CN211925381U - Integrated integrated oxygen supply valve - Google Patents

Abstract

The utility model discloses an integrated oxygen supply valve, which comprises a valve body, a valve cover, and a filling module, a flow adjusting module and a pulse oxygen supply module which are arranged on the valve body and the valve cover; oxygen in the gas tank passes through the filling module flow adjusting module and then is output by the pulse oxygen supply module; the pulse oxygen supply module comprises an air inlet unit, an air outlet unit and an air suction unit; the air inlet unit comprises a sixth air passage and a seventh air passage which are used for air inlet of the same air inlet source; the air outlet unit comprises an air outlet outer joint, an air outlet valve plate and an air outlet cavity which are arranged on the valve body; the air suction unit comprises an air suction outer joint, an air suction valve plate and an air suction cavity which are arranged on the valve cover, the air suction valve plate is provided with an air inlet convex nozzle communicated with the air outlet cavity, and an air inlet diaphragm used for opening and closing the air inlet convex nozzle is arranged above the air inlet convex nozzle; the utility model discloses a valve adopts integrated form integration mechanical structure, and it is simple convenient with simple to use to fill dress operation, can satisfy the demand of different flows, also can satisfy the requirement of different breathing modes.

Description

Integrated integrated oxygen supply valve

Technical Field

The utility model belongs to the technical field of equipment is made, a gaseous automatic control valve is related to, concretely relates to integrated form integration oxygen valve.

Background

In the production of oxygen supply equipment for plateau oxygen supply, underwater oxygen supply and people with dyspnea in hospitals, an oxygen tank is often adopted to supply oxygen to users through a gas control valve, high-pressure oxygen is required to be filled into the gas tank firstly in use, and then the high-pressure oxygen is separated from the gas tank to supply oxygen to the users. The existing gas cylinder oxygen supply structure is complex, comprises independent decompression, flow regulation and output modules, more conduits and leads, and the adopted gas supply mode is that the gas is continuously supplied with fixed flow, the output oxygen flow of the oxygen supply equipment is constant in the process of inspiration and expiration of people, only oxygen can be effectively utilized when people inhale, and the oxygen is completely discharged when the people exhale, thus causing great waste.

Chinese patent No. 201711022230.8, "a respiratory pulse valve", discloses a respiratory pulse valve, which uses a valve flap and a respiratory diaphragm to work together to sense the respiration of a user to realize pulse oxygen supply, thereby achieving the purpose of saving oxygen. When in use, the respiratory valve has poor air outlet sensitivity to a human body, a user can supply oxygen in a pulse mode only when the user is in a motion state or inhales air forcibly, and when the human body is in a static state or a sleep state or the valve body is in a horizontal position, the fault that air cannot be discharged or air cannot be discharged in a pulse mode often occurs; in addition, the pulse valve lacks the functions of pressure reduction and pressure stabilization and self-sealing filling, and the popularization and the application of multiple occasions are limited.

SUMMERY OF THE UTILITY MODEL

The utility model discloses an integrated form integration oxygen supply valve adopts whole mechanical parts to realize continuous and pulse dual mode oxygen suppliment down, and the internal integration voltage stabilizing module, fill dress module, has simplified the device structure, has made things convenient for user's use.

The technical scheme of the utility model as follows:

an integrated oxygen supply valve comprises a valve body, a valve cover, and a filling module, a flow regulating module and a pulse oxygen supply module which are arranged on the valve body and the valve cover; oxygen in the gas tank passes through the filling module flow adjusting module and then is output by the pulse oxygen supply module;

the pulse oxygen supply module comprises an air inlet unit, an air outlet unit and an air suction unit; the air inlet unit comprises a sixth air passage and a seventh air passage which are used for air inlet of the same air inlet source;

the air outlet unit (comprising an air outlet external joint, an air outlet valve plate and an air outlet cavity which are arranged on the valve body, wherein an air outlet convex nozzle communicated with a sixth air passage is arranged on the air outlet valve plate, and an air outlet diaphragm used for opening and closing the air outlet convex nozzle is arranged above the air outlet convex nozzle;

the air suction unit comprises an air suction outer joint, an air suction valve plate and an air suction cavity which are arranged on the valve cover, the air suction valve plate is provided with an air inlet convex nozzle communicated with the air outlet cavity, and an air inlet diaphragm used for opening and closing the air inlet convex nozzle is arranged above the air inlet convex nozzle; the air inlet diaphragm is positioned in the air inlet cavity, an adjusting elastic element is arranged above the air inlet diaphragm, and the air inlet cavity is communicated with an air passage of an air inlet external joint; the air suction unit is also provided with an air exhaust hole which is communicated with an air passage of the air inlet convex nozzle.

In the integrated oxygen supply valve, the seventh air passage is provided with the switching plate, so that the seventh air passage is closed and opened.

In the integrated oxygen supply valve, the filling module comprises an inflation connector arranged at the air inlet end of the valve body, a first air passage penetrating through the air inlet end is arranged in the air inlet end, and a tank body connector is arranged on the outer ring of an outlet of the first air passage; the inflation connector comprises an inflation nozzle and a plugging chamber, the inflation nozzle is communicated with the plugging chamber through a second air passage, and a one-way plug is arranged in the plugging chamber to realize plugging or opening of the second air passage; the second air passage is communicated with the interior of the first air passage.

