JP2020162968A - Medical gas coupling, nasal cannula, and oxygen gas supply device - Google Patents

Abstract

To provide a medical gas coupling and a nasal cannula that when a tube through which oxygen passes catches fire, are capable of immediately stopping supply of oxygen.SOLUTION: A medical gas coupling 40 comprises: a main body 50 that includes a hollow part 53 and a first connection end 56 and second connection end 57 and forms a gas conduction tube T through which oxygen gas passes; a valve body 60 disposed in the hollow part 53 so as to be movable; and first energizing means 71 and second energizing means 72 for retaining the valve body 60 at the center position of the hollow part 53. When the first connection end 56 is softened or melted by heat, the valve body 60 is moved by energizing force of the second energizing means 72 to close the gas conduction tube T's part between the first connection end 56 and the hollow part 53. When the second connection end 57 is softened or melted by heat, the valve body 60 is moved by energizing force of the first energizing means 71 to close the gas conduction tube T's part between the second connection end 57 and the hollow part 53.SELECTED DRAWING: Figure 4

Description

The present invention relates to a medical gas coupling, a nasal cannula with a medical gas coupling, and an oxygen gas supply device with a nasal cannula connected to a flexible tube or the like through which concentrated oxygen gas passes.

Oxygen concentrators are used in oxygen inhalation methods that are effective as a treatment for patients with respiratory diseases such as chronic bronchitis. In the oxygen concentrator, an adsorption method using zeolite as an adsorbent, which selectively adsorbs nitrogen while permeating oxygen in the air, is widely used. This type of oxygen concentrator is described in Patent Document 1.

Patients in need of therapeutic oxygen are supplied with oxygen in hospitals and homes, for example via nasal cannula. The nasal cannula is connected to the oxygen cylinder or oxygen concentrator side, which is an oxygen supply source, via a flexible plastic tube.

Japanese Patent No. 4636910

While the patient is being supplied with oxygen using the nasal cannula in this way, the plastic tube may be ignited if a flame, such as a cigarette, approaches. If the plastic tube ignites, the oxygen supply must be stopped immediately.

The present invention has been made to solve the above problems, and can be used for medical gas coupling, medical use, which can immediately stop the supply of oxygen when the pipe connected to the oxygen concentrator is ignited. It is an object of the present invention to provide a nasal cannula with a gas coupling and an oxygen gas supply device with a nasal cannula.

The subject is a medical gas coupling used in a flexible tube through which oxygen gas passes, with a first connection end having a hollow portion, connected to the hollow portion and connected to the pipe. A gas conduction path having a second connection end portion connected to the hollow portion and connected to the pipe, and the first connection end portion, the hollow portion, and the second connection end portion passing the oxygen gas is provided. The formed main body, the valve body movably arranged in the hollow portion of the main body, and the valve body are held at the central position of the hollow portion, and the oxygen gas is passed through the gas conduction path. A first urging means and a second urging means are provided, and when the first connecting end is softened or melted by heat, the valve body is subjected to the urging force of the second urging means in the first direction in the hollow portion. By moving to, the gas conduction path between the first connection end portion and the hollow portion is closed, and when the second connection end portion is softened or melted by heat, the valve body is attached to the first attachment. By moving in the hollow portion in the second direction opposite to the first direction by the urging force of the urging means, the gas conduction path between the second connection end portion and the hollow portion is closed. It is solved by the medical gas coupling according to the present invention, which is characterized.
A medical gas coupling featuring.

According to the medical gas coupling according to the present invention, when the first connection end is softened or melted by heat, the gas conduction path between the first connection end and the hollow portion is closed, and the second connection is made. When the end is softened or melted by heat, the gas conduction path between the second connecting end and the hollow is closed. Therefore, when the flexible tube through which oxygen gas is passed is ignited, the medical gas coupling can immediately stop the supply of oxygen.

In the medical gas coupling according to the present invention, preferably, the valve body includes a first valve body portion that can slide the inner surface of the hollow portion along the first direction and the second direction, and the valve body portion. It is characterized by having a second valve body portion that recedes inward from the first valve body portion and is separated from the inner surface.
According to the medical gas coupling according to the present invention, since the second valve body portion that recedes inward from the first valve body portion and is separated from the inner surface of the hollow portion is provided, the valve body is a hollow portion. A gas conduction path can be secured and a predetermined flow rate of oxygen gas can be secured in a state of being held at the central position of the gas. That is, the second valve body portion can suppress the pressure loss generated in the valve body and suppress the flow of oxygen gas from being obstructed.

In the medical gas coupling according to the present invention, preferably, each of the first connection end portion and the second connection end portion is detachably connected to the flexible pipe through which oxygen gas passes. It is characterized by having a engaged portion.
According to the medical gas coupling according to the present invention, the medical gas coupling is detachably connected to a flexible pipe through which oxygen gas is passed, and the flexible pipe through which oxygen gas is passed is provided. It can be prevented from easily coming off.

In the medical gas coupling according to the present invention, preferably, at least one of the engaging portion of the first connecting end portion and the engaging portion of the second connecting end portion has a coupler shape. And.
According to the medical gas coupling according to the present invention, the user or the like can easily attach or detach the medical gas coupling to the flexible tube through which oxygen gas passes, and the medical gas can be attached or detached. The coupling can be easily replaced.

The task is to have a flexible tube that allows oxygen gas to pass through, any of the medical gas couplings described above connected to one end of the tube, and the other end of the tube. This is solved by the nasal cannula according to the invention, which comprises a nostril insertion nozzle that supplies oxygen gas to the nostrils.
According to the nasal cannula according to the present invention, the user can use the nasal cannula provided with an integrated medical gas coupling. Further, when the first connection end is softened or melted by heat, the gas conduction path between the first connection end and the hollow portion is closed, and when the second connection end is softened or melted by heat, the first connection end is softened or melted. 2 The gas conduction path between the connection end and the hollow portion is closed. Therefore, when the flexible tube through which oxygen gas is passed is ignited, the medical gas coupling can immediately stop the supply of oxygen.

The challenges are a flexible tube that allows oxygen gas to pass through, a medical gas coupling connected to one end of the tube, and the oxygen gas connected to the other end of the tube into the nasal cavity. The medical gas coupling comprises a nasal cavity insertion nozzle to supply, and the medical gas coupling has a hollow portion, a first connecting end portion connected to the hollow portion, and a second connecting end portion connected to the hollow portion and connected to the tube. A main body having a connecting end, the hollow portion and the second connecting end forming a gas conduction path through which the oxygen gas passes, and the inside of the hollow portion of the main body. A valve body movably arranged on the sill and a first urging means and a second urging means that hold the valve body at the center of the hollow portion and allow the oxygen gas to pass through the gas conduction path. When the first connection end is softened or melted by heat, the valve body moves in the hollow portion by the urging force of the second urging means, so that the first connection end and the hollow portion are formed. It is solved by a nasal cannula according to the invention, characterized in that the gas conduction path between and is closed.
According to the nasal cannula according to the present invention, the user can use the nasal cannula provided with an integrated medical gas coupling. Further, when the first connection end portion is softened or melted by heat, the gas conduction path between the first connection end portion and the hollow portion is closed. Therefore, when the flexible tube through which oxygen gas is passed is ignited, the medical gas coupling can immediately stop the supply of oxygen.

