DE1491635C - Open circuit breathing apparatus - Google Patents

Description

by that the volume of the small bellows at which the control valve is open, corresponding to the amount the decrease of the small bellows can be changed. So the little container receives some of the gas that passes through the inhalation valve and releases it into the atmosphere when the exhalation valve is open and the control valve is closed, corresponding to the large bellows when it reaches its maximum volume, and is opened according to the small bellows when it reaches a predetermined volume. * q

According to further embodiments of the invention, the inhalation and exhalation valve are activated by the gas pressure a tube that connects the outlet of the small bellows with the control valve. the Pressure in the tube, as it rises, closes the exhalation valve and then the inhalation valve opens. The advantage is that the exhalation valve has been found to be desirable for medical purposes something to close sooner than the inhalation valve opens when a patient is breathing through the Breathing apparatus is supported.

A further development is that the inhalation valve is closed and opened when loaded is when the control pressure is between the maximum pressure in the large bellows and the maximum pressure in the small bellows and the outlet valve is open when loaded and closed when pressure is applied, which is less than the pressure at which the inhalation valve opens and is greater than the maximum pressure im big bellows. According to a further development, the large bellows has an outlet into a passage, as further disassembled below and this bellows is manually operated.

The volume of the container and the speed of the gas flow from the source to the device are predetermined and set low to the desired automatic operation of the device to surrender.

The present invention is based on the fact that a mathematical relationship between the body weights, tidal volume and breathing speeds for people whose Body weights can be within a range that varies from that of children to that of adults extends. This relationship is expressed graphically in the Raford nomogram, which is used in the New England Journal of Medicine, Vol. 251, 1954, p. 877.

It has been found that if a constant predetermined gas volume of the device during each breathing cycle is supplied in addition to the volume of gas that the patient needs per cycle, the volume per minute that is necessary to feed the device, preferably constant for patients with a wide range of body weight is when the volume per minute and the constant predetermined volume have a relationship with one another that justifies those who is recorded in the nomogram.

This relationship is set out in the following table, in which the constant predetermined Volume with 170 ml (milliliter) and the volume per minute with 8.4 1 is selected.

It can be seen from the table below that when gases are supplied to the device according to the invention are at an amount of 8.4 1 per minute, people with a body weight of 6 to 200 Ib are adequately ventilated (1 Ib = 0.4536 kg).

Expected frequency breath frequency body Respiratory volume (Radford volume (Volume Weight (ml) nomo- + 170 (ml) per minute (Ib) gram) Respiratory volume 13th 183 + 170) 6th 24 46 194 46 10 50 43 220 43 20th 90 38 260 38 35 130 32 300 32 50 180 28 350 28 70 280 24 450 24 100 450 19th 620 19th 150 600 14th 770 14th 200 11th 11th

The present invention is based on the assumption that the patient who is ventilated by the device has normal compliance. However, it has been found in practice that if compliance deviates from normal by any amount, the patient either over- or under-ventilated in to an extent that is sustainable for a fairly short period of time.

An example implementation of the invention is described with reference to the drawing, wherein

F i g. 1 shows a reproduction of a breathing apparatus according to the invention and

F i g. 2 the four possible positions of the cock 12 of FIG. 1 shows.

The device has a housing 2 with a cylinder 4 for oxygen, air or other gases and is attached to its base. The gas is fed in from the cylinder 4 via a conventional pressure reducing valve 6 Needle valve 8, a flow meter 10 and a cock 12 are fed to the inlet of the device.

In the housing 2 a small bellows 14 is arranged, which is loaded by a helical spring 16, so that the small bellows expands when the gas pressure in the bellows reaches a value of 100 cm Water column rises. Gas flows from the small bellows 14 to a tube 18. The movable end of the The bellows interacts with a lever 26 which is mounted at 28. On the free end of the Lever 26 is arranged a movable contact 30, the purpose of which will be described later. The order of contact 30 is such that it is touched and moved by the free end of lever 26, when the bellows 14 assumes a volume which is determined by the position of the contact 30.

The gas flowing from the small bellows 14 flows through the tube 18 into the interior of a large one Bellows 32 by a control valve 34 which is arranged in the bellows. One end of the bellows 32 is fixed on the container 2 while the movable end with a lever 36 in contact which is stored at 38. Lever 36 is supported by an intermediate member 40 which is mounted on a lever 42 is rotatably connected to a member 43 which is loaded by means of tension springs 44, so that the bellows 32 expands when the internal pressure reaches a pressure greater than 25 cm water column overpressure.

