SU1766369A1 - Apparatus for metered loading of breathing muscles - Google Patents

Abstract

Usage: in medical technology to measure endurance and training of respiratory muscles. The breathing chamber 1 has a breathing tube with inhalation valves 2 and expiration 3. On the valve side, removable nozzle 7 and loading chamber 10 are fixed. When changing the training mode from inspiration to exhalation nozzle 7 and the loading chamber 10 mutually interchange. The load chamber 10 is in communication with the atmosphere and provided with a load element in the form of an electromagnet with a fixed crust 16 and a core 14 arranged along a common axis. On both sides of the loading element, there are inspiratory 23 and expiratory 24 openings with saddle surfaces. In the holes, locking elements 21, 22 are installed, interacting with the saddle surfaces. The locking elements are rigidly mounted on the movable bark 16. In the fixed core 14, a guide hole 20 is made for reciprocating movement of the locking element 22. 2 sludge. CR-

Description

The invention relates to medical technology, namely to pulmonary therapeutic devices and functional methods for studying the respiratory system. It can be used to measure endurance and breathing muscle training.

A device for training the respiratory muscles / USSR Author's Certificate No. 1445692, cl. A 61 B 5/08, 1988 /

A disadvantage of the known device is the impossibility of a separate training of the respiratory muscles of inhalation and exhalation, which limits the scope of its use. In addition, when training the respiratory muscles, the respiratory pressure developed by

load, which makes it difficult to accurately dose inspiratory-expiratory loads, and also does not allow the study of the endurance of the respiratory muscles.

A device for examining endurance and breathing muscle training during inhalation is known, comprising a breathing chamber with an exhalation valve connected to a loading chamber through an inhalation valve and to a mouthpiece through a breathing tube having a fitting for connecting to a pressure sensor opposite to the inhalation valve of the side loading chamber provided with an insulator hole, blocked by a plunger, made with the possibility of longitudinal movement and equipped with a loading element, made in

VI

ABOUT

o so o

The form of an electromagnet, the measles of which is rigidly connected to the plunger, in addition, a serially connected setting device and load magnitude indicator, a power supply source and a load element disconnecting unit are introduced into the device during expiratory phase / Application No. 4469972/14 / 119313 / dated 29.07.88. rTK / f. cl. A 61 On 5/08, the decision to issue a second certificate from 09.21.89, the / - prototype.

0 However, the known device does not provide training for the expiratory muscles, and the node for disconnecting the load element installed in the breathing chamber during the expiration phase creates an unregulated additional resistance to the air flow during expiration and thus worsens the process of studying the endurance of the respiratory muscles. In addition, the presence of an electromagnet shutdown node in the expiratory phase in the respiratory chamber complicates the device.

In the study of the endurance of the respiratory muscles by a known device, a considerable amount of condensate of exhaled puffs accumulates in the respiratory chamber, which also contributes to the deterioration of the research process.

The aim of the invention is to expand the field of use by training respiratory muscles during exhalation.

This goal is achieved by the fact that in the device for metered load of respiratory muscles, there is a breathing chamber with inhalation and expiratory valves, including an expiratory manifold and a breathing tube with a fitting for connection to a pressure sensor, detachable, connected to the atmosphere, and installed on the inspiratory valve side a chamber with an inspirator orifice made with a saddle surface and equipped with a load element in the form of an electromagnet with a movable crust connected to a locking organ mounted with axial movement, the control unit, in the loading chamber, an expiratory opening with a saddle surface is made, the loading element is additionally equipped with a locking member fixed coaxially with the main locking member capable of interacting with the saddle surface of the expiratory opening, the loading element being provided with a fixed core with a guide hole for additional valve body, and the exhalation tube is removable.