The problem is solved by the oxygen gas supply device according to the present invention, which comprises the nasal cannula and an oxygen cylinder and / or oxygen concentrator connected to the nasal cannula.
According to the oxygen gas supply device according to the present invention, the user can use a nasal cannula provided with an integrated medical gas coupling. Further, when the first connection end portion is softened or melted by heat, the gas conduction path between the first connection end portion and the hollow portion is closed. Therefore, when the flexible tube through which oxygen gas is passed is ignited, the medical gas coupling can immediately stop the supply of oxygen. As a result, safety in use can be ensured when the patient supplies oxygen using the oxygen gas supply device by connecting the nasal cannula to the oxygen cylinder and / or the oxygen concentrator.

According to the present invention, there is provided a medical gas coupling capable of immediately stopping the supply of oxygen in the event of ignition, a nasal cannula equipped with the medical gas coupling, and an oxygen gas supply device including the nasal cannula. be able to.

It is a perspective view which shows the appearance of the oxygen gas supply device which concerns on embodiment of this invention. It is a block diagram which shows the structural example of an oxygen concentrator. FIG. 3A is a front view of the medical gas coupling, and FIG. 3B is a side view of the medical gas coupling. 4 (A) is a cross-sectional view taken along the line AA of the medical gas coupling shown in FIG. 3 (B), and FIG. 4 (B) shows the medical gas coupling shown in FIG. 4 (A). It is sectional drawing in BB line. 5 (A) is a perspective view of the medical gas coupling shown in FIG. 3, and FIG. 5 (B) has a cross section of the medical gas coupling shown in FIG. 5 (A) on the VV line. It is a perspective view, and FIG. 5 (C) is a perspective view having a cross section of the medical gas coupling shown in FIG. 5 (A) along the WW line. FIG. 6 (A) shows a normal use state of the medical gas coupling, and FIG. 6 (B) is a cross-sectional view showing how the heat of the flame softens or melts one side of the medical gas coupling. .. It is sectional drawing which shows the 2nd Embodiment of this invention. It is sectional drawing which shows the 3rd Embodiment of this invention. It is sectional drawing which shows the 4th Embodiment of this invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.
Since the embodiments described below are suitable specific examples of the present invention, various technically preferable limitations are added, but the scope of the present invention particularly limits the present invention in the following description. Unless otherwise stated, the present invention is not limited to these aspects. Further, in each drawing, the same components are designated by the same reference numerals, and detailed description thereof will be omitted as appropriate.

(First Embodiment)
<Structural example of oxygen gas supply device 15 and oxygen concentrator 1>
FIG. 1 is a perspective view showing the appearance of the oxygen gas supply device according to the embodiment of the present invention.
FIG. 2 is a block diagram showing a configuration example of an oxygen concentrator.
In the block diagram of FIG. 2, thick lines and arrows indicate the flow directions of the piping flow path (conduit) and air (concentrated oxygen).

As shown in FIG. 1, the oxygen gas supply device 15 according to the embodiment of the present invention includes an oxygen concentrator 1 and a nasal cannula 30. The nasal cannula 20 shown in FIG. 1 is an example of the nasal cannula according to the comparative example. The oxygen concentrator 1 shown in FIG. 1 is, for example, a pressure fluctuation adsorption type oxygen concentrator that generates concentrated oxygen gas and sends it out at a predetermined flow rate. The source of the concentrated oxygen gas sent to the nasal cannula 30, which will be described later, is not limited to the oxygen concentrator 1, and may be an oxygen cylinder or the like. Alternatively, the oxygen gas supply device 15 may include both an oxygen concentrator and an oxygen cylinder as a supply source of the concentrated oxygen gas. For example, the oxygen gas supply device 15 may include an oxygen cylinder, and the supply source of the concentrated oxygen gas may be switched from the oxygen concentrator to the oxygen cylinder in the event of a power failure. In the description of this embodiment, the case where the source of the concentrated oxygen gas sent to the nasal cannula 30 is the oxygen concentrator 1 will be taken as an example.

The oxygen concentrator 1 has a size that is easy to use in clinical practice in hospitals, homes, and the like, and has an apparatus main body 2. The device main body 2 has a display / operation panel unit 3 and a handle 4. A caster unit 5 is detachably attached to the lower part of the apparatus main body 2. The caster unit 5 holds the apparatus main body 2 so as to be movable. The display / operation panel unit 3 shown in FIG. 1 includes an oxygen supply nozzle 6, an oxygen supply amount display unit 7, an oxygen supply amount setting button 8, a power switch 9, and a display unit 10 for displaying various information. Has. Further, a temperature sensitive element such as a thermistor may be provided at an appropriate position in the oxygen concentrator 1 and may be provided with a function of detecting overheating due to a flame and stopping the generation of concentrated oxygen in the oxygen concentrator 1.

The oxygen supply nozzle 6 can selectively connect the socket 21 of the nasal cannula 20 or the socket 31 of the nasal cannula 30, which will be described later, when the patient is supplied with oxygen. In a broad sense, the nasal cannulas 20 and 30 include sockets 21 and 31, respectively. In the vicinity of the oxygen supply nozzle 6, for example, a circuit breaker (not shown) is provided to prevent a flame from entering the inside of the apparatus main body 2 through the nasal cannula 30. The oxygen supply amount display unit 7 digitally displays the actual oxygen supply amount. The oxygen supply amount setting button 8 can increase or decrease the oxygen supply amount according to the operation of the user to set the oxygen supply amount. The power switch 9 switches the power supply of the oxygen concentrator 1 on / off. The display unit 10 that displays various information displays various items such as remaining amount information of the built-in battery and the like.

Next, a configuration example of the oxygen concentrator 1 will be described with reference to FIG. As shown in FIG. 2, the air taken into the oxygen concentrator 1 is taken in from the air intake 100, and after dust is removed by the filter 101 and the intake filter 102 that also serves as a muffling buffer, the compressor (compression) is used. Means) Compressed by 105. The compressor (compression means) 105 is cooled by the cooling fan 104.