In the integrated oxygen supply valve, a third air passage is arranged inside the air inlet end of the valve body, the third air passage is perpendicular to and communicated with the first air passage, and a pressure gauge is connected to the outside of the third air passage.

In the integrated oxygen supply valve, the one-way plug comprises a conical head, a transition section and a conical tail, and a second conical surface matched with the conical head is arranged at one end, close to the second air passage, of the plugging chamber.

In the integrated oxygen supply valve, the oxygen supply valve also comprises a pressure reducing and stabilizing module arranged inside the valve body;

the pressure reducing and stabilizing module comprises an air inlet joint, an air inlet plate, an air outlet plate and a pressure reducing chamber cover plate which are sequentially arranged from bottom to top; a fourth air passage is arranged in the air inlet joint, a fifth air passage is arranged in the air outlet plate, and an upper port of the fourth air passage and a lower port of the fifth air passage are arranged in a staggered manner; a pressure reducing cavity is arranged between the pressure reducing chamber cover plate and the upper end surface of the air outlet plate, and the fifth air passage is communicated with the pressure reducing cavity; an elastic element is arranged between the air inlet plate and the air outlet plate, and the air outlet plate moves up and down under the action of the elastic element and the internal pressure of the decompression cavity, so that the upper port of the fourth air passage is opened or closed by the lower end face of the air outlet plate.

In the integrated oxygen supply valve, the upper end of the air inlet connector is provided with the convex air faucet, the lower end face of the air outlet plate is provided with the sealing rubber mat, and the sealing rubber mat seals the fourth air passage when touching the convex air faucet.

In the integrated oxygen supply valve, the fourth gas channel comprises an upper straight hole and a lower straight hole which are communicated with each other, and the upper straight hole and the lower straight hole are arranged in a staggered manner in the horizontal direction.

In the integrated oxygen supply valve, the flow regulating module comprises a second valve body and a gear ring which synchronously rotate around the valve rod, the second valve body is provided with a plurality of throttling holes and bypass holes, the decompression chamber cover plate is provided with a sixth air passage corresponding to the throttling holes in position, and the sixth air passage and the seventh air passage are respectively communicated with the air inlet source through the throttling holes and the bypass holes;

in the integrated oxygen supply valve, a spring snap ring is arranged at the position, close to the upper end surface of the pressure reduction chamber cover plate, on the valve rod; the pressure reduction chamber cover plate is provided with a positioning component, and the upper end surface of the second valve body corresponding to the positioning component is provided with a groove.

The utility model has the advantages of as follows:

1. the utility model discloses a valve adopts integrated form integration mechanical structure, by filling dress function, decompression steady voltage function, pulse/direct current function height integrated, is different from the split type of other types of valve, has saved connection interface and connecting pipe simultaneously, has reduced occupation space. Structurally, only flow control switch and pulse change over switch do not have and fill dress switch, air supply switch and power supply, only need the lug connection when filling the dress and fill the dress pipe, only need shift gear and action pulse switch according to demand action flow when using gas and shift gear, it is simple convenient with the use to fill dress operation, can satisfy the demand of different flows, also can satisfy the requirement of different breathing modes.

2. The utility model discloses the valve can be opened and close the valve according to user's respiratory frequency in step under the pulse mode for carry out oxygen when breathing in and carry, and close oxygen when exhaling and carry, thereby reach the purpose of practicing thrift the oxygen quantity, integration compact structure is reliable simultaneously, has made things convenient for user's use. The pulse oxygen supply mode is based on the dynamic change of the upper surface pressure and the lower surface pressure of the inspiration and expiration double-diaphragm sensing diaphragm, and the corresponding actions of the two ports of the air outlet external joint, the air inlet external joint and the air exhaust hole are matched, the sensitivity of the sensing detection of weak inspiration signals of a human body and the reliability of later-period response are improved, the pulse state air outlet time is completely synchronous with the human body air inlet time, the oxygen outlet time and the oxygen outlet amount can be effectively guaranteed no matter in a motion state, a sleep state or in the same valve body direction, the problems of false triggering and discontinuous oxygen supply cannot occur, and the purposes of saving oxygen and being suitable for different application occasions are achieved.

3. The utility model discloses a fill dress module adopts integrated structure to realize inflating of high pressurized air source, the normal use of air supply closure and gas pitcher, has characteristics such as compact structure, hookup part are few to have pressure monitoring table, the monitoring of convenience of customers residual capacity in to the gas pitcher. The filling module is provided with a self-sealing structure, and after filling is completed, as long as the internal pressure is greater than the external atmospheric pressure, the sealing ring on the plug can be effectively sealed with the connecting structure, so that the operation of a manual switch is left, and the sealing effect is improved.

4. The utility model discloses decompression voltage stabilizing module is based on the pressure phase balance mode of elastic element and inside gas, high-pressure gas's decompression and constant voltage output have been realized automatically, gear adjustable throttle structure has been increased at the output simultaneously, the regulation of output air current size has been realized, compact structure has, adapting unit characteristics such as few, user's use has been made things convenient for, the device structure has been simplified, simultaneously through the model of changing elastic element and change pressure and the air current parameter that the gear can change the output, the special application of different occasions has been satisfied.

