RU2496065C2 - System for cooling of glassware, which is equipped with liquid carbon dioxide removal device - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: system for cooling of glassware or other receivers is equipped with distributing box for removal of liquid carbon dioxide, includes base, to which hollow tubular element, and spraying assembly that is faced downwards, the first reflector above base for arrangement of shot glass, and under reflector, connection pipe with pipeline, electric valve and spraying assembly facing downwards, as well as the second reflector of smaller size is attached. Pipeline represents flexible sleeve of steel net with internal hose made from Teflon, and distributing box includes connection element with lower compartment, side holes and upper compartment.

EFFECT: use of this invention allows increasing system operating efficiency.

18 cl, 21 dwg

Description

FIELD OF THE INVENTION

The invention, as follows from the title of the description, relates to an improved system for cooling glassware and other receivers, equipped with a junction box for removing liquid carbon dioxide.

In particular, the invention relates to a cooling system used to cool glassware or other receivers to a low temperature in a very short time by spraying them with liquid carbon dioxide (cryogenic liquid), and is particularly intended for use in the hotel and restaurant business. It features a number of improvements over other devices already available on the market, which offers an improved alternative that offers significant benefits.

For example, among other features that will be described in detail below, the proposed system has, as a major improvement, the feature that its design allows you to place a glass or receiver under the nozzle from which gas is sprayed over them, which gives a number of advantages that significantly increase the functionality and system efficiency.

The proposed system also includes an innovative junction box for removing liquid carbon dioxide, which is used to spray glassware. The features of this junction box will be described below.

The scope of the invention is the technical services of industries related to cooling technologies or refrigeration units and household appliances, and the production of parts for connecting elements and mechanisms for removing gases and / or liquids.

State of the art

There are many systems on the market for cooling glassware belonging to the type in question. They usually have characteristics and features that significantly differ from the system described in this document, and it should be noted that the applicant has an application related to equipment for cooling glassware, which, although satisfactory in terms of solving the problems posed by its creation, but in certain respects can be improved. The objective of the present invention is to offer a new improved system for cooling glassware or other receivers corresponding to the prior art in the field of the task.

Specifically, the system includes a housing with a connecting fitting inside it connecting the electric valve to a hose through which gas from the cylinder enters the housing. The valve, in turn, is connected to a programmable digital or analogue electronic circuit associated with a flow regulator formed by a calibrated brass part, providing an accurate value of the gas flow. The regulator, in turn, is connected to the extension part and, through the inner sleeve, to the second extension part, at the end of which there is a nozzle spraying cold gas. Gas escapes through the openings in the nozzle and enters the glassware intended for cooling. Glassware should be placed above the nozzle, on the glass holder, created for this purpose in the housing.

Thus, one of the main drawbacks of this system is that since the glass must be placed above the nozzle and the gas is directed upwards, there is a risk of injury or injury to personnel, since liquid carbon dioxide is so cold that it could burn your hand if it comes into contact with skin or user’s face.

On the other hand, the outlet gas pressure can cause the receiver or glass to move.

In addition, another limitation of this type of system is that the glass can only be cooled from the inside, which means that the number of calories required to reach the desired temperature is greater than when the dishes are cooled both from the outside and from the inside, which is desirable to achieve savings in gas consumption.

Finally, the fact that the glass is placed upside down over the nozzle makes it impossible to cool the elements inside it, such as ice cubes, which, as is well known, can be stored longer without melting after carbon dioxide cooling. This fact is especially important in the hotel and restaurant business, for which this type of system is mainly intended.

On the other hand, although liquid carbon dioxide junction boxes on the market usually fulfill the function for which they are intended, nevertheless they can be improved in certain respects, especially with regard to the safety and sealing of the system.

Thus, the system itself and the gas junction box must be improved in many ways. An object of the present invention is to provide a practical and effective solution based on a new, appropriately improved cooling system to eliminate all the above-described inconveniences, and in this regard, no other inventions with similar technical, structural or layout characteristics are known.

