DE1491659B2 - Respiratory device - Google Patents

Description

The invention relates to a breathing apparatus having a patient adapter that communicates with the airway a patient is connected, a pressurized gas source, a supply circuit for gas from the source to the patient adapter and to deliver to the patient's airway, and having an exhalation valve device, which is connected to the patient adapter.

There are known breathing devices, which exhalation valves that are operated by mechanical locking devices. An example one such breathing device is described in US Pat. No. 91,596.

A disadvantage of such known breathing devices is that it is difficult, for example to give mechanical support to a child, which is attached to a hyaline membrane (vocal cord cartilage), lung obstruction or congestion, or any other respiratory disease suffers because a child's lungs are very small and the necessary breathing speeds are very high. In addition, it is used to ventilate the small children's lungs required pressure sometimes higher than the corresponding adult pressure. Another The disadvantage of the known devices is that the exhalation valves, which by means of mechanical Locking devices or locking members do not work effectively on changes in breathing resistance that may be encountered in the patient due to obstructions in the airways

ίο of the lungs and changes in lung compliance. The known mechanically operated exhalation valves are also ineffective in terms of creation rapid switching between the exhalation phase and the inhalation phase, which is special This is important when breathing assistance is given to children when breathing is fast required are.

The object of the invention is to design a breathing device so that more effective ventilation is especially made possible by children and that rapid switching between inhalation phase and Exhalation phase and effective response to changes in breathing resistance are created. This object is achieved according to the invention, proceeding from a breathing device of the introductory part mentioned type, characterized in that the exhalation valve device has a body with a venturi-like Passage, one end of which is connected to the patient adapter, a nozzle attached to the body and facing one end of the passage, and that means are provided to to supply positive pressure gas to the nozzle during the inhalation phase to create a barrier from gas molecules to prevent gases from escaping from the patient adapter during the inhalation phase resists.

The invention provides a breathing device by means of which children ventilate more effectively can be. In addition, there is a very rapid switchover between the inhalation phase and the exhalation phase and the device is also effective in responding to changes in breathing resistance.

A preferred embodiment of the invention is characterized in that an additional nozzle is attached attached to the body and facing the opposite end of the body passage, and that means are provided to divert pressurized gas from the additional nozzle during the exhalation phase to direct a jet of gas towards the passageway to remove gases from the airway of the Aspirate patient. With this design, another gas jet is created in the opposite direction Directed through the venturi-like passage to remove gases from the patient's airway during the exhalation phase suck in. This ensures that the mode of operation changes rapidly from inhalation to exhalation it can be switched with pneumatic support for the escape of the gases from the patient. Yet another preferred embodiment of the

<> ° Invention is characterized in that the opposite End of the passage of the nozzle adjacent to the atmosphere is open, thereby leaving the nozzle leaking gas takes air with it from the atmosphere and through the opposite end and in the passageway moved downward to form the barrier of Gus molecules to prevent gases from escaping; ius the patient adapter resists during the inhalation phase. Here the venturi-like passage is close

that nozzle open to the atmosphere, which the gas jet generated to take away air from the atmosphere. This ensures that additional gas can be fed from the atmosphere to the patient adapter for entrainment by the flow of the Pressurized gas source.

The invention is explained below with reference to the drawing, for example.

F i g. Fig. 1 is a schematic representation of certain parts of a breathing device according to the invention;

F i g. FIG. 2 is a cross-sectional view of the control insert used as part of the breathing device according to FIG F i g. 1 is used;

F i g. 3 is a cross-sectional view taken along line 3-3 of FIG. 2; ·

F i g. Figure 4 is a cross-sectional view taken along line 4-4 of Figure 2;

F i g. FIG. 5 is an enlarged sectional view of the breathing apparatus of FIG F i g. 1 used exhalation valve.

