RU2804575C1 - Cryotherapeutic unit - Google Patents

Abstract

FIELD: cryogenic technology; medical equipment.

SUBSTANCE: cryotherapy installation contains a cabin including a channel for supplying a nitrogen-air mixture to the cabin located on top, a cooling unit including a gasifier mixer, a fan, a channel for supplying a heated nitrogen-air mixture from the cabin to the gasifier mixer and a channel for supplying liquid nitrogen with a valve, and control unit including controller, valve control relay and fan speed converter. The installation is equipped with a slotted nitrogen-air mixture flow distributor located in the upper part of the cabin with movable guide plates, designed to rotate around an axis located along their upper edge, and a diffuser located in the lower part of the cabin. The gasifier mixer is equipped with a capillary porous coating of internal elements. The control unit is equipped with a module for measuring skin temperature, including a pyrometer located in the housing with the ability to be directed towards the user’s back, and a module for controlling the movement of the plates and at the same time is configured to regulate the mass flow of liquid nitrogen, the fan rotation speed, the direction of the flow of nitrogen-air supplied to the cabin mixture and the duration of its supply depending on skin temperature.

EFFECT: increase of the accuracy of temperature control of the user's skin surface.

3 cl, 6 dwg

Description

The invention relates to cryogenic technology, in particular to medical equipment, namely to physiotherapeutic installations for individual use for carrying out general cryotherapy on human skin with cryogenic gas - a mixture of liquid nitrogen vapor and air without cryodamage to tissue structures, as well as to simulators for carrying out hardening procedures using cold gas. The invention can be used for carrying out general cryotherapy procedures in inpatient and outpatient departments of treatment and prophylactic, sanatorium, health and sports institutions, as well as for private use.

Technical solutions are known from the prior art regarding the design of devices for carrying out general cryotherapy on human skin with cryogenic gas.

Known modern installations are not capable of regulating the cryotherapy process. The main reason for this is the concept of immersing a biological object in a passive cooling environment with unregulated temperature and flow rate at the entrance to the apparatus in relation to it, like “being in a container with a low-moving fluid medium.” The advantage of this approach was its simplicity, which, in conditions of insufficient research of the method, made it possible to reduce the number of considered degrees of freedom in organizing the heat exchange process in the cabin. With this approach, the temperature and speed of gas movement should be low, which in a particular case can provide a relatively uniform heat flow over the surface of the object. Therefore, in practice, only duration control for specific equipment is used. But one parameter - duration - is not enough. It is limited by local temperature minima on the surface of the cooling object. So, for example, in conditions of too high a heat flow due to the heterogeneity of the structure of the human body, locally the surface temperature of an object can reach the maximum permitted values, for example, the temperature of a cold burn, while in other places and at depth it will not have time to cool properly. In this case, it is necessary to move on to the more general case of regulating the heat exchange process in this apparatus.

A cryotherapy installation is known from the prior art, containing a treatment cabin for placing a patient, a heat exchanger with a source of cold fluid flow, and a device for supplying a fluid flow to the patient. The known installation is equipped with a thermally insulated refrigerating chamber in which a treatment cabin is installed, and the device for supplying fluid flow to the patient is made in the form of at least one fan installed with the ability to move in the hole of the cabin wall, made in the form of a screen (see patent for utility model RU 131612 U1, 08/27/2013).

The disadvantage of the known device is the limitation in the accuracy of general cryotherapy due to the immobility of the guide device, which does not allow the separation of cooling of the torso and limbs, and also due to the inability to quickly regulate the temperature of the gas in the cabin.

The closest to the claimed invention is a cryotherapy unit known from the utility model patent RU 48473 U1, October 27, 2005, containing a cabin including a gas supply channel located on top, a cooling unit including a mixer-gasifier, a fan with a speed converter, a valve, gas and liquid supply channels, and a control unit including a controller, valve control relay and fan speed converter.

The disadvantages of the known device are the inability to carry out directional convective cooling and, therefore, to separate the cooling of the torso and limbs, as well as to regulate the consumption of liquid nitrogen, and, consequently, the cold performance of the device.

The technical problem that the utility model is aimed at solving is increasing the accuracy of general cryotherapy. Insufficient accuracy of object cooling significantly affects consumer characteristics: reduction in skin temperature and uniformity of cooling. When cooling different people in known devices, the same gas supply mode is used. This leads to the fact that with the same duration of cryoexposure, different people achieve different average body surface temperatures and significant heterogeneity in cooling of the torso and limbs is observed (more than 10 K). Changing the duration does not solve the problem of cooling inhomogeneity. Therefore, a range of gas supply modes is required to accommodate differences in body type and other human characteristics.

The technical result achieved when using the claimed invention is to increase the accuracy of skin surface temperature control, taking into account the characteristics of the user undergoing the cooling procedure by providing adjustable general cryotherapy.

