FR3075033A1 - CRYOTHERAPY DEVICE - Google Patents

Abstract

 Cryotherapy device comprising a treatment cabin for a person connected to a system for producing and transporting a cryogenic fluid, said system comprising: at least one reservoir for storing a cryogenic liquid under pressure supplying, through means for diffusing said liquid, an evaporation duct opening out, through gas diffusion means in said treatment cabin,  means for circulating the cryogenic fluid, having upstream heating means and downstream said evaporation duct, characterized in that:  said storage tank comprises a cryogenic liquid maintained at a pressure of between 1 and 1.5 bars;  said evaporation duct, extending from said at least one storage tank to said gas diffusion means, has a narrowing.

Description

® CRYOTHERAPY DEVICE.

©) Cryotherapy device comprising a treatment cabin for a person connected to a system for producing and transporting a cryogenic fluid, said system comprising: at least one reservoir for storing a cryogenic liquid under pressure supplying, through means for diffusing said liquid, an evaporation duct opening, through gas diffusion means in said treatment cabin, means for circulating the cryogenic fluid, having upstream heating means and downstream said duct evaporation, characterized in that:

said storage tank comprises a cryogenic liquid maintained at a pressure between 1 and 1.5 bars;

said evaporation duct, extending from said at least one storage tank to said gas diffusion means, has a narrowing.

The present invention enters the field of cryotherapy booths.

The term “cryotherapy” refers to medical, aesthetic or well-being techniques or procedures, consisting of localized or generalized treatment of the body at low temperature. This cold therapy uses a cold gas such as carbon dioxide CO ₂ or dinitrogen N ₂ and allows, using the cold:

reduce body heat in order to reduce pain, promote blood circulation, thanks in particular to vasoconstriction, lead to a relaxation of muscle fibers, to treat skin lesions in particular of the eczema, psoriasis or neurodermatitis type.

In known manner, for a whole body treatment in gas cryotherapy, that is to say for the part of the body going from the soles of the feet to the top of the shoulders, the person is placed in a closed cabin called “cryotherapy cabin »,« Cryotherapy room »,« cryogenic room »or even« cryosauna ». This cryotherapy cabin is connected to a cold source generally consisting of an external container of pressurized nitrogen. During treatment, when the person is in the cabin, the nitrogen under pressure is evaporated, then transferred and injected into the cryotherapy cabin, in order to cool it down to the treatment temperature. The person will then be in contact with nitrogen gas, that is to say at temperatures between -70 ° C and 150 ° C, preferably - 110 ° C and - 150 ° C maximum for 3 min. This person / nitrogen gas contact constitutes the treatment.

However, the techniques and apparatus existing in the prior art have a number of drawbacks.

Generally the liquid nitrogen is kept in a tank under a pressure of 4 to 7 Bars. Then the pressurized liquid nitrogen is evaporated in contact with an air stream using a fan. For the evaporation to take place, the air flow must have a sufficient flow and temperature for the transformation into gas, in contact with pressurized liquid nitrogen, to occur. This is why, in known devices, a large fan with a power of 600 Watts is often necessary.

The need to produce a sufficient current of air for the phenomenon of evaporation to take place has several drawbacks.

The size of the power fans at 600 Watts is often substantial, so a corresponding space must be available to accommodate it near the cryotherapy cabin.

In addition, the power of these fans is such that its operating noise can be disturbing and stressful for the person being treated. Indeed, during treatment, the person can undergo and hear deafeningly the noise of the movement in rotation of the blades of the ventilator generating the current of air, which can destabilize it.

In addition, existing current devices require the consumption of 5 to 7 L of pressurized liquid nitrogen between 4 and 7 bars to treat a person. However, out of this volume of liquid nitrogen under pressure in stock, only about 65% of the liquid nitrogen under pressure will actually be evaporated, the other non-evaporated part constituting a pure loss. The existing devices are therefore not suitable for avoiding nitrogen losses. In general, the liquid nitrogen container is connected to an evaporation tank of a cryotherapy cabin by a piping device. In the container, the nitrogen is kept under pressure between 4 and 7 bars and it is necessary to carry out a degassing step to reduce the pressure before transferring the nitrogen to the evaporation tank. This results in a loss of gas, therefore a non-negligible economic cost.

