KR101583686B1 - Ventilator - Google Patents

Abstract

The present invention relates to a device for artificial respiration. The present invention comprises: a housing having a supply hole coupled to an oxygen tank, and coupled to oral cavity or nasal cavity of a patient; a pressure reducing valve which is installed in the housing, and reduces oxygen pressure of the oxygen tank and supplies air, wherein the oxygen pressure is supplied from the supply hole of the housing; an air supply control valve which control air supply through opening and closing movement passage while providing movement passage of the oxygen supplied from the pressure reducing valve; a flow rate control valve which controls oxygen flow rate provided by opening operation of the air supply control valve; and an air supply flow which guides the oxygen supplied from the flow rate control valve to a discharge hole of the housing. The present invention can be smoothly carried out guiding oxygen decompressed in the pressure reducing valve to the air supply flow.

Description

Ventilator {VENTILATOR}

The present invention relates to an artificial respiratory apparatus, and more particularly, to an artificial respiratory apparatus that supplies oxygen to a patient who is unable to self-breathe.

In general, the resuscitator is used in the intensive care unit or emergency room of the hospital. It can be used immediately after the patient has stopped breathing, or in patients who have difficulty in self-breathing or in self-breathing, but by supplying oxygen to patients with cyanosis due to oxygen deficiency, .

It is important that the artificial respiration apparatus supplies oxygen by the amount of oxygen and the respiratory cycle in accordance with the breathing ability of the patient, and the prior art related to such artificial respiration apparatus is the automatic respiration apparatus disclosed in U.S. Patent No. 5,520,170.

This prior art automatic breathing apparatus is provided with a manual button and a control slider in a housing shell having an oxygen inlet and an outlet, and includes a pressure regulator, a main switch, a timing shuttle, a demand valve, a flow control rotor and a diaphragm housing The oxygen is supplied through the organic operation of the patient to breathe.

Also, in the prior art automatic respiratory apparatus, a plurality of flow holes are formed in the disk to control the flow rate of oxygen, and the respiratory cycle is controlled through a plurality of orifices. That is, as the volume of the flow hole and the orifice is variable while the disk is rotated by the control slider, the supply amount of the oxygen and the supply period are varied.

However, in the above-described conventional automatic respiration apparatus, the control slider for rotating the disk is connected to the disk through separate grooves provided on the side of the housing shell. Therefore, it is very complicated to manufacture and assemble the bar. Rise.

Meanwhile, the applicant of the present invention has been registered as a 20-440379 (automatic respirator for oxygen supply) by applying for a utility model registration of artificial respiration apparatus in the Korean Intellectual Property Office in order to provide a more functional and convenient artificial respiration apparatus. Such another conventional technique is provided so that the breathing of the patient supplied to the control valve 400 is transmitted as shown in the claims (with reference numerals on the registration dossier for the sake of clarity), and the regulator 100 A time cylinder (200) installed to supply oxygen to the main valve (300) to block oxygen supplied to the main valve from the regulator; A main valve 300; A regulator (100) installed to supply the main valve (300) and the time cylinder (200) in a differential manner after the supplied oxygen is changed to a prescribed pressure; A control valve 400 installed to adjust the supply amount of oxygen supplied to the oral cavity of the patient by operating the knob 410 when delivering oxygen of the main valve 300 to the air supply unit 600; And a ventilating unit 600 installed to supply the patient's breath to the control valve 400 when the patient spontaneously breathes through the spontaneous breathing unit 500.

The main valve 300 includes a first oxygen inlet hole 310 and a second oxygen inlet hole 310 connected to the regulator 100 and the control valve 400 so as to be opened and closed by the operation of the first piston 360, The second actuator inlet hole 350 connected to the time cylinder is provided on one side of the first cover 370 supporting the first piston 360 while the oxygen exhaust holes 330 are provided, The second cover 240 supports the second piston 270 while the first actuator inlet hole 230 and the first actuator exhaust hole 250 are respectively opened and closed by the second piston 270 And a third respiratory inflow hole 210 connected to the control valve on one side to automatically open and close the main valve by the operation of the time cylinder.

The control valve 400 is provided with an actuator 470 for controlling the supply amount of oxygen from the main valve 300 to the air supply unit 600 so as to control the amount of oxygen supplied to the time cylinder 200 And an adjustment pin 450 for adjusting the respiratory rate according to the patient's body shape.

The automatic ventilator includes a control valve 400, a spontaneous breathing unit 500, a ventilation unit 600 and a fixed cap 670 disposed in a vertical direction of the housing 700, The regulator 100, the main valve 300 and the time cylinder 200 are disposed in the direction of the arrow.

The control valve 400 is characterized in that a tapered surface 470a is formed at an end of the actuator 470 to accurately control the amount of oxygen.

The gas supply unit 600 is provided with a mask connection port 660 and an exhaust diaphragm 640 and a gas supply valve 620. The gas supply unit 600 is provided at one side of the gas supply valve 620 with a drain valve Is further provided.

However, another conventional technique as described above is such that the oxygen of the regulator 100 is supplied to the time cylinder 200 even in the closing operation of the main valve 300 as the reduced-pressure oxygen is supplied directly to the time cylinder 200 in the regulator 100 200, so that the operation of the main valve 300 is controlled through the time cylinder 200 regardless of the operation state of the main valve 300, which may cause malfunctions. That is, since the oxygen in the regulator 100 is directly supplied to the time cylinder 200 that controls the operation of the main valve 300, the time cylinder 200 malfunctions the main valve 300 due to the oxygen of the regulator 100 .

And. When the knob 410 connected to the actuator 470 having the tapered surface 470a is rotated, the actuator 470 moves along with the amount of rotation of the knob 410, The amount of oxygen supplied to the actuator 200 can be easily adjusted. However, it is practically not easy to precisely move the actuator 470 when the hand operated knob 410 is not rotated precisely. In addition, The adjusting pin 450 for adjusting the amount of oxygen supplied to the human body is supported by the spring, but the adjusting pin 450 can not be moved directly, so that the amount of oxygen supplied to the human body can not be precisely adjusted.

The spontaneous respiratory unit 500, which is separately provided from the time cylinder 200 and controls the operation of the main valve 300 together with the time cylinder 200, includes a pressure plate 560, a sensing plate 550, And the second respiratory air inlet / outlet holes 510 and 530, the number of parts is increased, and the assembling process is increased, so that the unit price of the product is greatly increased.

In addition, since the elastic force of the spring supporting the exhaust diaphragm 640 provided in the air sending unit 600 can not be controlled, the exhaust amount can not be smoothly adjusted even if defects occur due to manufacturing scattering or assembly scattering.

In addition, although the emergency button 22 in the form of a trigger to be manually operated is provided, the configuration of the emergency button 22 is very complicated, and there is a fear of malfunction, and the operation structure is complicated.

The matters described in the background section described above are intended to enhance understanding of the background of the invention and may include matters not previously known to those skilled in the art.

US 05520170A KR 20-440379

It is an object of the present invention to provide an artificial respiratory apparatus which can reduce the quantity of components for controlling the flow rate of oxygen supplied to the human body, as well as the flow rate.

In particular, it is an object of the present invention to provide an artificial respiratory apparatus capable of controlling the flow rate of oxygen directly supplied to the human body in proportion to the rotation angle of a rotatable rotary member.

Another object of the present invention is to provide an artificial respiratory apparatus which is capable of easily mounting the above-mentioned rotating member, and in addition, has a mechanism capable of controlling the rotation angle of the above-mentioned rotating member.

Another object of the present invention is to provide an artificial respiration apparatus capable of easily depressurizing oxygen mechanically and further capable of supplying or stopping oxygen by the pressure of decompressed oxygen.

In addition, when the oxygen supplied to the human body is supercharged, some supercharged oxygen can be overflowed. As described above, the operation of the oxygen supply member can be controlled through the pressure of oxygen. It is another object to provide a ventilator capable of supplying air.

Another object of the present invention is to provide an artificial respiration apparatus capable of doubling the pressure of oxygen supplied for the operation of an internal member.

Another object of the present invention is to provide an artificial respiration apparatus capable of exhausting oxygen supplied to the human body to the outside during exhalation due to spontaneous breathing.

In order to accomplish the above object, according to an aspect of the present invention, there is provided a medical device comprising: a housing having a supply port connected to an oxygen tank and having an outlet connected to a patient's mouth or nasal cavity; A pressure reducing valve built in the housing and reducing pressure and supplying oxygen pressure of the oxygen tank supplied through a supply port of the housing; An air supply control valve for controlling the air supply by opening or closing the movement path while providing a movement path of oxygen provided by the pressure reducing valve; A flow control valve for controlling a flow rate of oxygen provided by an opening operation of the air supply control valve; And an air supply passage for supplying oxygen from the flow control valve to the outlet of the housing.

The flow control valve includes, for example, a valve cylinder having a supply hole for supplying oxygen from the supply air control valve and a discharge hole for discharging oxygen, and for providing a valve seat between the supply hole and the discharge hole; A flow rate regulating valve member movably incorporated in the valve cylinder for regulating the discharge flow rate of oxygen discharged to the discharge hole of the valve cylinder by varying an interval between the valve seat and the valve seat while being moved by a rotational force externally provided; A dial rotatably fixed to the housing to provide rotational force to the flow control valve member while rotating; And a connector connecting the dial to the flow control valve member to interlock the dial and the valve member.

The connector includes, for example, a rotary ring integrally fixed to the valve member and rotating together with the flow control valve member; A fastener detachably fixing the rotary ring to the flow control valve member; A fitting protrusion protruding from the one side of the rotary ring toward the dial; And a protrusion holder provided in the dial and having a groove shape in which the fitting protrusion is fitted and fixed in a hooked state.