The specified technical result is achieved in that a cryotherapeutic installation containing a cabin, including a channel for supplying a nitrogen-air mixture to the cabin located on top, a cooling unit including a mixer-gasifier, a fan, a channel for supplying a heated nitrogen-air mixture from the cabin into the mixer-gasifier and a liquid nitrogen supply channel with a valve, and a control unit, including a controller, a valve control relay and a fan speed converter, according to the invention, equipped with a slotted distributor of the flow of nitrogen-air mixture located in the upper part of the cabin with movable guide plates, designed to rotate around an axis , located along their upper edge, and a diffuser located in the lower part of the cabin, while the mixer-gasifier is equipped with a capillary-porous coating of internal elements, and the control unit is equipped with a skin temperature measurement module, including a pyrometer located in the housing with the ability to be directed towards the user’s back , and a plate movement control module, and is configured to regulate the mass flow of liquid nitrogen, the fan rotation speed, the direction of flow of the nitrogen-air mixture supplied to the cabin and the duration of its supply depending on the skin temperature.

In one embodiment, the mixer-gasifier may be equipped with a spiral chamber and a spray at its bottom.

In another embodiment, the mixer-gasifier can be made countercurrent and equipped with a sprayer in its upper part.

The developed design allows you to configure the gas supply mode according to the purpose of arbitrary cryo-exposure, changing the fan speed, liquid nitrogen flow rate, direction of the supply jet flow and the duration of cryo-exposure. As a result, it is possible to both increase the uniformity of cooling and regulate cryotherapy locally.

The claimed invention proposes to change the principle of creating equipment for general cryotherapy from immersing an object (person) in a coolant to regulated its supply to the object with feedback on the surface temperature.

In this design, it is possible to regulate the heat flow from a person by changing the flow rate of the cooling gas, the direction of the jet, the duration, and control the cooling of the skin using a pyrometer module that can operate in icy fog.

Thus, equipment for general cryotherapy with regulation of human cooling (heat flow regulation) is proposed to ensure dosing of cryotherapy with higher accuracy than using known equipment.

The invention is illustrated by drawings, which show:

in fig. 1 - general installation diagram,

in fig. 2 - cabin drawing,

in fig. 3, 4 - gasifier options,

in fig. 5 - control unit diagram,

in fig. 6 - skin temperature control module.

The installation contains a cabin 1 for cooling the person 2 in it and a refrigerant circuit, including a gas supply channel (nitrogen-air mixture) 3 and a gas exhaust channel 4 with a fan 6, connecting the cabin 1 with an evaporator-gasifier 5. The evaporator-gasifier 5 is connected by a pipeline 8 for supplying liquid nitrogen, on which valves 7 are located, with a Dewar vessel 9.

Cabin 1 contains an external load-bearing hexagonal housing covered with an internal layer of thermal insulation, a slot flow distributor 10 with guide plates 11, gas inlet and outlet channels 12, 13, gas temperature sensors 14 and a skin temperature control module 15. In the lower part of the side wall of the housing there is an outlet hole with diffuser 16.

The spiral mixer-gasifier shown in FIG. 3 is made as follows.

The gasifier contains internal and external walls 17 with a cavity 18 between them, a pipe 19 for air inlet, spiral nozzles 20 located in the cavity to form a spiral chamber 21, a pipe 22 for the outlet of the nitrogen-air mixture, and a sprayer 23. The internal surfaces of the gasifier are made with capillary porous coating. The outlet 24 for the nitrogen-air mixture is located in the upper part of the apparatus.

By making the chamber spiral, the path of evaporating nitrogen in the flow part is increased. By spraying liquid nitrogen into a spiral chamber perpendicular to the flow movement for cross-flow distribution of flows and the use of capillary-porous coatings, an increase in the time of drop movement is ensured. The hollow walls and outer cavity are designed to reduce heat flow to the gas. Along the axis of the cylinder, in its lower part, there is a threaded connection for connecting the sprayer 23. The air supply from the recirculation is carried out tangentially in a spiral.

The countercurrent mixer-gasifier is a housing 25 with a nozzle 26. At the bottom of the housing there is a pipe 19 for air inlet, above which there is a flow equalizer 27, which is a cylindrical plate in which an array of small cylindrical channels is made, due to which one flow is divided into many flows .

This design uses the principle of gas movement from bottom to top without swirling the flow. The gas enters from below through the nozzle 19, passes through cylindrical channels, above which a nozzle 26 is installed to increase the duration of the droplet flow, then the gas rises upward and exits through the upper outlet 24. The liquid, which is gasified, enters through the sprayer 23, located above, in the direction down, partially mixed with gas in the free space of the apparatus, and partially mixed in the nozzle. This design does not allow liquid to flow down and allows the gas flow to be equalized.

To delay the downward flow of liquid, the gasifier elements are made with a capillary-porous coating.