According to the drawing, the breathing apparatus according to the invention has a controller It of those Art, which is described in U.S. Patent 3,191,596. As described in this patent specification, such a controller 11 has an inlet 12 with a source of pressurized gas can be connected, and an outlet 13 connected to the Airway of the patient can be connected. Such a controller 11 also has a not shown Main control valve, which is movable in it between an open and a closed position is to control the flow of gas from the inlet to the outlet. A device is provided for Operate the main control valve so that it is in the open position during the inhalation phase and is in the closed position during the exhalation phase of the breathing device. the Means for actuating the main control valve comprises means which senses when a predetermined one Pressure in the outlet is reached to move the main control valve from the open position to the closed To move position. Such a controller 11 also has an outlet 16 for positive Pressure and an outlet 17 for negative pressure.

The breathing device also has a control insert 21 which is connected to the inlet 12 of the controller 11 and can be connected to a source 22 of pressurized gas. The breathing device further comprises an exhalation valve 23, a nebulizer 24 and a patient adapter 26. The nebulizer 24 may be of the type disclosed in pending U.S. Patent Application Serial No. 4 47 852 of April 13, 1965 (patent application B 86 632 IX d / 30 k). As in this application described, the nebulizer 24 has an inlet 28 which, as shown in FIG. 1 shown on the Outlet 13 of the controller 11 is arranged. The atomizer 24 is also with an outlet ^ and a additional inlet 31 is provided.

The control insert 21 has a cylindrical housing 36 with a large centrally arranged bore is provided, which extends in the longitudinal direction of the housing 36. The bore 37 opens into a large cylindrical recess 38 at one end of the housing 36, as shown in FIG. 2 is shown. The large (> 5 Bore 37 continues to open at its other end into a smaller cylindrical bore 39. The Bore 39 communicates with a further, even smaller bore 41 in the housing 36. the Bore 41 is in communication with a larger bore 42, which in turn is connected to a cup-shaped Recess 43 is in communication, which is formed at that end of the housing 36 that the end opposite, on which the recess 38 is formed.

A valve member or holder 46 is arranged in the large bore 37 and provided with an annular shoulder 47, which lies against the bottom of the recess 38. The valve member 46 is still with a self radially extending flange 48 which is substantially the same diameter as the recess 38 and which is in engagement with a snap ring 49 which is arranged in a recess 51 which is arranged for holding the valve part 46 in the housing 36 therein.

The valve part 46 is provided with a bore 52 which extends between its ends in the longitudinal direction stretching him through. The bore 52 opens at one end into a flat-sided circular shape Recess 53 and at the other end in a larger bore 54. The innermost end of the valve part 46 is provided with an oblique annular valve seat 56. A piston or plunger 57 is in the bore 52 slidably arranged and can with respect to the valve seat 56 between an open and a closed position. A suitable sealing device, for example a O-ring 58, is carried by the plunger 57 in an annular recess 59 which is radially between a extending collar 61 and a shoulder 62 is formed, which in turn as an integral part of the plunger 57 is formed. A sealing device is located between the plunger 57 and the side wall forming the bore 52 arranged, which has an O-ring 63, which is provided in a provided on the plunger 57 annular Recess 64 is arranged. Furthermore, a sealing device is between the valve part 46 and The side wall forming the bore 37 arranged, and it has an O-ring 65, which is in an annular Recess 66 is arranged in the housing 36. A device is provided for yielding Pushing the plunger 57 towards the closed position, and this device has a Coil spring 67, one end of which is in engagement with a cylindrical projection 68, as an integral Part of the plunger 57 is formed.

The other end of the spring 67 is connected to a cylindrical projection 69, which is an integral one Forms part of a second tappet valve 71. The tappet valve 71 has a valve tappet 72 in the Bore 41 slidably disposed and related between open and closed positions is movable on an annular inclined valve seat 73, which is in the housing 36 near the outer end the bore 39 is formed. It is a suitable sealing device for the poppet valve 71 is provided which has an O-ring 74 which can engage with the seat 73 and in an annular shape Recess 76 is carried between a radially extending collar 77 and a shoulder 78 is formed, which in turn forms an integral part of the tappet valve 71.