Disclosure of invention

The present invention, which is an improved system for cooling glassware or other receivers, equipped with a junction box for removing liquid carbon dioxide, has novelty in its field of application, since its implementation more than meets the above requirements, differing in characteristics that allow them to be included in the formula inventions attached to the present description.

Specifically, as described in the patent referenced in the previous section (prior art), and indicated herein, the system is based on the use of liquid carbon dioxide sprayed from a nozzle into a glass or receiver in order to rapidly cool them to a very low temperature ( between -20 ° C and -30 ° C). Essential functional parts of this system are the fitting connecting the electric valve to the hose, through which gas enters the valve from an external carbon dioxide cylinder. This hose is equipped with a fitting that allows you to connect the hose to the cylinder and is equipped with a pressure control valve, purge valve and pressure gauge. In turn, the electric valve is connected to a programmable microprocessor, which allows you to adjust the pulses and pauses of the gas supply, and is also connected to a flow regulator, at least one extension part, on which the spray nozzle is located. The nozzle has openings through which gas escapes to cool the corresponding glass or receiver.

Based on this arrangement, the proposed device is characterized by a design feature, due to which, instead of having to place a shot glass above the nozzle, this shot glass - or receiver - can be placed under the nozzle to receive gas sprayed from above.

For this purpose, the device is arranged on a low, generally flat base, to which, preferably on one side, a hollow tubular element is attached. This element goes vertically and at a certain height bends at an angle of 180 °. Its far end is equipped with a reflector that is facing down at a certain distance from the base, and this distance is sufficient so that a glass or any other receiver of more or less normal sizes can be placed between the reflector and the base and placed under the reflector for cooling.

It should be noted here that there is an option for fitting the mechanism for adjusting this distance between the reflector and the base to ensure that the position of the receivers under the reflector is adjusted either by vertical displacement of the tubular element and, therefore, the reflector, for example, using a telescopic device, or by vertical displacement of the base on which is placed a receiver designed for cooling, for example, using a lifting platform.

Further, according to the invention, inside the reflector, which acts as a protective casing, the functional elements of the device are placed in the form of a connecting fitting connecting the electric valve to the hose through which the gas enters. This fitting is connected to the distal end of the tubular element, and the hose extender passes through the tubular element, leaving under the base, and goes to the gas bottle, while the electrical valve, microcontroller, regulator, extension cord and nozzle are appropriately connected to each other and face down and mounted under the reflector.

In addition, the installation of a second, reduced reflector containing a regulator, extension cord and nozzle is provided to form another, more adjacent shell, which is created around the upper edge of the glass or receiver intended for cooling, thereby promoting the circulation of gas entering the receiver. This second reflector is also designed to protect the electrical valve and microcontroller from direct contact with gas.

On the other hand, with regard to the functional elements of the system, it should be noted that the regulator, extension cord and nozzle have also undergone a number of improvements, which include, firstly, the installation of an insulated hose, specifically a teflon-coated hose, in order to ensure as low a loss as possible. To do this, Teflon covers the inside of the regulator and reaches the height of the spray nozzle or gas outlet diffuser.

In turn, the outlet of the extension cord at a location immediately behind this Teflon hose has a constriction that halves the diameter of the jet exiting this Teflon hose, causing the gas to flow under higher pressure. After this narrow part, the hose becomes wider and the gas dissipates at an angle of about 38 °, so that it expands faster and enters the nozzle outlet chamber having a more or less the same inner diameter.

In the gas atomizer nozzle, a series of regulatory obstacles are created in calibrated gas atomization holes that are distributed in three levels of six holes, as well as in the central hole, by creating stamped oblique parts in the inner wall to cause the gas to pass these obstacles, instead to flow directly through the central hole, so that gas can evenly exit through the holes.

