JP2018130285A - Medical gas supply device, and attachment of medical gas supply device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To confirm, by a simple constitution, a supply state of medical gas from an injection hole to a mounting fixture such as a cannula.SOLUTION: A medical gas supply device includes a gas supply part for supplying medical gas, and a pipe fitting part 132 having a pipe 301 attached thereto, for communicating with a mounting fixture fixed to a patient, and also having an injection hole 132a for discharging therefrom medical gas supplied from the gas supply part. The pipe fitting part 132 has a whistling part 136 whistling by utilizing flow of medical gas discharged from the injection hole 132a, when the pipe 301 is separated.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a medical gas supply device and an attachment of a medical gas supply device.

  As a medical gas supply device for supplying medical gas to a patient, for example, oxygen which is a kind of oxygen supply device for a patient with respiratory disease to inhale oxygen using a wearing device such as a nasal cannula or an oxygen mask A concentrator is known (see, for example, Patent Document 1).

  The oxygen concentrator compresses indoor air taken in through a filter and an intake tank by a compressor. The oxygen concentrator adsorbs nitrogen in the adsorption tower by passing the compressed air through a sieve bed (adsorption tower) a plurality of times, and generates high-concentration oxygen from the compressed air. The adsorption tower is packed with an adsorbent (for example, zeolite) having the property of adsorbing nitrogen when pressurized and desorbing nitrogen when decompressing. The generated high-concentration oxygen is supplied into the patient's body through the above-described wearing device worn by the patient during use.

  Of the wearing devices worn by the patient, nasal cavity cannula (hereinafter simply referred to as cannula) is frequently exchanged because it tends to have a user's secretions and the like. For this reason, many oxygen concentrators can be easily attached and detached from the cannula. Specifically, the attachment of the cannula to the oxygen concentrator is performed by inserting a cannula connector into a tube attachment portion having an oxygen discharge port (oxygen outlet) protruding from the oxygen concentrator. The connector of the cannula is configured to have flexibility, and is harder and / or thicker than the tube portion of the cannula. As a result, the connector is securely fitted to the tube mounting portion when inserted into the oxygen outlet of the oxygen concentrator.

JP 2006-263441 A

  As described above, since the cannula is frequently changed, the cannula can be attached to the oxygen concentrator by a simple operation such as inserting the cannula into the oxygen outlet to the oxygen concentrator. ing.

  On the other hand, in such an oxygen concentrator, an inadvertent force is applied during use of the oxygen concentrator, so that the cannula may come off the oxygen concentrator. In addition, when the cannula connector is not firmly inserted to the inner side of the tube attachment portion, a gap is formed between the connector and the tube attachment portion, and high-concentration oxygen tends to leak from the gap.

  In order to cope with such a problem of oxygen leakage, it is conceivable to provide a sensor for detecting the flow rate in the cannula. However, it is preferable to provide a sensor in a cannula that is a consumable part and is frequently replaced in terms of cost and the like. Absent.

  An object of the present invention is to provide a medical gas supply device and an attachment of a medical gas supply device that can confirm a supply state of medical gas from a discharge port to a mounting tool such as a cannula with a simple configuration. Is to provide.

The medical gas supply apparatus according to the present invention is:
A gas supply unit for supplying medical gas;
A tube attaching part having a discharge port for releasing the medical gas supplied from the gas supply part, wherein a pipe communicating with the wearing tool worn by the patient is attached and detached;
The tube attachment portion has a blowing portion that blows using the flow of the medical gas discharged from the discharge port when the tube is detached.

The attachment of the medical gas supply device according to the present invention is as follows.
An attachment interposed between a medical gas discharge port in a medical gas supply device and a wearing tool worn by a patient who receives the provision of the medical gas,
A tube attachment portion detachably attached to a tube communicating with the mounting tool;
The tube attachment portion includes a blowing portion that blows using the flow of the medical gas when the tube is detached.

  According to the present invention, it is possible to check the supply state of medical gas from a discharge port to a wearing tool such as a cannula with a simple configuration.

