SE437768B - Combined venturi unit and exhalation valve unit - Google Patents

Abstract

The invention applies to a combined venturi and exhalation valve aggregate, that has a main section (817) with a channel (818), which stretches axially and builds a central airway opening (823), which is intended to be coupled to the patient. A venturi section (826) is displaceably affixed in the channel (818) inside the main section (817) for movement between the first and second positions. The main section (817) is designed with an outlet opening (819), which communicates with the channel (818) and is separate from the central airway opening (823). The main section (817) is also designed with an inlet opening (848) that communicates with the channel (818) and is separated from the outlet opening (819). The venturi section (826) has a venturi-like channel (833), which stretches axially through the venturi section. A nozzle (851) is supported by the venturi section (826) and has an opening (852) axially positioned with the venturi-like channel (833). A membrane (861) is supported by the main section (817) and stretches across the channel in the section. An end casing (858) is supported by the section and has an inlet (864), communicating with one side of the membrane (861). The channel (863) establishes communication between the inlet (864) and the nozzle (851) and stretches through the membrane (861), so that, when gas is supplied through the inlet (864), the venturi section (826) is displaced from the first to the second position in order to close the outlet opening (819). A spring (841) returns the venturi section (826) from the second to the first position in order to open the outlet opening, when gas is not applied to the inlet (864).<IMAGE>

Description

Bšüêâäåtâ 2 with reference to the accompanying drawing, which shows an exemplary embodiment and in which a pneumatically combined venturi and exhalation valve assembly according to the invention is illustrated in section. The unit can be used with different types of fans for ventilation of the lungs of mammals.

The combined venturi and exhalation valve assembly 816 shown in the drawing consists of a substantially cylindrical, hollow body 817 having a continuous cylindrical channel 818. An exhalation outlet 819 is mounted in the body 817 and communicates with the channel 818.

A further outlet 821 communicates with the channel 818 and is mounted in the body so as to extend diametrically therefrom, and is used for sampling the airway pressure in the channel 818. The shown outlet 821 is screwed into the body 817 and an O-ring 822 is provided for to airtight seal against the body. The channel 818 terminates in a central airway opening 823, which is adapted to receive a suitable patient adapter, such as a mouthpiece or an endotracheal tube, which is connected to the patient's airway. A substantially cylindrical venturi body 826 is arranged and positioned in such a way that it can slide in the channel 818 in the body 817. The body 817 is mounted in a cylindrical venturi bushing 827 in such a way that the bushing 827 moves with the venturi body 826 The venturi body 826 is provided with an annular flange 828 at its front end, which engages with the front end of the bushing 827. It is also provided with a centrally arranged, annular flange 829, which also frictionally engages the bushing 827.

At its rear end, the body 826 is provided with another annular flange 831, which engages with a lip 832, which is L-shaped in cross section and arranged on the rear end of the bushing 827. The venturi body 826 is provided with a venturi-like channel 833 , which extends axially in the venturi body and is open in both ends of the venturi body 826. The front end of the venturi body has a bevel 834 in which an inner main groove 836 is provided, in which an O-ring 837 is located. The O-ring 837 serves as a valve means and is arranged to engage a conical valve seat 838, which is formed in the body 817 immediately in front of the exhalation outlet 819.

Means are provided for resiliently pressing the venturi body 826 with associated bushing 827 to such a position that the O-ring 837 forming a valve member is disengaged from the valve seat 838, and consists of a coil spring 841, one end of which rests against the the lip 832 is arranged on the bushing 827 while its other end engages with an annular stop 842 formed in the venturi body 826. the venturi body 826 is provided with a cylindrical, threaded end 844, on which a cylindrical housing 846 is screwed, which housing has cut-off portions to provide openings 847 which communicate with an inlet 848 mounted in the body 817 and also communicate with the channel 818. The remaining portions of the housing 846 form L-shaped legs 849 which serve to support a nozzle 851 in such a position that a centrally located, thereby extending channel 852 is in axial alignment with the axis of the venturi-like channel 833 arranged in the venturi body 826. A nozzle 851 is provided in the larger cylindrical bore B53 in the axial direction with the channel 852. An annular groove 854 is formed in the bore 853 and carries an O-ring 856. An end cap 858 is screwed into the outermost rear end of the body 817 An annular groove 859 is provided in the body 817 and receives the outer annular edge of a membrane 861, which is made of a suitable material, such as neoprene. The diaphragm 861 extends across the inner surface of the end cap 858 and carries a hollow diaphragm shaft 862 which has a flow passage 863. The shaft is intended to be inserted into the bore 853 of the nozzle 851 and arranged to establish V .. «-.,» 4.a. ............._-.,. . . . A sealing engagement with the O-ring 856, so that an airtight seal is established between the shaft 862 and the nozzle 851. The passage 863 is aligned and communicates with a flow passage 864, which is arranged in the end cap. 858. The end cap is provided with an inlet connection 866, which is intended to receive compressed gas in a suitable form, such as periodic gas pulses from a fan.