The compressed air is sent to one of the suction cylinders 108a and 108b arranged in parallel via a three-way switching valve 107 as a flow path switching means for switching the piping flow path. The number of suction cylinders is not limited to two, and may be, for example, four. The adsorption cylinders 108a and 108b are filled with an adsorbent. The adsorbent performs gas separation between nitrogen and oxygen. As a result, concentrated oxygen gas is generated. The generated concentrated oxygen gas is temporarily sent to the product tank 111. Further, the flow rate based on the pressure and the flow velocity of the concentrated oxygen gas is controlled by using the pressure regulator 112 and the flow rate regulator 115. At this time, the oxygen concentration is detected by the oxygen concentration sensor 114 connected to the pressure regulator 112.

For example, oxygen concentrated to a maximum flow rate of about 90% per minute and appropriately humidified is passed through the synchronizer 116 from the oxygen supply nozzle (one-touch oxygen outlet) 6 of the oxygen concentrator 1 to FIG. It is supplied via the indicated nasal cannula 20 or nasal cannula 30.

The decompression means VP, the exhaust muffler 120, and the exhaust port 121 of the compressor 105 of FIG. 2 discharge (exhaust) components such as nitrogen other than oxygen adsorbed by the adsorbents of the adsorption cylinders 108a and 108b. An open valve 118 is provided in the exhaust flow path. The oxygen concentrator 1 is usually driven by a commercial power supply via an AC power supply connector 130 connected to an AC power supply and a switching power supply unit 125. When the AC power connector 130 is not connected to a commercial power source when going out, the oxygen concentrator 1 is driven by the switching power supply unit 125 with the power supply from the AC battery (rechargeable battery) 127.

The display unit 10 is formed of LEDs or the like, and is an inspection that displays an operation lamp that indicates an operating state (lights or blinks green during normal operation / lights or blinks red during abnormal or stop), and displays the remaining battery level and the like. With a lamp.

The intake filter 102 has a muffling structure. The drive control of the compressor 105 is performed by the control unit (CPU) 124, the motor control unit 123, and the variable speed controller 123a. The compressor 105 has both a pressurizing function (pressurizing means: P) and a depressurizing function (pressurizing means: VP). The compressor 105 may have only a pressurizing function (pressurizing means: P). The rotation speed of the compressor 105 is controlled according to the oxygen flow rate taken out. Also, the speed of the compressor 105 is controlled between 500 rpm and 3000 rpm.

At least two or more adsorption cylinders are arranged in parallel on the adsorption cylinders 108a and 108b as the gas separation means. For example, examples of the adsorbent to be filled include X-type zeolite having a measured value of granules of less than 1 mm and having a SiO ₂ / Al ₂ O ₃ ratio of 2.0 to 3.0, and Al ₂ O ₃ More preferably, at least 88% or more of the tetrahedral units are fused with the lithium cation. In the product tank 111, the pressure fluctuates in synchronization with the pressure inside the suction cylinder. Therefore, the pressure regulator 112 functions to reduce the pressure of concentrated oxygen to a substantially constant pressure.

<Structural example of nasal cannula 20 and nasal cannula 30>
The nasal cannula 20 shown in FIG. 1 is a commonly used cannula and does not have a medical gas coupling 40 having a fire protection function. The nasal cannula 20 of the present embodiment is an example of the nasal cannula according to a comparative example. The nasal cannula 20 comprises a flexible transparent plastic tube 22, a flexible transparent plastic nostril insertion nozzle 23, and a resin or metal socket 21. Have. The tube 22 is, for example, a transparent plastic tube. A nostril insertion nozzle 23 is airtightly connected to one end of the tube 22 with respect to a set concentrated oxygen gas flow rate (L / min), and a socket 21 is airtightly connected to the other end of the tube 22. Has been done. The socket 21 is called a coupler or the like, and is detachably and airtightly connected to the oxygen supply nozzle 6 of the apparatus main body 2.

On the other hand, another nasal cannula 30 shown in FIG. 1 has a medical gas coupling 40 having a fire prevention function at an appropriate position on the way. The nasal cannula 30 of the present embodiment is an example of the nasal cannula according to the present invention. The nasal cannula 30 has a first tube (tube) 35 made of a transparent plastic having flexibility and thermoplastic such as polyvinyl chloride resin and a polyamide resin, and a second tube (tube) made of transparent plastic having flexibility. ) 36, a flexible transparent plastic nasal cavity insertion nozzle 33, and a resin or metal socket 31. A socket 31 is airtightly connected to the first end 35A of the first pipe 35. The first end 35A corresponds to the upstream end of the flow of concentrated oxygen gas in the first pipe 35. The socket 31 is called a coupler or the like, and is detachably and airtightly connected to the oxygen supply nozzle 6 of the apparatus main body 2. A nostril insertion nozzle 33 is airtightly connected to the second end 36B of the second tube 36. The second end 36B corresponds to the downstream end of the flow of concentrated oxygen gas in the second pipe 36. A medical gas coupling 40 is airtightly connected between the second end portion 35B of the first pipe 35 and the first end portion 36A of the second pipe 36. The second end 35B corresponds to the downstream end of the flow of concentrated oxygen gas in the first pipe 35. The first end 36A corresponds to the upstream end of the flow of concentrated oxygen gas in the second pipe 36.

As shown in FIG. 1, the medical gas coupling 40 is detachably attached between the second end portion 35B of the first pipe 35 and the first end portion 36A of the second pipe 36, and is fireproof. It is an intermediate connecting member having a function. The medical gas coupling 40 is made of, for example, a plastic material that can be softened or melted by the heat of a flame.

<Structural example of medical gas coupling 40>
Next, a structural example of the medical gas coupling 40 will be described with reference to FIGS. 3 to 5.
FIG. 3A is a front view of the medical gas coupling 40. FIG. 3B is a side view of the medical gas coupling 40. FIG. 4A is a cross-sectional view taken along the line AA of the medical gas coupling 40 shown in FIG. 3B. FIG. 4B is a cross-sectional view taken along the line BB of the medical gas coupling 40 shown in FIG. 4A. FIG. 5A is a perspective view of the medical gas coupling 40 shown in FIG. 5 (B) is a perspective view having a cross section of the medical gas coupling 40 shown in FIG. 5 (A) along the VV line. 5 (C) is a perspective view having a cross section of the medical gas coupling 40 shown in FIG. 5 (A) along the WW line.

The medical gas couplings 40 shown in FIGS. 3 to 5 are also referred to as bidirectional couplings, and as illustrated in FIG. 1, flexible first tubes 35 and second tubes 35 for supplying concentrated oxygen gas. It is provided between the pipe 36 and used. The length of the medical gas coupling 40 in the axial direction X is about 60 mm. As shown in FIGS. 3 and 4, the medical gas coupling 40 has a main body 50, a valve body 60, a first spring 71, and a second spring 72.