Thus, in known devices, the efficiency of transformation of liquid nitrogen under pressure into evaporated nitrogen is not yet satisfactory. This has the disadvantage of consuming a lot of liquid nitrogen and of regularly changing the empty container between a series of people to another.

In addition, it is customary for the transformation of liquid nitrogen into evaporated nitrogen to take place outside of a person's treatment cabin. This is why known devices often have means for storing evaporated nitrogen connected to means for conveying this evaporated nitrogen to the treatment bath in which said person is located.

These disadvantages of storing evaporated nitrogen have the disadvantage of occupying an important place in the room. Consequently, a room of substantial size must exist, just for the establishment of the cryotherapy booth.

A way must be found to minimize as much as possible the space occupied by the cryotherapy cabin.

In addition, the means for conveying evaporated nitrogen further increase the risk of possible nitrogen loss between the container of liquid nitrogen and the treatment bath in which the person is located.

Consequently, the apparatuses of the prior art have a certain number of drawbacks which must be remedied. Indeed, it is necessary to find a cryotherapy cabin which is both compact, non-noisy and with a maximum cryogenic flow production efficiency in order to optimize the overall operation of said cabin.

More specifically, it is necessary to reduce the total space requirement in a room of the cryotherapy cabin, as well as to reduce its operating noise while minimizing the nitrogen consumption necessary for a person.

An alternative solution should be found to the cryotherapy cabin device which has both operating noise and reduced energy consumption, while increasing the efficiency of transformation of liquid nitrogen into evaporated nitrogen, this in order to optimize the operating costs of the cryotherapy booth for the treatment of a person.

The present invention aims to overcome the drawbacks of the state of the art, by proposing a cryotherapy device comprising a treatment cabin for a person, said cabin being connected to a system for producing and transporting a fluid. cryogenic, said system comprising:

- At least one tank for storing a cryogenic liquid under pressure supplying, through means for diffusing said liquid, an evaporation duct opening out, through means for diffusing gas in said treatment cabin.

Thus, the pressurized liquid is transformed into gas within the evaporation duct and then injected into the treatment cabin to reach and treat the person.

Said system also comprises means for circulating the cryogenic fluid, having upstream heating means and downstream said evaporation duct.

These cryogenic fluid circulation means allow its movement in a certain direction of circulation but also its change of chemical state, that is to say the transition from a liquid to gaseous state to carry out the evaporation reaction.

According to a specific feature of the invention, said storage tank comprises a cryogenic liquid maintained at a pressure of between 1 and 1.5 bars.

This low pressure has the advantage of facilitating storage but also the transfer of the pressurized liquid to the conduit where the evaporation reaction will take place. Indeed, during the transfer of the liquid under pressure to said conduit, the opening of the storage tank causes degassing causing loss of liquid. The higher the tank pressure, the greater the losses during opening for transfer. Thus, in order to limit the losses during the opening of the storage tank for the transfer of the liquid, the pressure has been minimized to the maximum. It has been specifically found that a pressure of between 1 and 1.5 bars makes it possible to transfer and evaporate at least 90% of the cryogenic liquid within the conduit.

According to an additional specificity of the device of the invention, said evaporation duct, extending from said at least one storage tank to said gas diffusion means, has a narrowing.

The presence of a narrowing of the dimensions of said evaporation duct promotes the evaporation reaction. The narrowing thus increases the efficiency of transformation of the cryogenic liquid, introduced into said conduit, into a cryogenic gas, which can be used to treat the person within the treatment cabin.

In addition, according to other characteristics of the cryotherapy device of the invention:

said cryogenic liquid consists of liquid nitrogen under pressure at 1 or 1.5 bars,

- Said heating means consist of at least one resistance.