It is a figure which shows schematic structure of the oxygen concentrator which concerns on embodiment. It is a figure which shows the structure of the top case in an oxygen concentrator. It is a figure which shows the structure of the top case in an oxygen concentrator. It is sectional drawing which shows the structure of the oxygen exit part in an oxygen concentrator. It is sectional drawing which shows the state by which the cannula was attached to the cannula attaching part of an oxygen exit part. It is a figure explaining the other structural example of a cannula attaching part. FIG. 7A is a partially cutaway cross-sectional view for explaining the configuration of the attachment of the oxygen concentrator according to the embodiment, FIG. 7A is a view showing a nasal prong side of the cannula, and FIG. 7B is a view where the cannula and the extension tube are attached to the attachment. It is an expanded sectional view which shows the state.

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

[1] Schematic Configuration of Medical Gas Supply Device (Oxygen Concentrator) FIG. 1 shows a schematic configuration of an oxygen concentrator 1 as a medical gas supply device. The oxygen concentrator 1 of the present embodiment is a PSA (Pressure Swing Adsorption) type device, and includes an air intake unit 10, an air compression unit 20, a PSA unit 30, an oxygen storage unit 40, and an oxygen supply unit 50. Yes.

  In the oxygen concentrator 1, the raw air introduced from the air intake unit 10 is compressed by the air compression unit 20 to become compressed air. Such compressed air is sent to the PSA unit 30 which is a high-concentration oxygen generation unit.

  The PSA section 30 has two sheave beds (adsorption towers) 33A and 33B filled with an adsorbent such as zeolite having the property of adsorbing nitrogen faster than oxygen. When compressed air is sent to the sieve beds 33A and 33B and is in a pressurized state, nitrogen and moisture are adsorbed and only oxygen passes, and high-concentration oxygen is generated. On the other hand, when the sieve beds 33A and 33B having adsorbed nitrogen are returned to a reduced pressure state (for example, atmospheric pressure), the adsorbed nitrogen is desorbed and released, and the adsorption capability of the sieve beds 33A and 33B is regenerated. That is, in the PSA unit 30, it is possible to continuously generate high-concentration oxygen by alternately repeating pressurization and pressure reduction with the two sheave beds 33A and 33B.

  The high-concentration oxygen generated by the PSA unit 30 is once stored in the product tank 41 of the oxygen storage unit 40 and then adjusted to a constant pressure by a pressure adjustment unit (pressure regulator) 42. High-concentration oxygen is released from the oxygen supply unit 50, which is a gas supply unit, and enters the patient's body via a cannula, an oxygen mask, or other wearing tool (hereinafter referred to as a cannula) connected to the oxygen concentrator 1. Supplied.

  In the present embodiment, the oxygen supply unit 50 is of a variable flow rate type provided with a flow rate regulator 51. The flow rate regulator 51 has a valve configured to adjust the opening degree. In the present embodiment, the user can change the flow rate of the oxygen gas supplied from the oxygen concentrator 1 to the patient by setting the opening of the valve of the flow rate regulator 51.

[2] Attachment Structure of Cannula, etc. Next, an attachment structure such as a cannula in the present embodiment will be described with reference to FIG. In the following, a case where the cannula 300 is attached to the oxygen concentrator 1 will be exemplified.

  2 and 3 are perspective views showing the configuration of the top case of the oxygen concentrator 1. FIG. FIG. 4 is a cross-sectional view showing the configuration of the oxygen outlet portion. FIG. 5 is a cross-sectional view showing a state where the cannula is attached to the oxygen outlet portion.

  As shown in FIG. 2, the oxygen concentrator 1 includes a main body case 200 and a top case 100. The top case 100 is attached to the upper part of the main body case 200. The main body case 200 accommodates the air intake unit 10, the air compression unit 20, the PSA unit 30, the oxygen storage unit 40, and the oxygen supply unit 50 described in FIG.

  The top case 100 is provided with a handle 110 for carrying the oxygen concentrator 1, a display / operation panel 120, and an oxygen outlet portion 130. The display / operation panel 120 includes a display unit for displaying the remaining battery level and other operating states of the oxygen concentrator 1, an operation unit for setting the oxygen concentrator 1 on / off operation, an oxygen flow rate, and the like. Is provided.

