KR100404754B1 - Breathing Apparatus - Google Patents

Abstract

The present invention relates to a submerged spherical body, which is molded into a hollow cross-sectional shape to maintain a floating state on the water surface by buoyancy and an assembly hole (11) is formed; and the spherical body (10) The connecting pipe 21 is inserted into the formed assembly hole 11 of the upper end is exposed to the upper portion of the substructure 10, the connecting hose 25 and the connecting body 20 is connected to a predetermined length at the bottom; The connector 21 of the connector 20 is fixed so as not to be separated from the upper portion of the substructure 10, and the inlet hole 34 is drilled to supply external oxygen through the connector 21 and the connection hose 25. Fixed cap 30 and; Connecting the mouse so that the mouthpiece 43 is in communication with the mouth so that the oxygen is supplied to the user's mouth from the connection hose 25 of the connector 20 and comfortably bite to the mouth connection Member 40 and; Located at the front end oxygen inlet side of the mouse connection member 40 through the connection hose 25 Oxygen inflow check member 50 having an inlet check valve 51 and the oxygen outlet side of the mouse connection member 40 so as to be opened only in the direction in which the supplied oxygen is introduced and to prevent the reverse flow of oxygen; A water inflow check member (60) having a discharge check valve (61) to open and close in a reverse direction with the inflow check valve (51) so that the discharged air is discharged and the external water does not flow into the inside; It is connected to the discharge pipe portion 42 of the 40 is composed of an induction pipe 80 to guide the bubbles generated during breathing to the rear of the field of view, the connection body 20 connected to the spherical body 10 according to the user's convenience ), And the subsidiary body 10 is molded by a blow molding method to prevent damage such as puncture during use, so that the connector 20 and the mouse connecting member ( 40) and kite It can be used with confidence when using the tube when playing in the water while separated from the water, so that the user can expand the choice of use and give the confidence and stability. It is a very useful invention that allows you to enjoy diving for a long time while receiving oxygen from the air in the connection.

Description

Breathing Apparatus {Breathing Apparatus}

The present invention relates to a combined oxygen supply tube, and more specifically, it is invented to be used in conjunction with the tube function as well as to enable continuous water play by connecting the connection hose when oxygen is supplied.

In general, a tube and an oxygen supply device are widely used as a water play equipment known in the art.

The tube is a donut shape made of rubber or thin vinyl, which is filled with air, and is used for maintaining a buoyancy of the body so that the user can enjoy playing in the water so as not to fall into the water on the surface of the water.

In addition, the oxygen supply device is a respiratory equipment capable of supplying oxygen to the user in the water when diving.

These equipments are manufactured and distributed individually depending on the intended use.

In the above case, since the tube is made of a material such as thin vinyl or rubber, there is a disadvantage that it may burst due to external pressure when playing in water, and the snorkel is used to dive for a short time at a limited depth, so there are many limitations in using it.

In addition, as a more advanced mechanism, the oxygen supplyer that supplies oxygen to the diver when the diver submerges is an oxygen tank that stores compressed air, and has a disadvantage in that it can only dive for a limited time depending on its capacity.

In addition, this oxygen tank is expensive and expensive equipment, so it is not suitable for use by the general public or infants for play, and in particular, it requires a breathing oxygen supplier that can safely and long-term dive when infants play in the water. to be.

It is an object of the present invention to provide a submersible spherical body that can be used as a tube or oxygen supply depending on the use of the user when playing in the water.

Another object of the present invention is to provide a tube-compatible oxygen supply to prevent the dangerous accident caused by the breakage of the tube in use to improve the user's confidence.

It is still another object of the present invention to provide a tubular oxygen feeder capable of improving its marketability.

1 is a perspective view of the present invention

2 is a longitudinal cross-sectional view of the present invention;

Figure 3 is an enlarged side cross-sectional view showing the main part of the connecting pipe connecting the connection hose so that the oxygen is supplied by a fixed cap fixed to the supply hose.

