float 110 Air supply buoy (100) consisting of a center of gravity (170) coupled and fixed to the bottom center of the center to maintain the balance of the lower float (110); An air supply pipe 200 communicating with an air inflow space of the air supply buoy 100; It comprises a scuba mouthpiece (Mouthpiece) 300 is coupled to the air supply pipe (200).

The floating portable air supply device of the present invention having the above-described configuration will be described in more detail including their coupling relationship as follows.

Fig. 5A is a partially cutaway exploded perspective view showing the inside of the floating portable air supply device of the present invention, and Fig. 5B is a partially cutaway perspective view showing the inside of the floating portable air supply device of the present invention.

Referring to the drawings, the lower float 110, which is one of the components of the air supply buoy 100, is an object that can float on the surface of the water primarily by buoyancy, and the inside thereof is a compressed air storage chamber. It is formed of a box-shaped disk having a hollow portion of the hollow space to function as 112, the inlet pipe through-hole 110a for the passage of the intake pipe 200 is formed in the center of the disk, the lower side of the disk Branch pipe coupling hole (110b) is coupled to the branch pipe 210 branching from the intake pipe 200, the discharge pipe coupling hole is coupled to the discharge pipe 180b of the air compression pump 180 on the other end of the disc 110c is formed. The material of the lower floating body 110 having the above-described shape is a material that does not change even when the compressed air is stored, that is, the shape does not easily change or break with respect to vacuum compressed styrofoam or plastic or external force. It is obvious that it can be composed of a wide variety of materials such as iron plate or tempered glass having a thickness.

In addition, the cover 130 coupled to the upper surface of the lower float 110 made of the above-described shape and material by a fastening member (not shown) such as a bonding material or a bracket to form an air inflow space 135, It is made of a hemispherical (半球) type body, the surface of the body is formed with a plurality of air communication holes (130a) in communication with the atmosphere, the lower portion of the cover 130, that is, of the lower floating body 110 The coupling surface of the cover 130 body coupled to the upper surface is formed of a protruding leg 130b having a predetermined interval so as to have a spaced groove 132 spaced apart from the upper surface of the lower float 110. The upper portion of the cover 130 body is formed of a flat portion (130c). As the material of the cover 130 having the above-described shape, like the material of the lower floating body 110, a steel sheet having a thickness such that the shape does not easily change or break with respect to styrofoam or plastic or external force, which is vacuum compressed. It can be composed of many different materials such as tempered glass.

In addition, by the fastening member (not shown) such as a bonding material or a bracket on the top of the hemispherical cover 130 made of the above-described shape and material, that is, the upper portion of the flat portion 130c that is the upper portion of the cover 130 body. The upper float 150 to be coupled is an object that can be floated on the surface of the secondary secondary by buoyancy, the inside of which is made of a circular shape having a solid portion filled with the same material, the bottom surface of the cover 130 It is formed as a flat portion (not shown) to be in close contact with the flat portion 130c which is the upper portion of the body, the upper surface is formed in a round circle shape. The material of the upper floating body 150 having the above-mentioned shape is made of styrofoam compressed in vacuum, but is not limited thereto and may be formed of various materials having buoyancy.

As the last component constituting the air supply buoy 100, the center of gravity 170, which is coupled to the center of the lower end of the lower floating body 110 by a fastening member (not shown) such as a bonding material or a bracket, the lower portion An object for maintaining the balance of the entire air supply buoy 100 including the fluid 110, is formed in the shape of a disk, the center of the center of gravity of the weight-shaped body 170, the intake pipe 200 passes through the intake pipe 200 The ball 170a is formed. The weight center body 170 having the above-described shape is made of a material having a specific gravity that is heavier than water, and when the air supply buoy 100 is inclined or inverted on the water surface, the weight center body 170 cooperates with the upper floating body 150 on the water surface as shown in the figure. It is to serve to restore the balance of the air supply buoy (100). The weight center body 170 having the above role is described as being installed only at the bottom center of the lower floating body 110 in the form of a disk, but is not limited thereto, and the lower side of the circular lower floating body 110 in the form of a rod. It can also be installed symmetrically in a circle.

The air supply pipe 200 is installed at the center of the air supply buoy 100 constituting the above configuration. Hereinafter, the configuration and installation relationship of the air supply pipe 200 will be described.