As shown in FIG. 4, the main body 50 is made of a thermoplastic plastic material such as a polyvinyl chloride resin or a polyamide resin that softens or melts at a predetermined temperature due to the heat of a flame ignited due to a cigarette fire or the like. It is molded to a diameter of about 18 to 20 mm. The main body 50 has a first portion 51 and a second portion 52. The first portion 51 and the second portion 52 have a hollow portion 53 having a circular cross section inside. A sealing material 54 is arranged between the connection end surface 51D of the first portion 51 and the connection end surface 52D of the second portion 52. As a result, the airtightness of the oxygen gas is maintained between the first portion 51 and the second portion 52 of the main body 50. One of the connection end face 51D and the connection end face 52D is made a female screw, and one of the connection end face 51D and the connection end face 52D is made a male screw, and the connection end face 51D and the connection end face 52D are airtightly screwed together. You may do so.

The connection end surface 51D of the first portion 51 and the connection end surface 52D of the second portion 52 are joined to each other so as to maintain the airtightness of oxygen gas at a pressure of about 400 kPa with the sealing material 54 sandwiched between them. The bonding form between the connecting end surface 51D of the first portion 51 and the connecting end surface 52D of the second portion 52 may be adhesion by an adhesive or welding by heating. Alternatively, as in the examples shown in FIGS. 6A and 6B, the first portion 51 may have a flange portion 51F and the second portion 52 may have a flange portion 52F. In the examples shown in FIGS. 6 (A) and 6 (B), the first portion 51 and the second portion 52 are fastening members 55 such as a plurality of bolts and nuts passed through the flange portion 51F and the flange portion 52F. Is fixed by.

As shown in FIG. 4, the first portion 51 of the main body 50 has a hollow first connection end 56. The second portion 52 of the body 50 has a hollow second connection end 57. The first connection end portion 56 is formed so as to project from the first portion 51 along the X1 direction of the axial direction X of the main body 50. For example, the X1 direction is a direction toward the downstream side of the flow of oxygen gas, which is an example of the "first direction" of the present invention. Similarly, the second connection end portion 57 is formed so as to project from the second portion 52 along the X2 direction of the axial direction X of the main body 50. For example, the X2 direction is a direction toward the upstream side of the flow of oxygen gas, which is an example of the "second direction" of the present invention.

As shown in FIG. 4 (A), the first connection end portion 56 has an outer end portion 56A and an inner end portion 56B. The inner end portion 56B is connected to one end side of the hollow portion 53. Similarly, the second connection end portion 57 has an outer end portion 57A and an inner end portion 57B. The inner end portion 57B is connected to the other end side of the hollow portion 53. As a result, the hollow hole 56H of the first connection end 56, the hollow portion 53, and the hollow hole 57H of the second connection end 57 are connected along the axial direction X, and a gas through which concentrated oxygen gas passes. A conduction path T is formed. The inner diameter of the hollow portion 53 is set to be larger than the inner diameter of the hollow hole 56H of the first connection end portion 56 and the hollow hole 57H of the second connection end portion 57.

In order to prevent the first spring 71 and the second spring 72 from protruding from the outer end portion 56A and the outer end portion 57A of the medical gas coupling 40 under normal use conditions, the outer end portion 56A and the outer end portion 57A An annular or a plurality of protrusions are slightly projected inside the and so that the flow rate does not interfere with the flow rate of oxygen gas at a maximum of 20 L / min.

As shown in FIG. 3, the first connection end portion 56 is detachably connected to the second end portion 35B of the first pipe 35 shown in FIG. 1 by press fitting. The first connection end 56 has an engaging portion 56M. The engaging portion 56M is a portion called, for example, a bamboo shoot shape, and has a shape in which a plurality of inclined portions (ribs) 56K are arranged side by side. As a result, the engaging portion 56M is detachably connected to the second end portion 35B of the first pipe 35 and is airtightly connected so that oxygen gas having a maximum flow rate of 20 L / min does not leak to the outside. It is possible to prevent the second end portion 35B of the pipe 35 from easily coming off in the X1 direction.

Similarly, the second connection end portion 57 is detachably connected to the first end portion 36A of the second pipe 36 shown in FIG. 1 by press fitting. The second connection end 57 has an engaging portion 57M. The engaging portion 57M is a portion called, for example, a bamboo shoot shape, and has a shape in which a plurality of inclined portions 57K are arranged side by side. As a result, the engaging portion 57M is detachably connected to the first end portion 36A of the second pipe 36, and the first end portion 36A of the second pipe 36 is prevented from easily coming off in the X2 direction. be able to. As a result, the main body 50 cannot be easily pulled out in a state of being connected to the second end portion 35B of the first pipe 35 and the first end portion 36A of the second pipe 36. As a result, safety in use can be achieved.

Further, the shapes of the first connection end portion 56 and the second connection end portion 57 shown in FIGS. 3 and 4 have high versatility. That is, the first connection end 56 and the second connection end 57 are made connectable to a general flexible plastic tube used in oxygen concentrators. As a result, the medical gas coupling 40 of the present embodiment can be used in various oxygen concentrators.

The valve body 60 shown in FIG. 4 is made of a fluororesin such as Teflon (registered trademark), a plastic such as nylon, or a metal such as aluminum, which has a higher softening temperature and melting temperature than the main body 50 and has heat resistance, and is hollow. Within the portion 53, it is movable along the axial direction X. As shown in FIGS. 4 (B), 5 (B) and 5 (C), the valve body 60 is a medium entity having a pair of curved surface portions 61 and 62 and a pair of flat surface portions 63 and 64. is there. The curved surface portions 61 and 62 of the present embodiment are an example of the "first valve body portion" of the present invention. The plane portions 63 and 64 of the present embodiment are an example of the "second valve body portion" of the present invention. As shown in FIG. 4B, the curved surface portions 61 and 62 are portions guided in the axial direction X along the inner peripheral surface 53R of the hollow portion 53. That is, the curved surface portions 61 and 62 can slide on the inner peripheral surface 53R of the hollow portion 53 along the axial direction X. The flat surface portions 63 and 64 are portions recessed from the curved surface portions 61 and 62 toward the inside of the valve body 60 or are notched portions, and are separated from the inner peripheral surface 53R. The flat surface portions 63 and 64 form a part of the gas conduction path T for passing oxygen gas. As described above, since the flat surface portions 63 and 64 that recede from the curved surface portions 61 and 62 toward the inside of the valve body 60 and are separated from the inner peripheral surface 53R are provided, the valve body 60 has a hollow portion in the axial direction X. In the state of being arranged at the central position in 53 (normal use state), the gas conduction path T can be secured and a predetermined flow rate of oxygen gas can be secured. That is, the flat surfaces 63 and 64 can suppress the pressure loss generated in the valve body 60 and suppress the flow of oxygen gas from being obstructed. Therefore, the cross-sectional area of the oxygen gas flow path in the portion where the flat surfaces 63 and 64 are provided is the cross-sectional area of the flow path of the hollow hole 56H of the first connection end 56 and the hollow hole 57H of the second connection end 57. Since it is formed so as to be substantially the same as the cross-sectional area of the flow path, the oxygen gas having a maximum flow rate of 20 L / min smoothly reaches the nasal cannula 30 at a set predetermined flow rate.

