SU839551A1 - Spraying device for respiratory systems - Google Patents

Description

(54) DISTRIBUTIVE DEVICE FOR RESPIRATORY APPARATUS

The invention relates to medical technology, namely, to pulmonary distribution devices and can be used when conducting bronchoscopic studies under conditions of spontaneous firing disengaged.

A respiratory distribution device is known which comprises a cylindrical housing with connections for connecting the patient to the patient and for communicating with the atmosphere and a fitting for supplying the gas mixture 1.

However, this device is intended to guide a catheter into the trachea, and not a broncho-fibroscope. In addition, it does not automatically separate the flow of inhaled and exhaled gases when performing artificial ventilation of the lungs along a half-open circuit, and also significantly increases the resistance to passive exhalation. As a result, the device does not allow for bronchoscopic examinations without disturbing artificial ventilation of the lungs.

The purpose of the invention is to provide bronchoscopic examinations without interrupting mechanical ventilation of the lungs.

The goal is achieved by the fact that in a switchgear for breathing apparatus, containing a cylindrical body with

a connection for the patient and for communication with the atmosphere and a gas mixture fitting, a connection for the patient and a connection for the atmosphere are installed in the form of fixed coaxially truncated cones, while the connection for the atmosphere is installed inside the connection for the patient , and their large bases are connected to the end parts of the body in such a way that the inner surface of the suction nozzle (single to the patient and

the outer surface of the front part of the nozzle for the connection with the atmosphere forms a ring-shaped nozzle, with both nozzles mounted for movement

along their longitudinal axis. At the same time, the fitting for the gas mixture is set tangentially to the body.

Figure 1 shows the distribution device for breathing apparatus, longitudinal section, figure 2-4 - diagrams illustrating the operation of the device.

The device comprises a cylindrical body 1, at the end ends of which a thread is made to be attached to its distal part by a pipe 2 for connection to the patient, and a pipe 3 is mounted in the proximal part of the body for communication with the atmosphere. On the side surface of the housing 1 there is a pipe 4 with a fitting for feeding the gas mixture with a check valve 5.

A connecting pipe 2 for connecting to a patient, having a truncated conical shape with an AOR angle, is fixed with a large base on one of the ends of the cylindrical body 1, and with a smaller base with a distal opening 6 directed towards the patient.

A nozzle 3 for communication with the atmosphere is installed inside the housing 1 coaxially with the nozzle 2 and is also made in the form of a truncated cone, 15 which is fixed to the other end end of the cylindrical body 1 by a large base and towards the patient 2 to the smaller base. In this case, the truncated cones of the nozzles 2 and 3 form an annular nozzle 7, which provides a certain linear velocity of the gas, its direction and a uniform pneumodynamic pressure around the entire circumference of the working chamber of the valve device. The pipe 3 is installed on the housing 1, taking into account the possibility of its longitudinal change.

The size of the gap of the annular nozzle 7 depends on the depth of the nozzle 3 in the housing 1. The cross-sectional area of the annular nozzle is adjusted by turning the knob 8 with knurling for convenient gripping and rotation. The rotation is carried out using a micrometer thread on the outer surface of the nozzle 3, which regulates the cross-sectional area of the annular nozzle and ensures the appearance or cessation of the effect of ejection of atmospheric air.

The effect of ejection of atmospheric air into the valve device depends on the linear velocity of the gas flowing through the annular nozzle through the | Current, the cross-sectional area of the nozzle and the angle of the jet

lead gas (the latter draws atmospheric air into the valve).

To reduce the resistance of the exhaled gas, the cross-sectional area of the smaller base of the nozzle 3 is 1.5 times larger than the distal opening of the nozzle 2, however the smallest cross section of the internal channel of each of these nozzles allows free introduction of broncho fibroscope with an external diameter 4,2) 4 , 0 and 3.2 mm, not an obstacle in the conduct of artificial ventilation of the lungs

The pipe 4 connecting the source of the gas mixture, installed tangentially to the cylindrical body, is equipped with a check valve 5 with a petal 9, which only allows the gas to move in one direction - into the working part of the valve device, as well as the possibility of connecting the valve device to the gas source or respirator.

The device works as follows

Continuous automatic ventilation of the lungs is performed with a bronchoscopic respirator in two phases.

In the inhale phase, the gas-narcotic mixture displaces the petal 9 of valve 5, enters the respirator's fur in the cavity of housing 1, and, flowing through the annular nozzle 7, is converted into a gas flow strictly directed to the distal end of the device.

In the first position of the pipe 3. entered into the housing 1 to failure, forming a ring-shaped nozzle 7 that is minimal in cross-sectional area. The leak through the specified gap, the leading gas sent from the respirator, develops a high linear velocity and, according to the Venturi effect, sucks the atmospheric air surrounding the nozzle into the patient's airway (figure 2).

In the second position, the nozzle 3 is maximally withdrawn (unscrewed) from the housing 1. The gap between the walls of the nozzle 2 and the circumference of the distal end of the nozzle 3 increases to such an extent that when flowing through the maximally extended annular nozzle, the drive gas sharply reduces its linear velocity. At the same time, the effect of ejection of atmospheric air into the valve device is completely eliminated (Fig. 3). As a result, in the inspiratory phase, the leading gas is not emitted into the atmosphere through the proximal opening of Patruk 3, where the gas pressure measured by pressure is zero. Thus, in the second position of the nozzle 3 of communication with the atmosphere, the pressure of the counteraction and the pressure created by the driving gas in the annular nozzle 7 are balanced. The intermediate positions between the first and the second positions of the position of the nozzle 3 in the housing 1 correspond to different (in the range from 0 to 30%) degree of ejection of atmospheric air into the device. In the faer bore, the petal 9 hermetically intersects the saddle of the back valve 5 and prevents the penetration of exhaust gas into the respirator. Passively inhaled gas is directed through the endotracheal tube (not shown in the drawing) and the leakage through the nozzle 3 is freely released into the atmosphere (Fig. 4). Thus, the device provides automatic separation of flows of inhaled and exhaled gases under conditions of artificial ventilation of the lungs, conducted in normal and tachypnoic regimes. The device has no obstacles to passively inhaled gas and, consequently, the resistance to the exhaled gas in it is parctically zero, which favorably affects the hemodynamics of the pulmonary circulation and especially during prolonged mechanical ventilation. The device allows to carry it through the valve to the respiratory tract Brophy fibroscope, catheter, for suction of mucus, fluid, sputum, blood and other manipulative tools, without interrupting artificial ventilation of the lungs. Due to the absence of one of the valves with a vshknnm locking element twice

Claims (2)

The j2a2bzzszzzzz improves the reliability of the device and simplifies its design. Claims 1. A respiratory distributing device comprising. a cylindrical body with nozzles for connection to the patient and for communication with the atmosphere and a choke for supplying the gas mixture, o; -that is, so that, in order to carry out bronchoscopic studies without interrupting artificial ventilation of the lungs, for connection to the patient and a nozzle for communication with the atmosphere are made in the form of fixed coaxially truncated cones, wherein the nozzle for communication with the atmosphere is installed inside the nozzle for connection to the patient, and their large bases are connected to the end parts of the housing in such a way that the inner surface of the nozzle for connection to the patient and the outer surface of the front part of the nozzle form an annular nozzle for communication with the atmosphere, with both nozzles being mounted for movement along their longitudinal axis. 2. Device POP.1, characterized in that the fitting for the gas mixture is mounted on a tangent to the body. Sources of information taken into account in the examination & e 1. USSR Copyright Certificate No. 211751, cl. A 61 M 17/00, 1966. US