This means that since gas escapes through all openings, it loses its output potential energy, which leads to a decrease in its pressure and prevents an impact into the glass with excessive force, which allows better use of cold. In addition, since the blow occurs with less force, the gas does not move the glass and does not overturn it; and since the pressure is less, more gas is collected inside the glass, which increases the cooling rate.

At the same time, when gas enters the internal reflector, which covers the nozzle, which works vertically, an aerodynamic force presses the gas against the walls of the glass, causing the gas to circulate towards the other end and move downward along the inner walls on both sides of the glass.

This means that the cold mass, or heat absorption, is distributed not only inside the glass, but on both sides, inside and outside, providing significant savings in liquid and cold, and, therefore, consumption, since the temperature of the glass reaches 20 or 30 degrees below zero with the cost of a small amount of gas, thereby reducing consumption by 20-30%.

It should also be noted that since the nozzle, as mentioned above, is placed above the glass, which remains in the vertical position, it is possible to cool other elements besides glassware and receivers, for example, ice cubes. Based on the described nozzle arrangement, inserting a filter tube or filter into it from above can make the gas flow more evenly, which means that it is sprayed with smaller drops, forming a colder fog, which reaches the glass in the form of wet snow.

This snow has the advantage of absorbing water in ice cubes, with the formation of some kind of artificial snow that covers them. This moisture absorbed from ice, dissipating naturally through evaporation, leaves no residue, forming a white haze that produces a particularly unexpected and relevant effect.

On the other hand, with respect to a junction box mounted in the system for removing liquid carbon dioxide, the device according to the invention is provided with a more or less long hose, depending on what is required in each particular case. At the ends of the hose there are rotating nuts for connecting a cylindrical junction box and a connecting fitting for the cooling system. It should be noted that this box is suitable not only for use with this system, but also suitable for any other cooling system.

It is important to note that the hose used to supply cryogenic gas from the cylinder to the cooling system is made in the form of a flexible sleeve formed by a steel mesh, worn on a smooth inner hose, preferably made of Teflon (polytetrafluoroethylene), very thin, fire-resistant, chemically inert and suitable for use in the food industry. Outside, a protective shell is provided, which is fastened with washers at least at two points, providing a permanent connection with the hose, with the formation of loops, one at each end of the hose, with the appropriate tensioning devices used to fix the connection of the cooling system to the cylinder, with the aim of prevent the undocking of these elements, which could lead to damage to the connection or make its useless.

In turn, the cylindrical junction box assembly is essentially formed by a central connecting element with a machined brass base and various holes for connecting and placing other connecting and protective elements making up this assembly.

A rupture plate and a sleeve are connected to the lower part of this connecting element to hold this plate during gas removal and any destruction of the plate.

On one side of the connecting element (on the side used to connect the cylinder, which is slightly wider than the others), there is a filter disk located directly at the center point where the liquid from the cylinder flows and used to filter out microparticles that could damage the electrical valves and cooling circuit. Behind this filter disk there is a nut for connecting to the cylinder, a connecting rod equipped with an inner insulated hose (preferably Teflon coated) and an O-ring for connecting the central body and the rod connected to the cylinder.

A pressure gauge of 100 bar is mounted on top of this connecting element;

the element can also be equipped with a pressure sensor or a computerized pressure indicator.

From the side opposite to the connection to the cylinder, the central connecting element has a double pin connector, which can be connected to the hose using a rotating connecting nut; such nuts are available at both ends of the hose. As already noted, inside this double pin connector there is a hose with an insulating Teflon coating.

In addition, located at right angles to the connecting elements of the cylinder and the hose, the central connecting element has a purge valve, which is essential for purging and relieving the pressure drop between the glass and cooler. A device based on the breakdown of a metal plate guarantees the sealing of the discharge valves of liquid carbon dioxide. The valve is connected to the central body by a double pin connector.

Finally, on the opposite side of the valve, there is a plug on the connecting element that closes the connection created for the input of a temperature sensor or a computerized temperature indicator.