Drawings

FIG. 1 is a schematic view of the integrated oxygen supply valve of the present invention;

FIG. 2 is a schematic view of the composition principle and structure of the unidirectional inflating joint of the present invention;

FIG. 3 is a schematic view of the connection principle and structure of the unidirectional inflation joint and the air source of the present invention;

FIG. 4 is a schematic structural view of the one-way plug of the present invention;

FIG. 5 is a schematic diagram of the operation of the filling module of the present invention when used for inflating from an external air source;

FIG. 6 is a schematic diagram of the operation of the filling module of the present invention when the gas is supplied from the gas tank;

FIG. 7 is a schematic view of the pressure reducing and stabilizing valve assembly and the working principle when the air passage is opened according to the present invention;

fig. 8 is a schematic view of the working principle of the air passage of the present invention when closed;

fig. 9 is a schematic arrangement diagram of the fourth air passage and the fifth air passage in the first embodiment;

fig. 10 is a schematic arrangement diagram of a fourth air passage and a fifth air passage in the second embodiment;

FIG. 11 is a schematic view of the oxygen supply module structure and the principle of the continuous air outlet state;

fig. 12 is a schematic structural diagram of the flow rate adjusting module of the present invention;

FIG. 13 is a schematic view of the flow conditioning module orifice and bypass hole locations of the present invention;

fig. 14 is a schematic view of the oxygen supply module according to the present invention in a pulse expiration state;

fig. 15 is a schematic diagram of the oxygen supply module according to the present invention in a pulse inspiration state;

fig. 16 is a schematic view illustrating the switching plate according to the present invention when the seventh air passage is closed;

fig. 17 is a schematic view illustrating the switching plate according to the present invention when the seventh air passage is opened;

the reference signs are: 1-one-way plug; 2-an inflation joint; 3, a pressure reducing and stabilizing module; 4-a flow regulation module; 5-a pulse oxygen supply module; 6-valve body; 7-valve cover; 8-a filling module; 11-an air intake unit; 12-an air outlet unit; 13-a suction unit; 14-a switch board; 15-a suction valve plate; 16-pulse orifice; 17-switching plate plectrum; 18-an air outlet external joint; 19-an air-breathing external joint; 20-air outlet membrane; 21-a getter membrane; 22-adjusting the elastic element; 25-air elimination hole; 31-an air outlet cavity; 32-an aspiration lumen; 33-a suction convex nozzle; 34-air outlet convex nozzle; 35-an air outlet valve plate; 36-suction pipe; 37-an air outlet pipe; 38-air outlet grooves; 41-valve stem; 42-gear ring; 43-snap ring; 44-a second valve body; 45-a positioning assembly; 46-opening a hole; 47-a bypass hole; a 48-orifice; 49-plectrum; 100-an air inlet end; 101-a first airway; 102-a second airway; 103-a third airway; 105-an inflation nozzle; 106-blocking the cavity; 107-a gas-filled tube; 108-a gas tank; 109-tank interface; 110-pressure gauge; 111-a first external thread; 150-a first taper; 151-sealing ring; 152-a cone head; 153-a first step; 154-second step; 155-third step; 156-cone tail; 158-second tapered surface; 159 — a splice core; 160-a connector housing; 161-second external thread; 162-a retainer ring; 163-gas filled pipe joints; 301-air inlet plate; 302-gas outlet plate; 303-pressure reduction chamber cover plate; 305-a fifth airway; 306-a sixth airway; 307-seventh airway; 308-a reduced pressure chamber; 309-a resilient element; 310-an air inlet joint; 311-annular boss; 312-an annular cavity; 313-sealing the rubber mat; 314-convex air tap; 315-straight hole above; 316, straight hole.

Detailed Description

As shown in fig. 1, the integrated oxygen supply valve of the present invention comprises a valve body 6, a valve cover 7, and a filling module 8, a pressure reducing and stabilizing module 3, a flow regulating module 4 and a pulse oxygen supply module 5 which are installed on the valve body 6 and the valve cover 7; oxygen in the gas tank 108 passes through the filling module 8, the pressure reducing and stabilizing module 3 and the flow regulating module 4 and then is output by the pulse oxygen supply module 5. The following are introduced separately:

filling module

The filling module 8 comprises a valve body 6 and an inflation connector 2 arranged at an air inlet end 100 of the valve body, a first air passage 101 penetrating through the air inlet end 100 of the valve body is arranged in the air inlet end 100, and a tank body interface 109 is arranged on the outer ring of an outlet of the first air passage 101; the tank body interface 109 is matched with an interface of a gas tank, and is connected with and tightly presses an O-shaped ring through a standard threaded interface, so that the sealing property and the firmness of the tank body interface are ensured. The outer ring of the tail end of the inflation connector 2 is provided with a first external thread 111, and the position corresponding to the valve body 6 is provided with an internal thread, so that the inflation connector 2 can be detachably connected to the valve body 6, and sealing is realized.

The inflation connector 2 comprises an inflation nozzle 105 and a plugging chamber 106, and the inflation nozzle 105 is used for connecting an inflation pipe 107 of a high-pressure air source. The charging connector 105 is communicated with the blocking chamber 106 through the second air passage 102, and a one-way plug 1 is arranged in the blocking chamber 106 to realize the closing and opening of the second air passage 102. The second air passage 102 is communicated with the interior of the first air passage 101; the blocking chamber 106 and the one-way plug 1 mainly fill the high-pressure gas in the gas filling pipe 107 into the gas tank 108, and the self-closing of the second gas passage 102 is realized after the gas filling pipe 107 is detached.

