RU130836U1 - CRYOTHERAPEUTIC DEVICE - Google Patents

Abstract

1. A cryotherapeutic device comprising a vertically located cabin with a door, a lifting floor installed at the bottom of the cabin associated with a drive for moving it, a cryogenic gas preparation system and means for supplying it to the cabin, as well as a control unit, characterized in that the cabin forms a closed door a closed thermally insulated cavity with an opening on the side surface in the form of a window for the patient’s face, the window being edged with soft elastic material to ensure tight contact with the patient’s face, while in rhney of the cab mounted release excessive davleniya.2 valve. The device according to claim 1, characterized in that the cab body and its door are made of heat-insulating materials. The device according to claim 1, characterized in that the means for supplying cryogenic gas to the cabin include nozzles located in the cabin and at least two vertical rows and channels connecting these nozzles to the cryogenic gas preparation system. The device according to claim 3, characterized in that the nozzles along the height of the cabin are located in it in the upper and middle parts. The device according to claim 1, characterized in that the overpressure relief valve is installed on the door. A device according to any one of claims 1 or 5, characterized in that the overpressure relief valve is made gravitational. The device according to claim 1, characterized in that the control unit is configured to automatically maintain a given operating pressure of the cryogenic gas in its supply means. A device according to any one of claims 1 or 7, characterized in that the control unit is configured to automatically maintain a predetermined temperature inside the cabin. Arranging

Description

The utility model relates to medical equipment, namely, to individual use devices for the general cryo-extreme exposure of human skin to a mixture of liquid nitrogen and air vapors with a temperature of minus 130 ° -160 ° C without crippling tissue structures. The utility model can be used to carry out general cryotherapy procedures in inpatient and outpatient departments of medical and prophylactic, sanatorium and health-improving institutions.

The principle of the cryotherapeutic procedure is based on quick and short-term cooling of the body surface to a temperature of 0 to -2 ° C on the skin surface.

Cryotherapy sessions are carried out in special cryogenic physiotherapeutic units - cryocabin. To cool the human body using a gas mixture of vapor of liquid nitrogen and air with a temperature of minus 130-160 ° C, which creates the necessary cryotherapeutic effect. The procedure lasts an average of 2-3 minutes, during which the human body experiences a powerful general cryotherapeutic effect, the effect of which persists for a long time. The effectiveness of general cryotherapy is directly proportional to the area of skin contact with the cooling medium.

General cryotherapy is used to treat diseases such as rheumatoid arthritis, bronchial asthma, psoriasis, hormonal disorders, while general cryotherapy stimulates the human immune and endocrine systems, metabolism, and causes saturation of human blood with endorphins.

A device for cryotherapy according to patent RU 48473 U1 is known, including a cabin for accommodating a patient with a thermally insulated body and a heat exchanger with a channel for supplying refrigerant in the form of liquid nitrogen. The channel is made in the upper part of the cab, the heat exchanger is installed inside the cab body and is located along its entire height, and the walls of the heat exchanger are painted black and equipped with panels with openings to protect a person from touching the walls of the heat exchanger. When using such a device, the patient, while completely in the cockpit, breathes cold air, which leads to its entry into the upper respiratory tract and lungs with the risk of cryosampling of their tissue structures.

Designs of other well-known individual cryosaunas for personal use are basically similar and are “glass” or box-type cabins with a system for supplying liquid nitrogen vapors and exhaust gases.

Thus, UA 44294 U describes a cryosauna containing a cabin for accommodating a patient with a lift, a gas treatment device and a control device with software, while the body of the gas treatment device is a wooden structure.

RU 38591 U1 describes a cryotherapy unit comprising a cabin for accommodating a patient, a thermally insulated container with a condenser, and a cryostat system with a flow rate inducer. In addition, the known installation includes a system for utilizing exhaust gases made of pipelines with a fan and a three-way valve. In this case, the coolant flow rate inducer is connected by a pipeline to a thermally insulated tank, and the fan of a thermally insulated tank is installed on the pipeline connecting the cabin for accommodating a patient with a thermally insulated tank.

Closest to the present utility model is the cryosauna “KAEKT-01 KRION”, produced by NPP “KRION” (St. Petersburg, Russian Federation, http://www.krion.ru). The cryosauna consists of a “glass” type cabin for accommodating a patient, a lifting device, a pump for pumping liquid nitrogen, a Dewar vessel for storing liquid nitrogen, and a control system. In the cockpit, the patient is immersed in cryogenic gas around his neck. The space above the upper section of the cryosauna is ventilated to prevent cryogenic gas from entering the patient’s upper respiratory tract. The floor of the cryosauna is lifting, which allows you to adjust the height of the internal volume of the cabin for patients of different stature. During the procedure, the patient’s skin cools for a short time, and this creates the necessary physiotherapeutic effect.

