RU2385742C2 - Intermittent normobaric hyperoxi- and hypoxitherapy apparatus - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medial equipment and can be used for improving human tolerance in various morbid conditions. An apparatus comprises series compressor used as a pressure source, a gas permeator with a hyperoxic and hypoxic outputs used as an air-separating module, a regulated valve connected to the hypoxic output of the gas permeator, and a respiratory unit of the patient. The flow switch has two inputs, one of which is connected to the regulated valve and another through an ejector to the hyperoxic output of the air-separating unit, and two outputs, one of which is connected to the output of the connector to the respiratory unit of the patient, another contacts the ambient environment. The flow switch is connected to an output of a control unit and switches the air mix supply to the hypoxic and hyperoxic units by a signal of the control unit, while the other input of the ejector is connected to the pressure source.

EFFECT: invention enables intermittent normobaric hyperoxi-hypoxitherapy.

6 cl, 3 dwg

Description

The invention relates to medical equipment and can be used to increase the body's stability under various pathological conditions, for example, in the practice of treating bronchial asthma, hypoplastic and iron deficiency anemia, chronic leukemia, neurocircular dystonia, hypertension, obesity and others, as well as for treatment and prevention respiratory, circular and metabolic disorders, increasing nonspecific resistance and compensatory abilities of the body, reducing side effects Via ionizing radiation on the body, etc.

In medicine, methods and devices for normobaric oxygen therapy are widely used, in which the patient inhales the oxygen-rich breathing mixture (see, for example, US patent No. 4281651, A61M 16/00, 1981, US patent No. 4236513, A61M 16/00, 1982, patent US No. 5172687, A61C 10/00, 1992 or application of Great Britain No. 1526957, A61M 16/00, 1978).

To obtain gas hypoxic mixtures, devices operating on the principle of respiration are widely used (see, for example, AS No. 1335294, A61M 16/00, 1985 or AS No. 1826918, A61M 16/00, 1991).

However, these devices do not provide changes in the composition of the mixture according to the required law with sufficient speed.

Closest to the proposed device is a device for complex oxygen and hypoxytherapy (Russian patent No. 2121854, A61M 16/10).

The device includes a series-connected compressor used as a pressure source, a gas separation module and a valve connected in series with the flow sensor. The gas separation module is equipped with a package of gas separation membranes with the possibility of obtaining hypoxic and hyperoxic mixtures at its outputs, while the outputs of the gas separation module are connected to the outlet pipes of the device, one directly, the other through a valve and a flow sensor. The respiratory assembly of the device is made with a flow switch, the inputs of which are connected to the outlet pipes of the device, and the flow switch is connected to the control unit. In addition, the device may contain, in addition to the compressor used as a pressure source, a vacuum compressor for supplying an exhaust stream to the compressor inlet.

However, this device also has disadvantages due to the use of an additional vacuum pump, which leads to an increase in the mass and dimensions of the device, as well as high operating costs. In addition, the switch of hypoxic and hyperoxic flows is made in conjunction with a respiratory node, which increases the bulkiness of the node and creates inconvenience for the patient. The flow switch is made without discharge outputs of hypoxic and hyperoxic flows, which can lead to a change in the operating mode of the membrane apparatus, and the programs entered into the control unit do not take into account the current state of the patient exposed to the exposure of the hypoxic and hyperoxic air mixture.

The aim of the invention is to intensify the therapeutic and training processes, increase the efficiency of the method and reduce the time of one session and the treatment period or training in general, the possibility of selecting the individual composition of the hypoxic mixture and increase safety, as well as the creation of an effective, inexpensive, simple, autonomous and reliable device for periodic normobaric hyperoxy and hypoxic therapy.

This result is achieved by the fact that the device for conducting complex periodic normobaric hyperoxy and hypoxy therapy, containing a series-connected compressor used as a pressure source, a gas separation module and a control valve, is equipped with a gas separation module with the possibility of obtaining hypoxic and hyperoxic mixtures at its outputs, while the outputs of the gas separation module are connected to the inputs of the flow switch, one through the ejector, and the other through the control valve.

At the same time, the device can be placed in the housing both in conjunction with a compressor with one inlet and with as many outlet pipes as there are patients at the same time serviced by the device, and separately from the compressor, and equipped with a respiratory unit that can be taken out of the device to the required distance.

It is also recommended to install a filter-moisture separator and a regulator-pressure regulator of the air supplying the membrane apparatus between the compressor and the module.