In a preferred embodiment, the inner diameter of the first air passage 101 is larger than that of the second air passage 102, and the second air passage 102 and the first air passage 101 are perpendicular to each other in space position, so that the installation of the air tank 108 and the inflation tube 107 is facilitated.

As a further preferred embodiment, a third air passage 103 is arranged inside the air inlet end 100 of the valve body, the third air passage 103 is perpendicular to and communicated with the first air passage 101, a pressure gauge 110 is connected to the outside of the third air passage 103 through threads of an airtight structure, and the pressure gauge is used for monitoring residual gas in a gas tank 108 and reminding a user of filling when the pressure is insufficient. The third air passage 103 and the second air passage 102 are respectively disposed at both sides of the first air passage 101, which facilitates installation and fixation of the pressure gauge 110. The pressure gauge 110 is directly communicated with the storage tank to display the oxygen pressure in the storage tank in real time. The pressure value needs to be observed during filling, and when the maximum use pressure (20 MPa) is reached, the oxygen filling source needs to be closed; the pressure value is observed when the gas is used, so as to ensure whether the gas can be used continuously.

As shown in fig. 2-4, the one-way plug 1 includes a conical head 152, a transition section and a conical tail 156, wherein the transition section includes a first step 153, a second step 154 and a third step 155 sequentially arranged from the conical head 152 to the conical tail 156. The outside of the coupling core 159 near one end of the closed chamber 106 is provided with a first male screw 111 for fixing the coupling to a valve body or the like. The part of the blocking chamber 106 close to the second air passage 102 is provided with a second conical surface 158 matched with the conical head 152, and the size and the conical angle of the second conical surface 158 and the conical head 152 are consistent, so that the second air passage 102 can be closed when the two contact under the pressure. In order to further enhance the blocking effect, a sealing ring 151 is disposed at a portion of the transition section near the conical head 152, and the sealing ring 151 is in close contact with the second conical surface 158 under pressure.

In fig. 2, a retainer ring 162 is arranged at a position of the plugging chamber 106 far away from the second air passage 102, the one-way plug 1 is plugged between the second conical surface 158 and the retainer ring 162, and a gap is formed between the retainer ring 162 and the conical tail 156, so that the one-way plug 1 can move back and forth in the plugging chamber 106. The one-way plug 1 is made of metal material, and the diameter of the cone head 152 is smaller than that of the cone tail 156.

Further, the outer ring of the joint core 159 is provided with a joint housing 160, and the joint housing 160 is sleeved on the joint core 159 and can rotate around the outer ring of the joint core 159, and the working principle of the joint housing is similar to that of the existing movable air joint or cable joint. The exterior of the joint housing 160 is provided with a second external thread 161. An inflation tube connector 163 is disposed on the exterior of inflation tube 107, and inflation tube connector 163 is movably coupled to second external thread 161. The charging connector 105 is movably connected with the charging tube 107, and a first conical surface 150 matched with the head of the charging tube 107 is arranged inside the charging connector 105. The head of the inflation tube 107 is generally a conical surface or similar curved surface structure with the same size and cone angle, and is connected with the internal thread inside the inflation tube connector 163 by the second external thread 161 during inflation, so that the first conical surface 150 is tightly contacted with the head of the inflation tube 107 to achieve the effect of sealing connection, a high-pressure air source is inflated to the air tank 108 through the one-way inflation connector, and the air is not leaked during filling.

The working principle of the gas control valve filling module is described below by taking an oxygen supply device as an example.

As shown in fig. 5 and 6, before oxygen is used by human body, the gas filling tube 107 is required to fill the gas tank 108 with a sufficient amount of high-pressure oxygen through the filling module, and the head of the gas filling tube 107 is in sealed butt joint with the gas filling nozzle 105. Because the external oxygen pressure is higher than the pressure in the gas tank 108, the unidirectional plug 1 is opened to supplement gas into the gas tank 108; at the moment, oxygen enters the blocking chamber 106 through the second air passage 102, the one-way plug 1 does not play a blocking role after being flushed by high-pressure gas, the gas enters the second air passage 102 through the first air passage 101 to inflate the gas tank 108, and meanwhile, the inflation pressure can be monitored through the pressure gauge 110; when the inflation pipe 107 is connected with the one-way inflation connector, under the action of high-pressure gas, the pressure of the conical head 152 of the one-way plug 1 is greater than that of the conical tail 156, so that the one-way plug 1 moves backwards horizontally, and the high-pressure gas flows forwards along gaps around the one-way plug 2 and enters the gas tank 108 through the first gas channel 101 to be stored.

As shown in fig. 6, when the internal gas tank 108 is filled to a certain pressure, since the diameter of the conical head 152 is smaller than that of the conical tail 156, the pressure of the conical tail 156 is greater than that of the conical head 152, so that the one-way choke plug 2 moves horizontally forward, and the sealing ring 151 is in sealing contact with the second conical surface 158 inside the gas charging connector 2 to block the second gas channel 102; or when the inflation reaches the set amount, the inflation tube 107 is directly pulled out, so that the one-way plug 2 horizontally moves forward to plug the second air passage 102, and the rapid inflation and sealing of oxygen or other gases are realized. The outlet at the upper end of the first air passage 101 is directly communicated with the air supply interface or communicated with the air supply interface of the user through the pressure reduction module, and when the air is needed, the air is supplied to the user through the outlet at the upper end of the first air passage 101 by the air tank 108.