According to other additional characteristics of the cryotherapy device of the invention:

said means for circulating the cryogenic fluid comprise at least one fan,

- Said fan is an action fan, with a power between 55 and 70 Watts.

According to a specific embodiment, the power of the fan can be further reduced by being between 30 and 70 watts.

Said fan has the advantage of operating at a low wattage, therefore of limiting the energy consumption necessary for the operation of the cryotherapy device. In addition, the fan in operation makes it possible to generate both the circulation of the cryogenic fluid within the device and to contribute to the evaporation reaction. Indeed, the air flow at the outlet of the fan coming into contact with the cryogenic liquid under pressure will allow its evaporation into gas.

According to other advantageous characteristics of the device of the invention:

- Said treatment cabin comprises at least one suction opening of the cryogenic gas present within said treatment cabin, said at least one suction opening opening onto a duct for recovering the gas present within said treatment cabin;

- Said heating means are integrated within said recovery duct so as to increase the temperature of the cryogenization gas passing through said recovery duct;

- Said circulation means are positioned at the intersection between the recovery duct and the evaporation duct, and are intended to suck the gas from said treatment cabin through the suction openings in order to return it to said duct d 'evaporation.

Thus, the presence of the heating means upstream of the circulation means makes it possible to heat the cryogenic fluid upstream of the circulation means and consequently avoid the possible formation of frost on the blades of the fan which can block their operation.

Indeed, between two treatment sessions, when the person is not in the treatment cabin, the heating means are put into operation and the supply of pressurized cryogenic liquid is stopped to allow the fluid circulating in the device to warm up and defrost the means of circulation.

In addition, the cryogenic fluid production and transport system is a semi-closed circuit which minimizes losses of cryogenic fluid. Indeed, the gas injected into the treatment cabin is recycled. The recycled gas contributes to the evaporation reaction transforming the liquid under pressure at the outlet of the diffusion means into gas intended to be used to treat the person.

In order to further limit the losses of the cryogenic fluid circulating within the device, said transformation / evaporation conduit comprises means for receiving cryogenic liquid under pressure intended to recover the cryogenic liquid under pressure not evaporated within said transformation conduit. / evaporation.

The cryotherapy device of the invention makes it possible to reduce the energy consumption, to avoid noise pollution necessary for its operation while limiting the consumption of cryogenic liquid necessary for the treatment of a person by an increase in the efficiency of evaporation of said liquid.

The cryotherapy device therefore has an economic advantage for users.

Other characteristics and advantages of the invention will emerge from the detailed description which follows of nonlimiting embodiments of the invention, with reference to the appended figures, in which:

- Figure 1 schematically shows a view of the cryotherapy device of the invention.

The present invention relates to a cryotherapy device 1 comprising a treatment cabin 2 for a person 3, as illustrated in FIG. 1.

According to a particularly advantageous embodiment of the cryotherapy device of the invention, said treatment cabin 2 comprises an access door for the entry and exit of a person 3 and an opening on the top to hold the head of person 3 outside said treatment booth 2.

Said treatment cabin 2 is connected to a production and transport system 4 of a cryogenic fluid 5.

Said cryogenic fluid 5 can be, for example, a gas, in particular of the dinitrogen N ₂ type carbon dioxide CO ₂ or oxygen O ₂ , or any of the possible combinations.

It should be noted that according to the invention, said cryogenic fluid 5 can be in different chemical states depending on its position and its movement within the system 4. For example, said cryogenic fluid 5 can be in the form of cryogenic liquid under pressure or else in the form of gas.

According to the invention, said system 4 comprises at least one storage tank 6 for a cryogenic liquid under pressure.

The expression “cryogenic liquid under pressure” is understood to mean the cryogenic fluid 5 having predominantly a liquid form and which is contained in said reservoir 6.

Preferably, said pressurized cryogenic liquid consists of nitrogen stored in liquid form at a temperature at -196 ° C within the storage tank 6. However, due to the pressure inside the storage tank 6 part of this nitrogen may be in the form of nitrogen gas.