Figure 4 is a side cross-sectional view showing the shape of the fixing cap for fixing the connection pipe

5 is a bottom view of the fixing cap

Figure 6 is a side cross-sectional view showing the configuration of the mouthpiece for supplying oxygen to the user underwater

Fig. 7 is an enlarged sectional side view showing the main part of the installation state of a valve installed to advance the flow of air in one direction when oxygen is supplied by the mouthpiece;

8 is a reference diagram showing a state of use of the present invention

Explanation of symbols for main parts of the drawings

10-Sphere 11-Assembly Hole

20-connector 21-connector

30-Retaining cap 31-Male thread

32-Spacing 33-Groove

34-Inlet hole 40-Mouse connection member

41-Inlet pipe 42-Outlet pipe

43-Mouthpiece 50-Oxygen inlet check member

51-Inlet check valve 60-Water inlet check member

61-Drain check valve

The object of the present invention, and is formed into a hollow cross-sectional shape to maintain a floating state on the water surface by buoyancy and the assembling hole 11 is formed;

The connecting tube 21 is inserted into the assembly hole 11 formed in the substructure 10 so that the upper end is exposed to the upper portion of the substructure 10, and the connecting hose 25 is connected to the lower end at a predetermined length. 20 and;

The connection tube 21 of the connector 20 is fixed so as not to be separated from the upper portion of the substructure 10 and the inlet hole 34 is drilled to supply external oxygen through the connector 21 and the connection hose 25. The fixed cap 30 and the mouse; The connection hose 25 of the connector 20 is connected to the oxygen supply to the user's mouth and the mouthpiece 43 is provided so that the mouthpiece 43 is in communication with the mouth comfortably A connection member 40 and an inlet check valve positioned at the tip oxygen inlet side of the mouse connection member 40 to open only in a direction in which oxygen supplied through the connection hose 25 is introduced, and to prevent backflow of oxygen; The oxygen inlet check member (50) having a 51; and the inlet check valve (located at the oxygen outlet side of the mouse connection member (40) so that the exhaust air emitted by the user is discharged and external water does not enter the inside) The discharge check valve ( A water inflow check member 60 having a 61; and an induction pipe 80 connected to the discharge pipe portion 42 of the mouse connection member 40 to guide bubbles generated during respiration to the rear of the field of view. Therefore, the user can use the tube when playing in water on the water surface using only the float 10 of the combined oxygen supply tube, by connecting the connector 20 and the mouse connecting member 40 when diving As it allows external oxygen to be supplied to the user's respiratory system in the submerged state, it is possible to continuously play diving.

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

1 is a perspective view illustrating the shape of the present invention as an example, and the connecting body 20 and the mouse connecting member 40 are connected to the lower part of the subsidiary body 10, respectively, and the connecting body 20 and the subsidiary body 10 are connected to each other. The assembly state of the oxygen respirator use to fix the fixed cap 30 can be seen.

Figure 2 is a side cross-sectional view of the assembled state of the present invention, the connection pipe 21 is fixed to the assembly hole 11 formed in the center of the substructure 10 by a fixing cap 30, the lower portion of the connection hose 25 ) Shows the structure in which the mouse connection member 40 is connected in cross section.

3 is a cross-sectional view illustrating a state in which the connection pipe 21 is fixedly installed in the assembly hole 11 of the substructure 10 by the fixing cap 30, and the upper end of the connection pipe 21 is fixed cap. The inlet hole of the connecting body 20 corresponding to the oxygen inlet is positioned at the top of the subsidiary body 10 by being fastened with the screw 30, and the interval maintaining piece 32 of the fixing cap 30 is the subsidiary body. (10) It is shown that the external air can be sucked through the inlet hole 34 by maintaining a predetermined interval on the upper surface.

4 and 5 show a cross-sectional side view and a bottom view of the fixing cap 30, respectively, the cutout 33 is formed by the gap retaining piece 32 formed on the bottom of the fixing cap 30, After the air is introduced into the fixing cap 30 into the several inlet holes 34 drilled on the bottom surface, the structure is connected to the suction tube through the connection pipe 21.

6 is a side cross-sectional view showing a configuration of a mouse connection member 40 for supplying oxygen in a state where a user bites, and is introduced by each of the inlet check valve 51 and the outlet check valve 61. The direction in which the oxygen is introduced and the direction in which the oxygen is discharged is reversed, and thus water is not inhaled, but only pure oxygen can be supplied to the respirator.

7 is an enlarged cross-sectional view of the oxygen inlet check member 50. The inlet check valve 51 is a soft elastic material, which is open in the oxygen suction direction but is blocked by the support in the discharge direction, so that the flow of oxygen is one direction. The intermittent configuration is shown to flow only to the (user's respirator).

8 is a reference diagram showing a state of use of the present invention.

The buoyancy body 10 having a dual-purpose oxygen supply function is a buoyancy function that maintains a floating state on the water surface without being submerged even by a predetermined external pressure by its own buoyancy. Is filled and molded to have buoyancy.

The substructure 10 may be formed of a material having good buoyancy but filled with a buoyancy like styrofoam, but considering the weight, formability, and merchandise, molding the air to be filled into the case as shown in the drawing. It is desirable.

