SE434702B - exhalation valve - Google Patents

Description

1s12143 ~ in a seat which on the downstream side is covered by a spring-loaded valve disc, so that exhalation takes place only through the valves, if the exhalation pressure is able to open the valve against the valve disc affecting the spring force.> Spring-loaded PEEP valves have the advantage of being compact and usable without the need for pneumatic pressure or liquid containers. However, known constructions have had the disadvantage that they have a tendency to vibrate during exhalation, which reduces the accuracy of the valve's adjustability and results in an unbearably high noise level. The present invention seeks to eliminate or at least reduce the occurrence of undesirable vibration associated with exhalation valves. The invention is based on a construction known from US-A-3 850 405, although it is not intended as a ventilation valve in connection with the sJ <. PEEP ventilation without such as pressure and flow control valve. The construction of the known valve is in itself completely unsuitable for use in the supply of breathing air, where extremely high requirements apply with regard to the accuracy of the valve opening and closing.

The present invention seeks to design the prior art valve so that it is useful as an exhalation valve, whereby the exact opening and closing requirements which must be set for such a valve are met and the required operating forces are extremely small by minimizing all the frictional forces occurring.

This object is solved according to the invention by the construction details specified in the characterizing part of claim 1.

For the present invention it is of particular importance that the two arranged diaphragms not only limit the damping chamber but also enable a "floating", i.e. frictionless control of the valve disc unit, whereby the opening and closing pressures critical for an exhalation valve can be maintained precisely. The practically frictionless control of the valve disc unit, which is achieved according to the invention, is of particular importance for the reason that the difference between opening and 7812143 The closing pressures are very small and consequently the frictional force occurring in other previously known constructions is so large in relation to said pressure difference that an exact maintenance of the opening and closing pressures can practically not be ensured.

The disc 14 also arranged within the scope of the present invention further improves the mode of operation of the valve in that the required narrowing of the flow channel is achieved. In addition, said disc also provides protection for the thin diaphragms against impermissible stresses which may occur during disassembly of the valve for cleaning or disinfection, since the disc prevents the unlimited relative movement of the valve stem relative to the valve disc assembly.

A preferred embodiment of the exhalation valve according to the present invention is now described as an exemplary embodiment with reference to the drawing, which shows a longitudinal section of such an exhalation valve.

The exhaled valve shown consists of a two-part, substantially circular cylindrical valve housing 1, which is divided into two chambers by an annular partition 2. A first chamber, the inlet chamber 1a, lies substantially within an outwardly open valve stub 3, arranged to be airtightly connected to the exhalation outlet in an apparatus for artificial ventilation of a patient's lungs under overpressure, while a second chamber, the outlet chamber 1b, is in communication with the atmosphere through openings 4 in the wall of the valve housing 1.

The inner edge of the partition wall 2 forms a circular valve seat 13 on the downstream side of the partition wall 2, and this seat 13 engages a valve disc unit 30, which is pressed against the seat 13 by a coil spring 5 arranged in the outlet chamber 1b. The spring 5 has such a position that one end abuts against the valve disc assembly 30, while its other end abuts a movable member 6, which is adjustably held in position by a threaded hood 7, which is screwed onto the end portion of the housing 1 and which is thus movable in the direction of the longitudinal axis of the spring, so that on the spring force acting on the valve disc unit 30 can be adjusted by turning the threaded hood 7. The valve disc unit 30 comprises a flexible, annular diaphragm 8 of rubber or similar elastic material which forms the outer circumference of the valve disc unit and which is able to completely seal the opening. in the partition 2 under the influence of even a light pressure on the downstream side. An outwardly projecting flange 9 on a support element 31, consisting of rigid material of low weight, for example a suitable plastic, is attached to the inner circumference of the ring 8.

The support element 31 also has a central hub portion 10, which extends axially into the interior of the prestressed spring 5, which abuts against the downstream side of the flange 9. The hub portion 10 has an inner bore 11, which extends centrally through the support element 31.

A valve rod 12 is attached within the valve housing 11 in line with the longitudinal axis of the housing and projecting through the bore 11 and thus at right angles to the seat 13. A small disc 14 is attached to the rod 12 at a location within the bore 11 to limit the axial movement of the valve disc unit 30 in relation to the rod 12 and thus to the valve housing 1. For this purpose, two parts 15, 15 'are fixed in the bore 11, wherein grooves 16 suitable for receiving corresponding projections on the parts 15, 15' are arranged in the bore 11. As shown in the drawing, each part 15, 15 'comprises an inwardly projecting portion 17, 17', which extends around the rod 12 with a fairly large radial clearance. The portions 17, 17 'have such a position that they limit an annular recess within which the disc 14 lies, the opposite surfaces of the projecting portions 17, 17' forming abutment surfaces which, by contact with the disc 14, limit the axial movement of the valve disc unit 30 in advance. holding to the disc 14 and thus to the housing 1.