As shown in FIG. 4A, the valve body 60 includes a first protruding portion 65 extending toward the first connecting end 56 and a second protruding 66 extending toward the second connecting end 57. , Have. A first seal member 67 is arranged on the outer periphery of the first protrusion 65. A second seal member 68 is arranged on the outer periphery of the second protrusion 66. The first seal member 67 and the second seal member 68 include, for example, a fluororesin O-ring having a higher softening temperature and melting temperature than the main body 50 and heat resistance, and a fluororesin O-ring having a higher softening temperature and melting temperature than the main body 50 and having heat resistance. O-rings such as rubber that are elastically deformed can be adopted, but the present invention is not limited to these.

As shown in FIG. 4A, the first spring 71 is housed in a compressed state in the hollow hole 56H of the first connection end portion 56. The first spring 71 is, for example, a coil spring, which is an example of the “first urging means” of the present invention. The second spring 72 is housed in the hollow hole 57H of the second connection end 57 in a compressed state. The second spring 72 is a coil spring and is an example of the "second urging means" of the present invention.

For example, each of the first spring 71 and the second spring 72 is formed of, for example, a piano wire, a hard steel wire, a metal using a stainless steel wire having a spring property, or the like, and has a wire diameter of φ0.4 mm × outside. It has a shape with a diameter of φ3 mm and a free length of 30 mm. The holding loads of the first spring 71 and the second spring 72 are, for example, about 5N or more and 7N or less. However, the respective shapes and holding loads of the first spring 71 and the second spring 72 are not limited to this.

The first spring 71 and the second spring 72 exert equal spring loads on each other. When the coil spring is used as the first spring 71 and the second spring 72, the first spring 71 and the second spring 72 are the hollow holes 56H of the first connection end 56 and the second connection end 57. Even if the coil spring is compressed into the hollow hole 57H and accommodated in a state of having a predetermined urging force facing the hollow hole 57H, since the wire diameter of the coil spring is small, the cross-sectional area of the oxygen gas flow path is not substantially reduced. It does not substantially impede the flow of oxygen gas in the passage T. One end of the first spring 71 is held by a protrusion on the inside of the outer end 56A of the first connection end 56. The other end of the first spring 71 is engaged and held by the first protrusion 65 of the valve body 60. Similarly, one end of the second spring 72 is held by a protrusion on the inside of the outer end 57A of the second connection end 57. The other end of the second spring 72 is engaged and held by the second protrusion 66 of the valve body 60. The first spring 71 and the second spring 72 have equal urging forces with each other in a state of being housed in the hollow hole 56H of the first connection end 56 and the hollow hole 57H of the second connection end 57. As a result, the valve body 60 is arranged at a substantially central portion of the hollow portion 53 in the axial direction X.

On the other hand, when the urging force of the first spring 71 decreases, the valve body 60 receives the urging force of the second spring 72 and moves in the X1 direction. Then, the first seal member 67 seals (closes) the gas conduction path T between the hollow portion 53 and the hollow hole 56H of the first connection end portion 56 to block the movement of oxygen gas. Further, when the urging force of the second spring 72 decreases, the valve body 60 receives the urging force of the first spring 71 and moves in the X2 direction. Then, the second seal member 68 seals (closes) the gas conduction path T between the hollow portion 53 and the hollow hole 57H of the second connection end portion 57 to block the movement of oxygen gas.

<Usage example>
Next, an example of using the nasal cannula 30 with the medical gas coupling 40 will be described with reference to FIGS. 1 and 6.
FIG. 6A is a cross-sectional view showing a normal use state of the medical gas coupling 40.
FIG. 6B is a cross-sectional view showing how the heat of the flame softens or melts one side of the medical gas coupling 40.

As shown in FIG. 1, the medical gas coupling 40 is detachably attached between the second end portion 35B of the first pipe 35 and the first end portion 36A of the second pipe 36. Alternatively, if the medical gas coupling 40 is not provided as part of the nasal cannula 30 (if the medical gas coupling 40 and the nasal cannula 30 are not integrated), the user can use the first tube. A medical gas coupling 40 is attached between the second end 35B of 35 and the first end 36A of the second tube 36. The socket 31 of the nasal cannula 30 is attached to the oxygen supply nozzle 6 of the oxygen concentrator 1. As a result, the oxygen gas generated by the oxygen concentrator 1 passes through the first pipe 35, the medical gas coupling 40, the second pipe 36, and the nostril insertion nozzle 33, and has a set predetermined flow rate (L / min). Is supplied to the patient's nostrils.

Under normal use conditions, as shown in FIG. 6A, the first spring 71 and the second spring 72 oppose the valve body 60 and exert an equal urging force (equal spring load). .. Therefore, under normal use conditions, the valve body 60 made of fluororesin such as Teflon (registered trademark), plastic such as nylon, or metal such as aluminum, which has high softening temperature and melting temperature and has heat resistance, is axially oriented. With respect to X, it is positioned at the center position in the hollow portion 53. The gas conduction path T for passing the concentrated oxygen gas formed from the hollow hole 56H of the first connection end 56, the hollow portion 53, and the hollow hole 57H of the second connection end 57 is closed by the valve body 60. The oxygen gas generated by the oxygen concentrator 1 can be flowed toward the nasal opening insertion nozzle 33 at a set predetermined flow rate (L / min).

On the other hand, as illustrated in FIG. 6B, the second end 35B and the first connection end 56 of the first pipe 35 are used, for example, for the fire of a cigarette of a patient receiving oxygen supply. When softened or melted by the heat of the flame FR that ignites due to this, one end 71S of the first spring 71 is disconnected from the first connection end 56. Then, since the first spring 71 is housed in the hollow hole 56H of the first connection end 56 in a compressed state, the one end 71S of the first spring 71 is first connected by the restoring force of the first spring 71. It protrudes from the hollow hole 56H of the end portion 56 and becomes an open end portion.