Thus, the above-described improved system for cooling glassware or other receivers, equipped with a junction box for removing liquid carbon dioxide, is an innovative design with previously unknown structural and structural characteristics, which, together with its practicality, make it convincing enough to obtain an exclusive right, requested by this document.

A brief description of the graphic materials

To complete the description given in this document, and to provide a better understanding of the characteristics of the invention, this descriptive part is accompanied by a set of non-limiting the scope of the invention and constitute an integral part of the present document illustrations, which illustratively presented:

Figures 1 and 2 respectively represent a view of an exploded system and a partial sectional view of an example of using an improved cooling system for glassware or other receivers constituting the subject of the invention, with main parts and components included, as well as the layout and arrangement of these elements and parts.

Figures 3, 4 and 5 represent, respectively, a front view, a vertical section and a top view of the flow regulator.

6 is a partially cutaway perspective view of a flow regulator into which a Teflon-coated hose is inserted, and a configuration of a partial hose insert, including a portion of an extension.

7, 8, and 9 are, respectively, a front view, a vertical section, and a top view of an extension cord inserted into the spray assembly, and a narrowing of the diameter of the inner channel after the insulating hose.

10, 11 and 12 are, respectively, a front view, a vertical section and a top view of the nozzle; in FIG. you can see the structural elements of the nozzle to form obstacles in the outlet openings, as well as how they are inclined around its perimeter.

13 and 14 are a front view and a partial cross-sectional view of the assembly of the spray device assembly, showing the insert of an insulated hose and its outer Teflon-coated washer.

Fig. 15 is a perspective view of a junction box for removing liquid carbon dioxide, with enlarged part A, showing an inner hose with a steel mesh covering the tube that forms the conduit.

Fig.16 represents the individual parts of the node of the cylindrical junction box, the elements of this node, their layout and location.

17 and 18 are views in different partial sections of the assembly of the cylindrical junction box assembly, with all the elements included in the assembly connected together, showing their location with respect to the central connecting housing of the assembly.

Figures 19, 20 and 21 are, respectively, a front view, a vertical section and a horizontal section of a central connecting element, to which the remaining elements connecting the assembly of a cylindrical junction box are connected.

The implementation of the invention

A review of the drawings and the numbering used herein shows that they represent preferred uses of the invention, including the parts and elements described below.

Thus, as shown in FIGS. 1 and 2, the described cooling system (1) typically includes a connecting fitting (2) connecting the electric valve (3) to a pipe (4) conveniently connected at its opposite end to an external gas cylinder (not shown) for supplying carbon dioxide from the cylinder to the spray unit (5), to which this electric valve (3) is connected, equipped with a programmable microcontroller for adjusting pulses and gas supply pauses for cooling the glass (6) or the corresponding receiver. The spray unit (5) is formed by a flow regulator (7), an extension part (8) and a spray nozzle (9) with holes (10).

Since the characteristic element, the nozzle (9), is facing downward, the cooling gas leaving the holes (10) flows into the glass (6) or the receiver under the nozzle, for which the system (1) is composed of the lower base (11), which serves substantially a flat support to which a hollow tubular body (12) is attached, preferably one of its parts (12), which includes at least a vertical section (12a) of a certain height, bending at an angle of 180 ° along at least the other , curved section (12b) and equipped at the far end with the first reflex rum (13), which is facing down and located at a certain distance above the base (11). This is the distance of the size required to insert a glass (6) or other receiver of more or less normal sizes between the indicated reflector (13) and the base (11) for cooling.

As an option, a mechanism can be built in to adjust the distance between the first reflector (13) and the base (11) so that this distance can be adjusted to different sizes of glassware or receivers (6) or by vertical displacement of the tubular body (12) and, thereby, the reflector (13) using a telescopic mechanism, or by vertical displacement of the platform (On) of the base (11), on which a glass (6) or a receiver intended for cooling is placed, for example, using the plate lifting mechanism ormy.