Two thin-walled, elastic, annular diaphragms 18, 18 'of soft rubber and preferably of mechanical shape to facilitate axial movement extend between the axially outermost ends of the parts 15, 15' and the rod 12.

The inner edge of each diaphragm 18, 18 'is reinforced by an edging 19, 19', which connects tightly around the rod 12. The outer circumference of each diaphragm 18, 18 'is provided with a sealing edge ring 20, 20 'which is inserted into a recess in each of the parts 7812143-1 15, 15', whereby the outer edges of the diaphragms 18, 18 'are clamped between the bore 11 and the associated part 15, 15'.

A labyrinth or damping chamber 32 is thus formed by the rod 12 with its disc 14, the two diaphragms 18, 18 'and the parts 15, 15', and this chamber 32 is filled with a fluid 21 of high viscosity, for example silicone oil, which flows within the labyrinth chamber 32, as the valve disc assembly 30 moves relative to the fixed valve stem 12.

In the above-described construction of the valve disc assembly 30 for a spring-loaded PEEP valve, a person skilled in the art can easily coordinate the flow path in the labyrinth chamber 32 and the viscosity of the enclosed liquid 21 in such a way that a critical damping is obtained in the vibration system consisting of the biased spring 5 valve. the disc unit 30 and the volume of air underpressure present during the exhalation phase between the patient's airways and the valve disc unit 30.

When the valve described above is connected via the nozzle 3 to the exhalation outlet of the ventilator and the patient exhales through the valve, the valve disc unit 30 will be lifted from the seat 13 so that exhaled air can pass through the seat 13 to the ambient atmosphere as the patient exerts an exhalation pressure. sufficient to overcome the spring force acting on the downstream side of the valve disc assembly 30. Since the damping chamber 32 in the valve disc unit 30 provides a damping effect by means of a viscous fluid, no damping force is obtained if the valve disc unit 30 remains stationary in relation to the fixed valve rod 12. Only when the valve disc unit 30 is movable will a reaction force build up due to the pressure loss caused by the flow of liquid in the labyrinth chamber 32, and the direction of this force is always opposite to the direction of the momentary direction of movement of the valve disc unit. Thus, when the exhalation begins, the movement of the valve disc assembly 30 will begin at a pressure determined solely by the spring force and the area of the valve disc assembly. During the following opening movement, the spring force together with an addition from the damping device acts against the pressure exerted by the exhaled air towards the valve disc unit 30. When this opening movement ceases, the spring force and the exhalation pressure against the valve disc will again alone determine the position of the valve disc unit 30. valve seat 13. Should the pressure of the exhaled air decrease due to pressure vibrations in the air or decreasing exhalation rate, the spring force will move the valve disc assembly 30 towards the valve seat 13, the damping device producing a force acting in the opposite direction to the spring force, which in turn will counteract the acceleration of the valve disc unit 30 towards the seat 13. When the damping device is adjusted to critical damping in the manner described above, it will not be possible for the valve disc unit 30 to generate resonant vibrations through these movements, and the opening and closing pressure of the valve is requested. is tamed only by setting the adjustable spring force.

Claims (3)

7812143-1 PATENT REQUIREMENTS Valve with a valve seat (13) arranged in a ventilated housing (1) and a valve disc unit (30) which is biased in the upstream direction by a compression spring (5) acting on the downstream side of the unit and which is guided by a fixed housing ( l) connected valve rod (12) and in which a damping chamber (32) is arranged, which contains a viscous liquid (21), and which by corresponding design of the valve rod (12) within the damping chamber is divided into two chambers, which communicate with through a throttle channel, characterized in that for use as an exhalation valve for PEEP ventilation the valve rod (12) extends freely through a bore (11) in the valve disc unit (30) between its upstream and downstream sides, that for delimitation of the damping chamber (32) a pair of flexible annular diaphragms (18, 18 '), preferably of soft rubber and having a conical shape extending between the valve rod and the valve disc unit and that a rigid disc (14) is arranged within the damping the chamber (32) and fixedly connected to the valve stem (12), this disc (14) by contact with abutment surfaces (17, 17 ') within the bore (11) in the valve disc unit (30) limits the axial movement of the valve disc unit (30) relative to the valve rod (12). Valve according to Claim 1, characterized in that the compression spring (5) abuts against a threaded hood (7) which can be adjusted in the housing (1). Valve according to claim 1 or 2, characterized in that the valve disc unit (30) comprises a rigid support element (31), which is attached to the inner edge of a flexible, annular diaphragm (8), arranged to come into engagement with the valve seat (13).