PL157168B1 - Apparatus for carrying out cryotherapeutic operations - Google Patents

Abstract

1. Equipment for cryotherapeutic procedures consisting of a patient's chamber and its air supply system delivered at cryogenic temperatures that includes air supply circuit with a compressor and dehumidifier and air cooling circuit with a liquid gas cylinder and heat exchanger, characterised by the fact that it utilises an initial heat exchanger (5), final heat exchanger (11) and a spraying device (8), where the initial heat exchanger (5) is located in the patient's chamber (1) and connected to the liquid gas cylinder (2), to the heat exchanger (10) and to the spraying device (8) which is also located in the chamber (1), while the final heat exchanger (11) is connected to the heat exchanger (10) and ambient air as well as to the air compressor (13) and dehumidifier (14).<IMAGE>

Description

The subject of the invention is a device for performing cryotherapeutic treatments, during which the patient's body inside the chamber being a component of the device is exposed to gases at cryogenic temperature.

In medical technology, devices for the performance of cryotherapeutic procedures are known, in which the gases at cryogenic temperature act on the entire body of the patient. These devices consist of a chamber inside which the patient or patients are placed during the treatment, a system that supplies the chamber with gas at cryogenic temperature, and control, security and other systems.

From the patent application No. 3 213 919 published in Germany, a device is known to obtain air at cryogenic temperature, intended for supplying the chamber for cryotherapeutic treatments. The device includes: an air compressor, a dryer for removing water vapor from compressed air, a heat exchanger and a container for liquefied gas, preferably liquid nitrogen. All these components of the device are suitably connected by tubing. The liquefied gas from the tank goes to the heat exchanger and there it cools the air to cryogenic temperature, which then flows through an insulated pipe to the place where it is used for cryotherapy treatments. The dehumidifier is equipped with two tanks filled with a water vapor absorbing substance. These tanks work alternately; while one absorbs the water vapor of the flowing air, the other undergoes the process of regenerating the absorbent. The whole device is equipped with measuring, control and protection elements. The parts of the device containing refrigerants with cryogenic temperature are provided with thermal insulation.

Although the device described above fulfills its task of supplying air at cryogenic temperature for cryotherapeutic purposes, it nevertheless has a number of disadvantages. A disadvantageous operating characteristic of the device can be given here, which is manifested in the fact that its start-up time is long, that is, the time from switching on the compressor to the full efficiency of the device. It also takes a long time to bring the device to a standstill after the end of the treatments, i.e. the process of bringing the device to the ambient temperature and removing the condensed water vapor. The disadvantages of the device also include incomplete use of the thermal properties of liquefied gas.

The object of the invention is to provide such a cryotherapeutic device for treating the entire body of a patient - or patients, which exhibits the advantages of the known devices, but not the disadvantages of these. The device according to the invention should therefore provide the chamber with gas of optimal parameters for therapeutic reasons, create conditions for the full safety of patients and operating personnel, be characterized by favorable operating characteristics, including short start-up and standstill times, and be characterized by the maximum use of liquefied gas used as a coolant. The costs of making and operating the device should be as low as possible, and its operation should be relatively simple and possible to be performed by trained persons who do not have long-term experience in the operation of cryotechnical devices.

According to the invention, the device for the cryotherapy treatment has a chamber for patients and a device for supplying the chamber with air at cryogenic temperature. The unit includes an air supply circuit and an air cooling circuit. The essence of the invention is the use of three heat exchangers and a spray element in the cooling air circuit. These are a preliminary air exchanger, a heat exchanger and a final heat exchanger. A pre-heat exchanger and spray element are located inside the patient chamber. The pre-heat exchanger is connected by pipes to a liquid gas tank, a heat exchanger and a spray element. The final heat exchanger, on the other hand, is connected to the heat exchanger and to the air compressor and to the air dryer. Moreover, the final heat exchanger is connected to the surroundings.

In the preferred version of the solution of this device, the heat exchanger is connected to the dryer by means of two separate pipes with heaters built in them, and to the chamber - with a pipe with a built-in reducer and cut-off valve. The said air dryer is additionally connected via shut-off valves to a vacuum pump. In addition, two shut-off valves are installed in the line connecting the pre-heat exchanger to the spray element.