The fastener may include, for example, a cut-out portion provided to the rotary ring in the same manner as a portion of the rotary ring fitted to one side of the flow control valve member is cut off; A pair of spaced apart protrusions formed on a portion of the rotary ring at which both ends of the cutout are located and spaced apart from each other; And a rotary ring fastening member fastened to the spacing protrusions to reduce the spacing distance of the spacing protrusions to fix the rotary ring to the flow control valve member.

The connector may further include, for example, a stopper for controlling the rotation angle of the dial.

The stopper protrudes from both sides of the rotary ring and rotates together with the rotary ring, for example, and contacts the peripheral fixing member located outside the rotary ring to suppress the rotation of the dial to a predetermined angle. Can be configured.

The stopper needs to further include a spacer for adjusting a rotation angle of the dial by the stopper by adjusting a distance between one side of the side wing contacting the fixing member and the fixing member.

The spacer may be formed of, for example, a screw that is screwed to one side of the side wing and is protrudingly fixed, and is in contact with the fixing member by preference to one side of the side wing by the side wing to be rotated.

The pressure reducing valve may include, for example, a valve seat in which a supply port for supplying compressed oxygen from the oxygen tank is formed at one side and a hole for communicating oxygen is formed in the supply port, and oxygen supplied from the supply port to the other side A decompression cylinder in which an exhaust port for discharging is formed; A valve piston movably installed inside the decompression cylinder to reduce the pressure of oxygen while opening and closing the valve seat of the air supply port; And a piston spring for elastically supporting the valve piston.

The air supply control valve includes, for example, a valve housing having a supply orifice supplied with oxygen from the pressure reducing valve and a discharge orifice for discharging oxygen from the supply orifice and supplying the oxygen to the flow control valve; A valve plunger movably incorporated in the valve housing to open and close the supply orifice or discharge orifice; And a plunger spring for elastically supporting the valve plunger.

The present invention further needs to include an overflow unit for discharging a part of oxygen guided to the outlet of the housing through the air supply channel to the outside.

The overflow unit may include, for example, a collection chamber for collecting oxygen overflowed through the air supply passage and exhausting the oxygen to an exhaust hole provided at one side; And a relief valve mounted on the exhaust hole of the collecting chamber and opening / closing the exhaust hole while being operated by the pressure of oxygen collected in the collecting chamber.

The relief valve includes, for example, a valve disk for opening and closing an exhaust hole of the collecting chamber; A disc support spring for elastically supporting the valve disc; And a spring seat for restraining the disc support spring to prevent the disc support spring from being released.

The relief valve may further include a spring adjuster for moving the spring seat to adjust an elastic force of the disc support spring.

The spring adjuster may include, for example, a screw member for movably screwing the spring seat to the chamber case of the collection chamber or the housing.

The present invention also needs to further include an operation control unit for controlling the operation of the air supply control valve in accordance with the pressure of oxygen supplied to the flow control valve.

The operation control unit includes, for example, a bypass valve for externally bypassing a portion of the oxygen supplied to the flow control valve through the air supply control valve; And an operation for controlling the operation of the air supply control valve through the part of the reduced pressure oxygen by providing the air supply control valve with part of the reduced pressure oxygen supplied from the pressure reducing valve while being operated by bypass oxygen of the bypass valve And a control valve.

The bypass valve is provided with, for example, a communication hole communicating with the flow control valve, a part of oxygen supplied to the flow control valve is filled through the communication hole, and the charged oxygen is supplied to the operation control valve, An oxygen filling chamber having a bypass hole for passing; And an inclined valve member movably installed in the oxygen filling chamber, the inclined valve member having an inclined surface formed therein and moving to the inside of the communication hole to vary the cross-sectional area of the communication hole.

The operation control valve includes, for example, a bypass port through which the bypass oxygen of the bypass valve is introduced, an inlet port through which a part of the reduced pressure oxygen supplied from the pressure reducing valve flows into the inlet port, A valve chest provided in parallel with a discharge port for discharging decompressed oxygen; The bypass port being provided in the valve chest and communicating with or blocking the inlet port and the exhaust port through a splitter on the outer circumferential surface while being moved by the bypass oxygen flowing into the bypass port, A spool for guiding oxygen of the pressure reducing valve to the air supply control valve to operate the air supply control valve through oxygen of the discharge port; And a spool spring for elastically supporting the spool within the valve chest.

The present invention also needs to further include a manual control valve for directly supplying oxygen supplied from the pressure reducing valve to the air supply passage.

The manual control valve includes, for example, a manual valve case provided with an input hole for receiving reduced pressure oxygen from the pressure reducing valve, and an output hole for discharging oxygen introduced into the input hole on the other side; An opening / closing member movably installed in the manual valve case to open / close at least one of the input hole and the output hole; An elastic body for elastically supporting the opening and closing member; And a trigger which is rotatably provided on one side of the opening and closing member and opens the input hole by pressing the opening and closing member supported by the elastic body while being rotated.

The operation control unit may further include a pressurizing chamber provided on the flow path connecting between the bypass valve and the operation control valve to pressurize the oxygen supplied to the operation control valve from the bypass valve .

On the other hand, the present invention is characterized in that it further comprises a flow rate varying unit for varying a flow rate of oxygen guided through the air supply flow path by exhausting at least a part of oxygen guided by the air supply flow path or shutting off exhaust gas have.

The flow rate varying unit includes a drain valve having a drain hole communicating with the air supply flow passage and opening or closing a drain hole to exhaust at least a part of oxygen guided through the air supply flow passage or shut off exhaust gas; And a switching valve for supplying oxygen to the drain valve to operate the drain valve.

The drain valve may include, for example, a drain body having one side connected to the air supply passage and the other side communicating oxygen through the other side and having the drain hole on one side; An opening / closing bundle movably installed in the drain body and being opened and closed by the oxygen of the switching valve supplied to the drain body, while opening / closing the drain hole; And a drain spring for elastically supporting the opening / closing bundle.

The switching valve may include, for example, a needle housing having an oxygen inlet hole through which oxygen supplied from the pressure reducing valve is formed, and an oxygen supply hole communicating with the oxygen inlet hole to supply oxygen to the oxygen inlet hole; A needle which is movably incorporated in the needle housing to open and close the oxygen inflow hole of the needle housing; And a needle spring for elastically supporting the needle.

Alternatively, the switching valve may include, for example, an oxygen supply hole through which oxygen supplied from the pressure reducing valve is formed, and an oxygen supply hole communicating with the oxygen inlet hole to supply oxygen to the drain valve, A needle housing having a charging hole and a guide hole through which oxygen of the pressure reducing valve is supplied to the manual control valve from the pressure reducing valve, respectively; A needle which is movably incorporated in the needle housing and moves while opening and closing the oxygen inflow hole of the needle housing or communicating the oxygen supply hole and the guide hole of the needle housing; And a needle spring for elastically supporting the needle.

Since the operation of the air supply control valve is controlled without the need for a complicated spontaneous breathing unit as in the prior art, the manufacturing cost can be reduced by reducing the number of components and the manufacturing process can be shortened. Flow Control of Flow Control Valve As the dial connected to the valve member is rotated to adjust the flow rate by rotating the flow control valve member that controls the flow rate of oxygen directly supplied to the human body, the flow rate of oxygen supplied to the human body is adjusted to a suitable amount As shown in FIG.

Particularly, since the rotation angle of the flow control valve member is determined according to the rotation angle of the dial, not only the responsiveness in controlling the flow rate is improved, but also the amount of oxygen supplied to the human body can be precisely controlled to a desired amount.

In addition, since the dial is fixed to the flow control valve member through the connector, the dial can be easily attached to the flow control valve member in a detachable manner, thereby improving assembling convenience and reassembling if necessary. In addition, since the fastening member constituting the fastener of the connector is fastened to the spaced-apart projection formed on the rotary ring, the dial is fixed to the flow control valve member through the rotary ring without damaging the flow control valve member And the rotation ring can be reassembled when necessary. Further, since the stopper is provided in the connector, the rotation angle of the dial can be set to a desired angle, so that the operation of the flow control valve member can be precisely controlled.

In addition, since the side wing of the stopper can be spaced apart from the flow control valve member by a desired distance through the spacer provided in the stopper, not only the operation of the flow control valve member can be controlled more precisely, have.

Further, since the valve piston of the pressure reducing valve operates by the pressure of the oxygen flowing into the pressure reducing cylinder of the pressure reducing valve, the pressure of the introduced oxygen can be easily reduced and the pressure can be operated without power supply, The valve plunger of the valve housing moves inside due to the pressure of oxygen or elastic force of the spring and opens or closes the supply orifice or the discharge orifice, so that the supplied oxygen can be easily supplied or stopped.

In addition, since oxygen supercharged through the supply air flow path is discharged through the overflow unit, it is possible to prevent safety accidents due to supercharging. In addition, since the relief valve of the overflow unit operates by the oxygen pressure, Further, since the valve disc of the relief valve is supported by the disc support spring, not only the relief valve can be easily constructed, but also the spring force of the disc support spring can be adjusted through the spring adjuster, So that the amount of exhaust overflowing can be precisely adjusted, and the spring adjuster can be easily operated because the spring adjuster is constructed by a screw type structure.