As shown in FIGS. 5A and 5B, the air supply pipe 200 extending through the lower portion of the air supply buoy 100 to the outside after passing through the central portion of the air supply buoy 100 is the air supply buoy 100. The circular air inlet box 220 which is tightly coupled and fixed to the flat portion 130c which is an inner upper end of the cover 130 and integrally coupled to the center of the circular air inlet box 220 communicates with the lower floating body. The first air supply coupled to one side of the mouthpiece 300 for scuba after extending through the intake pipe through-hole (110a) of the 110 and the intake pipe through-hole (170a) of the center of gravity 170 in order to extend outside A pipe 200a and a second air supply pipe 200b coupled to the other side of the scuba mouthpiece 300 and then integrally coupled to and communicated with any one side of the first air supply pipe 200a.

In the above configuration, the lower end of the circular air inlet box 220, that is, the lower end of the circular air inlet box 220 on the side of the upper end of the first air supply pipe 200a, the first air supply pipe 200a A plurality of air inlet holes 220a are formed around the outer circumference thereof.

As described above, a first air supply is located on the side of the first air supply pipe 200a penetrating the central portion of the air supply buoy 100, that is, between the lower float 110 and the flat portion 130c that is the upper portion of the cover 130. On the pipe 200a side, a float 121 and a rubber pad 122 are coupled to each other so that the first air supply pipe 200a can be moved up and down with an axis, and the rubber pad 122 is an air inflow box ( It has a function of opening and closing the air inlet hole (220a) of 220, is integrally coupled with the float 121 in the upper portion of the float 121 to move together when the float 121 is moved.

Meanwhile, one side of the branch pipe 210 communicates with the first air supply pipe 200a extending through the intake pipe through hole 170a of the center of gravity body 170 and extending outwardly (lower portion), and the branch pipe 210 is connected. The other side of the) is in communication with the compressed air storage compartment 112 of the lower floating body 110, the suction pipe (180a) of the air compression pump 180 on the side of the first air supply pipe (200a) located above the branch pipe (210) This is in communication. At this time, the discharge pipe 180b of the air air compression pump 180 is in communication with the compressed air storage compartment 112 of the lower floating body 110 as mentioned above. The air compression pump 180 having the connection relationship is a conventional device, which is made of a small size and is protected by a waterproof cover, and its installation is provided at an outer side of the air supply buoy 100 as shown in the drawing. Although it may be installed, the present invention is not limited thereto and may be installed in the air supply buoy 100.

Subsequently, the first air supply pipe 200a located between the suction pipe 180a communicating part of the air compression pump 180 and the branch pipe 210 communicating part has a function of opening and closing according to a change in air pressure. 1 One-way valve (Check Valve) 201 is installed, the first air supply pipe (200a) coupled to one side of the mouthpiece 300 for the scuba is coupled to the first air supply pipe (200a) coupled to the same function as the water pressure Has a second one-way valve 203 is installed, the breathing air is coupled to the second air supply pipe 200b coupled to the other side of the mouthpiece 300 for the scuba through the second air supply pipe (200b) A third one-way valve 205 having a function of flowing only toward the scuba mouthpiece 300 is installed, and the scuba extends outwardly between the second one-way valve 203 and the third one-way valve 205. Short run of mouthpiece 300 for A fourth one-way valve 207 is installed in the pipe (not shown) to prevent water from flowing back into the scuba mouthpiece 300 when the diver inhales the air inhaled. On the coupling side of the first air supply pipe 200a and the second air supply pipe 200b, the compressed air compressed through the air compression pump 180 and the external air of atmospheric pressure communicating with the air are separated and blocked. A direction control valve 209 having a function is provided.

Referring to the operation of the valve having the above installation structure and function in more detail as follows.