Pressure reducing and stabilizing module

As shown in fig. 7 and 8, the decompression and pressure stabilization module 3 includes an air inlet joint 310, an air inlet plate 301, an air outlet plate 302, a decompression chamber cover plate 303 and a flow rate adjustment unit 4, which are sequentially arranged from bottom to top; the fourth air passage 304 is arranged inside the air inlet joint 310, the fifth air passage 305 is arranged inside the air outlet plate 302, and the upper port of the fourth air passage 304 and the lower port of the fifth air passage 305 are arranged in a staggered manner, so that the fourth air passage 304 and the fifth air passage 305 cannot be directly communicated.

A sixth air passage 306 is arranged on the decompression chamber cover plate 303, a decompression cavity 308 is arranged between the decompression chamber cover plate 303 and the upper end face of the air outlet plate 302, and the fifth air passage 305 and the sixth air passage 306 are both communicated with the decompression cavity 308; an elastic element 309 is arranged between the air inlet plate 301 and the air outlet plate 302, and the air outlet plate 302 moves up and down under the action of the elastic element 309 and the internal pressure of the decompression cavity 308, so that the upper port of the fourth air channel 304 is opened or closed by the lower end face of the air outlet plate. The resilient member 309 is a spring.

Further, a sealing rubber gasket 313 is arranged on the lower end face of the air outlet plate, and the sealing rubber gasket 313 can better seal the fourth air channel 304. The sealing rubber pad 313 is rectangular or trapezoidal in cross section, and the sealing rubber pad 313 is bonded in the groove after the groove is formed in the lower end face of the air outlet plate in advance.

Further, the air outlet plate 302 and the air inlet plate 301 are both flange-type structures, an annular concave cavity 312 is arranged inside the air outlet plate 302, an annular boss 311 is arranged on the outer ring of the air inlet plate 301, the elastic element is arranged between the annular boss 311 and the annular concave cavity 312, and the annular boss 311 and the annular concave cavity 312 position the elastic element, so that the elastic element is ensured to keep the upper position and the lower position and output stable elastic force.

The lower part of the pressure reduction chamber cover plate 303 is of a hollow groove structure, can be a circular groove or a square groove, and is matched with the external structure of the air outlet plate 302, and the number of the hollow grooves is two, so that on one hand, a pressure reduction chamber 308 is formed by the upper surface of the hollow groove and the upper end surface of the air outlet plate 302; on the other hand, the up-and-down movement of the air plate 302 is provided for providing reference positioning, so that the outer ring of the air plate 302 moves up and down along the inner surface 307 of the hollow groove body, and has higher position precision, the position precision between the lower end surface of the air outlet plate and the upper port of the fourth air channel 304 is ensured, and the air flow is smoothly opened or closed.

Two specific embodiments are given below to illustrate how the present invention can realize the voltage stabilization operation.

As shown in fig. 9, in the first embodiment, the upper end of the air inlet joint 310 is provided with a convex air tap 314, the upper end of the fourth air passage 304 is provided with the convex air tap 314, the fourth air passage 304 is a straight hole which is arranged in a staggered manner with the fifth air passage 305, and as can be seen in fig. 7 and 8, when the lower end surface of the air outlet plate does not contact the convex air tap 314, the air flow can normally flow from the fourth air passage 304 into the fifth air passage 305; when the sealing rubber pad 313 at the lower end of the air outlet plate touches the convex air faucet 314, the fourth air channel 304 can be closed.

As shown in fig. 10, in the second embodiment, the fourth air passage 304 includes an upper straight hole 315 and a lower straight hole 316 communicating with each other, wherein the upper straight hole 315 and the lower straight hole 316 are arranged in a staggered manner and are kept at a distance in the horizontal direction. When the lower end surface of the air outlet plate does not contact the convex air tap 314, the air flow can normally flow into the fifth air passage 305 from the fourth air passage 304; when the lower end surface of the air outlet plate touches the convex air faucet 314, the fourth air channel 304 can be closed.

The working principle of the utility model is as follows:

as shown in fig. 7, when the human body uses oxygen, the oxygen in the air tank enters the air inlet joint 310 through the first air passage 101, wherein the aperture of the fourth air passage 304 in the air inlet joint 310 is smaller than the aperture of the first air passage 101, and after the fourth air passage 304 is throttled, the oxygen reaches the interior of the decompression chamber 308 through the fifth air passage 305. If the orifice 48 of the second valve body 44 is directly opposite the sixth air passage 306, the air flow is throttled by the orifice 48 and then output along the sixth air passage 306.

When the pressure in the decompression chamber 308 reaches the set pressure of 0.3MPa, the atmospheric pressure (downward direction) applied to the upper surface of the gas outlet plate 302 is greater than the supporting force (upward direction) of the elastic element 309 on the top surface of the annular cavity 312 of the gas outlet plate 302, so that the gas outlet plate 302 moves vertically downward against the supporting force of the elastic element, the upper port of the fourth gas passage 304 is closed by the lower end surface of the gas outlet plate, and the gas coming from the fourth gas passage 304 is blocked (as shown in fig. 8). The internal pressure of the decompression chamber 308 can be adjusted by replacing elastic elements with different parameters, so as to adapt to different users and occasions.