The other end of the link 43 is connected to a double-armed lever 45 which is mounted at 46 is. The other arm of the lever 45 is rotatably supported between the ends of a second lever 47, one arm of which is provided with the contact 30.

The lever 47 is connected by an articulated connection to a rocker arm 48, which is mounted at 49 is. One end of the lever 48 is supported by a coil spring 50 with an arm of a double lever 51 connected, which is mounted at 52 and the other arm with the valve member 35 of the control valve 34 is connected so that when the lever 48 is in its illustrated lower position, the valve is in the closed position, and when it moves through the tilt position to the up position, the valve 34 snaps into the open position.

The movement of the lever 48 and thus the position of the lever 34 is controlled directly by the movement of the contact 30 . However, because lever 47 is located on lever 45 which is controlled by the position of the large bellows, movement of valve 34 is controlled by both the amount of enlargement of large bellows 32 and that of small bellows 14. This is because, when the large bladder is inflated, the contact arm 30 is physically lifted away from the tip of the bladder 14 in accordance with the downward movement of the limb 47. As a result, the small bladder 14 is inflated to a much greater amount before the tip 26 closes Contact 30 touched and operated. Accordingly, when the large bellows is almost collapsed, it can be seen that only a relatively small inflation of the bellows 14 is necessary before contact 30 is actuated. The reason for this will be fully described below.

When the large bellows 32 is collapsed under the action of the loading springs 44, it flows the gas through a wide-bore passage to a breathing valve disc 54 from which the gas flows through one arm of a conventional movable two-arm tube 55 connected to a breathing mask 56 is. The other arm of the tube 55 is connected to the inlet side of an exhalation valve, which forms part of the device. The gas flowing through the exhalation valve 60 is released into the atmosphere emptied.

The inhalation valve 54 is of the type in which the mouth 62 of the outlet tube of the valve is closed by a valve member 64 which is arranged on a diaphragm 65 and is loaded in the closed position by means of a compression spring 66 which acts on a push rod 69. The bumper 69 is attached at one end to a button 70 which is disposed on the center of a flexible membrane 72. The membrane and the walls of valve 54 form a chamber in fluid communication with the tube.

The exhalation valve 60 has a mouth 74, the inlet tube of which is closed by a valve member 76 which is moved by a tension spring 78 so that the tube 60 is loaded in the open position. The valve member 76 is arranged on a flexible membrane 80 and the spring 78 is arranged in a chamber housed in communication with the chamber of the inhalation valve 54 and the tube 18 is.

Both the loading springs 66 and 78 of the inhalation and exhalation valve can be used in a known manner Way to adjust the operation of the valve. The loads on the valves are arranged so that the inhalation valve 54 at a pressure between the maximum pressure in the large Bellows 32 and the maximum pressure in the small bellows 14 opens; the Ausatemveitil 60 is set up to close at a pressure lower than the pressure at which inhalation valve 54 opens, and higher than the maximum pressure in the large bellows 32.

In communication with the tube 84 extending from the inhalation valve, there is a collapsible container 86. The container is in the form of a chamber with a movable end wall so that the Difference in volume between the smallest and largest volume of the container a selectable amount is, in the current example 170 ml. The movable end wall 88 is by a compression spring 80 loaded so that the end wall moves to its remote position when the pressure in the Chamber a pressure of 5 cm of water exceeds.

A valve 100 with four positions and three outputs, in which two of the positions are closed, is assigned to the cock 12. One of the outlets is connected to tube 84, a second outlet to tube 18 and the third outlet to passage 53. The respective positions of valve 100 and cock 12 are shown in FIG. 2 a to 2 d shown. F i g. 2a shows the arrangement in the "off" position, FIG. 2b in the "oxygen position, FIG. 2 c in the "hand" position and F i g. 2 d in the "automatic" position.

It can be seen that F i g. 1 shows the arrangement in the "automatic" position in which it follows is working:

Gas flows from the cylinder 4 with a pressure of 300 cm of water to the entrance of the small bellows 14, from which the gas at a low pressure is accepted by the control relay 34, which is in the open position flows into the interior of the large bellows 32. The time to completely fill the bellows 32 depends on the tidal volume that the patient had during the previous breathing cycle was delivered.