The incoming flow is supplied using jet hydraulic nozzles 28. They are simple to manufacture compared to centrifugal ones and are not subject to clogging by moisture frozen from the air. When designing liquid nitrogen-based spray cooling systems, it is also necessary to take into account the effect on mass flow of injection pressure pulsations and cavitation due to phase heterogeneity of the flow. The use of multi-nozzle atomizers with hydraulic nozzles as part of a mixing gasifier with pulsed supply of cryogenic liquid ensures regulation of the apparatus's performance without the need to return the remaining cryogenic liquid to the Dewar vessel.

The cryotherapy unit works as follows. Liquid nitrogen boiling in the gasifier cools the air, reduces the oxygen concentration and forms a dense ice fog. It enters cabin 1, moves and intensively cools the surface of the skin. A person stands in the cabin, and he is surrounded up to his shoulders by cooling gas, which enters through the gas supply channel 12 located on top. The flow is distributed on all sides in a slotted flow distributor 10, from which it emerges as follows: 2 jets, controlled by plates 11, blow on the person, the remaining jets pass by. Thus, the gas flow is directed towards the person and into the free space of the cabin 1. The plates 11 are used to regulate the direction of the flow in order to avoid hypothermia. Excess gas is released into the environment. The output channel with a diffuser for returning the nitrogen-air mixture to the cooling unit is located closer to the bottom of cabin 1.

A slot gas flow distributor 10 with plates 11 allows you to direct the flow along a person from different sides from top to bottom, with part of the flow directed towards the person (there are jets at the back and front, adjustable using a movable plate).

The heated nitrogen-air mixture is discharged from cabin 1 through outlet 13 with diffuser 16.

By using a diffuser, it is possible to both move the flow away from the wall at the same level in height and to change the entry location vertically, which leads to increased air mobility at the feet. This allows you to regulate its speed. The intensity of the flow can be adjusted for different legs to balance the cooling of the legs and torso. For example, for a large leg - increase the gas speed, for a thin one - slow down.

The control unit (Fig. 5) contains power and control electronics, including a controller, a timer, a skin temperature measurement module, a valve control relay, a fan speed converter, a plate movement control module and a skin temperature control module. The skin temperature control module allows you to create feedback between the gas supply and skin temperature, which improves the accuracy of cooling a person, because people have different dimensions, and only a program executed in advance cannot regulate the cooling process accurately enough.

The skin temperature control module shown in FIG. 6, contains a housing, a pyrometer 30 (sensitive element of the device) with a laser for indicating the measurement spot for measuring temperature, and an axial fan 29 for thermostatting the pyrometer. The pyrometer is aimed at the person's back. The control unit can take into account a correction depending on the distance and density of the fog for the presence of ice fog between the pyrometer and the surface of the object - the skin (measurement in conditions of the presence of a low-temperature dispersed medium). The correction is selected empirically, using calibration based on test measurements.

The control unit allows you to adjust the gas supply mode according to the target of the voluntary exposure to improve the distribution of skin temperature by changing the gas temperature by changing the liquid nitrogen mass flow rate and fan speed, the direction of the inlet gas flow in the cabin (using rotating plates) and the duration of exposure. The control unit allows you to change the heat flow to achieve a given skin temperature both on average and locally. Thus, to increase the cooling accuracy, regulation is provided both at the level of the control unit and at the level of the actuators.

Temperature sensors, including a skin temperature control module, as well as a timer, provide the ability to influence a pre-prepared cooling program, and actuators (frequency converter, valve, plates) can change the exposure mode and thereby regulate the heat flow from a person to the gas. Gas temperature sensors installed in the cabin transmit information to regulate the supply of liquid nitrogen.

Claims (3)

1. A cryotherapeutic installation containing a cabin, including a channel for supplying a nitrogen-air mixture to the cabin located on top, a cooling unit including a mixer-gasifier, a fan, a channel for supplying a heated nitrogen-air mixture from the cabin to the mixer-gasifier, and a channel for supplying liquid nitrogen with valve, and a control unit, including a controller, a valve control relay and a fan speed converter, characterized in that it is equipped with a slot distributor for the flow of nitrogen-air mixture located in the upper part of the cabin with movable guide plates, designed to rotate around an axis located along their upper edge, and a diffuser located in the lower part of the cabin, while the mixer-gasifier is equipped with a capillary-porous coating of internal elements, and the control unit is equipped with a module for measuring skin temperature, including a pyrometer located in the housing with the ability to be directed towards the user’s back, and a module controls the movement of the plates and is configured to regulate the mass flow of liquid nitrogen, the fan rotation speed, the direction of flow of the nitrogen-air mixture supplied to the cabin and the duration of its supply depending on the skin temperature. 2. Installation according to claim 1, characterized in that the mixer-gasifier is equipped with a spiral chamber and a sprayer in its lower part. 3. Installation according to claim 1, characterized in that the mixer-gasifier is countercurrent and equipped with a sprayer in its upper part.