Said storage tank 6 consists, for example, of a tank of 20 to 1000 L, preferably of 2 to 4 L, containing liquid nitrogen under pressure.

Said storage tank 6 supplies, with said cryogenic liquid under pressure, an evaporation duct 7.

Said cryogenic liquid under pressure can, following an evaporation reaction, be transformed into a gas circulating in said system 4, in particular within said evaporation duct 7.

Diffusion means 8 for said liquid, at the outlet of the storage tank 6, make it possible to supply said evaporation duct 7 with said cryogenic liquid under pressure.

Advantageously, said diffusion means 8 consist of at least one nozzle for spraying said cryogenic liquid under pressure within said evaporation duct 7.

According to another embodiment of the invention, said diffusion means 8 consist of a diffusion nozzle which will allow transfer of the liquid nitrogen under pressure from the storage tank 6 to the evaporation duct 7.

Said evaporation duct 7 opens into said treatment cabin 2 for a person 3.

The flow of cryogenic fluid 5, in the form of gas, present within the evaporation duct 7, will enter said cabin 2 to reach the person 3 and treat him. The passage and movement of the cryogenic fluid 5 contained in said evaporation duct 7 towards said cabin 2 is possible thanks to gas diffusion means 9.

Said gas diffusion means 9 consist for example of at least one gas diffusion nozzle whose opening can be controlled by a valve system.

Preferably, said gas diffusion means 9 are positioned on the upper part of said treatment cabin 2, so that the diffusion of gas takes place at the shoulders of person 3.

Within the evaporation duct 7 an evaporation reaction of the cryogenic liquid under pressure takes place, thus the liquid under pressure is transformed into gas which will be able to come into contact with the person 3 installed in the cabin 2.

According to the invention, said system 4 also includes means 10 for circulating the cryogenic fluid through the cryotherapy device 1.

Advantageously, said means for circulating the fluid 10 comprise at least one centrifugal fan, preferably a three-phase centrifugal fan.

The said circulation means 10 have the effect of transporting the said cryogenic fluid 5 within the system 4 and of giving it a direction of movement, represented by the arrows in FIG. 1.

In addition, said circulation means 10 of fan type provide a stream of air within the evaporation duct 7. In contact with the cryogenic liquid under pressure at the outlet of the diffusion means 8, said stream of air, which has a temperature> that of the cryogenic liquid under pressure, will allow the evaporation reaction, that is to say the transformation of the cryogenic liquid under pressure into gas.

In other words, said circulation means 10 in addition to transporting and giving a direction of circulation to the cryogenic fluid 5, will allow its change of chemical state by promoting the evaporation reaction.

Specifically to the invention, said centrifugal fan has a power of between 55 and 70 Watts, preferably 60 Watts. Thus, the operating noise of the cryotherapy device 1 of the invention is reduced compared to the devices of the prior art which use power ventilators of the order of 600 Watts.

The device 1 has the advantage of operating by reducing as much as possible the power required by the circulation means 10 for carrying out the evaporation reaction, that is to say the transformation of the liquid into cryogenic gas, while reducing the operating noise.

Thus, the production of cryogenic gas, reaching the person 3 installed in the treatment cabin 2, is less noisy, less costly in energy, hence an economic gain.

According to a particular embodiment of the invention, said fan is a three-phase centrifugal fan with action, that is to say that it has blades inclined towards the front.

During fan operation, the inclination forward of the blades has the advantage in a humid environment of limiting the fixing of the water molecules on the blades. Thus, at temperatures below 0 ° C, the risk of frost on the blades is reduced by the lack of fixation of the water molecules.