When the pressure in the decompression chamber 308 is lower than the set pressure by 0.3MPa, the force applied to the upper surface of the gas outlet plate 302 (vertically downward) is smaller than the supporting force of the elastic element 309 on the gas outlet plate 302 (vertically upward), and the gas outlet plate 302 moves vertically upward, so that the upper port of the fourth air passage 304 is separated by the lower end surface of the gas outlet plate (as shown in fig. 7), and oxygen again flows from the fourth air passage 304, through the fifth air passage 305, enters the decompression chamber 308, and is output through the orifice. Therefore, the device can realize the reduction of the pressure value in the decompression cavity 308 and the stable pressure output according to the dynamic critical change of the stress value of the air outlet plate 302 in the air using process. The oxygen in the decompression chamber 308 flows out to the subsequent port through the sixth air passage 306 after passing through the adjustable orifice. The utility model discloses whole mechanical parts that adopt have realized steady voltage and decompression function to the flow is adjustable, has satisfied the application of special occasion.

Flow regulating module

11-13, the flow regulating module 4 includes a second valve body 44 and a gear ring 42 which rotate synchronously about the valve stem 41, and the second valve body 44 is provided with a plurality of throttle holes 48 and a plurality of bypass holes 47; the flow regulating module is used for outputting the decompressed oxygen through the throttling hole 48 so as to meet the requirements of different user gas flow, and the user can regulate the flow gear through the gear ring 42. The pressure reduction chamber cover 303 is provided with a sixth air passage 306 corresponding to the position of the orifice 48, and the second valve body 44 of the present invention is provided with the orifice 48 having a different aperture, so as to adjust the size of the air flow passing through the sixth air passage 306. The bypass hole 47 is a through hole with the same diameter and size corresponding to the position of the seventh air passage 307, and when the position of the retainer ring 42 is adjusted to different positions, where the throttling hole 48 corresponds to the sixth air passage 306, the bypass hole 47 is correspondingly adjusted to the seventh air passage 307. The oxygen in the decompression chamber 308 passes through the orifice 48 and then flows out to the subsequent port through the sixth air passage 306, and also flows out to the corresponding subsequent port through the bypass hole 47.

A snap ring 43 is provided on the valve stem 41 in close contact with the upper end surface of the pressure reduction chamber cover 303, so that the second valve body 44 can be rotated in close contact with the end surface of the pressure reduction chamber cover 303, the orifice 48 is in close contact with the sixth gas passage 306, and the bypass hole 47 is in close contact with the seventh gas passage 307. The pressure reduction chamber cover plate 303 is provided with a positioning component 45, and the upper end face of the second valve body 44 at the position corresponding to the positioning component 45 is provided with a groove; the positioning assembly 45 is a conventional spring-ball assembly, with the balls corresponding to the grooves. Because the ball can be conveniently clamped into the gear groove or rolled out from the groove, overlarge resistance can not be generated when the valve rod 41 is rotated, and the adjustment is convenient and labor-saving.

The positions, corresponding to the sixth air passage 306 and the seventh air passage 307, of the gear ring 42 are provided with the open holes 46, so that the sixth air passage 306 and the seventh air passage 307 can penetrate through the open holes, the edge of the gear ring 42 is provided with the shifting piece 49, when the shifting piece 49 is shifted, the second valve body 44 and the gear ring 42 synchronously rotate around the valve rod 41, the throttling holes 48 with different apertures are opposite to the sixth air passage 306, the bypass holes 47 are opposite to the seventh air passage 307, and meanwhile, the balls of the positioning assembly 45 just reach the corresponding groove positions, and positioning is achieved.

Four, pulse oxygen supply module

As shown in fig. 11 to 15, the pulse oxygen supply module 5 includes an inlet cell 11, an outlet cell 12, and an inlet cell 13;

the air inlet unit 11 comprises a sixth air passage 306 and a seventh air passage 307 which are used for air inlet by the same air source, wherein the sixth air passage 306 and the seventh air passage 307 are communicated through the same air source, namely a decompression chamber 308, so that the sixth air passage 306 and the seventh air passage 307 are ensured to have the same pressure. Switching plate 14 is disposed on seventh air duct 307 to close and open seventh air duct 307, wherein an air outlet of seventh air duct 307 is disposed above air outlet membrane 20, and the pressure of the air flow output from seventh air duct 307 can act on the upper end surface (back surface) of air outlet membrane 20.

The air outlet unit 12 comprises an air outlet external joint 18, an air outlet valve plate 35 and an air outlet cavity 31 which are arranged on the valve body; the air outlet valve plate 35 is provided with an air outlet convex nozzle 34 communicated with the sixth air channel 306, and an air outlet diaphragm 20 for opening and closing the air outlet convex nozzle 34 is arranged above the air outlet convex nozzle 34; the air outlet diaphragm 20 is positioned in the air outlet cavity 31, and the air outlet cavity 31 is in air path communication with the air outlet outer joint 18; the air outlet convex nozzle 34 is arranged in the air outlet groove 38, the air outlet membrane 20 covers the upper part of the air outlet groove 38, and the air flow area borne by the upper end surface (back surface) of the air outlet membrane 20 is larger than the air flow area borne by the lower end surface (front surface) during operation.