To form a seal around the valve tappet 72, an O-ring 81 is provided, which is located in the bore 42 is arranged and the valve stem 72 surrounds. The seal also has a ring 82 which passes through

a snap ring 83 is held in place. The outer end of the valve lifter 72 is at the middle Part of a resilient membrane 86 attached. The outer ring edge of the membrane 86 is in the recess 43 clamped between the housing 36 and a cap 87 which is screwed into the housing 36. It can be seen that separate chambers 88 and 89 are formed on opposite sides of the membrane 86 are. The chamber 88 is vented to atmosphere via a small passage 91 made in the housing 36 is formed. A gas under positive pressure can be screwed into the cap 87 via a Nipple 92 of the chamber 89 are fed. A cap screw 93 is used to close another in of the cap 87 provided opening, which is not used. The bore 39 is in communication with a passage 96 in the housing 36 and opens into it. The passage 96 opens into one Bore 97 in housing 36. Bore 97 is still in communication with another in FIG The passage 98 formed in the housing 36 opens into another bore 99 formed in the housing 36 is (see Fig. 3). A nipple 101 is screwed into the bore 99, while a manually controlled flow valve 102 is arranged in the bore 97.

The valve 102 is of a conventional type and has a valve body 103 which is screwed into the bore 97 is. The body 103 is provided with an annular recess 104 which carries an O-ring 106, which is in sealing engagement with housing 36 and in alignment with passage 96. The body 103 is still with a passage

107 provided, which is opened and closed by a needle valve 108 screwed into the valve body 103 can be. A button 109 is on the needle valve

108 provided for its adjustment axially to the valve body 103 in order to control the size of the opening, through which gases can flow into a chamber 111 provided in the valve body 103. A small passage 112 in the valve body 103 creates a connection between the chamber 111 and the in the passage 98 provided in the housing 36.

Means are provided to move the valve stem 57 to the open position, and this The device comprises a knee joint portion 116 which is a cylindrical member 117 provided with a planar side on which a handle 118 is formed. A sealing ring 119 is disposed over the handle 118 and held in place by a cap 121 that screws onto the outer end of the valve member 46 is. The cap 121 is provided with a centrally arranged opening 122 through which the handle 118 extends therethrough. The cylindrical one Part 117 is formed with an arcuate recess 123 and can receive a ball 124, as shown in FIG the F i g. 2 and 4 is shown. The ball 124 is essentially the same diameter as that Outer end of the plunger 57 and can be moved into the bore 52 by moving the joint part 116, to move the plunger 57 into the open position and hold it in this position. The hinge part 116 is such designed that the plunger 57 with respect to the valve seat 56 in either the open or the closed Position can be held.

Means are provided for supplying pressurized gas into the bore 37 formed chamber, and this device has a threaded bore 126 on. in which a threaded nipple 127 is screwed in. A nut 128 is screwed onto the nipple 127 for connection to a to produce an appropriate pressure source, for example the one shown in FIG. 1 reproduced pressure source 22. The bore 126 communicates with a passage 129 which opens into the bore 37. It is furthermore a device is provided for discharging or withdrawing gases from the through the bore 37 formed chamber, and this device has a passage 131, which is with a in the Housing 36 formed bore 132 is in communication. A connecting piece 133 is screwed into the bore, that with the inlet 12 of the in F i g. 1 shown controller 11 can be connected directly.