As a result, the urging force given to the valve body 60 by the first spring 71 is reduced, so that the urging force given to the valve body 60 by the second spring 72 is larger than the urging force given to the valve body 60 by the first spring 71. Will also grow. Therefore, the valve body 60 is pushed in the hollow portion 53 in the X1 direction by the second spring 72. As a result, the first seal member 67 of the valve body 60 seals (closes) the gas conduction path T between the hollow portion 53 and the hollow hole 56H of the first connection end portion 56, so that the oxygen gas flows. To shut off.

Further, contrary to the example shown in FIG. 6B, the first end portion 36A and the second connection end portion 57 of the second pipe 36 are used, for example, for the fire of a cigarette of a patient receiving oxygen supply. When softened or melted by the heat of the flame FR ignited due to this, one end 72S of the second spring 72 is disconnected from the second connection end 57. Then, since the second spring 72 is housed in the hollow hole 57H of the second connection end portion 57 in a compressed state, the one end portion 72S of the second spring 72 is connected to the second spring 72 by the restoring force of the second spring 72. It protrudes from the hollow hole 57H of the end portion 57 and becomes an open end portion.

As a result, the urging force given to the valve body 60 by the second spring 72 is reduced, so that the urging force given to the valve body 60 by the first spring 71 is larger than the urging force given to the valve body 60 by the second spring 72. Will also grow. Therefore, the valve body 60 is pushed in the hollow portion 53 in the X2 direction by the first spring 71. As a result, the second seal member 68 of the valve body 60 seals (closes) the gas conduction path T between the hollow portion 53 and the hollow hole 57H of the second connection end portion 57, and the oxygen gas flows. To shut off.

In this way, even if one side or the other side of the medical gas coupling 40 is softened or melted by the heat of a heat source such as a flame ignited due to a cigarette fire or the like, the sealing member of the valve body 60 67 and 68 can immediately close the gas conduction path T and cut off the supply of oxygen gas. That is, if either the first connection end 56 or the second connection end 57 is damaged by a flame (fire), the balance between the spring load of the first spring 71 and the spring load of the second spring 72 is lost. Therefore, the valve body 60 can move to the connection end on the damaged side and immediately shut off the supply of oxygen gas.

Since the medical gas coupling 40 can stop the supply of oxygen gas in both directions in the axial direction X, it can be said to be a bidirectional fire prevention coupling. The medical gas coupling 40 can immediately stop the supply of oxygen when the tube is ignited, and is safe to use when the patient applies the nasal cannula 30 to the oxygen concentrator 1 to supply oxygen. Sex can be ensured.

Next, the medical gas couplings of the second to fourth embodiments of the present invention will be described with reference to FIGS. 7 to 9. When the parts of the second to fourth embodiments are the same as the corresponding parts of the first embodiment described above, the same reference numerals are given and the description thereof will be omitted. Unlike the medical gas couplings 40 of the first embodiment, the medical gas couplings 240, 340, 440 of the second to fourth embodiments supply oxygen gas in only one direction of the axial direction X. It is a one-way coupling that can be stopped.

(Second Embodiment)
A second embodiment of the present invention will be described with reference to FIG.
The medical gas coupling 240 shown in FIG. 7 is used on the nasal cannula 30 like the medical gas coupling 40 shown in FIG. As shown in FIG. 7, the medical gas coupling 40 has a main body 250, a valve body 260, a first spring 271 and a second spring 272. For example, the first spring 271 is made of, for example, a metal such as a piano wire, a hard steel wire, or a stainless steel wire having a spring property, and has a wire diameter of φ0.4 mm × an outer diameter of φ3 mm × a free length of 30 mm. Has a shape. The holding load of the first spring 271 is about 5N or more and 7N or less. For example, the second spring 272 is formed of, for example, a metal such as a piano wire, a hard steel wire, or a stainless steel wire having a spring property, and has a wire diameter of φ0.5 mm × an outer diameter of 6 mm × a free length of 10 mm. Has a shape. The holding load of the second spring 272 is about 5N or more and 7N or less.

The main body 250 is made of a thermoplastic material such as a plastic material that softens or melts due to the heat of a flame ignited by, for example, a cigarette fire, a polyvinyl chloride resin, or a polyamide resin. The main body 250 has a first portion 251 and a second portion 252. The first portion 251 and the second portion 252 have a hollow portion 253 having a circular cross section inside. The first portion 251 of the body 250 has a hollow first connection end 256. The second portion 252 of the body 250 has a hollow second connection end 257. The hollow hole 256H of the first connection end portion 256, the hollow portion 253, and the hollow hole 257H of the second connection end portion 257 are connected along the axial direction X, and the gas conduction path T through which the concentrated oxygen gas passes. Is forming.

The first connection end portion 256 has a coupler-shaped engaging portion 256M. That is, the engaging portion 256M of the first connection end portion 256 shown in FIG. 7 is a male type coupler and is detachably connected to the female type coupler. When the female coupler is attached to the first end 36A of the second tube 36, the first connection end 256 is detachably connected to the first end 36A of the second tube 36. To. Examples of the female coupler include the socket 31 shown in FIG.

The second connection end portion 257 has an engaging portion 257M having a simple shape, and is detachably connected to the second end portion 35B of the first pipe 35 shown in FIG. 1 by press fitting. The engaging portion 257M of the second connection end portion 257 is detachably connected to the second end portion 35B of the first pipe 35, and the second end portion 35B of the first pipe 35 is easily connected in the X1 direction. It is possible to prevent it from coming off. As a result, the main body 250 is connected to the second end 35B of the first pipe 35 and the first end 36A of the second pipe 36, so that the main body 250 cannot be easily removed. As a result, safety in use can be achieved.

The valve body 260 has a softening temperature and a melting temperature higher than those of the main body 250, and is made of a fluororesin such as Teflon (registered trademark), a plastic such as nylon, or a metal such as aluminum, and has heat resistance. It can move along the axial direction X. The valve body 260 has a protrusion 265 extending toward the first connection end 256. Further, the valve body 260 has a recess 266 provided on the side of the second connection end portion 257. A first seal member 267 is arranged on the outer periphery of the protruding portion 265.

By providing a notch or the like at an appropriate position in the valve body 260, a gas conduction path T is secured in a state of being arranged at the center position in the hollow portion 253 with respect to the axial direction X (normal use state), and oxygen gas can be used. A predetermined flow rate can be secured. Therefore, the flow path cross-sectional area of the oxygen gas in this portion is almost the same as the flow path cross-sectional area of the hollow hole 56H of the first connection end portion 256 and the flow path cross-sectional area of the hollow hole 57H of the second connection end portion 257. Oxygen gas having a maximum flow rate of 20 L / min reaches the nasal cannula 30 smoothly at a set predetermined flow rate.