That is, as a method of forming the spherical body 10, a blow mold method (hollow molding method: a type of plastic molding) is a sheet-shaped molded product or a tubular molded product, which is a combination of two sheets, is placed in a mold. Molding method to blow the air into the hollow to make a hollow product] is suitable, the inside of the hollow is filled with air tightly maintained, the outside will have a variety of designs according to consumer needs.

Therefore, the substructure 10 is used as a diving device for diving when connecting the connecting body 20 and the mouse connecting member 40 as shown in the drawing, the connecting body 20 and the mouse connecting member 40 If it is not connected, it can be used as a tube using only buoyancy when the user plays in the water.

The assembly hole 11 for connecting the connection pipe 21 and the connection hose 25 of the connection body 20 is formed in the center of this substructure 10.

That is, the assembling hole 11 passes through the connecting pipe 21 of the connecting body 20 and is assembled, and the tip of the connecting pipe 21 is positioned on the upper surface of the substructure 10 by the fixing cap 30. It is fixed.

The close contact piece 22 is integrally molded in the flange shape in the lower part of the said connection pipe 21.

When the connection piece 22 is fixed to the float 10 by the fixing cap 30, the contact piece 22 is brought into close contact with the bottom surface of the float 10 so that water flows backward through the gap of the connection portion. It is to prevent the flow into the pipe (21).

In order to improve the airtightness, it is preferable to provide an O-ring 23 between the subsidiary bodies 10 at the close contact position of the close contact piece 22.

In addition, the upper outer circumferential surface of the connecting pipe 21 is formed by the male screw 24 is fixed and disassembled by the fixing cap 30 by being screwed with the female spiral portion 31 when assembled with the fixing cap 30 Make the process easy.

When the upper surface of the fixing body 30 and the fixing cap 30 is completely in contact with the bottom surface of the fixing cap 30, the gap is maintained in order to prevent oxygen inflow required for breathing from being introduced into the connecting pipe 21. It is good to protrude the piece 32 downward.

Since the gap retaining piece 32 maintains a gap between the lower end of the fixed cap 30 and the upper portion of the substructure 10 as shown in FIG. 3, the inflow hole drilled in the bottom surface of the fixed cap 30 through this gap. The 34 can be kept open at all times so that the air inflow is always smooth.

On the other hand, the gap retaining piece 32 is formed in such a manner as to form a cutting space 33 cut in several places as shown in FIG.

The fixed cap 30 has a structure in which the bottom member 35 and the upper member 36 are divided and coupled to the bolt 39 for separation from the mold when the gap retaining piece 32 is injection molded in the mold. Is assembled.

The fixing cap 30 is screwed to the connecting pipe 21 and the connecting pipe 21 is fixed to the subsidiary body 10, the lower portion of the connecting pipe 21 is the close contact piece 22 is a sub-sphere 10 is tightly supported, and the fixing cap 30 is screwed on the upper portion thereof so that the connector 21 of the connector 20 is firmly fixed to the substructure 10.

In addition, a connection hose 25 is connected to a lower end of the connection pipe 21, and the connection hose 25 is connected to a predetermined length according to its use purpose (submersion depth), and is flexible and flexible. Made of a material, the connecting portion 21 and the connection portion with the mouse connecting member 40 is to be tightly connected using the cable tie 70 for airtightness.

In addition, a tubular mouse connection member 40 is connected to the lower end of the connection hose 25 so that the user can receive oxygen supplied through the connection hose while biting in the mouth.

The mouse connecting member 40 has an inlet pipe portion 41 on the oxygen inlet side and an air discharge pipe portion 42 on the outlet side and a user's mouth inside shape in a tubular shape communicating with each other and connected to the connection hose 25. These communicating mouthpieces 43 are formed in three-way passages, respectively.

At this time, the inflow side of the inlet pipe 41 of the oxygen is to be introduced only in the direction of the mouthpiece 43 by the user's breathing, and has an inlet check valve 51 to selectively control this when discharged by the breathing The oxygen inflow check member 50 is positioned, and the water inlet check member 60 having the discharge check valve 61 is integrally formed in the discharge pipe portion 42 so as to be opened and closed in the opposite direction to the inflow check valve 51. As shown in Figure 5, the separate valve body is installed in a manner that is screwed together.

The oxygen inlet check member 50 and the water inlet check member 60 are positioned opposite to the inlet pipe part 41 and the outlet air outlet pipe part 42 of the mouse connection member 40 as shown in FIG. The inlet check valve 51 and the discharge check valve 61 selectively block the holes 53 and 63 drilled in the support bars 52 and 62.