The large bellows 32 rises until projections 103 from member 43 come into contact with lever 47, the movement of which is sufficient to operate the tilt mechanism and close valve 34. Immediately when this occurs, the pressure in the tube 18 begins to rise to the pressure of 100 cm of water to which the small bellows is set. When this pressure is reached, the exhalation valve 60 is first closed and then the E-breathing valve 54 is opened in order to allow the large bellows 32 to sink under the action of the loading spring 74 and to press gas to the patient. The inhalation valve 24 is opened because the increase in pressure in the tube 18 actuates both the large diaphragm 72 and the smaller diaphragm 65, with a resultant force acting on the valve member 64 from the right, as shown in FIG. 1 can be seen, and valve 54 is opened accordingly. This lowering of the bellows 32 has the effect that the contact 32 is moved away from the bellows 14, with the position of the valve 34 unchanged.

As gas flows to the patient, the gas pressure in the small bellows 14 reaches the predetermined value of 100 cm of water; the bellows rises to its position in which the contact member 30 is moved in order to open the control valve 34. When this occurs, the pressure in the tube 18 drops and causes the inhalation valve 54 to close and then to close

Open the exhalation valve 60 to allow the patient to exhale into the atmosphere through valve 60 to allow.

During the inhalation portion of each breathing cycle, when gas flows from the inhalation valve to the patient, the container 86 is fully inflated to its maximum volume; i.e. that 170 ml of the total volume are stored in the container upon passage through the inhalation valve 54. When the exhalation part the breathing cycle is reached, the inhalation valve is closed and the exhalation valve is opened, to allow container 86 to empty, thereby releasing the 170 ml of gas to atmosphere exhaled through the exhalation valve 60; while the patient exhales, what with a pressure happens from only 5 cm of water, the gas does not go to the patient, but bypasses the gas mask 56 and go to the exhalation valve 60.

The breathing apparatus according to the invention works so that the volume of gas, which from the large bellows 32 emerges per breathing cycle, is equal to the tidal volume required for the patient, plus the volume delivered by the container 86. If the device is used to ventilate an adult is needed, the large bellows 32 empties almost completely with each cycle. That causes a Pivoting the lever 45 as a bell handle clockwise and thereby a movement of the contact 30 away from the small bladder so that the small bladder inflates to its maximum value before valve 34 is opened. This extends the period that the patient is supplied with gas.

When used to ventilate a child, the large bellows only go a small amount per cycle back. This will not make contact 30 entirely, just a small amount of that Moves away small bellows, which thereby takes a shorter time to open the valve 34 enough to get bloated. This causes a brief period of bloating and one accordingly rapid amount of breath.

When the cock 12 and the valve 100 coupled to it in their position shown in FIG. 2b are moved, the breathing apparatus delivers gas, e.g. B. oxygen, directly to the patient, the cyclical mechanism is ineffective. In this position tube 18 is in communication with the exhalation valve, and the gas is delivered at a low pressure so that the exhalation valve remains open. The gas is delivered evenly to the patient; all gas that is not inhaled works directly to the exhalation valve.

The in F i g. 2 c position enables the device for hand-operated air supply to the patient. This option is particularly common and permitted the device still has a use when the supply of gas from the container 4 is exhausted. In In this position, the gas supply to the device is blocked by a tap 12 and the passage 53 and the working chamber of the inhalation valve 54 in communication with the valve 100. The lever 36 of the large bellows 32 is provided with a button 101 or handle, with the help of which the bellows through Can be hand pumped. When the lever 36 is raised to inflate the bellows, the atmospheric air from inside the container 2, which is not airtight, through a loaded one-way valve 102 in the bellows 32.

During this period, the exhalation valve remains open under its load, allowing the patient the exhalation.

When lever 36 is pressed to deflate the bladder, pressure builds up in passage 53 of the Chamber of the valve 54 and in the tube 18. First the exhalation valve is closed and then the inhalation valve is opened by the action of this pressure on the membrane 72.

The fact that the container 86 is loaded and unloaded on each breathing cycle is of neither Importance when the device is operated manually.

Thus, the device according to the invention automatically adjusts itself to the delivery of a small volume of gas at a high cyclical speed in a child or on a large volume of gas at low speed in an adult; Speed and volume are exactly the same that of a normally breathing patient.

The invention is based on the premise that the patient ventilated by the device has lungs has normal compliance. Practice shows, however, that if compliance is reduced by an amount from normal deviates, the patient is either over- or under-ventilated to an extent that is still suitable for a relatively short period of time is sustainable.