Furthermore, since the operation control unit controls the operation of the air supply control valve in accordance with the pressure of oxygen, the air supply control valve can be operated substantially automatically, and in addition, the operation control valve of the operation control unit, which controls the operation of the air supply control valve, Since the operation control valve is actuated by some oxygen that is bypassed by the pass valve, not only the operation control valve can be gradually activated automatically but also by the part of oxygen to be bypassed, the operation control valve is operated in response to the breathing cycle, Lt; / RTI >

In particular, since the oxygen of the pressure reducing valve is not directly supplied to the operation control valve, the operation control valve can be operated in accordance with the state of the air supply control valve, thereby precisely and precisely controlling the air supply control valve.

In addition, since the bypass valve is composed of the inclined valve member having the oxygen filling chamber and the inclined surface, not only the bypass valve can be easily constructed, but also when the inclined valve member is configured to be pressed and interlocked with the flow control valve member, And the flow rate of oxygen bypassed to the operation control valve can be adjusted simultaneously. Since the operation control valve is composed of the valve chest, the spool and the sprue spring and is operated by the oxygen pressure, the operation control valve can be automatically Can be operated.

In addition, since the manual control valve is provided, oxygen can be manually supplied to the human body in an emergency, and in addition, since the manual control valve is mechanically operated, the manual control valve can be stably operated as well as easily configured, Since the trigger is provided, the manual control valve can be operated easily.

In addition, the pressure of oxygen supplied from the bypass valve to the operation control valve through the pressurizing chamber can be doubled, so that the operation control valve can be smoothly operated.

In addition, when the exhalation due to spontaneous breathing is guided through the air supply flow path, the flow rate variable unit interlocks with the air supply control valve or the manual control valve to exhaust oxygen or shut off the exhaust gas, It is possible to prevent the exhaust air from being re-sucked by the vortex of the exhaust air due to the oxygen.

In particular, since the flow rate varying unit is composed of a drain valve connected to the air supply flow path and a switching valve for controlling the operation of the drain valve in cooperation with the air supply control valve or the manual control valve, the flow rate variable unit can be mechanically operated.

In addition, since the drain hole of the drain valve is opened and closed by the opening / closing batch operated by the oxygen supplied from the air supply control valve or the manual control valve, it can be operated accurately at the time of exhalation.

Further, since the needle of the switching valve operates the oxygen supplied from the air supply control valve or the manual control valve and operates the opening / closing bundle of the drain valve, the drain valve can be easily interlocked with the air supply control valve or the manual control valve.

1 is a perspective view of an artificial respiratory apparatus according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view showing the internal structure of the ventilator according to the embodiment of the present invention.
FIG. 3 is a sectional view of the internal structure of the artificial respiratory apparatus according to the embodiment of the present invention, as viewed from above.
4 is a system diagram schematically showing the overall configuration of a respiratory apparatus according to an embodiment of the present invention.
FIG. 5 is a cross-sectional view illustrating a configuration of a pressure reducing valve applied to an artificial respiratory apparatus according to an embodiment of the present invention.
6 is an operation diagram of a pressure reducing valve applied to an artificial respiratory apparatus according to an embodiment of the present invention.
FIG. 7 is a sectional view showing a configuration of an air supply control valve applied to a ventilator according to an embodiment of the present invention.
FIG. 8 is an operation diagram showing the operation of the air supply control valve applied to the ventilator according to the embodiment of the present invention.
FIG. 9 is a sectional view showing the configuration of a flow control valve applied to the artificial respiratory apparatus according to the embodiment of the present invention.
10 is a plan view showing a configuration of a connector applied to a flow control valve of an artificial respiratory apparatus according to an embodiment of the present invention.
11 is a cross-sectional view illustrating the configuration of an overflow unit applied to a ventilator according to an embodiment of the present invention.
FIG. 12 is an operation diagram showing an operation of an overflow unit applied to a ventilator according to an embodiment of the present invention.
13 is a cross-sectional view showing the configuration of an operation control unit applied to the artificial respiratory apparatus according to the embodiment of the present invention.
FIG. 14 is an operation diagram of an operation control valve applied to a ventilator according to an embodiment of the present invention. FIG.
FIG. 15 is a sectional view showing the construction of a manual control valve applied to an artificial respiratory apparatus according to an embodiment of the present invention. FIG.
16 is an operation diagram of a manual control valve applied to a ventilator according to an embodiment of the present invention.
17 is an operation diagram of the artificial respiratory apparatus according to the embodiment of the present invention.
18 is a system diagram showing a flow rate variable unit installed in a ventilator according to an embodiment of the present invention.
19 is an enlarged cross-sectional view of the flow rate varying unit shown in Fig.
20 is a system diagram showing the operating state of the flow rate varying unit shown in Fig.
21 is an enlarged cross-sectional view of the flow rate varying unit shown in Fig.
22 is a system diagram showing the interlocked state of the flow rate varying unit and the manual control valve shown in Fig.
23 is an enlarged cross-sectional view of the flow rate varying unit shown in Fig.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood, however, that the present invention is not limited to the illustrated embodiments, and that various changes and modifications may be made without departing from the spirit and scope of the invention. . In order to clearly illustrate the embodiments of the present invention, parts that are not related to the description are omitted. In the following description, names of the components are denoted by first and second names, And is not necessarily limited to the order. And throughout the specification, it is to be understood that, when a section includes a constituent element, it does not exclude other constituent elements, but may include other constituent elements, unless specifically stated otherwise. In addition, the term unit or means described in the specification means a unit of a comprehensive configuration that performs at least one function or operation.

1 through 4, the ventilator according to the embodiment of the present invention includes a housing 10, a pressure reducing valve 20, an air supply control valve 30, a flow control valve 40, an air supply passage 60, .

The housing 10 connects the oxygen (oxygen) of the oxygen tank (not shown) to the patient's respiratory organs. The housing 10 includes the pressure reducing valve 20, the air supply control valve 30, the flow control valve 40, (60) and the components described later, and a supply port (11) and a discharge port (12) are provided on both sides, respectively.

The housing 10 is connected to an oxygen tank (not shown) through a connection member such as a coupler and a supply port 11 to which oxygen is supplied is connected to an outlet 12 through which oxygen is discharged, And supplies oxygen to the oral cavity or nasal cavity of the patient through the respiratory mask 13.

5, the pressure reducing valve 20 is built in the housing 10 described above, and reduces the oxygen pressure of the oxygen tank supplied through the supply port 11 of the housing 10, Lt; / RTI > The pressure reducing valve 20 may include a pressure reducing cylinder 21, a valve piston 22, and a piston spring 23 as shown.

The decompression cylinder 21 has a valve seat 20a on one side of which an air supply port 24 for supplying compressed oxygen from the oxygen tank is formed and a hole for communicating oxygen to the air supply port 24, And a plurality of exhaust ports 25 and 26 communicating with the air supply port 24 and discharging oxygen supplied from the air supply port 24 are respectively formed. The exhaust ports 25 and 26 are connected to a first exhaust port 25 connected to the air supply control valve 30 through a first flow path D1 and a second exhaust port 25 connected to a passive control valve 70, And a second exhaust port 26 connected through a second exhaust port D2.

The valve piston 22 is movably incorporated through the oxygen pressure supplied to the interior of the decompression cylinder 21 to open and close the hole of the valve seat 20a provided in the air supply port 24. The valve piston 22 opens and closes the hole of the valve seat 20a through the valve head 22a provided on the connecting shaft as shown in the figure. The valve piston 22 is normally supported by a piston spring 23, which will be described later, to open the valve seat 20a. That is, the valve piston 22 normally maintains the original position by the elastic force of the piston spring 23, so that the valve head 22a is separated from the valve seat 20a to open the valve seat 20a as shown in the figure. Accordingly, the valve piston 22 supplies oxygen, which flows into the air supply port 24, to the first exhaust port 25 and the second exhaust port 26.

 However, when the pressure of the oxygen supplied to the air supply port 24 increases due to the ripple phenomenon or the like, the valve piston 22 moves the valve seat 20 by the increased oxygen pressure, do. At this time, the valve piston 22 moves together with the valve head 22a while compressing the piston spring 23 to shield the valve seat 20a, as shown in Fig. That is, the valve piston 22 closes the hole of the valve seat 20a by bringing the moved valve head 22a into close contact with the valve seat 20a. Thus, the valve piston 22 stops the supply of oxygen supplied to the first exhaust port 25 and the second exhaust port 26. [

The valve piston 22 returns to the original position together with the valve head 22a as the piston spring 23 expands again when the pressure of the oxygen supplied to the air supply port 24 is attenuated again to the steady state. At this time, the valve piston 22 reopens the valve seat 20a to supply the air supply port 24 again with the first exhaust port 25 and the second exhaust port 26 with oxygen.

Consequently, the valve piston 22 repeatedly opens and closes the valve seat 20a in accordance with the pressure of oxygen flowing into the air supply port 24, thereby reducing the pressure of oxygen. Accordingly, the first exhaust port 25 and the second exhaust port 26 can supply the carcassed oxygen.

Here, the valve piston 22 may be provided with a groove-shaped collecting portion 22b in the valve head 22a as shown in the figure. The collecting portion 22b collects oxygen to concentrate the pressure of oxygen to the valve head 22a. Therefore, the valve piston 22 can be easily moved by the collecting portion 22b when the pressure of the oxygen increases.

Referring to FIG. 6, the piston spring 23 elastically supports the valve piston 22. The piston spring 23 is inserted into the spring insertion groove 27 formed at the other side of the valve piston 22 and the other end is inserted into the outer peripheral surface of the first spring seat 28 protruding from the pressure reducing cylinder 21 So as to elastically support the valve piston 22. The piston spring 23 is expanded and contracted by the movement of the valve piston 22 as described above.