The air suction unit 13 comprises an air suction external joint 19, an air suction valve plate 15 and an air suction cavity 32 which are arranged on the valve cover 7, wherein an air inlet convex nozzle 33 communicated with the air outlet cavity 31 is arranged on the air suction valve plate 15, and an air inlet diaphragm 21 for opening and closing the air inlet convex nozzle 33 is arranged above the air inlet convex nozzle 33; the air inlet diaphragm 21 is positioned in the air suction cavity 32, the adjusting elastic element 22 is arranged above the air inlet diaphragm 21, and the adjusting elastic element 22 is a spring. The air suction cavity 32 is communicated with the air passage of the air suction outer joint 19; the air suction unit 13 is also provided with an air exhaust hole 25, and the air exhaust hole 25 is communicated with an air path of the air inlet convex nozzle 33. The air-bleeding hole 25 is provided in the housing below the air suction external joint 19.

As shown in fig. 16 and 17, a pulse orifice 16 is provided in the switching plate 14 at a position corresponding to the seventh air passage 307, and a switching plate paddle 17 is provided outside the switching plate 14. When the switch plate paddle 17 is moved to the open position, the pulse throttle hole 16 is aligned with the seventh air passage 307.

The pulse oxygen therapy function is the characteristic function of the utility model, the pulse mode means that the user carries out oxygen delivery when breathing in, and closes oxygen delivery when breathing out, and the core lies in the stress state of the diaphragm 20 and the diaphragm 21 of breathing in of giving vent to anger. According to the stress state difference of two diaphragms, the utility model discloses an air feed under continuous and pulse two kinds of modes.

(1) Continuous air supply mode

As shown in fig. 11 and 16, two paths of oxygen are output from a decompression chamber 308 arranged inside the valve body, and the first path of oxygen reaches the air outlet convex nozzle 34 of the air outlet unit 12 after passing through the sixth air passage 306; the second path passes through a seventh air duct 307 to the switching plate 14. When the switching plate 14 is adjusted to the position shown in fig. 16 by the switching plate shifting piece 17, so that the pulse throttle hole 16 is blocked, the top of the air outlet membrane 20 has no second path of oxygen pressure test, so that the first path of oxygen directly rushes the air outlet membrane 20, and the oxygen is output to the air terminal through the air outlet external joint 18, which is a direct flow oxygen outlet state.

(2) Pulse air supply mode

As shown in fig. 14 and 17, when the switch plate 14 is adjusted to the position of fig. 17 by the switch plate paddle 17, the pulse throttle hole 16 is opened, and the second path of oxygen passes through the pulse throttle hole 16 and reaches the back of the outlet membrane 20. Because of the pressure that receives at the diaphragm 20 back of giving vent to anger and positive unanimous (the air supply all comes from same air supply, the utility model discloses the air supply comes from decompression chamber 308), and the diaphragm 20 back of giving vent to anger is greater than its front atress area via the protruding mouth 34 outflow oxygen of giving vent to anger because of atress area, so the effort at the diaphragm 20 back of giving vent to anger is greater than its front effort via the protruding mouth 34 air current of giving vent to anger, therefore the positive gas outlet that can effectively seal the protruding mouth 34 of giving vent to anger.

As shown in fig. 15, after the instantaneous negative pressure generated when the human body inhales through the external inhaling connector 19 acts on the back surface of the inhaling diaphragm 21, the acting force (vertical upward) generated by inhaling is greater than the force (vertical downward) of the adjusting elastic element 22, so that the lower end surface of the inhaling diaphragm 21 is separated from the air outlet of the inhaling convex nozzle 33, the trace oxygen on the lower end surface of the inhaling diaphragm 21 escapes to the atmosphere through the air-eliminating hole 25, and the air pressure on the upper end surface of the air-out diaphragm 20 is instantaneously reduced, at this time, the oxygen in the air-out unit 12 via the air-out convex nozzle 34 flushes the air-out diaphragm 20, and is output to the air-using terminal through the. Wherein a highly sensitive perception of the inspiratory action of the human body can be achieved by changing or selecting the parameters of the suitable adjusting elastic element 22, i.e. the spring.

When the person stops inhaling, the force of the adjusting elastic member 22 causes the inhaling diaphragm 21 to descend and cover the air hole of the inhaling convex nozzle 33 to seal, and the state is returned to the state shown in fig. 14. The air pressure on the upper end face of the air outlet diaphragm 20 is recovered, the stress on the upper end face (back face) is larger than the stress on the lower end face (front face) to seal the air outlet convex nozzle 34, and oxygen supply is stopped.

The circulation is repeated, and the oxygen supply module controls the air outlet and the air outlet to be closed according to the breathing frequency of the human body, so that the pulse oxygen supply function is realized, and the purposes of saving oxygen and prolonging the oxygen use time are achieved. Practical tests prove that the gas using time of the pulse function is 3 times of the direct-current gas discharging time under the condition of ensuring the consistency of the oxygen concentration, and the oxygen using effect is greatly improved.