The exhalation valve 24 has a central body 136, one with two necks and one with one, respectively Double-necked venturi-like passage 137 which extends longitudinally through the body 136 extends through it. In other words, at each end of the body 136 there is a venturi-like one Passage created. The body 136 is recessed cylindrical surfaces 138 and 139 at opposite ends. An annular recess 141 is in each cylindrical Surface is formed and carries an O-ring 142. A positive beam generating subassembly 144 is located at one end of the central body 136, and a negative beam generating subassembly 146 is arranged at the other end of the central body 136. The subassembly 144 has a tubular shape Part J47, which is provided with a cylindrical bore 148, the over the cylindrical surface 138 fits tightly and can be held thereon by the O-ring 142 shown. The outer end of the tubular part 147 is provided with an inclined raised shoulder 149 which engages a hose can if one is connected to her.

A nozzle 151 is centrally located in the tubular portion 147 and in the bore 148 so that when arranged of the tubular part 147 on the central body 136, the nozzle 151 is in axial alignment with one end of the venturi-like passage 137 located in the central body 136. It's a facility provided for supplying air to the nozzle 151, and this device comprises a tube 152 which is provided with a part 152a, which extends through the side wall of the tubular part 147 in radial Direction extends through. Part 1526 extends at right angles to part 152a and is provided with a nipple 152c.

The negative beam subassembly 146 is constructed in a manner similar to that of the positive ones Beam generating sub-structure 144 and it has a tubular part 156, which is provided with bores 157, 158 and 159 communicating with each other and each having a different diameter to have. The bore 157 is sized to comfortably fit over the surface 139 on the other End of the body 136 is formed, and that the O-ring 142 can engage with her to the one negative To hold the beam generating subassembly 146 against the central body 136.

A nozzle 161 is disposed in the bore 158 of the tubular member 156 and the other neck of the facing venturi-like passage 137 and is thus in axial alignment, as shown in FIG. 5 is shown. Means are provided for supplying pressurized gas to the nozzle

161, and this device comprises a tube 162 which is provided with a part 162a which extends through one Wall of the tubular part 156 extends radially through and attached to the wall of the tubular part is. The tube 162 continues to have a section 162 that connects to section 162a in the right Angle extends and provided with a nipple 162c, which forms a continuation of the section 1626. The tubular part 156 is provided with an inclined, raised shoulder 160, with either soft or flexible one Hose can engage when it is connected to her.

As shown in the drawing, the nipple 101 of the control insert 21 has one end of a hose 166, the other end of which is connected to the tube 152. The nipple 92 of the control insert 21 is connected via a hose 167 to a T-shaped connector 168 which is in the Inlet 31 of the atomizer 24 is arranged. The T-shaped connector 168 is still on a Hose 169 connected to the positive pressure outlet 16 of the controller 11. The outlet 17 for negative Pressure from the controller 11 is connected to the pipe 162 via a hose 171. The tubular part 156 of the exhalation valve 23 is connected to a branch of a bifurcated or Y-shaped patient adapter 26 connected via a hose 172. The outlet 29 of the atomizer 24 is provided with a connector 173. The connecting piece 173 is connected to the patient adapter 26 via a hose 174. The patient adapter 26 may be of any convenient type, but according to FIG Drawing a tracheal connector.

The operation and use of the breathing device are briefly described below. Suppose that it is desired to operate the breathing device. This is achieved through Moving the joint part 116 into a position in which it presses the ball 124 into the bore 159 to the plunger 57 according to FIG. 2 to the right to push it against the force with respect to the valve seat 56 the spring 66 to move to the open position. Pressurized gas from source 22 flows therethrough the connector 127 and through the passage 129 into the bore 37. The gas then flows into bore 54, through passage 131 and connector 133 to inlet 12 of the controller 11th