That is, the discharge check valve 61 is made of a soft thin film so as to be opened and closed in the opposite direction to the inlet check valve 51. When the user drinks oxygen with the mouthpiece 43 in the mouth, the oxygen flows. As a result, the inlet check valve 51 of the oxygen inlet check member 50 is opened and opened freely by the flexible body.

Therefore, the external oxygen is connected through the connecting pipe 21 and the connecting hose 25 of the connecting body 20 which is connected by the subsidiary body 10 as a result of the opening of the hole 53 and in communication with the atmosphere on the water surface. Can be sucked into the body respiratory tract through the mouthpiece 43 is oxygen supply is made.

At this time, since the discharge check valve 61 of the water inlet check member 60 located on the discharge pipe part 42 side is opened and closed in the reverse direction with the inlet check valve 51, the external object is sucked into the inside of the mouse connecting member 40. To be prevented.

On the contrary, when the oxygen is exhaled, the inlet check valve 51 is closed, and the discharge check valve 61 which is operated in the reverse direction is opened to exhaust the exhaust air discharged from the lungs of the body through the hole 63 to the outside. Will be.

Therefore, when the user is breathing, this operation is repeated, the inlet hole 34 of the fixing cap 30 on the upper part of the float 10 becomes an oxygen inlet on the water surface, so that the user breathes in the suction direction when the connection hose ( 25) The oxygen introduced through the inlet check valve 51 is opened and oxygen is supplied to the user, and when breathing again, the process of exhausting the exhaust gas to the outside through the exhaust check valve 61 is repeated.

At this time, the discharge check valve 61 formed in close proximity to the mouthpiece 43 is opened in such a manner that the operation is performed in the water, and the exhaust gas is discharged to the outside to form bubbles to cover the user's view.

In order to prevent this, the discharge pipe portion 42 in which the discharge air is ejected is used by connecting an induction pipe 80 to guide the bubbles to be discharged from the rear of the user.

Since the induction pipe 80 is molded into a flexible tube of a corrugated pipe type and can be easily switched in a desired direction, the mouthpiece 43 is held in the mouth and breathed, and the exit side of the induction pipe 80 when swimming and diving To face the back of the face to prevent the view is blocked by the bubbles generated during breathing.

According to the present invention, it can be used as a tube or oxygen supply depending on whether or not the attachment or detachment of the connecting body 20 is connected to the subsidiary body 10 for the convenience of the user.

In addition, since the substructure 10 is molded by a blow molding method, it prevents damage such as puncture during use, and when playing in the water while being separated from the connector 20 and the mouse connecting member 40 without being connected. It can be used with confidence in the use of the tube, allowing the user to choose a wider range of choices, giving them confidence and stability.

In addition, when diving, it is a very useful invention to connect the connection hose 25 to enjoy diving for a long time while receiving atmospheric oxygen from the water.

Claims (6)

A substructure 10 formed in a hollow cross-sectional shape to maintain a floating state on the water surface by buoyancy and having an assembly hole 11 formed thereon; The connecting tube 21 is inserted into the assembly hole 11 formed in the substructure 10 so that the upper end is exposed to the upper portion of the substructure 10, and the connecting hose 25 is connected to the lower end at a predetermined length. 20 and; The connection tube 21 of the connector 20 is fixed so as not to be separated from the upper portion of the substructure 10 and the inlet hole 34 is drilled to supply external oxygen through the connector 21 and the connection hose 25. Fixed cap 30 and to be; A mouse connecting member 40 provided with a mouthpiece 43 connected to connect the oxygen supply to the user's mouth from the connection hose 25 of the connecting body 20 and to be comfortably bited by the mouth; Oxygen inflow check having an inlet check valve 51 positioned at the front end of the mouth connection member 40 to open only in the direction in which oxygen supplied through the connection hose 25 is introduced and to prevent backflow of oxygen. Member 50; The discharge check valve 61 is positioned on the oxygen discharge side of the mouse connection member 40 to discharge the exhaust air emitted by the user and to be opened and closed in the opposite direction to the inlet check valve 51 so that external water does not flow into the inside. In the water inlet check member 60 having a; Submerged spherical sphere characterized in that it is further provided with an induction pipe (80) connected to the discharge pipe portion (42) of the mouse connection member 40 to guide the bubbles generated during breathing to the rear of the field of view. delete delete According to claim 1, The connecting portion 21 and the connecting portion of the connection member 21 and the mouse connecting member 40 connected to the connection hose 25 of the connector 20 is characterized in that the fastening by tightening with a cable tie 70 Floating spheres. delete The submersible spherical body according to claim 1, wherein an O-ring (23) is provided between the close contact member (22) and the close contact surface of the substructure (10) to improve airtightness.