The device for performing cryotherapeutic treatments according to the invention combines the advantages of known devices of this type, but does not have the disadvantages of the same. It ensures the fulfillment of the basic goals, which are to obtain a gaseous cryogenic agent with parameters used to achieve the assumed therapeutic goals and then subject the patients to treatments in a closed chamber, which is a component of the device, as well as creates conditions for complete safety both for patients during the procedure and for staff during the treatment. all activities related to the operation of the device. The expenditure on making the device is moderate and operating costs are low, which is positively influenced by the optimal use of liquefied gas. The device is characterized by favorable operating characteristics, as both start-up and stopping takes little time. The operation of the device is easy and can be performed by persons trained, not qualified in the field of cryotechnics.

The subject of the invention is shown in an exemplary embodiment in a schematic drawing.

The device for cryotherapeutic treatments consists of a closed-type chamber 1 and other elements serving to supply it with a working medium with appropriate parameters, selected purposefully from the point of view of therapeutic needs. Due to the schematic nature of the drawing, chamber 1 has been shown in a very simplified manner, excluding such components as vestibule, doors, windows and others. In order to feed the chamber 1 with the working medium in the device according to the invention, two factors are used, namely air in gaseous form and a liquefied gas, preferably liquid nitrogen. The role of the working medium acting during the procedure directly on the organisms of patients in chamber 1 is air in gaseous form, while the liquefied gas is

157 168 used as a coolant, used to lower the temperature of the working medium and components of the equipment. Therefore, the elements for feeding the chamber 1 can be divided into two groups according to what medium they store or conduct, and a third group, i.e. those with both factors, can be given. Thus, the device includes elements for the circulation of liquefied gas, for the circulation of air and elements for the contact of these two circuits.

The first element in the liquefied gas circuit is a tank 2 containing a liquefied gas, preferably liquid nitrogen. The tank 2 is connected to the chamber 1 by a pipeline provided with an insulating jacket. A shut-off valve 3 and a regulating valve 4 are arranged on the line. The pipe leads to a preliminary heat exchanger 5 located inside the chamber 1. The pipe downstream of the preliminary heat exchanger 5 leads out of the chamber 1 and divides into two branches after it. The first branch of the pipeline, provided with two shut-off valves 6 and 7, leads to the spray element 8 located inside the chamber 1 under its ceiling. The adoption of the two shut-off valves 6 and 7 is dictated by the safety of using the chamber when a patient or patients are present. In this case, there should be no escape of liquefied gas through the spray element 8. The second branch of the piping, provided with a shut-off valve 9, leads to the heat exchanger 10 and then to the final heat exchanger 11. The piping between chamber 1 and the final heat exchanger 11 it is provided with an insulating jacket. The final heat exchanger 11 is connected to the atmosphere by a pipe on which a non-return valve 12 is installed. This pipe is not provided with an insulating jacket.

The first element of the air circulation is the compressor 13. From there, the piping leads to the final heat exchanger 11 and from there another section of the pipe leads to the dryer 14. The pipe between the compressor 13 and the final heat exchanger 11 is not insulated, while the pipe between the final heat exchanger 11 and the desiccant 14 is provided with a jacket. The dryer 14 includes two sorbent containers 15 and 16 and eight shut-off valves 17, 18, 19, 20, 21, 22, 23, 24. The dryer 14 is connected by a pipe to an oil vacuum pump 25. Another pipe on which a regulating valve 26 and a heater 27 are placed, leads to the heat exchanger 10. The dryer 14 is additionally connected to the heat exchanger 10 by a pipe on which a heater 30 is installed. The heat exchanger 10 is connected to the chamber 1 by a pipe on which the reducer is placed 28 and a shut-off valve 29. At the lowest point of the bottom of chamber 1 is a condensate drain 31. A drain valve 32 is provided at the bottom of the heat exchanger 10, and a drain valve 33 is provided at the bottom of the final heat exchanger 11.

After opening the shut-off valve 3, the liquefied gas flows from the tank 2 and flows through the pipeline to the preliminary heat exchanger 5, located inside the chamber 1. The flow rate of the liquefied gas is set by the control valve 4. The preliminary heat exchanger 5 lowers the temperature of the working medium in chamber 1 After leaving the preliminary heat exchanger 5, the liquefied gas continues through a pipeline which is led out of chamber 1 and splits into two branches outside of it. During the start-up of the chamber, the two shut-off valves 6 and 7 located on the first branch of the conduit are opened for a specified time, while the shut-off valve 9 located on the second branch is closed. Then the liquefied gas flows to the spraying element 8 and flowing out of it causes the temperature of the gas filling chamber 1 to drop very quickly. After the start-up period, shut-off valves 6 and 7 are closed, and shut-off valve 9 is opened. The liquefied gas then flows through the pipeline to the heat exchanger 10. and from there to the final heat exchanger 11. As it flows through the successive components of the circuit, the liquefied gas gradually evaporates into a gaseous state. As it flows through the subsequent components of the circuit, the temperature of the gas increases, so that when it leaves the atmosphere downstream of the non-return valve 12, it is slightly lower than the temperature of the surrounding atmosphere.