  The oxygen outlet portion 130 communicates with the oxygen supply portion 50 (FIG. 1) and guides high-concentration oxygen to the oxygen outlet portion 130. The oxygen outlet portion 130 branches from the guide tube 131 into a T shape and is attached to the cannula 300. A cannula mounting portion 132 as a tube mounting portion. The cannula mounting portion 132 has a tubular shape that becomes thinner toward the tip, and the cannula 300 can be attached and removed.

  Further, the guide tube 131 is rotatably supported by the top case 100 of the oxygen concentrator 1, so that the cannula mounting portion 132 is also rotatable integrally with the guide tube 131. FIG. 2 shows a state where the cannula mounting portion 132 is in a tilted rotational position, and FIG. 3 shows a state where the cannula mounting portion 132 is in an upright rotational position. As described above, the cannula mounting part 132 is configured to be rotatable, so that the cannula mounting part 132 rotates following the movement and position of the patient wearing the cannula 300. Here, when an unreasonable force is applied to the cannula 300, a tube 302 described later can be bent to prevent problems such as high concentration oxygen generated by the oxygen concentrator 1 being not supplied to the patient.

  FIG. 4 is a cross-sectional view of the oxygen outlet portion 130. One end side of the guide tube 131 communicates with the oxygen supply unit 50 (FIG. 1), and the other end side is closed. The cannula mounting portion 132 branches from the guide tube 131 in a T shape. High-concentration oxygen flows from the guide tube 131 to the cannula mounting portion 132 as indicated by arrows in the figure.

  The cannula mounting portion 132 is a tubular body having a discharge port 132a through which high-concentration oxygen is released, and has a trumpet shape that becomes thinner toward the tip. Further, a return portion 133 is formed on the side surface of the cannula mounting portion 132. Thereby, the cannula attachment part 132 is made into the shape where it is easy to insert the cannula 300 (FIG. 2, FIG. 3), and the cannula 300 is hard to come off.

  Concave portions 134 and 135 are formed on the outer surface of the guide tube 131, and the guide tube 131 is rotatably attached to the top case 100 by fitting the convex portions of the top case 100 into the concave portions 134 and 135. ing.

  A user of the oxygen concentrator 1 uses the cannula 300 by inserting the cannula 300 into the cannula mounting part 132.

  FIG. 5 is a cross-sectional view showing a state where the cannula 300 is attached to the oxygen outlet portion 130.

  The cannula 300 includes a connector 301 that is a portion to be inserted into the cannula mounting portion 132, and a tube 302 that is connected to a nasal prong 303 (see FIG. 7). The connector 301 has a so-called hem-opening shape in which the diameter of the base side in the insertion direction is increased. The connector 301 is harder and / or thicker than the tube 302. Thus, when the connector 301 is inserted into the cannula mounting portion 132, the connector 301 is firmly fitted to the cannula mounting portion 132 so as not to leak high concentration oxygen.

  As described above, the oxygen concentrator 1 has a structure that prevents the cannula 300 from easily coming out of the cannula mounting part 132, but the connector 301 of the cannula 300 is still connected to the cannula mounting part during use of the oxygen concentrator 1. There may be a situation where it is disengaged from 132. This is a case where, for example, the tube 302 of the cannula 300 is caught in something while the oxygen concentrator 1 is used, and an inadvertent force is applied to the cannula 300, so that the connector 301 is detached from the cannula attachment part 132. When the cannula 300 has escaped from the oxygen concentrator 1 in this way, all of the high-concentration oxygen generated by the oxygen concentrator 1 flows out of the cannula mounting portion 132 and is not supplied to the patient.

  Further, when the cannula 300 is not firmly inserted to the back side of the cannula mounting part 132, the cannula 300 is not only easily removed from the cannula mounting part 132, but also between the cannula mounting part 132 and the connector 301. A gap is likely to occur. When such a gap is generated, the high-concentration oxygen generated by the oxygen concentrator 1 leaks from the gap, thereby reducing the flow rate supplied to the patient.