Further, according to the invention, the interior of the reflector (13), which acts as a protective casing, contains the functional elements of the system, so that a connecting fitting (2) connecting the electric valve (3) to the pipeline (4), through which gas from the carbon dioxide cylinder is supplied , connected with the distal end of the tubular element (12), and the pipeline (4) passes inside this tubular element (12), leaving under the base (11) and going further to the balloon.

In turn, the electric valve (3) and the spray unit (5), which are facing down, are located under the reflector (13), covering the second reflector (14), which is smaller than the first reflector (13), includes only the spray unit (5 ) and is located around the upper edge of the glass (6) or the receiver intended for cooling. This second reflector (14) also protects the electric valve (3) and the microcontroller from direct contact with gas.

On the other hand, as shown in FIGS. 3-14, the spray assembly (5) formed by the flow regulator (7), the extension part (8) and the nozzle (9) is characterized in that it contains an insulated hose (15), specifically a hose coated to minimize cold loss or heat transfer with Teflon, which, as shown in FIGS. 6 and 14, covers the inside of the flow regulator (7) and the extension part (8) to the height of the spray nozzle (9) or outlet diffuser, and the outer - coated with teflon - washer (21).

Further, the outlet of the extension cord or nozzle (8) in the place immediately behind said Teflon hose (15) has a constriction (16), which reduces the inner diameter of the jet exiting this Teflon hose (15), halving it, causing gas to flow under the action higher pressure. After this narrowing (16), the conical expansion element (17) makes the hose wider and the gas is scattered at an angle of about 38 ° so that it expands faster and enters the outlet chamber of the nozzle (9), which has more or less the same inner diameter.

In turn, the holes (10) in the spray nozzle (9) and in the center are distributed in groups of six in two corner grooves (18) and on the upper conical surface (19) of the nozzle (9), so that these holes (10) pass obliquely through the walls of this nozzle (9) into the interior of the chamber. The lower walls of this chamber have several acute-angled steps (20) that form oblique obstacles so that upon exiting the flow regulator (7) the gas strikes into them and is evenly distributed over all openings (10).

In addition, in order to distribute the gas more evenly so that it leaves the nozzle holes (10) (9) in smaller droplets, forming a colder mist turning into wet snow, the inside of the nozzle chamber (9) is equipped with a filter (not shown) formed by sintered element or sintered part.

In turn, as shown in FIGS. 15-21, the junction box for removing liquid carbon dioxide includes, firstly, said conduit (4) and, secondly, a junction box (102) in which this conduit (4) has a variable length, in each particular case, and at one end there is a row of rotating nuts (103) for connecting the junction box (102) to the cylinder and to the connecting fitting (2) of the cooling system (1), thereby supplying liquid carbon dioxide from one element to another.

Fig. 15 represents this conduit (4), which consists of a flexible sleeve (104) formed by a reinforcing steel mesh (105) covering a smooth inner tube (106), preferably made of thin Teflon (polytetrafluoroethylene).

This sleeve (104) has an outside protective sheath (107), which is fastened at least at both ends by washers (108) so that the sheath remains connected to the hose, forming loops (109), one at each end of the hose, with appropriate tensioning devices (110) used to secure the hose to the cooling system and cylinder.

In turn, a junction box (102), which, as shown in FIGS. 16-21, is formed by a machined central connecting element (111) having several openings and compartments, as shown in FIGS. 19, 20 and 21, are specially designed for connecting and placing various connecting and protective elements, it forms a node comprising a lower compartment (111a) with four side openings (111b, 111b ') extending radially and an upper compartment (111c), the compartments being connected to each other in the center of the connecting element nta (111).

This connecting element (111) has a brass base and is externally nickel-plated to prevent rust.

The bursting plate (112) and the sleeve (113) for holding this plate are connected to the lower hole (111a) of this connecting element, working during the gas outlet and any destruction of the plate. This bursting plate (112) is specially designed and manufactured with a maximum burst pressure of 100 bar and includes a brass and copper ring and a microdiaphragm (112a) made of pure nickel.

