EP0152528A1 - Respiratory mask with overpressure inside - Google Patents

Abstract

The lung-controlled valve is separated by a control membrane (5) into a breathing (7) and an outer chamber (6). The breathing chamber, connected to the inside of the mask, has its internal pressure; for breathing gas supply it is connected to the breathing gas source via an inlet valve (8) controlled by the control membrane via a coupling device (10). The outer chamber contains a locking device with which, triggered manually by a magnetic switch (14), the control membrane is held in a locking position while the inlet valve is closed. With the respirator mask removed, an unnecessary flow of breathing gas is prevented. When the patient starts to breathe and starts breathing, the control membrane is pulled off the magnet without any further action to be taken by the user and is thus released from the blocking position. The normal lung-controlled supply of breathing gas with the excess pressure inside the mask is possible again.

Description

Breathing mask with positive pressure inside the mask

The invention relates to a breathing mask with excess pressure in the mask interior according to the preamble of claim 1.

Such a breathing mask with excess pressure in the interior of the mask is already known from German patent application P 32 45 717.

In the compressed gas respirators with overpressure in the respirator it is ensured that there is an overpressure in the respirator during use both in the exhalation and in the inhalation phase. This overpressure prevents the ingress of ambient atmosphere, which may be dangerous, into the respirator in all circumstances during use. Possible leaks always create a gas flow from the inside to the outside. In these devices, however, the difficulties that arise from the fact that with the end of use and removal of the respiratory mask, i.e. opening the breathing circuit, the breathing gas storage containers have to be closed or the function of the regulator must be switched over, otherwise there will be an outflow of the breathing gas and thus a reduction in the time of use. From DE-OS 30 38 100 the equipment of a respiratory mask with a lung-controlled valve is known, with which an excess pressure is generated and maintained in the interior of the mask. The valve comprises, in a valve housing between a breathing chamber opening out in front of the user's respiratory organs and an outer chamber connected to the external atmosphere, a pressure chamber connected to both chambers via a valve. With this pressure chamber, an excess pressure is generated in the breathing chamber and thus in the mask interior both during inhalation and during exhalation. For this purpose, a wall part of the pressure chamber is movably connected to the inner wall of the valve housing via a control membrane. An inlet valve of the breathing mask for breathing gas is actuated via an actuating device via the respiratory pressure movement of the pressure chamber.

A switchable blocking device enables the breathing gas supply to be interrupted when the mask is removed. The locking device consists of a shaft rotatably mounted in the breathing chamber. One end is guided in an airtight guide bushing through the wall of the breathing chamber to the outside and there is provided with a radial actuating lever. At this the shaft can be swiveled between two end positions. In one end position, the locked position, a resilient tongue of the actuating lever engages in a recess in the wall of the breathing chamber. The shaft has a wire bracket inside. The wire bracket touches the lever arm of the inlet valve in the locked position and brings it into the closed position. A leg spring pushes the wire bracket, which can be pivoted with the shaft, into the other end position, the release position, in which it fits the inner wall of the Breathing chamber rests and allows free movement of the lever arm. When the mask is removed, the actuating lever to be actuated has been locked into the locked position, thereby interrupting the breathing gas supply. After putting on the respirator, the first breath is activated automatically. A force must be generated by the suction of inhalation acting on the diaphragm on the lever arm, which is sufficient to force the locking device out of the locking position. The leg spring then brings the locking device into the release position.

However, since the force determining the switch-on depends on the locking mechanism on the outside, changes in the course of use due to dirt, the effects of force or wear can result in a change in the switch-on resistance and reliability. The required sealing of the bushing through the wall of the breathing chamber is complex and a possible source of interference, as is the construction of the locking device from numerous individual parts.

It is also known from German patent application P 32 45 717 a further breathing mask with excess pressure in the interior of the mask, which is also generated and maintained by a lung-controlled valve. The housing of the lung-controlled valve with a breathing gas connector for the supply and an outlet connector for the breathing mask for the breathing gas is closed with a housing cover. The housing is separated by a control membrane, forming an outer chamber towards the housing cover and a breathing chamber below. The breathing chamber is connected to the inside of the breathing mask via the outlet connection. The breathing gas nozzle is switchable with the breathing chamber through an inlet valve which is in contact with the control membrane via a lever device.

The outer chamber contains a control device with which, triggered manually by a locking slide to be moved laterally, the control membrane is held in a locked position by means of a holding collar while the inlet valve is closed and the pressure is released. As you inhale, the pressure in the breathing mask and breathing chamber decreases. As a result, an overpressure lever moves the inlet valve into an open position under the force of a spring via the control membrane and the lever device. If the respiratory gas is to be prevented when the respirator mask is removed, i.e. even if there is no excess pressure, then the locking slide, which has been moved into the locked position, lifts the overpressure lever against the spring against the control diaphragm, which then loses pressure under the action of the closing spring of the valve that closes up. Your retaining collar is pinched after you release the locking slide. The inlet valve remains closed until the next deep breath after the respirator is put on.