The main disadvantages of the known cryosaunas are: the inability to achieve a uniform temperature gradient inside the cabin, cryotherapy on a small (less than 50%) surface area of the patient’s skin, the danger of cryogas entering the upper respiratory tract and lungs. In particular, in the KAEKT-01 KRION cryosauna indicated above, the cryogenic gas entering the lower part of the cabin is mixed with the warm air of the room in the upper part and heated, which does not provide a uniform temperature gradient in the lower and upper parts of the cabin. Thus, the cryotherapeutic effect on the lower and upper parts of the patient’s body differs significantly in cooling degree. In addition, the patient, being in the cabin along the neck, also breathes cold nitrogen-air mixture, which is supplied by the fan from the lower part of the cabin to the upper one, which does not exclude the possibility of cryogenic gas entering the upper respiratory tract and lungs of the patient with the risk of cryogenic damage tissue structures.

The objective of the utility model is to eliminate the shortcomings of known cryosaunas - ensuring a uniform temperature gradient inside the cabin, increasing the area of cryotherapy to 98% of the body surface and eliminating the possibility of cryogenic gas entering the upper respiratory tract and lungs of the patient.

The problem is solved in a cryotherapy device containing a vertically located cabin with a door, a lifting floor installed at the bottom of the cabin, connected with a drive for moving it, a cryogenic gas preparation system and means for supplying it to the cabin, as well as a control unit. According to a utility model, the cabin, when the door is closed, forms a closed thermally insulated cavity with an opening on the side surface in the form of a window for the patient’s face, and the window is edged with soft elastic material to ensure close contact with the patient’s face, which ensures that the cabin is tight when the face is pressed to the window during the procedure while an overpressure relief valve is installed in the upper part of the cab.

This design of the device allows to reduce the temperature difference in the lower and upper parts of the cab during the procedure to 10-15 ° C, which is significantly lower than that of known devices. As a result, a uniform cryotherapeutic effect is achieved throughout the patient’s body, which practically does not feel such a temperature difference. It is not possible to achieve a zero difference due to the inevitable heating of cryogenic gas by the patient’s body in the cockpit. Thus, according to the utility model, the cryocapsule is more effective in achieving a cryotherapeutic effect and at the same time safer, since a patient whose body is almost completely surrounded by cryogenic gas breathes the air of the room in which the procedure is performed, which completely excludes the patient’s respiratory tract contact with cryogenic gas and their hypothermia.

Preferably, the cab body and its door are made of heat-insulating materials, which helps to reduce energy consumption during operation of the device.

Preferably, the means for supplying cryogenic gas to the cabin includes nozzles located in the cabin and at least two vertical rows and channels connecting these nozzles to the cryogenic gas preparation system, the nozzles being predominantly located along the height of the cabin in its upper and middle parts.

An overpressure relief valve may be mounted on the door, and is preferably gravitationally.

To ensure that the device can operate in automatic mode, the control unit is configured to automatically maintain a given operating pressure of the cryogenic gas in its supply means and / or to automatically maintain a predetermined temperature inside the cabin.

Preferably, the device is further provided with a user interface associated with the control unit and located on the outer surface of the cab. The user interface can be made in the form of a touch monitor.

The utility model is illustrated by drawings.

Figure 1 schematically shows a cryotherapy device, a front view in section;

figure 2 is the same, a top view in section;

figure 3 shows a cryotherapy device, a General view in perspective;

figure 4 is the same, top view.

The cryotherapeutic device comprises a cabin consisting of a body 1 and a door 2 made of heat-insulating materials. The cabin with the door closed forms a closed thermally insulated cavity with an opening on the side surface in the form of a window 3 for the patient's face. The window 3 is edged with soft elastic material 4 to ensure tight contact with the patient's face. The specified edging may contain genuine leather, providing a tight and safe contact with the patient's face. At the bottom of the cab there is a lifting floor 5 connected to the drive 6 of its movement. On one side of the cabin, a column 7 is attached to its body, in which a cryogenic gas preparation system is located, and on the other, a column 8 with a control unit. Cryogenic gas supply means are located in the cabin body 1 of the cabin, including nozzles 9 located in the cabin and at least two vertical rows and channels 10 connecting these nozzles to the cryogenic gas preparation system. Nozzles 9 along the height of the cabin are located in its upper and middle parts (Fig. 1). On the housing 1 of the cabin is also located a user interface made in the form of a touch monitor 11, for example, a 10-inch one, and controls for the drive 6 of the lifting floor 5, which are buttons or a joystick (not shown). To supply liquid nitrogen vapors to the cryogenic gas preparation system, column 7 has a fitting 12 for attaching a flexible hose 13 connected to the Dewar vessel 14. The internal cavity of the cabin through the return channel 15 is connected to the cryogenic gas preparation system located in the column 7, which ensures the return of the exhaust gas from the cabin to the cryogenic gas preparation system to reduce the total liquid nitrogen consumption. To relieve excess pressure from the inner cavity of the cabin, an overpressure relief valve 16 is installed in its upper part. Preferably, the valve 16 is gravitational, but the overpressure relief valve can also be spring or any other suitable type. In the embodiment of the utility model shown in FIGS. 3 and 4, the valve 16 is located in the ceiling part of the door 2 of the cab 1, however, it can also be installed in the ceiling part of the cab body 1.