Referring to FIG. 7, the air supply control valve 30 controls the flow of the air supply by opening or closing the movement path while providing a movement path of oxygen provided from the pressure reducing valve 20 described above. The air supply control valve 30 may include a valve housing 31, a valve plunger 32, and a plunger spring 33.

The valve housing 31 includes a discharge orifice 34 for supplying oxygen from the pressure reducing valve 20 and a discharge orifice 35 for discharging oxygen supplied to the supply orifice 34 to the flow control valve 40, Of oxygen. At this time, as shown in FIG. 4, the supply orifice 34 is connected to the pressure reducing valve 20 through the first flow path D1 to receive oxygen. The discharge orifice 35 is connected to the flow control valve 40 through the third flow path D3 as shown in FIG.

The valve plunger 32 is movably installed in the valve housing 31 along the longitudinal direction and opens and closes the supply orifice 34 and the discharge orifice 35 while moving along the longitudinal direction of the valve housing 31. At this time, the valve plunger 32 is provided with a first O-ring 36 on the outer circumferential surface of the front end for opening and closing the supply and discharge orifices 34 and 35, and the front end is sealed.

The plunger spring 33 elastically supports the valve plunger 32 in the valve housing 31 and is supported by the valve plunger 32 on one side and a spring support And is supported by the jaws 37. The plunger spring 33 is installed to press the valve plunger 32 toward one side of the valve housing 31. That is, the valve plunger 32 is elastically supported and biased to one side. Thus, the valve plunger 32 is normally located at one side of the valve housing 31 as shown by the resilient force of the plunger spring 33 to keep the supply and discharge orifices 34, 35 open.

Referring to FIG. 8, oxygen is introduced into the supply control valve 30 through a first flow path D1 connecting the pressure reducing valve 20 and the supply orifice 34, and the introduced oxygen is discharged through a discharge orifice 35 to the flow control valve 40 via the flow control valve 40. When the valve plunger 32 flows into one side of the valve housing 31 and the oxygen of the pressure reducing valve 20 flows into the supply hole 38 described later via the sixth flow path D6, And moves while compressing the plunger spring 33 by the oxygen pressure in the supply hole 38. At this time, the valve plunger 32 shields the discharge orifice 35 to block oxygen supplied to the inside of the flow control valve 40 through the third flow path D3.

Here, the above-described supply hole 38 is connected to the operation control valve 101 via the sixth flow path D6 as shown in Fig. One end of the sixth flow path D6 is connected to the supply hole 38 of the air supply control valve 30 and the other end of the sixth flow path D6 is connected to the discharge port 115 of the operation control valve 101, To the operation control valve (101).

9, the flow control valve 40 may include a valve cylinder 41, a flow control valve member 42, a dial 43, and a connector 44.

The valve cylinder 41 has a supply hole 45 for supplying oxygen from the supply air control valve 30 and a discharge hole 46 for discharging the supplied oxygen and is provided between the supply hole 45 and the discharge hole 46 And the valve seat 47 is provided. The supply hole 45 is connected to a third flow path D3 connected to the discharge orifice 35 of the air supply control valve 30 and the discharge hole 46 is connected to the air supply flow path 60, (D4).

The flow control valve member 42 is vertically movably installed in the valve cylinder 41. The flow control valve member 42 is vertically moved by a rotational force provided by an external dial 43 to vary the gap with the valve seat 47, Thereby regulating the discharge flow rate of oxygen discharged to the hole 46. In other words, the flow control valve member 42 directly engages with the dial 43.

The dial 43 is rotatably fixed on the outside of the housing 10 and rotates to provide rotational force to the flow control valve member 42. At this time, a pointer is provided on the dial 43, and a weight or the like may be displayed on the surface of the outer housing 10 where the dial 43 is rotated. Accordingly, the dial 43 can be rotated and set so as to supply a suitable amount of oxygen according to the weight of the patient (not shown).

Here, the supply amount of oxygen is set in advance by data conversion of the amount of oxygen required according to body weight. Since this technique is well known in the art, a detailed description thereof will be omitted.

On the other hand, the connector 44 connects the dial 43 to the flow control valve member 42 to interlock the dial 43 and the flow control valve member 42 with each other.

Referring to FIG. 10, the connector 44 may include a rotary ring 48, a fastener, a fitting projection 50, and a projection holder 51.

The rotary ring 48 is integrally fixed to the flow control valve member 42 and rotates together with the flow control valve member 42. The fastener detachably fixes the rotary ring (48) to the flow control valve member (42).

Here, the fastener may be composed of a cutout portion 52, spacing protrusions 53 and 53a, and a rotary ring fastening member. The cut-out portion 52 is provided with an identical portion to the rotary ring 48 by cutting a part of the rotary ring 48 fitted to one side of the flow control valve member 42. The spacing protrusions 53 and 53a are formed to protrude from a part of the rotary ring 48 at which both ends of the cutout 52 are located, and are spaced apart from each other. The rotary ring fastening member is fastened to the spacing protrusions 53 and 53a to reduce the spacing width of the spacing protrusions 53 and 53a, that is, to reduce the inner diameter of the rotating ring 48, And is fixed to the valve member 42. At this time, the rotary ring fastening member may be formed of various types of bolts 54 as shown in the figure, and the fastening protrusions 53 and 53a are formed with fastening holes 55 through which the bolts 54 are screwed Can be mutually concluded.

According to such a rotary ring fastening member, the rotary ring 48 can be easily and detachably fixed to the flow control valve member 42 through screwing. Particularly, since the surface of the flow control valve member 42 and the bolts 54 of the rotary ring fastening member are not in direct contact with each other but are fixed to the rotary ring 48 in a noncontact manner, It is possible to prevent the occurrence of scratches in the form of grooves by the bolts 54 on the surface. That is, when the end of the bolt 54 is fastened to the outer circumferential surface of the flow control valve member 42 as a stop screw so that the outer circumferential surface is pressed, a groove can be formed by the end of the bolt 54, Is not directly contacted and is fastened to the spacing protrusions (53, 53a) located on the side of the flow control valve member (42), so that no groove is formed on the outer circumferential surface of the flow control valve member (42). Therefore, when the angle of the rotary ring 48 is to be adjusted, the bolt 54 is loosened again and then the angle of the rotary ring 48 is adjusted. Thereafter, the bolt 54 is fastened to the rotary protrusions 53, ) To the adjusted position.

If the bolt 54 is fastened to the flow control valve member 42 as a stop screw as described above, it is very difficult for the bolt 54 to be fastened again at a position close to the initially fastened position. This is because the end of the bolt 54 at the first time of fastening forms a groove in the outer circumferential surface of the flow control valve member 42 so that the bolt 54 is reinserted at a position close to the first fastening position, However, since the bolt 54 is provided laterally to the side of the flow control valve member 42 as described above and does not form a groove on the surface of the flow control valve member 42, Position.

On the other hand, a separate pad (not shown) may be interposed between the rotary ring 48 and the flow control valve member 42 in order to improve the fastening force and suppress the occurrence of scratches.

On the other hand, the fitting projection 50 of the connector 44 is vertically protruded from the one side of the rotary ring 48 toward the dial 43. At this time, it is preferable that the fitting protrusion 50 is formed on the second side wing 57 of the stopper, which will be described later, and the protrusion holder 51 is provided in the form of a groove inside the dial 43. Therefore, since the fitting protrusions 50 are inserted into the protrusion holder 51 and are fixed in a locked state to be mutually connected, not only are the connecting protrusions 50 easily connected, but also the rotational force generated when the dial 43 rotates is easily applied to the flow control valve member 42 / RTI >

The connector 44 may be provided with a stopper for controlling the rotation angle of the dial 43. The stopper is protruded from both sides of the rotary ring 48 and rotates together with the rotary ring 48 so as to make the rotation of the dial 43 come into contact with a peripheral fixing member located outside the rotary ring 48, And the first and second side wings 56 and 57, respectively. At this time, the fixing member can be applied, for example, to the air supply duct 61 formed inside the housing 10 to form the air supply duct 60 or the overflow unit 90 coupled to the air supply duct 61 .

The stopper may include a spacer, which is installed in any one of the first and second side wings 56, 57 contacting the fixing member, that is, the air supply pipe 61. In the embodiment of the present invention, the spacer is provided on the second side wing 57 as an example.

The spacer adjusts the separation distance between one side of the second side wing (57) and the air supply tube (61) and additionally controls the rotation angle of the dial (43) by the stopper. That is, the spacer is fixed to one side of the second side wing 57 so as to be protruded and fixed to the outer side of the second side wing 57, 90).

The spacer may be composed of, for example, a screw 58 and is engaged with a screw hole 58a formed in the second side wing 57 to be operated forward and backward. At this time, the screw 58 may be composed of a tongue bolt such that one side thereof protrudes while being smoothly moved forward and backward along the screw hole 58a.

Such spacers are formed by the operation of the user so that one end of the screw 58 protrudes along the screw hole 58a to the side of the air supply pipe 61 or the overflow unit 90 and is connected to the air supply pipe 61 or the overflow unit 90, The distance L between the second side wings 57 can be finely adjusted. Therefore, the spacer can adjust the separation distance by adjusting the separation distance L so as to deviate from the range of the set rotation angle of the dial 43. [ In other words, the rotation angle of the dial 43 is changed due to wear due to continuous use of the rotation, and an error of the rotation angle is generated due to manufacturing scattering and assembly scattering during the manufacturing process of the parts. At this time, the screw 58 is rotated so that the separation distance L of the second side wing 57 with respect to the air supply pipe 61 or the overflow unit 90 is shortened or increased, The range can be adjusted.