It is also recommended that a humidifier and / or fragrance be installed between the gas separation module and the hypoxicator respiratory assembly.

It is advisable to perform the device with a flow switch, one output of which is connected to the pneumatic line for connection with a respiratory unit, and the second is connected to the surrounding atmosphere, and also provide the device with a control unit that can control the modes of operation of the flow switch.

In this case, the control unit can be made in the form of a microcontroller executive unit that responds to input signals from a heart rate sensor, a patient’s blood hemoglobin oxygen filling sensor, a patient’s attention sensor and an oxygen sensor or a membrane operating mode sensor, and switching the switchgear in accordance with the operation algorithm recorded in the memory of the microcontroller, the state of the sensors and the parameters entered in the initial menu of the control unit. Before the procedures, the necessary exposure parameters for hyperoxic and hypoxic mixtures are introduced into the control unit.

Figure 1 shows the proposed device.

A device for periodic normobaric hyperoxy and hypoxy therapy contains a compressor 1 used as a pressure source, a filter-moisture separator 2, a pressure regulator-regulator 3, a gas separation module 4, a control valve 5 and an ejector 6. The device 4 has one input and two outputs - the output of the hypoxic mixture and the output of the hyperoxic mixture. To the output of the hypoxic mixture (the output of the gas separation module through which the oxygen depleted air exits) is connected a control valve 5 and an outlet equipped with a throttle 14 to supply the mixture to the gas analyzer 13. The range of changes in the oxygen concentration in the hypoxic mixture is from 1 to 18%. An ejector 6 is connected to the output of the hyperoxic mixture (the output of the gas separation module through which the oxygen enriched air flows), which is fed from the compressor 1 through a filter 2, a pressure stabilizer 3 and a throttle 15. The range of oxygen concentration in the hyperoxic mixture is from 25 to 45% . A membrane gas separation apparatus is used as an air separation module.

The membrane apparatus can be flat, hollow fiber or roll type. In addition to the membrane apparatus, other air separation devices, for example, such as short-cycle adsorption modules, etc., can be used as a gas separation module.

After the valve 5 and the ejector 6, the air mixture enters the flow switch 7. One output of the flow switch 7 is connected to the outlet pipe of the device to which the pneumatic line 10 is connected, and the second output communicates with the surrounding atmosphere. The thread switch 7 is connected to the output of the control unit 12, which provides signals for the operation of this node.

Figure 2 shows the respiratory assembly of the patient 20, which contains the inlet pipe 21, a reversible breathing valve 22, consisting of valves 25 and 26 (Figure 3), a backup bag 23 and a breathing mask 24. Between the output of the flow switch 7 and the patient's respiratory assembly humidifier / fragrance 8 and air line 10 are located.

Consider in more detail the operation of the device. The compressor 1 (FIG. 1) draws in air through the pipe 9 and delivers it to the filter-moisture separator 2, where compressed to pressure P1 air is cleaned of mechanical particles and drops of condensed moisture. Then the purified air is supplied to the pressure stabilizer 3 and from it to the inlet of the gas separation apparatus 4. In the gas separation apparatus, under the influence of a pressure drop, oxygen penetrates through the membrane. Thus, the stream passing through the membrane is enriched with oxygen, and the stream that has not penetrated through the membrane (residual) is enriched with nitrogen. The nitrogen concentration in the residual stream depends on:

1. The ratio of the rate of penetration of oxygen to the rate of penetration of nitrogen through the membrane (selectivity coefficient), which is a characteristic of a gas separation membrane apparatus.

2. The pressure of the air supplied to the membrane apparatus.

3. The ratio of the magnitude of the penetrated stream to the feed stream.

The penetrated flow depends on the parameters of the membrane apparatus (membrane permeability) and pressure. Since the air pressure at the inlet to the membrane apparatus is stabilized by a pressure stabilizer 3, the value of the permeated flow can be considered constant. By changing the value of the feed stream, which is the sum of the infiltrated and residual flows, i.e. By changing the value of the residual flow, one can change the concentration of nitrogen in the residual flow.

To adjust the nitrogen concentration after the membrane apparatus, a control valve 5 is installed, which is controlled either manually or by means of a control unit 12 based on the readings of the gas analyzer 13.