  In addition, in this embodiment, the high-concentration oxygen generated by the oxygen concentrator 1 is configured to flow through an open circuit instead of a closed circuit, in other words, a configuration in which the generated medical gas is unilaterally supplied. It has become. For this reason, leakage of high-concentration oxygen from the inside of the apparatus, that is, from the air intake unit 10 to the oxygen supply unit 50 can be detected by the pressure sensor inside the apparatus, but the flow path from the cannula mounting part 132 to the supply to the patient The leak of high concentration oxygen cannot be detected by the pressure sensor.

  In order to cope with such a problem of oxygen leakage, it is conceivable to provide a sensor for detecting the flow rate in the cannula 300. However, providing a sensor in the cannula 300, which is a consumable item and is frequently replaced, is costly. It is not preferable in terms.

  On the other hand, in city gas and propane gas, in order to make it easy to detect gas leakage, the gas contains a component that emits a bad odor. In the case of gas, such a configuration is not possible.

  Further, in order to cope with the problem of oxygen leakage, a hole is provided in the side surface of the cannula mounting portion 132, and for example, a bell is mounted in the hole, and when the cannula 300 comes out, a high concentration discharged from the discharge port 132a. It is also possible to use a structure that rings the bell using the flow of oxygen. However, in the case of such a configuration, since a bell is also sounded by mechanical vibration, it is not possible to accurately detect the positional deviation or detachment of the cannula 300 with respect to the cannula mounting portion 132.

  In view of such a situation, in the present embodiment, the cannula mounting portion 132 is provided with a blowing portion 136 that blows using the flow of high-concentration oxygen released from the discharge port 132a (see FIGS. 4 and 4). 5).

  In the example shown in FIGS. 4 and 5, the sound blowing portion 136 is a whistle hole 136 </ b> A, 136 </ b> B provided on the side surface of the cannula mounting portion 132. Each of the whistle holes 136A and 136B is formed so as to penetrate the side portion (outer surface and inner surface) of the cannula mounting portion 132. Moreover, each whistle 136A and 136B is formed so that the site | part with a large thickness may be penetrated from the part of the return part 133 of the cannula attaching part 132, as shown in the figure.

  In the present embodiment, whistle holes 136A and 136B are arranged along the axial direction of cannula attachment portion 132 (the direction in which high-concentration oxygen flows). Specifically, the whistle hole 136 </ b> A is provided on the distal end side of the cannula attachment part 132, and the whistle hole 136 </ b> B is provided on the proximal end (root) side of the cannula attachment part 132. In addition, the whistle 136A and the whistle 136B sound at different pitches (frequencies).

  As another example, a configuration in which the whistle hole 136B is provided on the distal end side of the cannula mounting part 132 similarly to the whistle hole 136A, or the whistle hole 136A is provided on the base end (base) side of the cannula mounting part 132 similarly to the whistle hole 136B. It is good also as a structure to provide.

  In the present embodiment, the case where two whistle holes (136A, 136B) are provided as the blowing part 136 is illustrated, but the number of whistle holes is arbitrary, and may be one or three or more. The shape and size of the whistle are also arbitrary. As the shape of the whistle hole, for example, an orifice shape in which the diameter of the intermediate portion is narrowed down (136A) can be formed, and a shape that facilitates the generation of Karman vortices on the outer surface side of the cannula mounting portion 132 can be formed (136B). .

  The shape and size of the whistle holes (136A, 136B) are not particularly limited, and can be appropriately changed according to the flow rate of the apparatus, that is, the flow rate of oxygen flowing out from the cannula mounting portion 132.

  As shown in FIG. 5, when the cannula 300 is mounted on the cannula mounting part 132 in the use state of the apparatus, specifically, the state where the connector 301 of the cannula 300 is securely mounted to the vicinity of the root of the cannula mounting part 132. Then, the sounding part 136 does not sound. That is, in such a mounted state, the whistle 136A is blocked by the inner surface of the connector 301 of the cannula 300, high-concentration oxygen cannot pass through the whistle 136A, and the whistle 136A does not blow. On the other hand, in such a mounted state, the root whistle 136 </ b> B is not covered with the inner surface of the connector 301, but is covered with the inner surface of the connector 301. In such a state, since the space between the inner surface of the connector 301 and the whistle 136B is sealed, high-concentration oxygen cannot pass through the whistle 136B continuously, and the whistle 136B does not blow.