According to a preferred embodiment of the invention, said fan is provided with several flat blades, wide and spaced apart. The flat blades have the advantage of sliding the molecules of cryogenic gas, in particular of water, to avoid their fixing on the surface of the blades therefore of preventing the formation of frost on the blades at temperatures f to 0 ° C., which are the temperatures of circulation of the cryogenic fluid 5 within the device 1. Thus in this specific embodiment, the ice setting of the blades during the operation of the cryotherapy device 1 is not possible. The spacing of the blades between them allows good circulation of the cryogenic fluid 5 through said fan, which however retains its action of circulation of the cryogenic fluid 5 favored by the width of the blades.

Said production and transport system 4 of said cryogenic fluid also comprises, upstream of said means of π

circulation 10, heating means 11. The latter are present within a recovery duct 12.

Said heating means 11 consist for example of a heating resistor. Such a resistance has for example a power of the order of 1 Watt.

Said heating means 11 make it possible to raise the temperature within the recovery duct 12, therefore to raise the temperature of the fluid circulating within the recovery duct 12.

According to FIG. 1, the recovery duct 12 opens onto the evaporation duct 7, said means for circulating 10 of the cryogenic fluid 5 within the system 4 are positioned at the junction of the recovery duct 12 with the duct d evaporation 7.

Thus, said heating means 11 being upstream of the circulation means 10, the gas, circulating in the recovery conduit 12 and passing through the circulation means 10, has a temperature> that of the cryogenic liquid injected into the evaporation conduit 7.

Consequently, the heating of the gas circulating in the recovery duct 12 has the effect, both, of contributing to the evaporation reaction which takes place downstream of the circulation means 10 and at the outlet of the liquid diffusion means 8 , but also to avoid the formation of frost on said circulation means 10.

Thus, changing the circulation means 10 or defrosting them is no longer a necessity with the device 1, unlike the device of the prior art.

In addition, said recovery conduit 12 allows the recovery and circulation of the gas initially present in the treatment cabin 2, for example after the treatment of a person 3.

More specifically, said treatment cabin 2 has suction openings 13 for the gas still present in the treatment cabin 2. These suction openings 13, opening onto the recovery duct 12, are intended to transport the gas from the cabin treatment 2 to the heating means 11.

The suction openings 13 allow recycling of the gas initially present in the treatment cabin 2.

The operation of the circulation means 10 will allow the circulation of the cryogenic fluid 5 in the direction indicated by the arrows in FIG. 1. The suction of the gas through said suction openings 13 will take place, in particular thanks to the movement of the blades of the fan positioned at the junction between the recovery duct 12 and the evaporation duct

7.

In other words, according to the invention, the cryogenic fluid 5 circulates from the storage tank 6 to the evaporation duct 7, to then reach the treatment cabin 2 where the person 3 is located, then it is sucked through openings 13, to come into contact with the heating means 11 and go towards the circulation means 10 to finally return to the evaporation duct 7.

As visible in FIG. 1, the cryogenic fluid circulates within the device 1 according to the direction of movement indicated by the arrows.

According to a feature of the invention, said storage tank 6 comprises a cryogenic liquid under pressure between 1 and 1.5 bars, or even between 0.2 and 1.5 bars, unlike the devices of the prior art where the cryogenic liquid under pressure is between 4 and 7 Bars.

The pressure maintained in the storage tank 6 of the cryogenic liquid is minimal. Thus, unlike the prior art, at the time of the transfer of the cryogenic liquid to the place where the evaporation reaction takes place, during the opening of the tank 6 degassing occurs, however the gas losses are limited.

In fact, the losses of cryogenic liquid are limited during the opening of the storage tank 6 because the pressure difference between said storage tank 6 and the evaporation duct 7 is small.

Thus, the management of the pressure within the device 1 is optimized to limit the losses during degassing. In addition, limiting the losses of cryogenic liquid during the opening of the reservoir 6 makes it possible to increase the efficiency of transformation of the cryogenic liquid into cryogenic gas.

In fact, in the device 1, the cryogenic liquid can directly enter the evaporation duct 7 and evaporate directly on contact with the stream of hot air leaving the fan.