6 is a schematic view showing the installation relationship of the valves for controlling the air flow of the floating portable air supply device of the present invention, as shown in the drawing, when first described comprehensively, the air compression pump 180 against water pressure in the water After generating the compressed air to deliver the compressed air to the compressed air storage compartment 112 of the lower floating body 110 through the discharge pipe (180b), the compressed air storage chamber 112 is stored in the compressed air. This is provided for the diver to overcome the influence of the water pressure and breathe, when a large amount of air supply is required in the water, the compressed air stored in the compressed air storage compartment 112, the scuba mouthpiece 300 of the diver It has a structure that is supplied to. That is, the air compression pump 180 generates compressed air against water pressure, and generates only a predetermined amount of compressed air, so that the amount of compressed air is variably changed correspondingly when the breathing volume of the diver increases momentarily. It cannot be increased. Therefore, in the present invention, when the respiratory volume of the diver increases as described above, in order to supply compressed air correspondingly, the compressed air storage chamber 112 is formed in the lower floating body 110. However, the present invention may supply the compressed air compressed by the air compression pump 180 directly to the scuba mouthpiece 300 of the diver through the air supply pipe 200 without passing through the compressed air storage chamber 112. have. At this time, the discharge pipe 180b of the air compression pump 180 is not directly connected to the compressed air storage chamber 112 but is directly connected to the air supply pipe 200.

In the above-described structure, when the underwater effect of the water pressure is greatly affected, that is, about 1 m or less from the water surface, the water pressure generally prevents the diver from directly inhaling atmospheric air. In other words, if the compressed air is not supplied at a predetermined depth (about 1 m from the water surface) or less, suction of external air at atmospheric pressure through the air supply pipe 200 is impossible due to the influence of the water pressure.

Therefore, due to the above reason, a diver located in the water of about 1 m or less from the surface of the water cannot inhale external air at atmospheric pressure, and if the diver cannot prevent breathing, the pressure in the air supply pipe 200 increases. At this time, the air compression pump 180 is automatically driven by a signal of a pressure sensor (not shown).

When the air compression pump 180 is driven as described above, the pressure B located below the first one-way valve 201 in the first air supply pipe 200a is located at the top of the first one-way valve 201. It becomes higher than (A). At this time, the first one-way valve 201 is closed to block the flow of air introduced from the atmosphere, whereby the compressed air stored in the compressed air storage chamber 112, branch pipe 210 and the second one-way valve 203 It is supplied to the scuba mouthpiece 300 through the). At this time, the following direction control valve 209 is in a state in which the second air passage (D) is closed.

On the contrary, since the air compression pump 180 is not driven when the underwater activity is less than 1m when the influence of the water pressure is not large, the pressure difference does not occur, so that the first one-way valve 201 is opened. Therefore, the external air flowing from the atmosphere is supplied to the scuba mouthpiece 300 through the first one-way valve 201 and the third one-way valve 205. At this time, the direction control valve 209 is in a state of closing the first air passage (C).

In addition, the direction control valve 209 installed at the coupling side of the first air supply pipe 200a and the second air supply pipe 200b may include compressed air compressed through the air compression pump 180 and the atmosphere. It has a function of distinguishing and blocking external air of communicating atmospheric pressure, wherein the compressed air is supplied to the scuba mouthpiece 300 through the first air passage C, and the external air of atmospheric pressure is second It is to be supplied to the scuba mouthpiece 300 through the air passage (D).

In addition, the second one-way valve 203 provided on the coupling portion side of the scuba mouthpiece 300 and the first air supply pipe 200a, the high-pressure air of the air tank of the scrubber diving equipment to the depth of the water It acts as a regulator, which is a pressure reducing device that adjusts to the same pressure as the pressure, according to the air flowing through the first air supply pipe (200a) to match the same as the water pressure, and the air is the first air passage ( It is opened to be delivered to the scuba mouthpiece 300 through C), and functions to close when a diver vomits breath through the scuba mouthpiece 300.

In addition, the third one-way valve 205 provided on the coupling portion side of the scuba mouthpiece 300 and the second air supply pipe 200b has an external air of atmospheric pressure by the action of the direction control valve 209. It is opened when supplied to the scuba mouthpiece 300 through the second air passage (D), and is closed when the diver vomits breath through the scuba mouthpiece 300.

In addition, the fourth one-way valve 207 is provided in the short extension pipe of the scuba mouthpiece 300 extending outward between the second one-way valve 203 and the third one-way valve 205, the diver When the air drunk through the scuba mouthpiece 300 is spouted into the water, it is opened and at this time, the water in the water serves to block backflow of the scuba mouthpiece 300 by the water pressure.

The above-mentioned air compression pump and the first to fourth one-way valves are not only applicable to the technical field to which the present invention belongs, but are all commonly known in the art, and their detailed configuration and detailed installation including each sensor The relationship will be omitted.

Hereinafter, the use and operation of the floating portable air supply apparatus of the present invention having the above-described configuration will be described.

