DE238278C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

™ Ju 238278 CLASS 30 /. GROUP

Dr. MAX PESCATORE in BAD EMS.

Breathing machine. Patented in the German Empire on September 4, 1908.

To physically influence breathing are mainly two different types of Devices known, namely a pneumatic device in the manner on the respiratory organs acts that during inhalation air through the airways into the Lungs are squeezed and air is sucked out of the lungs during exhalation, and a mechanical device that serves to

ίο the torso or parts while exhaling compressing the trunk and thereby expelling the air from the lungs. While the pneumatic devices mostly consist of alternating with the respiratory tract connected compressed air and suction lines exist, which alternate by hand are opened and closed, so that the lengths of the exhalation and inhalation phases are at the patient's discretion the mechanical breathing devices largely with mechanical drive devices provided by which the length of the phases of inhalation and exhalation is regulated and thus is brought under the control of the person to be treated. The mechanical However, breathing chairs that work according to the compression method have the disadvantage that by compressing the lungs not only the air but also the blood from the Lungs being squeezed. While the air is now releasing the compression of the The chest, i.e. at the beginning of the inhalation phase, quickly retreats into the lungs the blood only withdraws relatively slowly into the small capillary veins of the lungs, so that the air flowing into the lungs hits the lungs in an anemic state. Since the work of the lungs consists in the air in the lungs or the oxygen contained in this air is communicated to the blood through vital osmosis, so the lungs can use a mechanical compression machine to help them assigned work only. to a small extent.

The object of the present invention is intended to address the disadvantage that has just been mentioned should be avoided without eliminating the benefit of mechanical regulation of the respiratory phases. It becomes this through it achieved that a mechanical compression machine and a pneumatic breathing device be brought into connection with one another in such a way that the phases of both devices be mechanically reversed by a controllable drive device, so that during the exhalation phase at the same time the chest is compressed and air is sucked out of the lungs while In the inhalation phase the compression of the chest decreases and air enters the lungs is pressed in. It is thereby achieved that during the exhalation phase not only the Air is mechanically forced out of the chest, but that at the same time as a result the sucking action of the pneumatic device draws blood into the lungs will. As a result, the lungs are poor in air at the end of the exhalation phase, but rich in blood. so that the now during the inhalation phase

Inflowing air hits a blood-rich lungs and thus the lungs do their work at an increased rate Can meet dimensions.

The innovation is explained in the drawing, for example, namely FIG. 1 shows a schematic side view of the entire machine, FIG. 2 shows a top view of parts of the same and FIGS. 3 and 4 side view and section of the drive eccentric. In the drawing, α is a chair on which the person to be treated b sits, c is a belt that is to be placed around the chest and which can be tightened to compress the chest. The belt c is connected by a belt d adjustable in its length to a lever e mounted at f . A roller g is provided on the lever e and runs on an adjustable eccentric h . This eccentric sits on an axis * 'which carries a conical disc j (Fig. 2). These conical disc j, in conjunction with the conical transmission disk k and the higher-than-two discs drive belt I i a regulatable drive for the axis by the axis can be issued i a greater or lesser rate through Vera shift of the drive belt I. As can be seen from FIGS. 3 and 4, the eccentric h consists of two parts which can be displaced relative to one another, whereby the curve of this eccentric can be lengthened or shortened. . m is a container filled with compressed air and η is a vacuum container. These two containers are provided with tubes 0 and p which lead to a mask q that encloses the nose and mouth of the person to be treated. At the point where the tubes open into this mask, there is a tap r, through which the inside of the mask can be brought into connection alternately with the pressure line p and with the vacuum line 0. The changeover of this cock now also takes place from the lever e , mediated by the pull rod s.

Since the compression belt c as well as the cock r are influenced by the lever e , the phases of the pneumatic device are temporally related to the phases of the mechanical breathing machine. The strength of the action of the mechanical breathing machine can be regulated in that the point of application of the belt A on the lever e can be shifted. This is achieved in that the lever A engages a bolt t which is displaceable in a slot in the lever e. The drive device for reversing the phases can be regulated by shifting the belt I sideways, whereby the duration of a phase pair can be lengthened or shortened, and also by adjusting the eccentric h, whereby the length of one phase can be changed compared to the length of the other phase . *

Claims (1)

65 Sponsorship claim: Breathing machine, consisting of a device that compresses the trunk or parts of the trunk and from a device acting pneumatically on the airways, characterized by one of the phases of both Mechanically controllable drive device that reverses devices. 1 sheet of drawings,