  From the state shown in FIG. 5, it is assumed that, for example, an inadvertent force is applied to the tube 302 of the cannula 300 so that the cannula 300 is pulled out in the direction of arrow a and the connector 301 is detached from the cannula mounting portion 132. In this case, as shown in FIG. 4, when the connector 301 is detached, the end portion of the blowing portion 136 is exposed, and high-concentration oxygen flowing from the guide tube 131 to the discharge port 132a of the cannula mounting portion 132 passes through the whistle 136A, 136B. It becomes a state which can be performed, and the sounding part 136 sounds. Therefore, the user or the like can detect that the cannula 300 has come out of the cannula mounting portion 132.

  In the present embodiment, since a plurality of whistle holes (136A, 136B) are arranged along the axial direction of the cannula mounting part 132, the state before the cannula 300 is completely removed from the cannula mounting part 132. The whistle hole 136B sounds in a state where it is attached halfway. For this reason, it is possible to detect a state where high-concentration oxygen is likely to leak or is slightly leaking. In addition, since the whistle holes 136A and 136B sound at different frequencies, it is possible to easily detect how far the cannula 300 is detached from the cannula mounting part 132.

  As described above, according to the oxygen concentrator 1, the supply state of high-concentration oxygen to the patient and the mounting state of the cannula 300 with respect to the cannula mounting portion 132 can be checked with a simple and low-cost configuration. It is possible to easily check the supply state of high-concentration oxygen to the wearing tool.

In the above-described embodiment, the configuration in which the cannula 300 is directly connected to the oxygen concentrator 1 is illustrated. As another example, a configuration in which various intermediate devices such as a water trap, a nebulizer, or a filter (for example, a CO ₂ filter) are interposed between the oxygen concentrator 1 and the cannula 300 may be employed.

  In the above-described embodiment, the configuration in which the cannula mounting portion 132 is rotatable in the vertical direction (see FIGS. 2 and 3) is exemplified, but the rotation direction of the cannula mounting portion 132 can be variously changed. For example, the oxygen concentrator shown in FIG. 6 has a configuration in which the cannula mounting portion 132 can rotate in a substantially horizontal direction as indicated by a double-headed arrow in the drawing, and the same effect can be obtained in such a case.

  That is, the cannula mounting part 132 is configured to be rotatable in various directions, so that the cannula mounting part 132 rotates following the movement and position of the patient wearing the cannula 300. Furthermore, when an excessive force is applied to the cannula 300, the trouble that the high concentration oxygen is not supplied to the patient due to the bending of the tube 302 or the like is avoided, and the connector 301 is displaced from the cannula mounting part 132, so that the sounding part 136 sounds. Therefore, the user or the like can detect that the cannula 300 has come out of the cannula mounting portion 132.

[3] Structure of Attachment FIG. 7 shows the structure of the attachment 400 interposed between the cannula mounting portion 132 and the cannula 300 of the oxygen concentrator 1. 7A shows the nasal prong 303 side of the cannula 300, and FIG. 7B shows the attachment 400 in an enlarged manner. Hereinafter, the same reference numerals are given to the same parts as the above-described cannula mounting portion 132, and the description thereof is omitted as appropriate.

  An attachment 400 shown in FIG. 7 is a substantially cylindrical member in which an intermediate member 410, an extension tube attachment portion 411, and a cannula attachment portion 412 are integrally formed.

  The intermediate member 410 has a substantially ring shape, and has a hole 410 a having substantially the same diameter as the inner diameter of the extension tube attachment portion 411 and the cannula attachment portion 412.

  The extension tube attachment portion 411 is a part that is attached to and detached from the extension tube 350 attached to the cannula attachment portion 132 of the oxygen concentrator 1, and includes the return portion 133 described above. For example, the extension pipe 350 is provided with connectors 351 at both ends of a tube 352 serving as a pipe main body, one of the connectors 351 (not shown) is attached to the cannula attachment portion 132 of the oxygen concentrator 1, and the other of the connectors 351 is the extension pipe. It is attached to the attachment portion 411.