Claims (10)

1. An integrated oxygen supply valve is characterized in that: comprises a valve body (6), a valve cover (7), and a filling module (8), a flow regulating module (4) and a pulse oxygen supply module (5) which are arranged on the valve body (6) and the valve cover (7); oxygen in the gas tank (108) passes through the filling module (8) and the flow regulating module (4) and then is output by the pulse oxygen supply module (5);

the pulse oxygen supply module (5) comprises an air inlet unit (11), an air outlet unit (12) and an air suction unit (13); the air inlet unit (11) comprises a sixth air passage (306) and a seventh air passage (307) which are used for air inlet of the same air inlet source;

the air outlet unit (12) comprises an air outlet external joint (18), an air outlet valve plate (35) and an air outlet cavity (31) which are arranged on the valve body; an air outlet convex nozzle (34) communicated with the sixth air channel (306) is arranged on the air outlet valve plate (35), and an air outlet diaphragm (20) used for opening and closing the air outlet convex nozzle (34) is arranged above the air outlet convex nozzle (34); the air outlet diaphragm (20) is positioned in the air outlet cavity (31), and the air outlet cavity (31) is communicated with an air passage of the air outlet outer joint (18); the air outlet of the seventh air channel (307) is arranged above the air outlet diaphragm (20);

the air suction unit (13) comprises an air suction external joint (19), an air suction valve plate (15) and an air suction cavity (32) which are arranged on the valve cover (7), wherein an air inlet convex nozzle (33) communicated with the air outlet cavity (31) is arranged on the air suction valve plate (15), and an air inlet diaphragm (21) used for opening and closing the air inlet convex nozzle (33) is arranged above the air inlet convex nozzle (33); the air inlet diaphragm (21) is positioned in the air suction cavity (32), the adjusting elastic element (22) is arranged above the air inlet diaphragm (21), and the air suction cavity (32) is communicated with an air passage of the air suction outer joint (19); the air suction unit (13) is also provided with an air exhaust hole (25), and the air exhaust hole (25) is communicated with an air path of the air inlet convex nozzle (33).

2. The integrated oxygen supply valve of claim 1, wherein: a switching plate (14) is arranged on the seventh air passage (307) to realize the closing and opening of the seventh air passage (307).

3. The integrated oxygen supply valve of claim 1, wherein: the filling module (8) comprises an inflation connector (2) arranged at an air inlet end (100) of the valve body (6), a first air passage (101) penetrating through the air inlet end (100) is arranged in the air inlet end (100), and a tank body interface (109) is arranged on the outer ring of an outlet of the first air passage (101); the inflation connector (2) comprises an inflation nozzle (105) and a plugging chamber (106), the inflation nozzle (105) is communicated with the plugging chamber (106) through a second air passage (102), and a one-way plug (1) is arranged in the plugging chamber (106) to plug or open the second air passage (102); the second air passage (102) is communicated with the interior of the first air passage (101).

4. The integrated oxygen supply valve of claim 3, wherein: a third air passage (103) is arranged inside the air inlet end (100) of the valve body, the third air passage (103) is perpendicular to and communicated with the first air passage (101), and a pressure gauge (110) is connected to the outside of the third air passage (103).

5. The integrated oxygen supply valve of claim 3, wherein: the one-way plug (1) comprises a conical head (152), a transition section and a conical tail (156), and a second conical surface (158) matched with the conical head (152) is arranged at one end, close to the second air passage (102), of the plugging chamber (106).

6. The integrated oxygen supply valve of claim 1, wherein: the oxygen supply valve also comprises a pressure reducing and stabilizing module (3) arranged in the valve body;

the decompression and pressure stabilization module (3) comprises an air inlet joint (310), an air inlet plate (301), an air outlet plate (302) and a decompression chamber cover plate (303) which are sequentially arranged from bottom to top; a fourth air passage (304) is arranged in the air inlet joint (310), a fifth air passage (305) is arranged in the air outlet plate (302), and an upper port of the fourth air passage (304) and a lower port of the fifth air passage (305) are arranged in a staggered manner; a decompression cavity (308) is arranged between the upper end faces of the decompression chamber cover plate (303) and the air outlet plate (302), and the fifth air passage (305) is communicated with the decompression cavity (308); an elastic element (309) is arranged between the air inlet plate (301) and the air outlet plate (302), and the air outlet plate (302) moves up and down under the action of the internal pressure of the elastic element (309) and the decompression cavity (308), so that the upper port of the fourth air channel (304) is opened or closed by the lower end face of the air outlet plate.

7. The integrated oxygen supply valve of claim 6, wherein: the upper end of the air inlet joint (310) is provided with a convex air tap (314), the lower end face of the air outlet plate is provided with a sealing rubber gasket (313), and the sealing rubber gasket (313) seals the fourth air channel (304) when touching the convex air tap (314).

8. The integrated oxygen supply valve of claim 6, wherein: the fourth air passage (304) comprises an upper straight hole (315) and a lower straight hole (316) which are communicated with each other, and the upper straight hole (315) and the lower straight hole (316) are arranged in a staggered mode in the horizontal direction.

9. The integrated oxygen supply valve of claim 1, wherein: the flow regulating module (4) comprises a second valve body (44) and a gear ring (42) which synchronously rotate around a valve rod (41), a plurality of throttle holes (48) and bypass holes (47) are formed in the second valve body (44), a decompression chamber cover plate (303) is provided with a sixth air passage (306) corresponding to the throttle holes (48), and the sixth air passage (306) and the seventh air passage (307) are respectively communicated with an air inlet source through the throttle holes (48) and the bypass holes (47).

10. The integrated oxygen supply valve of claim 9, wherein: a spring snap ring (43) is arranged on the position of the valve rod (41) close to the upper end surface of the pressure reduction chamber cover plate (303); a positioning component (45) is arranged on the pressure reduction chamber cover plate (303), and a groove is formed in the upper end face of the second valve body (44) at the position corresponding to the positioning component (45).

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