NO131704B - - Google Patents

Description

Exercise model for artificial respiration.

The present invention relates to a model for practicing

artificial respiration according to the mouth-to-mouth or mouth-to-nose method, comprising parts which, among other things, represent the lungs and head, as the head

the part is hollow and partly exhibits a replaceable nose and mouth part, partly in its interior contains a replaceable, preferably intended for one-time use, inflatable bladder which - through its inlet opening - is in connection with at least one breathing opening in the nose and mouth part, while the cavity in the interior of the head part via a line is connected "with a bag which mainly constitutes the lung part and can be expanded by the air that is pressed out from the cavity in the head part when it is inflated in this arranged bladder through the nose and mouth part, and only the said bag which constitutes the lung part, simulates the resistance of the lungs and chest to inflation.

Models for artificial respiration are expensive and should therefore be suitable for teaching large groups of students who in turn perform simulated resuscitation attempts. Certain models, in addition to a sack or bag representing the lungs, are also provided with a corresponding sack or bag representing the stomach and with valve devices for introducing the insufflation air into the stomach instead of into the lungs in case of incorrect execution of the air supply. With all constructions where air is blown in from the student's mouth into bags or the like in the model, there is naturally a risk of spreading infections, even if the intake opening is provided with replaceable mouth guards that are changed for each new student. In reality, the risk of infection is to a large extent conditioned by infectious substances that penetrate into the interior of the model together with the intake air and remain in the model even when a possible mouth guard is replaced or even the entire intake section of the model is replaced. In order to eliminate this inconvenience, it has already been proposed to allow the nipple of a rubber balloon suitable for single use to join the inflation opening, the rubber balloon body extending sealingly in

in the head's internal cavity, which is airtight except for a wire connection with a bag representing the lung. When the balloon is inflated overcoming its inherent elasticity, it compresses the air

out from the cavity in the head and through the wire connection into the bag that represents the lung. The static or dynamic resistance to inflation thus depends entirely on the properties of the replaceable balloon. This means that great quality requirements must be placed on such a balloon in order for the practice model to work in a way that is both reproducible and anatomically correct. However, the normal toy rubber balloons that are usually used for cost reasons do not satisfy this essential requirement.

The purpose of the present invention is to provide an exercise model of the nature mentioned at the outset, where the simulation of the resistance of the lungs and chest to inflation is completely independent of the properties of the replaceable balloon or bladder, and which is adapted to certain patient groups - e.g. children or patients with a narrowed chest - who require smaller volumes of air during artificial respiration than is normally the case. The exercise model according to the invention is characterized in that the replaceable bladder in its maximally inflated state without resistance has a volume that is smaller than the cavity in the head part, but large enough so that the air that in this maximally inflated state is pushed into the bag that makes up the lung part, here it indicates the air supply required when using artificial respiration. Thereby, the principle that the bladder must always be able to be inflated without offering any resistance that could have an influence on the model's simulation function is maintained unchanged.

The bladder can be made of elastic material, such as rubber, elastic plastic or the like, but also of non-elastic material, e.g. paper, not elastic plastic or the like, depending on desire, availability and price, as the properties of the bladder no longer affect the way the exercise model works. This is because the bladder is inflated without overcoming any inherent elasticity. In this connection, it can e.g. mention that it is usually sufficient that an air volume of approx. 1.5 liters are displaced from the head in the case of correctly performed artificial respiration on an adult patient. For the simulation of artificial respiration on a patient with a smaller lung volume, displacement of correspondingly smaller amounts of air is already sufficient. As the bladder, depending on desire, availability and price, can be made either of stretchable material such as rubber, elastic plastic or the like or of non-stretchable material such as paper, inelastic plastic or the like, the displacement of a smaller amount of air can be provided in two different ways: When using stretchable material, a perforated separating element is arranged in the interior of the model head, e.g. in the form of a net, a grid, a perforated wall or the like which limits the bladder's ability to expand before the material's stretchability is put into use. When using non-stretchable material, the replaceable bladder is simply of a correspondingly smaller size, e.g. in the form of a paper bag whose volume when inflated corresponds to e.g. xa. 75% of the cavity volume. In the latter case, the transition from practicing artificial respiration in normal cases to practicing artificial respiration in special cases takes place simply by choosing a corresponding replaceable bladder.