Since the pressure of the residual flow is slightly different from the inlet pressure, it is not difficult to supply it to the patient. The penetrated stream has a pressure slightly different from atmospheric, i.e. not enough to deliver it to the patient's respiratory node 20. To overcome this condition, the penetrated (hyperoxic) stream is equipped with an ejector 6, which is fed by compressed air coming from a pressure stabilizer. The compressed air stream creates a vacuum in the cavity of the permeated stream, thereby pulling out the hyperoxic stream from the membrane apparatus and under a small pressure sufficient to overcome the pneumatic resistance of the flow switch 7, humidifier / fragrance 8, air line 10 and valves 25 and 26 of the respiratory assembly 20, is fed into respiratory node. Both streams, both hypoxic and hyperoxic, are supplied to the stream switch 7, the operation of which is regulated by the control unit 12. The stream switch 7 has two inputs and two outputs. Hyperoxic and hypoxic outputs of the membrane apparatus 4 are connected to its inputs, hyperoxic through an ejector 6, and hypoxic through an adjustable valve 5. A pneumatic line 10 is connected to one output of the flow switch 7 to supply the gas mixture to the patient's respiratory assembly 20, which can be at a sufficient away from the device. The second has a free exit to the atmosphere so that the operating parameters of the membrane apparatus do not change when switching flows, i.e. when a hypoxic mixture is supplied to the respiratory node, the hyperoxic mixture is discharged into the surrounding atmosphere and vice versa.

The patient's respiratory assembly 20 contains an inlet 21 sufficient for connecting the pneumatic line, a reversible breathing valve 22, a backup bag 23 and a breathing mask 24. The hypoxic or hyperoxic stream entering the inlet pipe 21 from the pneumatic line is distributed between the reserve bag 23 and the reversing breathing valve 22. Since the first valve 25 of the reversible breathing valve 22 has a small pneumatic resistance, part of the flow does not exit through the mask, but accumulates in the backup bag 23. P When you inhale, the outlet valve 26 closes, and the patient enters the flow from the backup bag 23 and the air line 10. When you exhale, the outlet valve 26 opens, and the valve 25 closes and the entire flow is directed to the backup bag 23.

The number of respiratory nodes of the patient is limited only by the performance of the device for hypoxic and hyperoxic mixtures and the number of flow switches. For comfortable breathing, each patient should have at least 12 liters per minute of the mixture. Each respiratory node is connected to its flow switch 7.

The control unit 12 is made on the basis of a microcontroller and operates as follows. In the first period of time, the control unit includes a flow switch 7 in such a way that a hypoxic air mixture is supplied to the patient in the respiratory unit, and the hyperoxic mixture is discharged into the surrounding atmosphere. After a certain time, previously entered into the control unit, the control unit switches the flow switch to a state where a hyperoxic mixture is supplied to the patient, and the hypoxic mixture is discharged into the atmosphere. This process is repeated as many times as the periods of hypoxia exposure were predefined in the control unit.

Thus, a device for conducting complex periodic normobaric hyperoxy and hypoxy therapy helps to intensify the treatment and training processes, increase the efficiency of the method and reduce the time of one session and the treatment or training period in general, the possibility of selecting the individual composition of the hypoxic mixture and increase safety.

Claims (6)

1. A device for conducting periodic normobaric hyperoxy and hypoxy therapy, comprising a series-connected compressor used as a pressure source, a gas separation membrane apparatus having hyperoxic and hypoxic outputs used as an air separation module, an adjustable valve connected to the hypoxic output of the gas separation module, and patient respiratory node, characterized in that a flow switch is inserted into it, which has two inputs, one of which It is connected to an adjustable valve, and the other through an ejector to the hyperoxic output of the air separation module, and two outputs, one of which is connected to the output of the device for connecting the patient's respiratory unit, the other is connected to the surrounding atmosphere, while the flow switch is connected to the output of the control unit and made with the possibility of switching the supply to the respiratory node of a hypoxic and hyperoxic air mixture by the signal of the control unit, and the other input of the ejector is connected to a pressure source. 2. The device according to claim 1, characterized in that it is housed in a housing with one inlet pipe and outlet pipes in an amount corresponding to the number of simultaneously served patients. 3. The device according to claim 1, characterized in that the respiratory assembly is equipped with a humidifier, a reversing valve, a backup bag and a face mask. 4. The device according to claim 1, characterized in that it is equipped with a filter-water separator, which is placed between the compressor and the separation module. 5. The device according to any one of claims 1 to 4, characterized in that the hollow fiber, or flat, or roll membrane devices are used as the air separation module. 6. The device according to any one of claims 1 to 4, characterized in that short-cycle adsorption devices are used as the gas separation module.

Images