The operation of the combined venturi nozzle and the exhalation valve assembly 816 in fans of the aforementioned type will now be briefly described.

It is assumed that suitable connections have been made to the exhalation valve assembly 866 from the fan. Gas such as air, oxygen or a mixture of air and oxygen can thus be supplied to the connection 866 on the end cap 858. The connection 821 can be used to provide patient airway pressure. It is assumed that the gas, for example gas pulses or pulsating gas, is supplied to the inlet connection 866. These pulsating gases are led through the channel 864, the channel 863, the nozzle 851 and through the bore 846 into the venturi-like channel 833 and then to the patient's airway. When the pressure in the channel 864 acts in the opening 852 in the nozzle 851, a pressure builds up behind the diaphragm 861, whereby the diaphragm with the hollow diaphragm shaft 862 moves forward and thereby displaces the venturi body 826 with associated bushing 827 forward in the body 817 until the valve means the ring 837 engages the body seat valve 838 to close the exhalation opening or outlet 819. In this way, the exhalation opening is closed in the same manner as when the exhalation valve assembly 721 is displaced to the closed position by compressed air supply to the exhalation valve assembly. The advantages of the arrangement shown in the drawings are that as soon as gas is no longer supplied to the assembly 816, the spring 841 returns the displaceable venturi body 826 to its rear position, which is determined by the rear position of the valve stem supported by the diaphragm 861. It has been found that the combination of the venturi nozzle and the exhalation valve assembly 816 has many advantages over the combination of containerized venturi assemblies and exhalation valve assemblies in previously described fans. These advantages include rapid opening and closing of the exhalation opening 819, which is due to the fact that the displaceable venturi body reacts very quickly to changes in the gas pressure behind the diaphragm 861. Immediately after the supply of gas to the nozzle 851, the diaphragm is thus affected to displace the displaceable venturi body forward to close the exhalation opening 819. Conversely, as soon as gas is no longer supplied to the nozzle 851, the spring will quickly return the displaceable venturi body to its initial position. This enables a much higher oscillation frequency with maximum stroke volume.

Since the inertia is small in the parts forming the unit, it has been found that frequencies as high as 30 Hz can be achieved without going out of phase.

Claims (4)

10 15 20 25 30 8584235-8 PATENT REQUIREMENTS Combined venturi and exhalation valve assembly (816), characterized by a main body (817) having an axial channel (818) forming a central airway opening (823), a venturi body, means (827), by means of the venturi body is displaceable between first and second positions in the channel (818) in the main body (817), means (841) carried by the main body (817) and resiliently presses the venturi body against the first position, a device (837, 837) which forms a seal between the venturi body and the main body, when the venturi body is in the first position, the main body (817) being formed with an exhalation opening (819), which communicates with the channel (818) and is separated from the central airway opening (823) and further formed with an intake opening (848) which communicates with the channel (818) in the main body (817) and is separated from the exhalation opening (819), and the venturi body has a venturi-like channel (833) extending axially thereby, a nozzle (851) supported by the venturi body and having an opening (852) axially aligned with the venturi-like channel (833), a diaphragm (861) supported by the body and extending across the channel therein, an end cap (858). ), which is supported by the body and has an inlet opening (864) in communication with one side of the membrane (861), a device (862) which forms a connection between the membrane (861) and the nozzle supported by the body, a means (863) arranged to establish communication between the inlet of the end cap and the nozzle (851) and extending through the diaphragm (861), whereby gas supplied to the inlet of the cover (858) is passed to the nozzle to bring the diaphragm ( 861) displacing the venturi body from the first to the second position, the device forming the nozzle (851) in the venturi body being designed to allow air passage from the inlet opening (848) to the venturi. - similar to the channel (833). 2. An assembly according to claim 1, characterized in that the device (837, 838), which forms a seal between the venturi body and the main body (817), comprises valve means supported by the front end of the venturi body. An assembly according to claim 1, characterized in that the venturi body consists of a sleeve (829) which extends substantially beyond the entire length of the venturi body. An assembly according to claim 1, characterized in that the nozzle comprises a housing (846), which is attached to the venturi body and has openings (847) and establishes communication between the channel in the venturi body and the inlet opening (848). 9903 QÜ I-mfi- “Y