It is obvious that a bladder with a smaller volume can generally also be used for other reasons, e.g. to avoid damage to the bladder as a result of contact with the inner walls of the cavity, especially in the case of bladders made of delicate material.

In that the relationship between the volume of the cavity in the head and the volume and the other properties of the lung bag is determined once and for all during the construction of the practice model, the device according to the invention will ensure full reproducibility regardless of the special nature of the disposable bladder used in a particular case.

In the cavity in the head, a protruding distance element can preferably be arranged, e.g. a rail extending between the two sides of the head near the entrance of the duct to the lung, and which prevents this duct from being obstructed by the fully inflated bladder. The rail further fulfills the purpose of conducting air away from such air pockets that may form between the inner surface of the head and the bladder when this expands during inhalation, at the same time it can also be mentioned that the presence of such air pockets could lead to a harmful reduction -tion of the achievable inflation volume in the head cavity, which in turn could lead to a change in the lung bag's observable reaction. Preferably, one or more protective elements are also arranged on one or both sides of the rail to prevent the folded bladder from hanging up under the rail when the model is mounted.

In order that in connection with the aforementioned protective element

free outlet of the air through the line to the lung bag is to be ensured, the inner side of the head model's cavity from which the line to the lung bag exits is preferably designed so that in at least one place it forms an angle of more than 120° with the adjacent inner sides. The replaceable bladder is best connected to the element representing the nose and mouth part, by means of a wide flange at the outer edge of which the wall part around the opening in the bladder is secured.

This precaution helps during the exhalation phase to prevent the bladder from closing the opening of one nipple part through which the inside of the bladder is connected to the nose and mouth part, since in this way a lower air velocity is obtained. The bladder can be made of a material and/or provided with a pattern which prevents its inner sides from sticking together in the folded state of the bladder. The replaceable bladder can also be inseparably connected to the connecting piece of the nose and mouth part in order to be replaced together with this part.

The invention will be explained in more detail with reference to the attached drawing of certain design examples. Fig. 1 shows in section an exercise model 1 according to the invention. Fig. 2 and 3 show on a larger scale details of the attachment of the bladder to the mouth area.

The rear part of a head 2, which consists of a one-piece shell with suggested anatomical details, primarily a nose projection part 3, rests on a base plate 1. On the side of the nose projection part 3 which is opposite the forehead of the model head, the skull 2 is provided with an opening H which in anatomical terms corresponds to the joint connection of the nose and mouth with the trachea.

etc

On the side facing the model's neck 5, the skull is provided with an opening 6 which is in connection with an air line 7 corresponding to the trachea which leads to a cavity 15 which represents the lung, and which is arranged in a body part la which is attached to the base plate 1. The cavity 15 is covered by an elastic membrane 16. A correct inflation of this membrane to the position 16a indicated by dotted lines under the influence of the blowing into the nose and mouth part of the head model indicates a correctly performed air supply.

Apart from the openings 4 and 6, shell 2, which represents the head, is completely closed.

Up to the side of the skull 2 which faces the neck 5, a lower jaw 8 is movably supported. The head itself is pivotably supported on the neck and together with this pivotably supported on the body part 1a. The movement of the head, neck and lower jaw, which is utilized for man-over of mutually interacting valves for release, resp. closing the air ducts in the model does not form any part of the present invention and will therefore not be described in more detail.

The space between the nasal projection part 3 and the lower jaw 8 is covered by a nose and mouth part 9 which consists of elastic material and fits tightly against the head above and next to the nasal projection part as well as the pharyngeal opening 4 into which the nose and mouth part 9 penetrates with a protruding flange part 10 which fits tightly against the limiting wall of the opening 4 and is held in this by means of a beaded edge 11 which projects into the head. In the embodiment shown, the nose and mouth part 9 is inserted into a recess in the head below the nasal projection part 3, while the pharyngeal opening ^ is located at the bottom of the recess.

The nose and mouth part 9 extends with a "lobe-shaped part 12

over the adjacent part of the lower jaw 8. Together, the head model 2, the nose and mouth part 9 and the jaw 8 form a lifelike model of a human head and face.