As a result, the spacer adjusts the error range according to the rotation angle of the dial 43 to prevent the oxygen supplied to the flow control valve 40, which is connected to the dial 43, from being supplied in excess or small amount And the amount of oxygen supplied to the flow control valve 40 can be controlled more precisely. Further, the spacer can easily adjust the amount of oxygen supplied to the flow control valve 40 to a desired flow rate by adjusting the above-described separation distance L. [ Therefore, since the flow control valve 40 can be precisely controlled through the spacer, the amount of oxygen supplied to the patient can be precisely controlled.

Here, the above-mentioned spacer is constituted by a plurality of screws 58, and when both the first and second side wings 56 and 57 are provided as shown by the solid line and the silver line, the bidirectional rotation angle of the dial 43 You can control them individually. That is, the screws 58 can control the rotation angles of the dies 43 during normal rotation and reverse rotation, respectively. Thus, the dial 43 can easily adjust the peak and the lowest point of the oxygen supplied to the flow control valve 40 through the screws 58.

The air supply passage 60 receives oxygen from the flow control valve 40 and guides the air to the outlet 12 of the housing 10. The air supply flow path 60 is formed through the air supply pipe 61 vertically installed in the discharge port 12 of the housing 10 and supplies oxygen to the respiratory mask 13 connected to the discharge port 12.

11, the ventilator according to the embodiment of the present invention includes an overflow unit (not shown) for discharging a part of oxygen guided to the discharge port 12 of the housing 10 through the air supply passage 60, 90).

The overflow unit 90 may be composed of a collection chamber 91 and a relief valve 92. The collection chamber 91 collects oxygen overflowing through the air supply flow path 60 and exhausts it to an exhaust hole 93 provided at one side. At this time, it is preferable that the collecting chamber 91 is provided at one side of the dial 43 as shown in the figure so that the interference of the dial 43 is prevented. The relief valve 92 is mounted on the exhaust hole 93 of the trapping chamber 91 and opens and closes the exhaust hole 93 by the pressure of oxygen trapped in the trapping chamber 91.

The relief valve 92 may include a valve disc 95, a disc support spring 96, and a second spring seat 94, for example. The valve disc 95 is constituted by a normal diaphragm and is assembled to a second spring seat 94 to be described later through a female and male screws 97a which are coupled to each other in an opposed state as shown, The exhaust hole 93 of the exhaust gas purification device 100 is shielded. The disc support spring 96 is constrained to the second spring seat 94 to prevent the release of the disc support spring 96 and the valve disc 95 is pressed through the other side of the disc support spring 96 to elastically support the valve disc 95 do.

The relief valve 95 may be provided with a spring adjuster 94 for adjusting the elastic force of the disc support spring 96 by moving the second spring seat 94. The spring adjuster 94 can be moved in the axial direction of the chamber case 91a or the housing 91a of the collecting chamber 91 so that the second spring seat 94 can be lifted And a screw member movably screw-connected to the base 10. That is, the spring adjuster 94 may be composed of a male screw formed on the outer peripheral surface of the second spring seat 94 and a female screw formed on the chamber case 91a.

The second spring seat 94 can rotate along the thread of the spring adjuster 94 as the spring adjuster 94 is composed of a screw member. At this time, the second spring seat 94 adjusts the elastic force of the disk support spring 96 by expanding and contracting the disk support spring 96 while ascending and descending. Thus, the disc supporting spring 96 is adjusted in the pressing force for pressing the valve disc 95. [

12, when the oxygen overflows within the collection chamber 91, the pressure inside the collection chamber 91 is raised and the valve disk 95 The exhaust hole 93 is opened and the overflowed oxygen is exhausted to the outside through the through hole H formed in the second spring seat 97 and the chamber case 91a. At this time, the valve disc 95 generates an audible sound that is "puffed" by the oxygen being exhausted.

Thereafter, when the internal pressure of the trapping chamber 91 is lowered to the set value level by the oxygen exhausted to the outside, the valve disc 95 returns to the original state due to the elastic restoring force of the disc support spring 96, And the exhaust hole 93 of the valve body 91 is shielded again.

The second spring seat 97 described above rotatably ascends and descends through the threaded spring adjuster 94 so that the valve disc 95 is operated when the pressure in the collecting chamber 91 is a set value, So as to adjust the elastic force of the disc spring 96. Therefore, the valve disc 95 is operated only at the set pressure.

4 and 9, the ventilator according to the embodiment of the present invention includes an operation for controlling the operation of the air supply control valve 30 in accordance with the pressure of oxygen supplied to the flow control valve 40 And may further include a control unit.

This operation control unit can be constituted by, for example, a bypass valve 100 and an operation control valve 101. [ The bypass valve 100 bypasses a part of the oxygen supplied to the flow control valve 40 through the air supply control valve 30 to the outside. The operation control valve 101 is provided with a part of the reduced pressure oxygen supplied from the pressure reducing valve 20 to the air supply control valve 30 while being operated by oxygen bypassed from the bypass valve 100, And controls the operation of the air supply control valve 30 through the decompressed oxygen.

The bypass valve 100 may include an oxygen filling chamber 102 and an inclined valve member 103. The oxygen filling chamber 102 is provided at a lower side of the flow control valve 40 and is provided with a communication hole 104 communicating with the flow control valve 40. The oxygen filling chamber 102 is connected to the bypass control valve 101 via a communication hole 104. The oxygen filling chamber 102 is filled with a part of oxygen supplied to the flow control valve 40 through the communication hole 104, (105). At this time, the bypass hole 105 is connected to the operation control valve 101 through the bypass flow passage 106.

Here, the oxygen filling chamber 102 may be integrally formed with the valve cylinder 41 of the flow control valve 40 as shown in the figure.

The inclined valve member 103 is installed inside the oxygen filling chamber 102 so as to be movable upward and downward and has a slope 107 formed therein to move to the inside of the communication hole 104, . The inclined valve member 103 may be formed in a conical shape as shown in the drawing, for example, and may have an inclined surface 107 formed on the outer circumferential surface thereof, and may be elastically supported by a support spring 108.

The support spring 108 has one end inserted into a spring end 108a protruding from the lower end of the inclined valve member 103 and the other end inserted into the oxygen filling chamber 102 from the spring- And the third spring seat 108b protruded to be protruded.

The inclined valve member 103 described above is attached to the flow control valve member 42 of the flow control valve 40 through the communication hole 104 so that the tip of the inclined surface 107 is in close contact with the flow control valve member 42, 43) and can be pressed against the flow control valve member (42) which is moved (lifted or lowered). Therefore, the inclined valve member 103 can be moved while compressing the support spring 108 by the urging force, or can be returned to the home position by the restoring force of the support spring 108.

Referring to FIG. 13, the operation control valve 101 includes a valve chest 110, a spool 111, and a spool spring 112.

The valve chest 110 is formed at one side with a bypass port 113 connected to the bypass flow path 106 to allow bypass oxygen of the bypass valve 100 to flow therethrough. The valve chest 110 is connected to the inlet port 114 through which the reduced pressure oxygen is supplied from the pressure reducing valve 20 to the other side through the supply control valve 30 and the reduced pressure oxygen of the introduced portion to the air supply control valve 30 And a discharge port 115 is provided in parallel. At this time, the inflow port 114 is connected to the second discharge orifice 34a of the air supply control valve 30 through the fifth flow path D5. The discharge port 115 is connected to the supply hole 38 formed at one side of the supply control valve 30 through the sixth flow path D6. The valve chest 110 may be provided with a vent orifice 116 communicating with the exhaust port 115 to exhaust a portion of the reduced pressure oxygen supplied to the exhaust port 115.

The spool 111 is installed in the valve chest 110 and communicates with the inlet port 114 and the outlet port 115 through a splitter on the outer circumferential surface while being moved by the bypass oxygen flowing into the bypass port 113 Or shut down. As shown in the drawing, the splitter may include a plurality of second O-rings 117 that are mounted on the outer circumferential surface of the spool 111 in a spaced apart manner, Any structure can be applied as long as it is formed so as to be capable of opening and closing the inflow port 114 and the discharge port 115.

The spool spring 112 elastically supports the spool 111 in the valve chest 110 and has one end and the other end which are respectively formed on the spool 111 and the valve chest 110, 118a.

14, when the oxygen in the air supply control valve 30 flows into the valve chest 110 along the bypass flow path 106 through the bypass valve 100, Communicates with and opens the inlet port 114 and the outlet port 115 which have been closed while being moved to one side. The open inlet port 114 supplies oxygen supplied from the air supply control valve 30 to the communicated exhaust port 115 through the fifth flow path D5 and supplies the oxygen supplied from the air supply control valve 30 to the sixth flow path D6 to the air supply control valve 30 again.

That is, the supplied oxygen is guided to the supply hole 38 of the air supply control valve 30 through the discharge port 115 opened together with the inlet port 114 to discharge the valve plunger 32 of the air supply control valve 30 Pressurized and moved to one side to close the supply and discharge orifices (34, 35).

Referring to FIG. 15, the ventilator according to the embodiment of the present invention is configured to supply oxygen supplied through the second flow path D2 connected to the second exhaust port 26 of the pressure reducing valve 20 to the air supply passage 60 And may further include a manual control valve 70 for supplying the gas immediately.

This manual control valve 70 may be constituted by a manual valve case 71, an opening and closing member 72, an elastic body 73 and a trigger 74.