With the device 1, it has been shown that more than 90% of the cryogenic liquid contained in the tank 6 evaporates in cryogenic gas within the evaporation duct 7, unlike the device of the prior art where the transformation yield of the liquid contained in the storage tank is on average <90%.

A high conversion efficiency, due to a low initial cryogenic liquid pressure, has the advantage of minimizing the amount of liquid required to treat a person 3. As a result, the loss of cryogenic liquid during the treatment procedure of a 3 person by cryotherapy are minimized.

According to a particular embodiment, the cryogenic liquid not transformed / evaporated into gas in the evaporation duct 7 is recovered, upstream of the means for diffusing a gas 9, using means for receiving said liquid.

These receiving means allow recovery and possible recycling of the non-evaporated cryogenic liquid within the evaporation duct 7.

Advantageously also, in order to increase the transformation efficiency of the cryogenic liquid and to favor the evaporation reaction, said evaporation duct 7 has a narrowing of these dimensions between its part associated with the storage tank 6 up to its opening part. on the gas diffusion means 9 within the treatment cabin

2. This narrowing of the evaporation duct 7, extending from the storage tank 6 by means of gas diffusion 9, accentuates the transformation of the cryogenic liquid into cryogenic gas, that is to say promotes the evaporation reaction , increases the efficiency of transformation of the liquid into gas and reduces the losses of said cryogenic liquid.

Thus, the configuration and the means of the cryotherapy device 1 has the advantage of optimizing its operation by limiting the losses of cryogenic fluid 5 to the maximum, by reducing the general operating noise and by preventing the deposit of frost on the ventilator. This allows the cryotherapy device 1 to be able to chain the number of people who will undergo the treatment within said treatment cabin 2, while limiting the general operating and maintenance costs.

Claims (9)

1. Cryotherapy device (1) comprising a treatment cabin (2) of a person (3) connected to a production and transport system (4) of a cryogenic fluid (5), said system (4) comprising : at least one storage tank (6) for a cryogenic liquid under pressure supplying, through diffusion means (8) of said liquid, an evaporation duct (7) opening out, through gas diffusion means (9 ) in said treatment cabin (2), means (10) for circulating the cryogenic fluid (5), having upstream heating means (11) and downstream said evaporation duct (7), characterized in that : said storage tank (6) comprises a cryogenic liquid maintained at a pressure between 1 and 1.5 bars; said evaporation duct (7), extending from said at least one storage tank (6) up to said gas diffusion means (9), has a narrowing. 2. cryotherapy device (1) according to the preceding claim, characterized in that said cryogenic liquid consists of liquid nitrogen under pressure at 1 or 1.5 bars. 3. Cryotherapy device (1) according to any one of the preceding claims, characterized in that said circulation means (10) of the cryogenic fluid (5) comprise at least one fan. 4. Cryotherapy device (1) according to the preceding claim, characterized in that said ventilator is an action ventilator, with a power of between 55 and 70 Watts. 5. cryotherapy device (1) according to any one of the preceding claims, characterized in that said heating means (11) consist of at least one resistance. 6. cryotherapy device (1) according to any one of the preceding claims, characterized in that said treatment cabin (2) comprises at least one suction opening (13) of the cryogenic gas present in said treatment cabin (2), said at least one suction opening (13) opening onto a recovery duct (12) for the gas present in said treatment cabin (2). 7. cryotherapy device (1) according to the preceding claim, characterized in that said heating means (11) are integrated within said recovery duct (12) so as to increase the temperature of the cryogenization gas passing through said duct. recovery (12). 8. cryotherapy device (1) according to claim 6, characterized in that said circulation means (10) are positioned at the intersection between the recovery duct (12) and the evaporation duct (7), and are intended to suck the gas from said treatment cabin (2) through the suction openings (13) in order to return it to said evaporation duct (7). 9. cryotherapy device (1) according to any one of the preceding claims, characterized in that said evaporation duct (7) comprises means for receiving cryogenic liquid under pressure intended to recover the cryogenic liquid under pressure not evaporated at within said evaporation duct (7).