The first seal member 267 includes, for example, an O-ring made of plastic such as fluororesin such as Teflon (registered trademark) having a softening temperature and melting temperature higher than that of the main body 250 and heat resistance, and a softening temperature and melting of the main body 250. O-rings such as rubber, which have high temperature, heat resistance, and elastic deformation, can be adopted, but are not limited thereto.

In order to prevent the first spring 271 from protruding from the outer end of the medical gas coupling 240 during normal use, the opening diameter of the hollow hole 256H is set to be annular or a plurality of protrusions are provided. It is formed to be slightly smaller than the coil diameter of the spring 271. Therefore, the first spring 271 is accommodated in a compressed state between the hollow hole 256H of the first connection end portion 256 and the valve body 260 without disturbing the flow rate of oxygen gas having a maximum flow rate of 20 L / min. ing. Further, the other end of the first spring 271 is engaged with the protruding portion 265 of the valve body 260. The second spring 272 is housed in a compressed state in the hollow hole 257H of the second connection end portion 257. One end of the second spring 272 is fixed to the connecting portion between the second portion 252 and the second connecting end portion 257. The other end of the second spring 272 is fixed to the recess 266 of the valve body 260. That is, the second spring 272 is provided in the hollow portion 253 between the recess 266 of the valve body 260 and the second connection end portion 257.

In a normal use state, the first spring 271 and the second spring 272 are in a state of being compressed by a predetermined amount, and face each other and have an equal urging force with respect to the valve body 260. Therefore, as shown in FIG. 7, under normal use conditions, the valve body 260 is positioned at the center position in the hollow portion 253 with respect to the axial direction X. Therefore, the gas conduction path T for passing the concentrated oxygen gas formed from the hollow hole 256H of the first connection end portion 56, the hollow portion 253, and the hollow hole 257H of the second connection end portion 257 is a valve body. The oxygen gas generated by the oxygen concentrator 1 can be flowed toward the nasal opening insertion nozzle 33 at a set predetermined flow rate (L / min) without being closed by 260.

On the other hand, when the first connection end 256 is softened or melted by the heat of the flame ignited due to, for example, the heat of the cigarette of a patient receiving oxygen, one end of the first spring 271 The 271S disengages from the first connection end 256. Then, since the first spring 271 was housed in the hollow hole 256H of the first connection end 256 in a compressed state, the one end 271S of the first spring 271 was first connected by the restoring force of the first spring 271. It protrudes from the hollow hole 256H of the end portion 256 and becomes an open end portion. As a result, the urging force given to the valve body 260 by the first spring 271 is reduced, so that the urging force given to the valve body 260 by the second spring 272 is larger than the urging force given to the valve body 60 by the first spring 271. Will also grow. Therefore, the valve body 260 is pushed in the hollow portion 253 in the X1 direction by the second spring 272. As a result, the seal member 267 seals (closes) the gas conduction path T between the hollow portion 253 and the hollow hole 256H of the first connection end portion 256, and blocks the movement of oxygen gas in the X1 direction. To do.

In this way, even if one side of the medical gas coupling 240 is softened or melted by the heat of a heat source such as a flame ignited due to the heat of a cigarette fire or the like, the sealing member 267 of the valve body 260 Can immediately close the gas conduction path T and shut off the supply of oxygen gas. The medical gas coupling 240 can be said to be a unidirectional fire prevention coupling because the supply of oxygen gas can be stopped in one direction of the axial direction X. The medical gas coupling 40 can immediately stop the supply of oxygen when the tube is ignited, and is safe to use when the patient applies the nasal cannula 30 to the oxygen concentrator 1 to supply oxygen. Sex can be ensured.

In the present embodiment, the case where the first connection end portion 256 has a coupler-shaped engaging portion 256M is given as an example. However, the form of the connection end portions 256 and 257 is not limited to this. For example, both the first connection end 256 and the second connection end 257 may have a coupler-shaped engaging portion. That is, in the medical gas coupling 240 of the present embodiment, at least one of the first connection end portion 256 and the second connection end portion 257 has a coupler-shaped engaging portion. When the engaging portion of the second connection end 257 is a male coupler, a female coupler is attached to the second end 35B of the first tube 35. Further, the coupler-shaped engaging portion of at least one of the first connection end portion 256 and the second connection end portion 257 may be a female coupler. In this case, a male coupler is attached to at least one of the first end 36A of the second tube 36 and the second end 35B of the first tube 35.

Since the medical gas coupling 240 of the present embodiment has a coupler-shaped engaging portion at at least one of the first connection end portion 256 and the second connection end portion 257, the user and the like can use the first pipe 35 and The medical gas coupling 240 can be easily attached to and detached from the second pipe 36, and the medical gas coupling 240 can be easily replaced.

(Third Embodiment)
A third embodiment of the present invention will be described with reference to FIG.
The medical gas coupling 340 of the third embodiment shown in FIG. 8 is a unidirectional fire prevention coupling because the supply of oxygen gas can be stopped in one direction of the axial direction X. In contrast to the medical gas coupling 240 described above with reference to FIG. 7 having a coupler-shaped engaging portion at at least one of the first connection end 256 and the second connection end 257, the medical gas of the present embodiment. The coupling 340 has a first connection end portion 356 having a structure similar to that of the first connection end portion 56 shown in FIG. 6 and a second connection end portion 357 having a structure similar to that of the second connection end portion 57. In this respect, the medical gas coupling 340 of the present embodiment is different from the medical gas coupling 240 described above with respect to FIG. 7. A first spring 371 is arranged at the first connection end portion 356. The other elements of the medical gas coupling 340 are substantially the same as the corresponding elements of the medical gas coupling 240 shown in FIG.

According to the medical gas coupling 340 of the present embodiment, the shapes of the first connection end 356 and the second connection end 357 have high versatility. That is, the first connection end 356 and the second connection end 357 are made connectable to a common flexible plastic tube used in oxygen concentrators. As a result, the medical gas coupling 340 of the present embodiment can be used in various oxygen concentrators.

(Fourth Embodiment)
A fourth embodiment of the present invention will be described with reference to FIG.
Since the medical gas coupling 440 of the fourth embodiment shown in FIG. 9 can stop the supply of oxygen gas in one direction of the axial direction X. It is a one-way fire protection coupling. With respect to FIG. 7, the medical gas coupling 240 described above has a coupler-shaped engaging portion at at least one of the first connection end portion 256 and the second connection end portion 257, whereas the medical gas of the present embodiment is used. The coupling 440 has a tubular first connection end 456 and a second connection end 457 with a simple structure. A first spring 471 is arranged at the first connection end portion 456. This makes it possible to simplify the structure of the medical gas coupling 440. The other elements of the medical gas coupling 440 are substantially the same as the corresponding elements of the medical gas coupling 240 shown in FIG.