The nose and mouth part 9 is hollow and is, in accordance with the human anatomy, provided with a mouth opening 13 and nose openings 14 which lead into the inner cavity in the nose and mouth part 9 - From this inner cavity extends an opening within the flange part 10 and bead edge 11 to provide a connection between the inner cavity in the head model 2 and the cavity in the nose and mouth part 9.

In the embodiment according to fig. 1 and 2 are set in a central opening through the flange part 10 and the bead edge 11 in the nose and mouth part 9. into a neck or nipple part 18 of a bladder 17 which is close to the inside of the frod 2 and open to the inside of the nose and mouth part 9, and which by blowing in air through the mouth and/or nose openings 13, 14 in the nose and mouth part 9 will be expanded to the dotted indicated position 17b, during which the bladder pushes the air contained in the head 2 into the trachea 7 and the cavity 15.

The bladder 17 is made of non-stretchable material and has a . such a volume that in a fully inflated state it has a volume of approx. 75%

of the entire cavity in the head 2, whereby a corresponding amount of air will penetrate into the cavity 15 and expand it so that the membrane 16 is lifted to the position 16a. The neck or nipple part 18 of the bladder is suitably widened in a bead-like manner at the outer end for secure retention of the bladder in the nose and mouth area during the bladder's expansion by blowing in air.

While the bladder's nipple part 18 (fig. 2) in the one in fig. 1 is inserted into a surrounding ring-shaped seat in the flange part 10 of the nose and mouth part with a thickened edge part, it is of course also possible to provide the flange part 10 on the side facing the interior of the head model with a protruding pipe piece as an elastic neck or nipple part of the bladder 17 is threaded over. In fig. 3 it is shown that the bladder 17 can also be attached directly to the bead edge 11 for joint replacement together with the entire nose and mouth part 9

In order to eliminate the risk of clogging of the throat 7 as a result of the bladder 17, a distance element 20, e.g. a rail, which projects into the interior of the head 2 and prevents contact between the wall of the fully inflated bladder 17

and the mouth of the opening 6 and ensures emptying of air from air pockets that may otherwise form between the bladder and the inner wall of the head. On one or both sides of the rail 20, one or more protective elements may be arranged which have the task of preventing the folded bladder 17 from hooking up under the rail 20 when mounting the model.

For each new student, the nose and mouth part 9 with attached bladder 17 is removed and replaced by a cleaned or new nose and mouth part 9 with a new bladder 17.

It is clear that the bladder 17 can be of such a cheap design

that it can be thrown away after one use without any poorer quality jeopardizing the anatomically correct function of the exercise model and the reproducibility of the exercises. The nose and mouth part can also be of the disposable type and possibly be made in one piece

with the bladder 17,. as it e.g. is shown on fig. 3- Usually, however, the nose and mouth area will be used again after cleaning and

only the bladder 17 be thrown away after one use. Finally, of course, there is also the option of cleaning both the nose and mouth area and the bladder for renewed use.

Claims (2)

1. Practice model for artificial respiration according to the mouth-to-mouth or mouth-to-nose method} comprising parts that represent lungs and head, with the head part (2) being hollow and partly showing a replaceable nose and mouth part , partly in its interior contains a replaceable, preferably intended for one-time use, inflatable bladder (17) which through its inlet opening is in connection with at least one breathing opening in the nose and mouth area, at the same time that the cavity in the interior of the head part via a line (7) is in connection with a bag (16) which mainly constitutes the lung part and can be expanded by the air that is pushed out from the cavity in the head part when the bladder (17) provided in this arrangement is inflated through the nose and mouth part, and only the said bag (l6) which constitutes the lung part, simulates the resistance of the lungs and chest to inflation, characterized in that the replaceable bladder (17) in its maximally inflated state without resistance has a volume that is smaller than the cavity in the head part, but sufficiently large t to the fact that the air which in this maximally inflated condition is pushed into the bag which forms the lung part, here indicates the air supply which is necessary when using artificial respiration. 2. Exercise model as specified in claim 1, characterized in that the bladder is made of mainly non-stretchable material.