1 sheet of drawings 209 547/91

Claims (6)

1 2 valve is connected, an inhalation valve through which the large bellows is connected to a patient in the case of his patent claims: connection with the device, and an exhalation valve for receiving the patient's 1. Open-circuit breathing apparatus, consisting of 5 th exhaled gas and exhaling into the from a small bellows for feeding with an atmosphere. steady gas flow, a large bellows, the Such devices are especially used for ventilation connected to the small by a control valve. People who drown or inhale is, an inhalation valve, through which the non-oxygen gases suffocate or whose breathing-sized bellows with a patient's muscles paralyzed by an electric shock binding is connected to the device, and a. Exhalation valve for the intake of the PA is known as such a device according to the British tient exhaled gas and exhale patent specification 900 866, which is a breathing apparatus with open into the atmosphere, thereby identified- describes a cycle consisting of a small draws that the inhalation and exhalation valve 15 bellows, with a steady gas flow below (54, 60) is supplied through a valve (34) for opening and pressure, and a large one. Bellow that with Close in sections each breathing cycle which is connected to the small by a two-way valve. Patient controllable and that the control valve (34) The bellows are enclosed with the patient is when the large bellows (32) is connected to a breathing valve, and that through the patient maximum Volume reaches, and is open, 20 th exhaled gas can through an exhalation valve when the small bellows (16) flow a predetermined volume to the atmosphere. lumen and that a small container (86) The gas flow of the device is essentially the same known to be parallel to the lungs of the moderately at all stages of the respiratory cycle, and that Patient is provided. all of the gas supplied to the device is available to the patient 2. Breathing apparatus according to claim 1, characterized in that 25 available; but this device fits when working indicates that the inhalation and exhalation valve does not automatically adjust the tidal volume and the frequency (54, 60) controlled by the gas pressure in a tube (18) of the breathing of a paste connected to the device that are the exit of the little patient. Such is a trained person to operate ges (14) connects to the control valve (34). and adaptation of the device to the patient to be treated 3. Breathing apparatus according to claim 1 or the following, 30 patients necessary; z. B. can the patient an earth through characterized as being the volume of the grower, which is a large tidal volume at small bellows (14) in which the control valve needs a relatively low frequency, (34) is open, corresponding to the amount of the or a child who has a small tidal volume in a The inclusion of the large bellows (32) requires a relatively high frequency, so that the is cash. 35 Adaptation to the device in a suitable manner 4. Breathing apparatus according to claim 1, 2 or 3, must be presented. characterized in that the inhalation valve. Other known devices have a plurality of (54) is closed and open when loaded, adjustable controls that control the output of the if the control pressure between the maximum device according to the breathing requirement of the individual patient pressure set in the large bellows (32) and the maximum 40th. Such devices suffer from the stress in the small bellows (14) lies, and the part that it can only be safely operated by trained people (60) open when loaded and can be used when. So is in the UK patent one Pressure is closed, which is smaller than font 832 477 a handle to control the gasder Pressure at which the inhalation valve opens and flows through the breathing apparatus and a second control variable than the maximum pressure in the large bellows. 45 handle provided to the effective capacity of a 5. Altemgerät according to claim 1 or the following, expandable chamber parallel to the lungs of the characterized in that the large bellows (32) vary the patient. The pressure-controlled breathing device designed to be let out into a passage (53) has two valves which, depending on the pressure bypassing the patient, are opened or closed to allow for exhalation differences.
valve (60) leads. 50 The object of the invention is to adapt the 6. Breathing apparatus according to one or more of the tidal volume and the frequency of breathing when preceding claims, characterized in that the devices mentioned at the outset are automatically designated, that the device act to absorb gas. determined at a volume of 8.4 l / minute This object is achieved according to the invention and the container (2) releases 170 ml per breathing cycle 55 that the inhalation and exhalation valve delivers through a ven. til to open and close in sections each The patient's breathing cycle can be controlled and that the control valve is closed when the large bellows closes reaches maximum volume, and is open when the small bellows reaches a predetermined volume, and that a small container is provided parallel to the patient's lungs in a known manner. The device can automatically determine the tidal volume and the breathing frequency of a patient. The invention relates to a respirator with 65 men, which is connected to the device. This can open circuit, consisting of a small bellows the device by a relatively inexperienced Perzur Feeding with a steady gas flow, a son can be operated. The automatic adaptation to large bellows, which is carried out with the small by a control lungs of a child or adult