According to the medical gas coupling 440 of the present embodiment, the structure of the first connection end portion 456 and the second connection end portion 457 can be simplified, and the structure of the first connection end portion 456 and the second connection end portion 456 can be simplified. The shape of 457 can have high versatility. As a result, the medical gas coupling 440 of the present embodiment can be used in various oxygen concentrators while simplifying the structures of the first connection end portion 456 and the second connection end portion 457.

The embodiment of the present invention has been described above. However, the present invention is not limited to the above embodiment, and various modifications can be made without departing from the scope of claims. For example, an oxygen concentrator equipped with an oxygen cylinder and switched to oxygen supply from the oxygen cylinder in the event of a power failure may be used as a supply source of concentrated oxygen gas. A part of the configuration of the above embodiment may be omitted, or may be arbitrarily combined so as to be different from the above.

1: Oxygen concentrator, 2: Device body, 3: Operation panel, 4: Handle, 5: Caster unit, 6: Oxygen supply nozzle, 7: Oxygen supply display, 8: Setting button, 9: Power switch, 10: Display, 15: Oxygen gas supply, 20: Nasal cannula, 21: Socket, 22: Pipe, 23: Nozzle insertion nozzle, 30: Nasal cannula, 31: Socket, 33: Nozzle insertion nozzle, 35: 1st pipe, 35A: 1st end, 35B: 2nd end, 36: 2nd pipe, 36A: 1st end, 36B: 2nd end, 40: Medical gas coupling, 50: Body, 51: 1st part, 51D: Connection end face, 51F: Flange part, 52: 2nd part, 52D: Connection end face, 52F: Flange part, 53: Hollow part, 53R: Inner peripheral surface, 54: Sealing material, 55: Fastening member, 56: 1st connection end, 56A: outer end, 56B: inner end, 56H: hollow hole, 56K: inclined part, 56M: engaging part, 57: 2nd connection end, 57A: outer End, 57B: Inner End, 57H: Hollow Hole, 57K: Inclined, 57M: Engagement, 60: Valve, 61, 62: Curved, 63, 64: Flat, 65: First Protrusion , 66: 2nd protruding part, 67: 1st sealing member, 68: 2nd sealing member, 71: 1st spring, 71S: one end, 72: 2nd spring, 72S: one end, 100: air intake, 101: Filter, 102: Intake Filter, 104: Cooling Fan, 105: Compressor, 107: 3-Way Switching Valve, 108a, 108b: Suction Cylinder, 111: Product Tank, 112: Pressure Regulator, 114: Oxygen Concentration Sensor, 115: Flow regulator, 116: Synchronizer, 118: Open valve, 120: Exhaust muffler, 121: Exhaust port, 123: Motor control unit, 123a: Variable speed controller, 124: Control unit, 125: Switching power supply unit, 127: Rechargeable Battery, 130: AC Power Connector, 132: Shock Sensor, 135: Acceleration Sensor, 240: Medical Gas Coupling, 250: Body, 251: First Part, 252: Second Part, 253: Hollow Part , 256: 1st connection end, 256H: hollow hole, 256M: engagement part, 257: 2nd connection end, 257H: hollow hole, 257M: engagement part, 260: valve body, 265: protrusion, 266 : Recess, 267: 1st seal member, 271: 1st spring, 271S: one end, 272: 2nd spring, 340: medical gas coupling, 356: 1st connection end, 357: 2nd connection end, 371: 1st spring, 440: Medical gas coupling, 456: 1st connection end, 457: 2nd connection end, 471: 1st spring, FR: Flame, T: Gas conduction path, VP: Decompression means

Claims (7)

A medical gas coupling used for flexible tubing that allows oxygen gas to pass through.
The first connection having a hollow portion, having a first connection end portion connected to the hollow portion and connected to the pipe, and a second connection end portion connected to the hollow portion and connected to the pipe. A main body in which an end portion, the hollow portion, and the second connection end portion form a gas conduction path through which the oxygen gas passes.
A valve body that is movably arranged in the hollow portion of the main body,
A first urging means and a second urging means that hold the valve body at the center position of the hollow portion and allow the oxygen gas to pass through the gas conduction path.
With
When the first connection end is softened or melted by heat, the valve body moves in the first direction in the hollow portion by the urging force of the second urging means, so that the first connection end and the hollow When the gas conduction path between the parts and the gas conduction path is closed and the second connection end is softened or melted by heat, the valve body moves to the first direction in the hollow part by the urging force of the first urging means. Is a medical gas coupling characterized by closing the gas conduction path between the second connecting end and the hollow portion by moving in the opposite second direction. The valve body
A first valve body portion that can slide on the inner surface of the hollow portion along the first direction and the second direction, and
A second valve body portion that recedes inward from the first valve body portion and is separated from the inner surface,
The medical gas coupling according to claim 1, wherein the medical gas coupling has. A claim, wherein each of the first connection end and the second connection end has an engaging portion that is detachably connected to the flexible tube through which the oxygen gas passes. The medical gas coupling according to 1 or 2. The medical gas coupling according to claim 3, wherein at least one of the engaging portion of the first connecting end portion and the engaging portion of the second connecting end portion has a coupler shape. A flexible tube that allows oxygen gas to pass through,
The medical gas coupling according to any one of claims 1 to 4, which is connected to one end of the pipe.
A nostril insertion nozzle connected to the other end of the tube to supply the oxygen gas to the nostrils,
A nasal cannula featuring a nasal cannula. A flexible tube that allows oxygen gas to pass through,
With a medical gas coupling connected to one end of the tube,
A nostril insertion nozzle connected to the other end of the tube to supply the oxygen gas to the nostrils,
With
The medical gas coupling is
It has a hollow portion and has a first connection end portion connected to the hollow portion and a second connection end portion connected to the hollow portion and connected to the pipe, and the first connection end portion and the hollow portion. And the main body in which the second connection end forms a gas conduction path through which the oxygen gas passes.
A valve body that is movably arranged in the hollow portion of the main body,
A first urging means and a second urging means that hold the valve body at the center position of the hollow portion and allow the oxygen gas to pass through the gas conduction path.
Have,
When the first connection end is softened or melted by heat, the valve body moves within the hollow due to the urging force of the second urging means, and thus between the first connection end and the hollow. Nasal cannula characterized by closing the gas conduction path. The nasal cannula according to claim 6 and
An oxygen cylinder and / or oxygen concentrator connected to the nasal cannula.
An oxygen gas supply device characterized by being equipped with.

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