Comparative analysis with the prototype allows us to conclude that the proposed device for the metered load of the respiratory muscles is characterized in that an expiratory opening with a saddle surface is made in the loading chamber, and

the load element is additionally provided with a locking organ fixed coaxially with the main locking organ with the possibility of interaction with the saddle surface of the expiratory opening,

0, the loading element is provided with a fixed core with a guide hole for an additional closure member, and the exhalation tube is removable.

five

Thus, the claimed technical solution meets the criterion of novelty.

Analysis of the known technical solutions in the study area and adjacent areas allows us to conclude that there are no signs in them that are similar to the significant distinguishing features in the proposed device for the metered load of breathing muscles, and to recognize the proposed solution as relevant. honors

FIG. 1 shows a device for dosed loading of respiratory muscles,

0 is a section, in FIG. 2 - control unit of the electromagnet and the heating element.

The device for dosed loading of the respiratory muscles contains a respiratory chamber 1 with valves 2 inhalations and 3 exhalations,

5 a breathing tube 4 with a fitting 5 for connecting to a pressure sensor / not shown /, a mouthpiece / not shown /, a heating element 6 placed on the breathing chamber 1, a connecting piece 7 with a fitting 8 for connecting a gas analyzer / not shown / and an opening 9 to connect the meter / not shown / air volumes, the load chamber 10, in the case 11 of which the coil 12c is mounted by a winding 13, along the axis of which a fixed core 14 connected to the flange 15 and an axially mounted 16 is placed by means of currents 17, 18 through guides m0 Verstov 19, 20 with the plungers 21, 22 mounted to cooperate with a saddle surface inspi--valued and expiratory ports 23, 24 which are connected to the openings 25, 26

5 with the atmosphere.

The electromagnet control unit contains a power supply source 27, a switch 28, a load magnitude indicator 29, a scale (not shown), which has been calibrated in grams, a setting device 30

load values connected in series with the winding 13.

The heating element control unit includes a power supply source 27, a switch 31, a temperature value indicator 32, a temperature value setter 33, a temperature value auto-control 34, connected in series with the heating element 6.

The device works as follows.

Before starting work with the device, the respiratory chamber 1 is heated to a temperature that prevents the formation of condensate of exhaled moisture. To do this, turn on the switch 31 and create a circuit for the passage of electric current from the power source 27 through the contacts of the switch 31, the indicator 32, the setpoint 33, the autoregulator 34 temperature and the heating element 6 to the second output of the source 27. The magnitude of the current and the corresponding value of the heating temperature element 6 is set by the setting device 33 and is monitored by the indicator 32. Upon reaching the value of the temperature preventing the formation of condensate, the exhaled moisture in the respiratory chamber 1 is switched on op 34, which supports it at a constant level.

When training the inspiratory muscles or studying the endurance of the respiratory muscles, the loading chamber 10 is connected with the respiration chamber 1 like this / fig. 1 / so that the load on the respiratory muscles is created during inhalation and the maximum inspiratory pressure is measured. To do this, switch 28 is turned on and a circuit is created for the passage of electric current from source 27 through contacts of switch 28, indicator 29 and unit load 30 through winding 13 to the second terminal of source 27. Unit 30 sets this current and, accordingly, load the patient cannot overcome with maximum inspiratory effort. At the same time, the measles 16 is attracted to the fixed core 14 and, accordingly, the plunger 21 is pressed against the saddle surface of the inspiratory orifice 23 with the force created by the setting device 30.

The patient's airway is connected to the mouthpiece and he produces the maximum exhalation. Exhalation valve 3 in the respiratory chamber 1 is opened and exhaled air freely exits through the opening 9 into the atmosphere. At the end of expiration, valve 3 closes and the patient performs with a maximum