  The cannula mounting portion 412 is a part that is attached to and detached from the connector 301 of the cannula 300, and includes the above-described return portion 133 and the blowing portion 136 (the whistle holes 136A and 136B).

  In this example, the attachment 400 has a configuration in which an extension pipe attachment portion 411 and a cannula attachment portion 412 extend in opposite directions from the intermediate member 410. As another example, the extension tube attachment portion 411 and the cannula attachment portion 412 may extend from the intermediate member 410 in an L shape.

  In this example, the attachment 400 is detachable from the extension tube 350 attached to the cannula attachment portion 132 of the oxygen concentrator 1. However, the attachment 400 may be integrated with the extension tube 350. Good.

  When the oxygen concentrator 1 is operated from the state shown in FIG. 7, high-concentration oxygen generated by the oxygen concentrator 1 enters the attachment 400 from the gas inlet 411 a through the extension pipe 350 and is released from the gas outlet 412 a to the cannula 300. The

  In this state of use, as shown in FIG. 7, when the cannula 300 is mounted on the cannula mounting portion 412 of the attachment 400, specifically, the connector 301 of the cannula 300 is firmly mounted until it is abutted against the intermediate member 410. In the state where it is, the sounding part 136 does not sound. That is, in such a wearing state, as described above, since high-concentration oxygen cannot pass through the blowing part 136, neither the whistle 136A nor 136B blows.

  On the other hand, from the state shown in FIG. 7, for example, when the cannula 300 is pulled out in the direction of arrow a and the end of the whistle 136B is exposed, high-concentration oxygen flowing from the oxygen concentrator 1 to the discharge port 132a of the cannula mounting portion 412 It will be in the state which can pass whistle hole 136B, and whistle hole 136B will sound. In this case, the user or the like can detect that the cannula 300 is not securely inserted into the attachment 400.

  Further, when the cannula 300 is pulled out from the cannula mounting portion 132, the end portion of the whistle hole 136A is also exposed, and high-concentration oxygen flowing from the oxygen concentrator 1 to the discharge port 132a of the cannula mounting portion 412 can pass through the whistle hole 136A. Then, the whistle hole 136B and the whistle hole 136A sound. In this case, the user or the like can detect that the cannula 300 has left the attachment 400.

In this embodiment, the configuration of the attachment 400 having a role of extending the distance between the oxygen concentrator 1 and the cannula 300 is illustrated. Other examples of attachments may include various functions as intermediate devices such as a water trap, a nebulizer, or a filter (for example, a CO ₂ filter).

  As described above, according to the above-described embodiment, the supply state of high-concentration oxygen to the patient and the wearing state of the cannula 300 with respect to the cannula mounting portion can be checked with a simple and low-cost configuration, and the oxygen of the oxygen concentrator 1 can be checked. The supply state of high-concentration oxygen from the outlet to the wearing tool such as a cannula can be easily confirmed.

  In the above-described embodiment, the oxygen concentrator adopting the PSA method is exemplified, but an oxygen concentrator of another method (for example, an oxygen-enriched membrane type) may be used.

In the above-described embodiment, the oxygen concentrator is exemplified as the medical gas supply device. However, the oxygen concentrator is not limited to the oxygen concentrator, and any type of oxygen supply device such as a liquid oxygen device and an oxygen cylinder may be used. Also good. Furthermore, as a medical gas supply device, it is also applicable to various devices that use medical gas other than oxygen (for example, nitrous oxide (N ₂ O) for anesthesia, air for artificial respiration therapy). Is possible.

  In the above-described embodiment, the whistling is stopped by covering or closing the whistle with the inner surface of the cannula, but the sounding may be stopped by closing the whistle with the outer surface of the cannula. .

  In the above-described embodiment, the case where each of the whistle 136A and the whistle 136B emits an audible wave, that is, a frequency band sound that can be heard by the human ear, has been described. On the other hand, in this specification, “sounding” is not limited to a case where an audible sound is emitted, but includes a case where a sound having a frequency exceeding an audible wave (for example, 20000 Hz) (non-audible sound) is emitted. Such inaudible sound can be detected by a microphone or the like even if it cannot be heard by humans.