The manual valve case 71 is provided with an input hole 75 which is connected to the second flow path D2 and is continuously supplied with reduced pressure oxygen from the pressure reducing valve 20, And an output hole 76 for discharging the introduced oxygen is provided. At this time, the output hole 76 is connected to the air supply passage 60 through the seventh passage D7.

The opening and closing member 72 is vertically movably installed in the manual valve case 71 to open and close at least one of the input hole 75 and the output hole 76.

The elastic body 73 elastically supports the opening and closing member 72 and can be formed of a coil spring as shown in the figure and has one side and the other side formed in the manual valve case 71 and the opening and closing member 72 5 spring seats 77, 77a.

The trigger 74 is rotatably provided on the lower side of the opening and closing member 72 on the basis of the hinge point H1 formed on the lower portion of the manual valve case 71 and rotatably supported by the elastic body 73, The member 72 is pressed upward to open the output hole 75.

The upper end of the hinge point H1 is brought into close contact with the lower end of the hinge point H1 and an inclined surface is formed at the close end of the hinge point H1 to press the opening and closing member 72 upward while sliding while rotating.

16, the trigger 74 has a cam groove 78 formed at an end portion of the trigger 74 which is in close contact with the opening and closing member 72. The cam groove 78 is formed at the lower end of the opening and closing member 72, A cam block 78a is formed.

17, when the user grasps the trigger 74 and rotates with respect to the hinge point H1, the opening / closing member 72 is moved upward by pressing and compressing the elastic body 73, Lt; / RTI > At this time, the oxygen that has flowed into the input hole 75 along the second flow path D2 and has been charged into the passive valve case 71 is discharged to the open output hole 76. Therefore, the output hole 76 supplies oxygen to the air supply passage 60 through the seventh passage D7.

Thereafter, when the user releases the gripping force of the trigger 74, the trigger 74 is restored to its original state by the restoring force of the compressed elastic body 73, and the output hole 76 that has been opened is closed.

Meanwhile, a sealing member 79 may be provided between the manual valve case 71 and the opening and closing member 72. The sealing material 79 is provided to prevent oxygen, which is normally input through the input hole 75, from being supplied to the output hole 76 side. At this time, the sealing member 79 may be installed with a washer, an O-ring, or the like, and one side thereof may be fixed to the manual valve case 71 or the opening and closing member 72.

Hereinafter, the operation of the artificial respiratory apparatus having the above-described configuration will be described with reference to the accompanying drawings.

First, in the ventilator according to the embodiment of the present invention, the housing 10 is connected to the oxygen tank through the supply port 11, and the respiratory mask 13 is held by the user at the discharge port 12 It is connected to the patient's respiratory system.

After the connection is completed, the user rotates the dial 43 to the set value according to the patient's condition, that is, his or her body weight, so that a proper amount of oxygen is supplied to the patient. That is, referring to the above-mentioned drawings and FIG. 17, the ventilator according to the embodiment of the present invention has a structure in which the oxygen of the oxygen tank is reduced to the inside of the housing 10 through the pressure reducing valve 20, . 5 and 6, the pressure reducing valve 20 reduces the pressure of the oxygen by repeatedly moving the valve piston 22 according to the oxygen pressure, thereby reducing the oxygen supplied to the air supply port 24 1 or the second exhaust port 25, 26, respectively. Accordingly, the pressure reducing valve 20 supplies the reduced pressure oxygen to the supply control valve 30 through the first flow path D1 as shown in FIG.

The oxygen supplied to the air supply control valve 30 is supplied to the flow control valve 40 along the third flow path D3 as shown in FIG. At this time, the oxygen supplied to the flow control valve 40 side is supplied to the air supply passage 60 along the fourth flow path D4 to be supplied to the patient through the respiratory mask 13.

A very small amount of oxygen supplied to the flow control valve 40 side flows into the bypass valve 100 as shown in FIG. 4 and flows toward the operation control valve 101 along the bypass flow path 106 Bypassed. At this time, as the amount of oxygen to be supplied gradually increases, the operation control valve 101 presses the spool 111 to slowly move the spool 111 to one side as shown in Fig. 14, The inlet port 114 and the outlet port 115 are opened.

On the other hand, the oxygen supplied to the supply control valve 30 through the first flow path D1 from the pressure reducing valve 20 before or during movement of the spool 111, as described above, 4 and 17 through the second discharge orifice 34a of the first control valve 30 to the fifth flow path D5 and thereafter flows through the fifth flow path D5 through the inflow of the operation control valve 101 Port 114 and is supplied to the operation control valve 101. When the inlet port 114 is communicated with the outlet port 115 as shown in FIG. 14, the oxygen introduced into the inlet port 114 is connected to the exhaust port 115 connected to the outlet port 115 as shown in FIG. Is again supplied to the supply hole 38 of the supply control valve 30 along the sixth flow path D6. At this time, the oxygen supplied to the air supply control valve 30 along the sixth flow path D6 is discharged through the discharge control valve 30 while pushing and moving the valve plunger 32 of the air supply control valve 30 as shown in FIG. Thereby closing the orifice 35. Thus, the air supply control valve 30 cuts off the oxygen supplied to the flow control valve 40 so that the breathing person can exhale (exhale) through the breathing mask 13. [

When the operation of the air supply control valve 30 is interrupted in this manner, the operation control valve 101 is operated so that the oxygen that has been charged into the valve chest 110 by the bypass valve 100 is biased as shown by the dotted line in FIG. Flows into the bypass valve 100 again via the path passage 106 and then is guided to the flow control valve 40 through the communication hole 104 of the bypass valve 100 and is connected to the flow control valve 40 Is guided to the air supply pipe (61) through the fourth flow path (D4) and discharged. At this time, the oxygen charged in the valve chest 110 is returned to the original position as shown in FIG. 13 by the spool spring 112 in the valve chest 110, so that the pressing force of the spool 111 The bypass port 113 of the valve chest 110 is gradually narrowed and overflowed inside the valve chest 110 and gradually discharged to the bypass port 113, And is supplied to the valve 100.

13, the exhaust port 115 and the vent orifice 116 of the valve chest 110 described above are communicated with each other as shown in the figure. At this time, as shown in Figs. 8 and 17, the oxygen supplied from the discharge port 115 of the valve chest 110 to the air supply control valve 30 through the sixth flow path D6 to pressurize the valve plunger 32 Is again returned to the discharge port 115 along the sixth flow path D6 as shown by the dotted line in Fig. 4, and is discharged to the outside through the orifice 116 of the orifice. Therefore, the supply control valve 30 is returned to the original state, that is, the state of FIG. 7, while the pressure of the oxygen which has been pressing the valve plunger 32 is released.

The supply orifice 35 is opened again as shown in Fig. 7 as the supply control valve 30 is released from pressure and the valve plunger 32 returns. 4, the air supply control valve 30 supplies oxygen to the flow control valve 40 and the bypass valve 100 through the third flow path D3 again to supply oxygen to the flow control valve 40 and the bypass valve 100, Perform the operation again.

The artificial respiratory apparatus according to the present invention repeats the above-described series of steps, that is, the state shown in FIG. 4 and the state shown in FIG. 17, and supplies oxygen to the patient or stops the breathing cycle .

On the other hand, the overflow unit exhausts the overcooked oxygen through the relief valve 92 as shown in FIG. 11 when oxygen is overcooked in the air supply pipe 61. Therefore, the overflow unit prevents excessive oxygen from being supplied to the human body.

On the other hand, when a failure of the above-described components occurs, that is, when a failure occurs in the supply air control valve 30, the operation control valve 101, the flow control valve 40, or the like, or a heart massage (CPR) , The user can manually supply oxygen to the patient by operating the manual control valve 70 to stop the automatic breathing and to switch manually.

A part of the oxygen supplied to the pressure reducing valve 20 is supplied to the manual valve case 71 through the second flow path D2 connected to the second exhaust port 26. [ At this time, the user grasps and rotates the trigger 74 of the manual control valve 70 as shown in Fig.

16, the oxygen charged into the input valve 75 connected to the second flow path D2 and filled in the manual valve case 71 is supplied to the seventh flow path D7 through the open output hole 76 And is supplied directly to the supply channel 60 and supplied to the patient.

Accordingly, the artificial respiratory apparatus according to the embodiment of the present invention can be used while supplying oxygen to the patient through the manual control valve 70 smoothly during emergency or heart massage due to failure of some parts.

On the other hand, the above-described operation control unit may be provided with the pressurizing chamber 140 as shown in Figs. The pressurizing chamber 140 is a closed housing having a filling space therein. The pressurizing chamber 140 is provided on the flow path connecting the bypass valve 100 and the operation control valve 101 to pressurize the oxygen supplied from the bypass valve 100 to the operation control valve 101.

The pressurizing chamber 140 is installed on the bypass flow path 106 connecting the bypass valve 100 and the operation control valve 101 as shown in Figs. At this time, the pressure chambers 140 may be installed in the bypass passage 106 as shown in the figure, but they may be sequentially arranged along the bypass passage 106, as shown in FIG. The pressure chamber 140 is connected to the bypass valve 100 through a flow path and the other side is connected to the operation control valve 101 through a flow path so that oxygen supplied through the bypass valve 100 flows through the bypass flow path 106, respectively.

When the oxygen in the bypass valve 100 is supplied again from the bypass valve 100 after the oxygen in the bypass valve 100 is filled, . At this time, since the internal pressure of the pressurizing chamber 140 is naturally raised by the overcirculation of oxygen, the oxygen previously charged into the pressurizing chamber 140 is discharged to the operation control valve 101. Oxygen discharged from the pressurizing chamber 140 to the operation control valve 101 passes through another pressurizing chamber 140 so that the pressure thereof is maintained or raised by overflowing and is supplied to the operation control valve 101. 9, even if only a small amount of oxygen is supplied through the bypass hole 105 of the bypass valve 100, the operation control valve 101 is operated with the oxygen pressure doubled by the pressurizing chamber 140 The inner spool 111 is smoothly operated as shown in FIGS. 13 and 14.