7 is an external air supply state diagram illustrating a state in which atmospheric air is supplied to a scuba mouthpiece through the floating portable air supply device according to the present invention, and FIG. 8 is compressed air through the floating portable air supply device according to the present invention. It is a compressed air supply state figure which shows the state supplied to the scuba mouthpiece.

First, as shown in FIG. 7, the submersible underwater air is supplied to the scuba mouthpiece through the floating portable air supply device of the present invention when the submersible is under water activity within 1m, where the influence of water pressure is not large. do.

First, the air supply buoy 100 maintains a floating state on the water surface due to the floating force of the lower floating body 110. Therefore, in the above state, the atmospheric pressure external air communicating with the atmosphere (Atmosphere), a plurality of air communication holes (formed in the hemispherical cover 130 coupled to the upper surface of the lower float 110) 130a), the outside air flowing into the air inlet space 135 inside the cover 130, and the air introduced into the air inlet space 135 is located in the air supply pipe 200 located above the air inlet space 135. It passes through the air supply pipe 200 through a plurality of air inlet holes (220a) formed in the circular air inlet box 220. At this time, as mentioned above, when the diver is active in the water within 1m from the water surface does not significantly affect the pressure, the first one-way valve 201 is opened, the direction control as the diver can naturally breathe Since the valve 209 closes the first air passage C, and the third one-way valve 205 is also opened, the external air introduced from the atmosphere passing through the air supply pipe 200 inside the second air passage (C). After passing through the D) is supplied to the diver through the scuba mouthpiece (300).

Subsequently, as shown in FIG. 8, the state in which the compressed air is supplied to the scuba mouthpiece through the floating portable air supply device of the present invention when the diver is underwater in the water within the influence of the hydraulic pressure greatly.

When a diver is active in the depth of the water where the influence of the water pressure is large, that is, about 1 m or less from the surface of the water, the water pressure prevents the diver from directly inhaling atmospheric air and makes it impossible to breathe. Accordingly, the pressure inside the air supply pipe 200 is increased. At this time, the pressure sensor (not shown) transmits a driving signal to the air compression pump 180 when the pressure inside the air supply pipe 200 is higher than a predetermined value. Accordingly, the air compression pump 180 is automatically driven.

When the air compression pump 180 is driven as described above, the pressure B located below the first one-way valve 201 is higher than the pressure A located above the first one-way valve 201. At this time, the first one-way valve 201 is closed to block the flow of the external air so that external air flowing from the atmosphere no longer passes through the inside of the air supply pipe 200. Accordingly, the external air introduced from the atmosphere is converted into compressed air by the air compression pump 180 and then stored in the compressed air storage compartment 112 of the lower float 110, and the compressed air stored in the compressed air storage compartment 112. Air flows on the air supply pipe 200 through the branch pipe 210. At this time, the direction control valve 209 is to close the second air passage (D), the second one-way valve 203 is open, the compressed air passing through the air supply pipe 200 inside the first air passage ( After passing through C) is supplied to the diver through the scuba mouthpiece (300).

On the other hand, in the floating-type portable air supply device of the present invention having the above function, the air supply buoy 100 floating on the water surface is always constantly maintained in a horizontal state by an external force acting from the outside, such as waves or wind. You won't be able to. That is, when a wave or wind acts on the air supply buoy 100, the air supply buoy 100 may be inclined or inverted without being balanced due to the influence thereof. In this case, the lower portion of the air supply buoy 100 may be inverted. The air supply buoy on the water surface is formed by interaction with the center of gravity body 170 installed at the bottom of the fluid 110 by the top floating body 150 of the air supply buoy 100 providing secondary floating force. Restore the total balance of 100).

And, as shown in FIG. 9, if water penetrates into the inside of the air supply buoy 100, that is, inside the hemispherical cover 130 (air inflow space), the central portion of the air supply buoy 100 is provided. The buoyancy force acts on the float 121 which can be moved up and down with the axis of the first air supply pipe 200a penetrating through the float 121, so that the float 121 rises above the water surface, and at the same time, the upper portion of the float 121 Rubber pad 122 is integrally coupled to the float 121 also closes the plurality of air inlet holes (220a) formed in the circular air inlet box 220 on the top of the first air supply pipe (200a) Let's go. Accordingly, the penetration of water through the air supply pipe 200 is blocked at the source.