Cryotherapy device works as follows.

The patient enters the cabin 1, and the operator conducting the procedure adjusts the height of the floor 5 by actuating the actuator 6 so that the patient’s face is at the level of window 3. The patient presses his face firmly against the edging of soft elastic material 4 in window 3, which allows him to breathe room air, that is, room temperature air. Thus, the possibility of cryogenic gas entering the respiratory tract and, therefore, supercooling of the upper respiratory tract is completely excluded. The door 2 of the cabin is closed, and the operator, by acting on the touch monitor 11, turns on the cryogenic gas supply, while setting the parameters (for example, time) of the cryogenic gas supply to the cabin. In this case, excess pressure is created in the Dewar vessel 14 due to the inclusion of a heating element located in it, and liquid nitrogen through a flexible hose 13 enters the heat exchanger of the column 7 of the cryogenic gas preparation system. An electronic control unit located in column 8 automatically maintains a given operating pressure in the Dewar vessel 14. In the heat exchanger of the cryogenic gas preparation system, liquid nitrogen goes into a gaseous state and mixes with atmospheric air. Thus obtained cryogenic gas is injected into the cabin 1 through a system of internal channels 10 and, using nozzles 9 arranged in vertical rows in the upper and middle parts of the cabin, is evenly distributed along the inner surface of the walls of the cabin body 1, affecting the skin of the patient. Temperature control inside the cabin is carried out automatically in accordance with the specified program and is visually controlled by the operator on the touch monitor 2, showing the readings from temperature sensors installed in the housing 1 and in the cryogenic gas preparation system. The overpressure relief valve 16 is set to an overpressure of about 0.7 atm. The device can be equipped with means to protect the heating element in the Dewar vessel from overheating, as well as a timer with a countdown and sound indication (factory setting - 2 minutes) and a clock with a direct countdown. The device is controlled in automatic mode, however, the operator has the opportunity to switch to manual control mode. If necessary, the patient can independently leave the cabin, acting on the door 2. The duration of the cryotherapy session can be set by the operator using the touch monitor 11, and in automatic mode it is 2 minutes.

When using a cryotherapy device according to the utility model, due to the fact that the cabin, when the door is closed, forms a closed thermally insulated cavity, a uniform temperature gradient is provided inside the cabin. In this case, only the patient’s face is not exposed to cryogenic gas, as a result of which the cryogenic area is more than 98% of the patient’s body surface. In addition, in the device, according to the utility model, the possibility of cryogenic gas entering the upper respiratory tract and lungs of the patient is absolutely excluded.

Claims (10)

1. A cryotherapeutic device comprising a vertically located cabin with a door, a lifting floor installed at the bottom of the cabin associated with a drive for moving it, a cryogenic gas preparation system and means for supplying it to the cabin, as well as a control unit, characterized in that the cabin forms a closed door a closed thermally insulated cavity with an opening on the side surface in the form of a window for the patient’s face, the window being edged with soft elastic material to ensure tight contact with the patient’s face, while in rhney of the cab installed overpressure relief valve. 2. The device according to claim 1, characterized in that the cab body and its door are made of heat-insulating materials. 3. The device according to claim 1, characterized in that the means for supplying cryogenic gas to the cabin include nozzles located in the cabin and at least two vertical rows and channels connecting these nozzles to the cryogenic gas preparation system. 4. The device according to claim 3, characterized in that the nozzles along the height of the cabin are located in it in the upper and middle parts. 5. The device according to claim 1, characterized in that the overpressure relief valve is installed on the door. 6. The device according to any one of claims 1 or 5, characterized in that the overpressure relief valve is made gravitational. 7. The device according to claim 1, characterized in that the control unit is configured to automatically maintain a given operating pressure of the cryogenic gas in its supply means. 8. The device according to any one of claims 1 or 7, characterized in that the control unit is configured to automatically maintain a predetermined temperature inside the cabin. 9. The device according to claim 1, characterized in that it is further provided with a user interface associated with the control unit and located on the outer surface of the cab. 10. The device according to claim 9, characterized in that the user interface is made in the form of a touch monitor.

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