Assume that the controller 11 is in the inhalation phase and a below positive Pressurized gas is generated through main outlet 13 and through nebulizer 24 into the outlet 29 of the nebulizer 24 to the bifurcated patient adapter 26 and to the patient's airway. At the same time that the gases under positive pressure are passed through outlet 13 gas will continue to be at a higher positive pressure through outlet 16 for positive pressure led to the T-shaped connector 168. A portion of this positive pressure is applied to the nebulizer 24 supplied to the bronchial medicament or any other substance contained in the nebulizer 26 atomize, so that drops of this substance enter the main gas flow from the outlet 29 to the patient adapter 26 flows. At this same time, gas under positive pressure will continue fed to the nipple 92 of the control insert 21 to supply positive pressure to the chamber 89 and the Membrane 86 according to FIG. 2 to the left and continue to move the plunger 72 into an open position with respect to the seat 73 Position to move. Therefore, pressurized gas flows into bore 39 through passage 96 and then through flow control valve 102 at a rate determined by valve 102. Extent through the passage 98 to the nipple 101 and to the nozzle 151 having a gas flow at one end of the venturi-like passage 137 leads. The jet of air passing through passage 137 causes that additional air molecules are drawn from the atmosphere and pushed into passage 137, so that additional pressurized gas is supplied to the patient adapter. The valve 102 is set so that that the extent of the gas flow out of the nozzle 151 is sufficient to achieve the result shown in FIG. 1 left end of the Effectively seal exhalation valve 123 to prevent gas supplied to the patient from escaping Prevent atmosphere. The valve 102 has another function which is to let atmospheric air into it according to FIG. 1 right end of the exhalation valve 23 to suck and the patient adapter 26 during the Supply additional pressurized gas to the breathing device during the inhalation phase. Accordingly, it can be said that during the inhalation phase the jet emerging from the nozzle 151 in conjunction with the venturi-like jet Passage 137 cause a valve closure at the rear end of the nozzle 151 because through the Venturi effect a molecular barrier is established. This lock can be stationary or it can be facing move on the patient at speeds or to an extent dependent on the setting of the Valve 102 and the resistances that occur in the patient's airways according to blockages or the like.

of the lungs and changes in the ability of the lungs to breathe as well as the resistances in the mechanical Circle to the patient adapter 26 depends.

As soon as the inhalation phase has ended and has been sensed by the controller 11, the controller 11 switches to the negative or exhalation phase. When this occurs, outlet 16 no longer becomes positive pressure supplied so that the plunger 72 is returned to its closed position by the action of the spring 66 will. This shuts off the gas flow from the nozzle 151. At the same time a flow becomes negative Pressure built up in the outlet 17 of the controller U and applied to the nozzle 161 to create a stream of air to generate, which flows through the venturi-like passage 137 in the opposite direction, to create a negative pressure gradient that is consistent with that in the patient's airway Sucks in gases located and emits them through the tubular part 147 to the atmosphere. So it is It can be seen that the exhaled gases flow through the exhalation valve 23 during the exhalation phase and released into the atmosphere.

As soon as the exhalation phase has ended, the controller 11 is switched to the inhalation phase and the same sequence of operations takes place.

From the above it can be seen that the through the nozzle 151 through into the venturi-like passage 137 flowing gas jets act as a pneumatic coupling. When changes in resistance and Changes in the blockage or obstacles or the like. Result, the gas flow is automatic converted from pressure to gas flow. In other words, when the resistance is in the air of the patient increases, the current is converted into pressure

509 537/131

changes according to this venturi-like effect, and when the resistance is reduced, becomes by the same venturi-like effect the pressure is converted into a flow of gases. In other Put in words, the kinetic energy of the gas flow is converted to higher pressures in order to to overcome the resistances, and the same kinetic energy is converted back into a flow, to increase the flow of gas to the patient to improve ventilation. During the inhalation phase represents the molecular barrier, which according to FIG. 1 is generated on the left side of the exhalation valve 23 is a type of relief valve which provides a build-up of premature peak inspiratory pressures when overcoming of blockages or the like. Prevents.

Due to the fact that the exhalation valve 23 contains no moving parts, it can be of the The inhalation phase can be switched quickly to the exhalation phase. As described above, do it alone the exhalation valve 23 makes it possible to apply a molecular barrier towards or from the patient to move away in order to fulfill all the functions of a conventional exhalation valve, the movable one Has parts that have inertia.