On the contrary, when the air supply buoy 100 rises above the surface of the water again, the float 121 and the rubber pad 122 are lowered back down the axis of the first air supply pipe 200a by gravity. The plurality of air inlet holes 220a formed in the circular air inlet box 220 on the upper end of the first air supply pipe 200a are all open to normally supply air through the air supply pipe 200.

In addition, since the air supply buoy 100 is always located on the water surface during use, water may always penetrate into the air supply buoy 100, that is, inside the cover 130 having a hemisphere shape. As shown in FIG. 3, the coupling surface of the cover 130, which is in contact with the upper surface of the lower floating body 110, is spaced apart to have a spaced groove 132 spaced apart from the upper surface of the lower floating body 110. As formed by the protruding leg 130b, the water penetrated as described above is easily discharged to the water through the spaced groove 132 when the lower float 110 is raised to the surface by buoyancy. do.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and it is common in the art that various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

As described above, the floating portable air supply device of the present invention can enjoy a beautiful and mysterious underwater world by providing a portable floating underwater air supply device for supplying air for human breathing when diving at a relatively shallow depth. In addition, it can be used safely in relatively deep water as it can automatically supply compressed air into water.

In addition, the floating portable air supply device of the present invention is lighter in weight than the underwater air supply device including a conventional compressed air cylinder and a filling device for filling the compressed air, and can be easily used and carried, thereby simplifying the construction thereof. As a result, the manufacturing cost of the device can be reduced, and the maintenance and storage of the device is easy, and the buoyancy of the buoy can prevent diving below a certain depth, thereby preventing safety accidents during underwater activities such as swimming. can do.

In addition, the air supply buoy of the floating portable air supply device of the present invention can reduce the risk of safety accidents in the water by being able to simultaneously serve as a safety tube as well as air in the water.

In addition, the floating portable air supply device of the present invention can be practically used to automatically block the water penetration which is a disadvantage of the snorkel and at the same time to compensate for the disadvantages of the conventional high-cost underwater air supply device.

Claims (10)

delete delete delete delete delete delete delete The cover 130 is fixed to the upper end of the lower floating body 110 to form an air inlet space 135 having a lower floating body 110 and a plurality of air communication holes (130a) to provide a floating force on the water surface The air supply buoy 100 configured and the plurality of air inlet holes 220a positioned at the top thereof communicate with the air inflow space 135 of the air supply buoy 100 and then pass through the center of the lower floating body 110. And a scuba mouthpiece 300 which is coupled to and communicated with the air supply pipe 200 extending to the air supply pipe 200, wherein the air supply pipe (inside or outside the air supply buoy 100) is provided at one side. In the floating portable air supply device is provided with an air compression pump 180 for supplying compressed air to the scuba mouthpiece 300 through the 200, The air supply pipe (200), the floating portable air supply device characterized in that the first one-way valve (201) having a function of opening and closing according to the change in the air pressure when the air compression pump 180 is installed. The method of claim 8, wherein the air supply pipe 200 is coupled to one side of the first air supply pipe (200a) and the other side of the mouthpiece 300 for the scuba mouth 300 is coupled to the scuba mouthpiece 300 The second air supply pipe 200b is coupled to and communicated with the first air supply pipe 200a, and the air introduced through the first air supply pipe 200a is equal to the water pressure at one side of the scuba mouthpiece 300. At the same time, a second one-way valve 203 is installed to open the inflow air only to the scuba mouthpiece 300, and the second air supply pipe 200b is provided on the other side of the scuba mouthpiece 300. The third one-way valve 205 is opened so that the inflow air introduced through the scuba mouthpiece 300 is delivered to the scuba mouthpiece 300, and is external from the middle between the second one-way valve 203 and the third one-way valve 205. Extension tube extending into the sleep Floating portable air supply device characterized in that the fourth one-way valve 207 has a function of blocking the inflow of water in the water back into the scuba mouthpiece 300 when the self-drained air spits out into the water . 10. The method of claim 9, wherein the coupling portion of the first air supply pipe 200a and the second air supply pipe 200b of the air supply pipe 200 communicates with compressed air compressed by the air compression pump 180 and the atmosphere. Floating portable air supply device, characterized in that the direction control valve 209 having a function to block the first air supply pipe (200a) or the second air supply pipe (200b) by separating the external air of the atmospheric pressure.

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