  Utilizing this property, for example, a non-audible sound is blown from the whistle 136B on the base side, and the non-audible sound blown from the whistle 136B is detected by a detection unit such as a microphone, for example, in a separate room (management Monitoring may be performed by a computer on the person side. By adopting such a configuration, for example, when the cannula 300 is about to come off from the cannula mounting portion 132 during sleep of a patient who uses the oxygen concentrator 1, the whistle 136A before blowing with an audible sound. At this stage, the manager can correct the mounting state of the cannula 300. Therefore, it is possible to prevent in advance a situation in which a sleeping patient is awakened or surprised by the sound of an audible sound, and to perform detailed nursing for the patient.

  Moreover, in embodiment mentioned above, the structure which provides a whistle hole as a blowing part was illustrated. As another structure of the blowing part, for example, an elongated hole that penetrates the side part (inner surface and outer surface) of the cannula mounting part is provided, a lead having a dimension corresponding to the hole is provided, and the lead is vibrated by the released gas. It is good also as a structure (namely, harmonica structure) which blows.

  The above-described embodiments are merely examples of implementation in carrying out the present invention, and the technical scope of the present invention should not be construed as being limited thereto. That is, the present invention can be implemented in various forms without departing from the gist or the main features thereof.

1 Oxygen concentrator (medical gas supply device)
10 Air Intake Unit 20 Air Compression Unit 30 PSA Unit (High Concentration Oxygen Generation Unit)
40 Oxygen storage part 50 Oxygen supply part 100 Top case 110 Handle 120 Display operation panel 130 Oxygen outlet part 131 Guide pipe 132 Cannula attachment part (tube attachment part)
132a Release port 133 Return part 134, 135 Concave part 136 Sounding part
136A, 136B Whistle 200 Main unit case 300 Cannula 301 Connector (pipe)
302 Tube 303 Nasal prong 350 Extension tube 351 Connector 352 Tube 400 Attachment 410 Intermediate member 411 Extension tube attachment portion 411a Gas inlet 412 Cannula attachment portion (tube attachment portion)
412a Gas outlet

Claims (9)

A gas supply unit for supplying medical gas;
A tube attaching part having a discharge port for releasing the medical gas supplied from the gas supply part, wherein a pipe communicating with the wearing tool worn by the patient is attached and detached;
The tube attachment portion has a blowing portion that blows using the flow of the medical gas discharged from the discharge port when the tube is detached.
Medical gas supply device. The tube attachment portion is tubular,
The sounding part is a whistle hole provided in a side part of the pipe mounting part.
The medical gas supply apparatus according to claim 1. The whistle is provided at a position where the tube is covered or blocked by the inner surface of the tube when the tube is attached to the tube mounting portion.
The medical gas supply apparatus according to claim 2. The tube mounting portion has a return portion,
The whistle is provided in the return part,
The medical gas supply apparatus according to claim 2 or 3. A plurality of the sound blowing parts are provided along the axial direction of the pipe mounting part,
The medical gas supply apparatus according to any one of claims 1 to 4. A plurality of the sounding parts are provided in the tube mounting part, and sound at different frequencies.
The medical gas supply apparatus according to any one of claims 1 to 5. Having a high-concentration oxygen generator that generates high-concentration oxygen;
The gas supply unit supplies the high concentration oxygen generated by the high concentration oxygen generation unit,
The medical gas supply apparatus according to any one of claims 1 to 6. An attachment interposed between a medical gas discharge port in a medical gas supply device and a wearing tool worn by a patient who receives the provision of the medical gas,
A tube attachment portion detachably attached to a tube communicating with the mounting tool;
The tube attachment portion has a blowing portion that blows using the flow of the medical gas when the tube is detached.
Attachment of medical gas supply device. The tube attachment portion is tubular,
The blowing part is a whistle hole provided on a side surface of the pipe mounting part.
The attachment of the medical gas supply apparatus of Claim 8.

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