The object of the invention is to improve a respirator mask with excess pressure in the mask interior of the type mentioned so that with the elimination of mechanical components from the lung-controlled valve, wear and thus possible jamming of a lever mechanism can no longer be a cause of error.

This object is achieved in a generic device by the characterizing features of claim 1. The characterizing features of subclaims 2 to 5 contain expedient refinements of the lung-controlled valve according to the invention.

The advantages achieved by the invention are, in particular, that instead of a plurality of components which have to move with one another, practically only the magnetic push button in relation to a steel plate in the control membrane in any case brings about the inlet valve shut-off. The magnetic forces can be safely controlled, wear is excluded.

• Figur 1 das lungengesteuerte Ventil in normaler Betriebsstellung
• Figur 2 den Sperrzustand.

An embodiment of the invention is shown in the drawing and is described below. Show it

• Figure 1 shows the lung-controlled valve in the normal operating position
• Figure 2 shows the locked state.

The lung-controlled valve upstream of the breathing mask has a valve housing 1 with a breathing gas connector 3 for the supply and an outlet connector 4 for the breathing mask and is closed with a housing cover 2. The valve housing 1 is separated from the housing cover 2 by a control membrane 5, forming an outer chamber 6 above the housing cover 2 and a respiratory chamber 7 below, the pressure of which corresponds to the internal pressure of the respirator. The breathing gas nozzle 3 is separated from the breathing chamber 7 by a lung-controlled inlet valve 8 for the breathing gas containing the valve body 9.

The valve body 9 is movably connected to the control membrane 5 via a coupling device 10.

The housing cover 2 contains, in the outer chamber 6 it forms, guided in spacers 11, an overpressure spring 12 which, with the pressure against the control membrane 5, determines the overpressure in the breathing chamber 7 and thus the interior of the mask. Axially supported in a guide 13, the housing cover 2 contains a magnetic switch 14, which is held by a return spring 15 on the outside in the operating position with the stop of its magnet 16. The control membrane 5, surrounded by the material, has a steel plate 17 opposite the magnet 16.

The lung-controlled valve works in a known manner during normal breathing operation with a respirator mask on. With inhalation, i.e. a negative pressure in the mask interior and thus also in the breathing chamber 7, the control membrane 5 opens the inlet valve 8 via the coupling device 10. The overpressure spring 12 controls the overpressure in the interior of the mask during further breathing.

When the respirator mask is removed, the inlet valve 8 must be securely closed in order to prevent an unnecessary outflow of breathing gas, even if there is no excess pressure in the breathing chamber 7. For this purpose, the magnetic button 14 is pressed against the return spring 15 in the housing cover 2. The magnetic force of the magnet 16 attracts the steel plate 17 and thus the control membrane 5 and holds it against the pressure spring 12 in the position shown in FIG. 2. The inlet valve 8 is closed.

When the respirator mask has been put on and then the wearer breathes with a first breath, the spring forces of the pressure spring 12 and the return spring 15 add to the negative pressure generated by the lungs in the breathing chamber 7 with a pulling force F. This force is sufficient to to separate the adhesion between the magnet 16 and the steel plate 17. The magnetic switch 14 jumps back into the operating position, as shown in FIG. 1.

The spacers 11 limit the path of the control membrane 5 when the inlet valve 8 is closed and ver thus prevent it from coming into the area of the magnetic force of the magnet 16 unintentionally against the force of the pressure spring 12 in the operating position.

Claims (5)

1. Respirator with overpressure in the mask interior with a lung-controlled valve, in the valve housing between a respiratory chamber opening out in front of the respiratory organs of the user and an external chamber connected to the outside, provided with a locking device, a control membrane is arranged with which an inlet valve for a coupling device the breathing gas can be actuated, characterized in that a) the locking device is a in the housing cover (2) guided by a return spring (15) held on the outside magnetic switch (14) in the outer chamber (6) a steel plate (17) in the control membrane (5) opposite in a magnet (16 ) ends b) the control membrane (5), which is connected to the inlet valve (8) via the coupling device (10), is controlled by an overpressure spring (12) as a function of the internal mask pressure and c) the magnetic button (14) pressed in keeps the inlet valve (8) closed via the magnetically adhesive steel plate (17). 2. Respirator with excess pressure in the mask interior according to claim 1, characterized in that the magnet (16) is a permanent magnet. 3. Respirator with excess pressure in the mask interior according to claim 1, characterized in that the magnet (16) is an electromagnet with a power source. 4. Respirator with excess pressure in the mask interior according to claim 1 to 3, characterized in that the pressure spring (12) is guided in spacers (11). 5. Respirator with excess pressure in the mask interior according to claim 1 to 4, characterized in that the steel plate (17) is enclosed by the material of the control membrane (5).

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