On the other hand, the flow rate of the oxygen, that is, the oxygen supplied to the breathing mask 13, which is guided inward as shown in Fig. 18, is controlled by the flow rate varying unit FV. As will be described later, the flow rate variable unit FV exhausts oxygen supplied to the respiratory mask 13 from the air supply passage 60 to the outside to stop the supply of oxygen, The oxygen is again supplied to the respiratory mask 13 by cutting off the exhaust gas. That is, the flow rate variable unit FV discharges the breathing mask 13 to the outside so as to allow the user to exhaust air at the time of the breath, and stops the supply of oxygen to the user, (13). Therefore, the flow rate of oxygen supplied to the respiratory mask 13 through the flow rate varying unit FV is controlled in the air supply flow path 60.

The reason why the flow rate variable unit FV exhausts the oxygen guided to the respiratory mask 13 through the air supply channel 60 during the exhalation is that the air is supplied to the respiratory mask 13 through the air supply channel 60 during the user's breath When oxygen is supplied, the carbon dioxide discharged from the human body can not be exhausted to the exhaust valve (check valve) of the respiratory mask 13 due to the pressure of oxygen supplied to the respiratory mask 13, It is provided to prevent this. Therefore, the user may not re-intake carbon dioxide at the time of exhalation when the flow rate variable unit FV is provided.

The flow rate variable unit FV may be configured to include, for example, a drain valve 160 and a switching valve 150 as shown in FIG. 18 and 19, the drain valve 160 has a drain hole 160a communicating with the air supply passage 60, and the drain valve 160a is guided through the air supply passage 60 by opening and closing the drain hole 160a At least a part of the oxygen is exhausted or the exhaust is shut off. The drain valve 160 may be communicated with the air supply passage 60 through the twelfth passage D12 as shown in the drawing. Alternatively, the drain valve 160 may be integrally attached to the air supply passage 60 to be communicable therewith. That is, the drain valve 160 is connected to the air supply passage 60 so as to receive oxygen from the air supply passage 60 and be exhausted through the drain hole 160a.

The drain valve 160 may include, for example, a drain body 161, an opening / closing bundle 163, and a drain spring 165 as shown in FIG. As shown in the drawing, the drain body 160a is formed on one side of the drain body 161, and the other side communicates with the air supply passage 60, and the oxygen of the air supply passage 60 is communicated with the other side. That is, the drain body 161 discharges oxygen in the air supply passage 60 flowing through the other side through the drain hole 160a on one side. The drain body 161 may have drain holes 160a formed at various positions, but it is preferable that the drain holes 160a are formed laterally as shown in FIG.

The opening / closing bundle 163 is movably housed in the drain body 161 as shown in Figs. 18 and 19. The opening / closing bundle 163 is moved by the oxygen of the switching valve 150 supplied to the drain body 161 to open / close the drain hole 160a, as shown in FIGS. It is preferable that the opening / closing bundle 163 is constituted by a poppet valve member as shown in the figure so as to open / close a drain hole 160a formed at the side of the drain body 161. [ The opening and closing batch 163 closes the drain hole 160a of the drain body 161 while being moved by the pressure of oxygen flowing into the drain body 161 through the switching valve 150 as shown in FIG. At this time, oxygen is introduced into the drain body 161 through the eleventh flow path D11 connected to the oxygen supply hole P2 of the switching valve 150.

The drain spring 165 is embedded in the drain body 161 to elastically support the opening / closing bundle 163 as shown in FIGS. 18 and 19. The drain spring 165 is compressed by the movement of the opening / closing bundle 163 as shown in Fig. When the oxygen supplied to the drain body 161 is shut off, the drain spring 165 is restored as shown in FIG. 21 to return the opening / closing bundle 163 to the original position. Therefore, the opening / closing bundle 163 opens the drain hole 160a of the drain body 161. [

The switching valve 150 provides the drain valve 160 with the oxygen provided by the pressure reducing valve 20 to operate the drain valve 160. The switching valve 150 may be supplied with oxygen directly from the pressure reducing valve 20 but may be supplied with the oxygen of the pressure reducing valve 20 through the air supply control valve 30 as shown in FIG. To the drain valve (160). 18, the supply control valve 30 supplies oxygen supplied from the pressure reducing valve 20 to the valve housing 31 through the additional hole 35a formed in the valve housing 31, (150). Accordingly, the switching valve 150 can interlock the supply control valve 30 and the drain valve 160.

Alternatively, the switching valve 150 may be supplied with the oxygen of the pressure reducing valve 20 through the manual control valve 70 as described above and provided to the drain valve 160 as shown in Figs. 22 and 23. Fig. Accordingly, the switching valve 150 may interlock the manual control valve 70 and the drain valve 160.

The switching valve 150 may comprise, for example, a needle housing 151, a needle 153 and a needle spring 155, as shown in Figs. 18 and 19. The needle housing 151 is connected to the above-described additional hole 35a of the air supply control valve 30 as shown in FIG. 10 and is connected to the pressure reducing valve 20 via the air supply control valve 30 The oxygen inflow hole P1 into which the oxygen to be supplied is introduced is formed on one side. That is, oxygen is introduced into the needle housing 151 through the oxygen inflow hole P1 connected to the tenth flow path D10. The needle housing 151 is connected to the oxygen inlet hole P1 to supply oxygen to the oxygen inlet hole P1 as shown by the arrow in FIG. P2 are provided on the other side. Accordingly, the needle housing 151 substantially supplies the oxygen of the pressure reducing valve 20 to the drain valve 160 to move the opening / closing bundle 163 of the drain valve 160.

The needle housing 151 is formed with a filling hole P3 through which the oxygen of the pressure reducing valve 20 supplied to the manual control valve 70 is charged as shown in Figs. 18 and 23. The needle housing 151 is formed with a guide hole P4 through which a part of the oxygen supplied to the filling hole P3 is guided as shown in the figure. At this time, the charging hole P3 and the guide hole P4 are connected to the above-described seventh flow path D7 for supplying the oxygen of the pressure reducing valve 20 from the manual control valve 70 to the air supply flow path 60 Oxygen is supplied. To this end, the manual control valve 70 includes an eighth flow path D8 and an eighth flow path D8 which branch from the seventh flow path D7 and are connected to the filling hole P3 of the needle housing 151, And a ninth flow path D9 branched from the guide hole P4 of the needle housing 151 and connected to the guide hole P4. Therefore, the filling hole P3 and the guide hole P4 are supplied with the oxygen of the manual control valve 70 through the eighth and eighth flow paths D8 and D9. However, the guide hole P4 may be supplied with oxygen directly from the seventh flow path D7 as described above.

19 and 23, the needle 153 is movably housed in the needle housing 151 and is opened and closed by opening and closing the oxygen inflow hole P1 and the oxygen supply hole P2 of the needle housing 151 . The needle 153 moves in the interior of the needle housing 151 by the pressure of oxygen flowing into the filling hole P3 of the needle housing 151 as shown in Fig. Thereby opening and closing the hole P2. At this time, the needle 153 opens and closes the oxygen inflow hole P1 or the oxygen supply hole P2 through the O-ring as the O-ring is installed on the outer circumferential surface as shown in the figure.

The needle 153 is normally fixed to the needle housing 151 at a predetermined position as shown in Fig. 19 so that the oxygen inflow hole P1 and the oxygen supply hole P2 are communicated with each other to be introduced into the oxygen inflow hole P1 And oxygen is supplied to the drain valve 160 through the oxygen supply hole P2. Therefore, the drain valve 160a is closed because the opening / closing bundle 163 is moved by the oxygen flowing into the drain body 161 through the eleventh flow path D11 as shown in the figure.

22 and 23, when the oxygen is introduced into the fill hole P3 and the guide hole P4 of the needle housing 151, the needle 153 is brought into contact with the oxygen of the fill hole P3 Thereby blocking the communication between the oxygen inflow hole P1 and the oxygen supply hole P2 of the needle housing 151 while moving. At this time, the needle 153 interrupts the communication between the oxygen inflow hole P1 and the oxygen supply hole P2 as the O-ring is positioned between the oxygen inflow hole P1 and the oxygen supply hole P2 as shown in the figure. However, the needle 153 communicates the guide hole P4 of the needle housing 151 and the oxygen supply hole P2 as shown by the arrow in Fig. 23, so that the oxygen, which flows into the guide hole P4, (P2) to the drain valve (160). Therefore, as shown in the drawing, oxygen is supplied to the drain body 161 through the eleventh flow path D11, so that the opening / closing bundle 163 is moved to close the drain hole 160a.

The needle spring 155 elastically supports the needle 153 inside the needle housing 151 as shown in Figs. 19 and 21, when the oxygen is not supplied to the filling hole P3 of the needle housing 151, the needle spring 155 supports the needle 153 through the self- . The needle spring 155 is compressed when oxygen is supplied to the filling hole P3 of the needle housing 151 to move the needle 153 as shown in Fig. 23, and the needle hole 151 of the needle housing 151 P3), the needle 153 is restored to the original shape and returned to its original position.