By using an exhalation valve of this type, a quick switchover from the exhalation phase can be achieved can be achieved on the inhalation phase. As a result of this, the breathing device especially suitable to give children mechanical support when breathing fast or large Breathing speeds is or are required.

The breathing apparatus shown in the drawing has additional advantages due to the fact that two separate flow passages lead to the patient adapter 26. One runs through the main controller 11, while the other runs through the exhalation valve 23. The control insert 16, 21 has a flow rate controlling valve 109 for adjusting the flow rate or the amount of flow through the exhalation valve 23, and the controller 11, as described in U.S. Pat. No. 3,191,596, further includes a The amount of flow controlling valve on to adjust the flow of gas through the other main outlet 13 to the patient adapter 26, via the nebulizer 24. The amount of flow to the patient adapter 26 can be increased by merely increasing the amount of gas flowing through the nozzle 151 will. The length of the inhalation phase can be controlled by the controller U's flow control valve. Accordingly, by adjusting the amount of gas flow through the controller 11, the amount of main gas flow through the nebulizer 24 can be conveniently controlled and adjusted to a desired value, with any additional gases required by the patient being passed through the exhalation valve 23 through actuation of the manually operated flow control valve 109 .

This parallel circuit in the breathing device according to the invention can furthermore be used to operate a spirometer and any other auxiliary devices or instruments. Due to the parallel circle, this can be done without disturbing the amount of flow to the patient controlled by the controller 11. If increased nebulization is required, additional flow can be allowed to flow through the nebulizer 24 while the flow through the exhalation valve 23 is decreased.

The control insert 21 also provides additional features for the breathing device. The joint part 116 makes it possible to switch the breathing device on and off with a single control. If a breathing plan has accordingly been drawn up for the controller 11, the entire breathing device with the joint part 116 can be switched off and on. The control insert 21 also makes it possible to arrange the parallel charging passage described above, which is arranged in phase with the controller 11 and operates only during the inhalation phase.

From the above it can be seen that the breathing device according to the invention has many advantages Has features, and is particularly suitable for the resuscitation or resuscitation of children. That particular pneumatically controlled exhalation valve used in the breathing device according to the invention is used is particularly novel and advantageous because it is very simple and not mechanical Requires movements. If desired, the exhalation valve can be equipped with only one a positive beam subassembly can be used. The exhalation valve is still insofar advantageous as it can be made relatively small and light in weight, so that it is particularly advantageous for patients to be treated on the trachea. The exhalation valve can still can be used in a Q cycle.

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. A breathing apparatus having a patient adapter connected to the patient's airway, a source of pressurized gas, a supply circuit for supplying gas from the source to the patient adapter and the patient's airway, and an exhalation valve device connected to the patient adapter, characterized in that the exhalation valve means (23) has a body (136) containing a venturi-like passage (137) one end (159) of which is connected to the patient adapter (26), a nozzle (151) on the body (136) ) and facing one end (159) of the passageway (137) , and that means (166) are provided for supplying gas under positive pressure to the nozzle (151) during the inhalation phase in order to create a barrier of gas molecules which resists the escape of gases from the patient adapter (26) during the inhalation phase. 2. Apparatus according to claim 1, characterized in that an additional nozzle (161) is attached to the body (136) and faces the opposite end (148) of the passage (137) , and that means (171) are provided to supplying pressurized gas to the auxiliary nozzle (161) during the exhalation phase to direct a jet of gas towards the passageway (137) to draw gases from the patient's airway. 3. Apparatus according to claim 2, characterized in that the opposite end (148) of the passage (137) of the nozzle (151) is open adjacent to the atmosphere, so that gas emerging from the nozzle (151) takes air with it from the atmosphere and through the opposite end of the passageway (148) and moved downwardly in the passageway (137) to form the barrier of air molecules that will resist the escape of gases from the patient adapter (26) during the inhalation phase.