force breath. In the respiratory chamber 1 and in the tube 4, a vacuum is created, which is transmitted through the nozzle 5 to the respiratory pressure sensor, where its value is recorded. Then, depending on the value of the maximum inspiratory pressure, by setting unit 30, the required load value with which the patient breathes for a predetermined time. During inhalation, the valve 2 opens under the action of negative pressure and the plunger 21 rises above the inspiratory orifice 23, creating the condition for the passage of air from the atmosphere through the orifices 25 and 23 into the patient's airway. The anchor 16 together with the stem 17 and with the plunger 21 moves in the direction opposite to the fixed core 14, and the force of attraction of the core 16 to the fixed core 14 prevents this movement, creating resistance to the muscles of the breath. The inspiratory pressure that occurs through the nozzle 5 is recorded by a respiratory pressure sensor. Upon completion of inhalation, the measles 16 is attracted to the core 14, the plunger 21 is pressed against the saddle surface of the inspiratory orifice 23, the inhalation valve 2 is closed, and during expiration the valve 3 is opened and the air from the lungs is removed through the opening 9 to the atmosphere.

In the study of respiratory muscle endurance, the load is increased in a stepwise manner by the setting device 30 at certain time intervals until the patient abandons the study. The magnitude of the maximum load indicated by indicator 29 or the corresponding inspiratory pressure. characterizes the endurance of the respiratory muscles.

When training the exhalation muscles, the loading chamber 10 is set so that the load on the respiratory muscles is created during exhalation. For this, the nozzle 7 and the load chamber 10 are disconnected from the respiratory chamber 1. Then, the nozzle 7 is attached to it from the inhalation valve 2 side, and the load chamber 10 from the exhalation valve 3 side with the part where the plunger 22 is placed. loads that the patient cannot overcome with maximum exhalation force and measure the maximum expiratory pressure. The patient's airway will be connected to the mouthpiece and he takes the maximum breath. With this, the inhalation valve 2 opens and air from the atmosphere enters through the opening 9 of the nozzle 7 into the lungs. At the end of inhalation, valve 2 closes and the patient makes an exhalation with maximum force. In the respiratory chamber 1 and the tube 4, an overpressure is created, which is transmitted through the nozzle 5 to the respiratory pressure sensor, where its value is recorded. Then, depending on the value of the maximum expiratory pressure, by setting unit 30, the required load value for training the expiratory muscles with which the patient breathes for a specified time. During exhalation in the respiratory chamber 1, the pressure increases. As a result of the pressure difference created between the pressure in the chamber 1 and the atmospheric pressure, the exhalation valve 3 opens, the plunger 22 opens the expiratory opening 24 and the exhaled air exits through the openings 24, 26 into the atmosphere. The anchor 16, together with the stem 18 and the plunger 22, moves in the direction opposite to the stationary core 14, and the force of attraction of the core 16 to the stationary core 14 prevents this movement, creating resistance to the expiratory muscles. The expiratory pressure developed by the respiratory muscles during exhalation through the nozzle 5 is recorded by a respiratory pressure sensor. Upon expiration, the measles 16 is attracted to the core 14, the plunger 22 is pressed against the saddle surface of the expiratory opening 24, closing it, the exhalation valve 3 is closed, and during inhalation the valve 2 opens and the air from the atmosphere passes through the opening 9 into the patient's airway .

Thus, the proposed device provides muscle training and inspiration,

and exhalation, as well as the study of respiratory muscle endurance, which expands its use.

Claims (1)

Invention Formula A device for dosed loading of the respiratory muscles, comprising a breathing chamber with inhalation and exhalation valves, including an expiratory manifold and a breathing tube with a fitting for connection to a pressure sensor, removable, connected to the atmosphere and mounted on the inspiratory valve side, a loading chamber with an insulator opening made with a saddle surface, and equipped with a load element in the form of an electromagnet with a movable leg connected to a shut-off member installed with the possibility of axial movement, the unit pack This is connected to the windings of the electromagnet, characterized in that, in order to expand the area of use by training the respiratory muscles during exhalation, an expiratory opening with a saddle surface is made in the loading chamber, and the loading element is additionally provided with a locking member fixed coaxially with the main locking body with the ability to interact with the saddle surface of the expiratory opening, while the loading element is equipped with a fixed core with a guide hole to complement of the closure organ, and the exhalation tube is removable. 24  / 2d