18, the air supply control valve 30 is opened to allow the oxygen of the pressure reducing valve 20 to flow through the air supply flow path 40 via the flow control valve 40, The supply orifice 34 of the supply control valve 30 flows into the discharge orifice 35 when the supply orifice 35 is supplied to the supply control valve 30 and is discharged to the additional hole 35a, Is introduced into the switching valve 150 through the tenth flow path D10. At this time, as shown in FIG. 19, the switching valve 150 is moved to the oxygen inflow hole P1 as the needle 153 is positioned at the home position and the oxygen inflow hole P1 and the oxygen supply hole P2 are communicated with each other Oxygen is directly supplied to the oxygen supply hole P2 to supply oxygen to the drain body 161 of the drain valve 160 through the eleventh flow path D11. Accordingly, the drain valve 160 moves the opening / closing bundle 163 by the oxygen flowing into the drain body 161, thereby shielding the drain hole 160a.

Therefore, the drain valve 160 can not exhaust the oxygen supplied to the air supply passage 60 through the flow control valve 40 as described above. Therefore, the air supply flow path 60 continuously supplies the oxygen of the flow control valve 40 to the respiratory mask 13 so that the user can take in air.

20, the discharge orifice 35 of the air supply control valve 30 is shielded together with the additional hole 35a so that the air supply flow path 60 is closed through the flow control valve 40, Oxygen can not be supplied to the drain body 161 of the drain valve 160 as shown in FIG. 21 because no oxygen is supplied to the oxygen inlet hole P1. The drain valve 160 opens the drain hole 160a formed in the drain body 161 while returning the opening / closing bundle 163 to the original position by the drain spring 165. [

At this time, as shown in Fig. 20, the operation control valve 101 is operated so that the oxygen charged therein, that is, the oxygen which is filled in the inside as shown in Fig. 14 and pressurized the spool 111, Flows into the bypass valve 100 through the bypass flow path 106 and then is supplied to the air supply flow path 60 by the flow control valve 40 and gradually exhausted through the air supply flow path 60. The drain body 161 is connected to the drain hole 160a as shown in FIG. 21 as the drain hole 160a is opened as described above, and the oxygen of the operation control valve 101, which is discharged through the air supply passage 60, . Of course, as shown in FIG. 20, the drain hole 160a discharges oxygen in the air supply passage 60 as oxygen of the air supply passage 60 flows into the drain body 161 through the twelfth passage D12 . Therefore, the air supply passage 60 does not provide oxygen to the breathing mask 13 at all. Accordingly, since the user does not supply oxygen to the respiratory mask 13 as described above, the vortex caused by the interference of the oxygen is prevented, The city does not re-intake carbon dioxide.

On the other hand, when the air supply control valve 30 is not operated due to a failure or the like, the manual control valve 70 is operated as described above for the respiration of the user (patient) D7 to supply the oxygen of the pressure reducing valve 20 to the air supply passage 60. [ At this time, as shown in FIGS. 22 and 23, the switching valve 150 is connected to the charging hole P3 of the needle housing 151 through an eighth flow path D8 branched from the seventh flow path D7, do. The switching valve 150 also receives the oxygen of the seventh flow path D7 through the ninth flow path D9 branched from the eighth flow path D8 to the guide hole P4.

The switching valve 150 moves the needle 153 embedded in the needle housing 151 by the oxygen introduced into the filling hole P3 as shown in FIG. P2. At the same time, the switching valve 150 communicates the guide hole P4 and the oxygen supply hole P2 to connect the oxygen introduced into the guide hole P4 to the drain valve 160 ). At this time, as the oxygen flows into the drain valve 160 through the eleventh flow path D11, the opening / closing batch 163 is moved again to close the drain hole 106a as shown in the figure. Therefore, the air flow passage 60 is not exhausted to the drain valve 160 because oxygen flowing into the air supply flow passage 60 smoothly supplies oxygen to the breathing mask 13. Thereby, the breathing mask 13 can continuously supply oxygen to the user who needs to intake air.

Consequently, as shown in Figs. 18 and 22, the flow rate variable unit FV operating in the above-described manner is configured such that oxygen is supplied to the air supply passage 60 by the operation of the air supply control valve 30 for intake of the user And closes the drain hole 160a of the drain valve 160 so that oxygen is supplied smoothly to the respiratory mask 13 when oxygen is supplied to the air supply passage 60 by the manual control valve 70. [ 20, the drainage passage 160a of the drain valve 160 is opened so that oxygen is not supplied to the respiratory mask 13 during the user's breath, To the outside.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And all changes to the scope that are deemed to be valid.

10: housing 11: supply port
12: Exit 13: Breathing mask
20: Reducing valve 21: Reducing cylinder
22: valve piston 23: piston spring
24: air supply port 25: first exhaust port
26: second exhaust port 27: spring insertion groove
28: first spring seat 30: supply control valve
31: valve housing 32: valve plunger
33: plunger spring 34: supply orifice
35: discharge orifice 36: first o-ring
37: spring support jaw 38: supply hole
40: Flow control valve 41: Valve cylinder
42: Flow control valve member 43: Dial
44: connector 45: supply hole
46: Exhaust hole 47: Valve seat
48: rotating ring 50: fitting projection
51: projection holder 52: incision part
53, 53a: spacing projection 54: bolt
55: fastening hole 56: first side wing
57: second side wing 58: screw
58a: screw hole L: separation distance
60: Supply air flow 61:
70: Manual control valve 71: Manual valve case
72: opening / closing member 73: elastic body
74: Trigger 75: input ball
76: output ball 77,77a: fifth spring seat
78: cam groove 78a: cam block
90: overflow unit 91: collection chamber
92: Relief valve 93: Exhaust hole
94: Spring adjuster 95: Valve disk
96: disk support spring 97: second spring seat
100: Bypass valve
101: Operation control valve 102: Oxygen filling chamber
103: Angle valve member 104:
105: Bypass ball 106: Bypass balloon
107: slope 108: support spring
108a: spring-loaded end 108b: third spring seat
110: valve chest 111: spool
112: spool spring 113: bypass port
114: inlet port 115: outlet port
116: Bant orifice 117: Second O-ring
118, 118a: fourth spring seat D1:
D2: first flow path D3: third flow path
D4: fourth flow path D5: fifth flow path
D6: sixth flow path D7: seventh flow path

Claims (14)

A housing having a supply port connected to the oxygen tank and having an outlet connected to the patient's mouth or nasal cavity;
A pressure reducing valve built in the housing and reducing pressure and supplying oxygen pressure of the oxygen tank supplied through a supply port of the housing;
An air supply control valve for controlling the air supply by opening or closing the movement path while providing a movement path of oxygen provided by the pressure reducing valve;
A flow control valve for controlling a flow rate of oxygen provided by an opening operation of the air supply control valve; And
And a supply air flow path for supplying oxygen from the flow control valve to the outlet of the housing,
And a flow rate changing unit for changing at least a part of the oxygen guided by the air supply flow path to the outside or blocking the exhaust air to vary the flow rate of oxygen guided through the air supply flow path. The flow control apparatus according to claim 1,
A drain valve having a drain hole communicating with the air supply passage and opening or closing a drain hole to exhaust at least a part of oxygen guided through the air supply passage or shut off exhaust; And
And a switching valve for supplying oxygen supplied from the pressure reducing valve to the drain valve to operate the drain valve. The exhaust gas purifying apparatus according to claim 2,
A drain body communicating with the air supply passage through the other side of the air supply passage and having the drain hole at one side thereof;
An opening / closing bundle movably installed in the drain body and being opened and closed by the oxygen of the switching valve supplied to the drain body, while opening / closing the drain hole; And
And a drain spring for elastically supporting the opening / closing bundle. 3. The switching valve according to claim 2,
A needle housing having an oxygen inlet hole through which oxygen supplied from the pressure reducing valve is formed and an oxygen supply hole communicating with the oxygen inlet hole to supply oxygen to the oxygen inlet hole to the drain valve;
A needle which is movably incorporated in the needle housing to open and close the oxygen inflow hole of the needle housing; And
And a needle spring for elastically supporting the needle. The method according to claim 1,
The flow rate varying unit includes:
A drain valve having a drain hole communicating with the air supply passage and opening or closing a drain hole to exhaust at least a part of oxygen guided through the air supply passage or shut off exhaust; And
And a switching valve for supplying oxygen to the drain valve to operate the drain valve,
Wherein the switching valve comprises:
An oxygen inlet hole through which oxygen supplied from the pressure reducing valve is formed and an oxygen supply hole communicating with the oxygen inlet hole to supply oxygen to the oxygen inlet hole to the drain valve, A needle housing having a charging hole and a guide hole into which oxygen of the supplied pressure reducing valve is introduced;
A needle which is movably incorporated in the needle housing and moves while opening and closing the oxygen inflow hole of the needle housing or communicating the oxygen supply hole and the guide hole of the needle housing; And
And a needle spring for elastically supporting the needle. delete delete delete The pressure reducing valve according to claim 1,
An exhaust port for discharging oxygen supplied from the air supply port is formed on the other side of the valve seat formed with a hole for communicating oxygen to the air supply port Decompression cylinder;
A valve piston movably installed inside the decompression cylinder to reduce the pressure of oxygen while opening and closing the valve seat of the air supply port; And
And a piston spring for elastically supporting the valve piston. The air conditioner according to claim 1,
A valve housing having a supply orifice for supplying oxygen from the pressure reducing valve and a discharge orifice for discharging the oxygen of the supply orifice and supplying the oxygen to the flow control valve;
A valve plunger movably incorporated in the valve housing to open and close the supply orifice or discharge orifice; And
And a plunger spring for elastically supporting the valve plunger. delete delete delete delete

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