The compressor 13 draws in atmospheric air and compresses it to the required pressure. Compressed air flows through a pipe to the final heat exchanger 11, where heat is exchanged between it and the gas resulting from the evaporation of the liquefied gas, as a result of which the air temperature is lowered. Air from final heat exchanger 11

157 168 flows through a conduit to the dryer 14 and from there via a conduit provided with a regulating valve 26 and a heater 27 to the heat exchanger 10. The heater 27 is then turned off. In the heat exchanger 10, heat exchange takes place between the air and the liquefied gas. From the heat exchanger 10, the air flows out through a pipeline, passes through the reducer 28 and the valve 29, and with the end section of the pipeline, it enters the chamber 1, where it serves as a working medium for performing cryotherapeutic treatments. The dryer 14 runs periodically. After leaving the final heat exchanger 11, the air flows alternately through the sorbent containers 15 and 16. During the first operating period, air flows through the sorbent container 15. Shut-off valves 22, 23, 17 and 20 are closed, shut-off valves 21 and 19 are open. Dry air from the exchanger 10 flows through a pipe and through the heater 30, in which it is heated, to the sorbent container 16. Shut-off valves 24 and 18 are open, the oil vacuum pump 25 works. During the second operating period, air flows through the sorbent container 16. Shut-off valves 24, 21, 19 and 18 are closed, shut-off valves 22 and 17 are open. Dry air from the heat exchanger 10 flows through the conduit and through the heater 30, where it is heated, and then flows into the sorbent container 15. The shut-off valves 23 and 20 are open, the oil vacuum pump 25 is operating.

After the cryotherapeutic procedures are completed, the device is brought to a standstill. For this purpose, the oil vacuum pump 25 is first switched off. The shut-off valves 3, 18, 20 and 29 are closed. The shut-off valves 22, 21, 23, 24, 17 and 19 are open. Drain valves 32 and 33 and condensate drain 31 are open. Heaters 27 and 30 are turned on at full power. The heat exchanger 10 is drained. The drain valves 32 and 33 are then closed, the shut-off valve 29 is opened and the warm air dries chamber 1. The next step is to open the shut-off valves 18 and 20, while the other shut-off valves are closed. The oil vacuum pump 25 is turned on and the sorbents are regenerated. Then the oil vacuum pump 25 is turned off and all valves are closed. At this point, the process of bringing the device to a standstill is completed. All cut-off valves 3, 6, 7, 9, 17, 18, 20, 21, 22, 23, 24 and 29 and drain valves 32, 33 are electromagnetically controlled from the control panel - omitted in the figure.

Department of Publishing of the UP RP. Circulation of 90 copies

Price PLN 5,000.

Claims (5)

Patent claims A device for cryotherapeutic treatment, comprising a chamber for patients and a unit for supplying this chamber with air at cryogenic temperature, which includes an air supply circuit with a compressor and dryer, and an air cooling circuit with a liquid gas tank and a heat exchanger, characterized by the fact that it has a preliminary heat exchanger (5), a final heat exchanger (11) and a shower element (8), the preliminary heat exchanger (5) located in the patient chamber (1) being connected by pipes to the liquid gas tank (2), heat exchanger ( 10) and a spray element (8), also seated in the chamber (1), while the final heat exchanger (11) is connected by pipes to the heat exchanger (10) and the environment, as well as to the air compressor (13) and the dryer (14). 2. The device according to claim The heat exchanger (10) is connected to the dryer (14) by two separate lines in which heaters (27) and (30) are built, and to the chamber (1) by a line via a reducer (28) and a valve shut-off valve (29). 3. The device according to claim The dryer according to claim 1, characterized in that the dryer (14) is connected to the vacuum pump (25) through a line with shut-off valves (18) and (19). 4. The device according to claim The apparatus as claimed in claim 1, characterized in that the preliminary heat exchanger (5) is connected to the spray element (8) via two shut-off valves (6 and 7). 5. The device according to claim 1 The method of claim 1, characterized in that the preliminary heat exchanger (5) is connected to the liquid gas reservoir (2) via a shut-off valve (3) and a control valve (4).