In turn, the sleeve (113) for holding the bursting plate is specially designed so that it corresponds to the lower compartment (111a) of the connecting element (111) to prevent injuries to personnel by a gas stream, since holes (113a) are made in this compartment (111a).

In one of the side holes (111b ') of the connecting element (111), through which the nozzle (114) is connected to the carbon dioxide cylinder, this hole is slightly wider than the other side holes (111b), there is a filter disk (115) that acts as a screen directly in the fluid inlet center to filter out all microparticles that could damage the electrical valves and cooling circuit. Behind this filter disk (115) is a connecting rod (116), which connects the central element (111) to the nozzle (114) of the cylinder, and on this rod (116) has a nut (117) for fixing the connection of this rod (116) and the nozzle (114), with an O-ring (118) located between both of these elements.

Further, inside the connecting rod (116) there is a small insulated tube (119), which is preferably coated with Teflon to prevent cold loss.

At the top of the connecting element (111) there is a compartment (111c) used to connect a pressure gauge (120) per 100 bar. This compartment (111c) is also suitable for mounting a pressure sensor or a computerized pressure indicator.

A double pin connector (121) is connected to the other side hole (111b) of the connecting element (111), located on the side opposite to the connection to the cylinder, which is used to connect the pipe (4) by screwing the rotating nut (103) on it. An insulating tube (122) (preferably Teflon coated) is placed inside this connector (121).

A purge valve (123), the main part of which is a metal punch, is connected to the third side hole (111b) of the central connecting element (111), which is located orthogonally with respect to the connecting elements of the cylinder and the pipe, this valve provides sealing of the relief valves of liquid carbon dioxide. This valve (123) is connected to the connecting element (111) via a double pin connector (124).

Finally, in the connecting element (111), in the side hole (111b) located on the side opposite to the specified purge valve (123), there is a plug (125), which, together with the O-ring (126), closes this hole, forming a connection that is prepared for the insertion of a temperature sensor or computer temperature indicator.

Having described in sufficient detail the essence of the present invention and its implementation in practice, we do not consider it necessary to go into further details of its work, believing that the specialist will easily understand its scope and the advantages that it gives.

Similarly, it is understood that the system described as an example of the preferred use of the essential functions of the invention can be used for other purposes, differing in detail, since the above is presented only as an example, and these functions are also included in the claimed scope of protection of the invention, since its main The principle has not been modified or modified.

Claims (18)

1. An improved cooling system for glassware or other receivers equipped with a junction box for removing liquid carbon dioxide, made as a system based on the use of cryogenic liquid carbon dioxide, including a connecting fitting (2) connecting the electric valve (3) to the pipeline (4), connected to the carbon dioxide cylinder, and the spray unit (5), the electric valve (3) equipped with a programmable microcontroller, and the spray unit (5) includes a flow controller (7), an extension part (8) and a spray nozzle (9) with holes (10), while the junction box for removing carbon dioxide includes, in addition to the pipeline (4), a junction box (102) connected to the nozzle (114) of the carbon dioxide cylinder, a pipeline ( 4) has a variable length and includes rotating nuts (103) provided at its ends for connection to a junction box (102) and to a connecting fitting (2) of the cooling system (1), respectively, and a junction box (102) connected to the cylinder, equipped with pressure gauge (120) and valve purge (123), characterized in that it has a support base (11), to which a hollow tubular element (12) is attached, with the spray nozzle connected at its end facing down to supply gas to the glass (6) or the receiver placed under the nozzle, and the far end of the tubular element (12) is equipped with a first, downward-facing reflector (13), raised a certain distance above the base (11), which is sufficient so that a glass (6) or a receiver of normal sizes can be placed under reflector, and inside, under this reflex (13), which works as a protective casing, the functional elements of the system are placed in such a way that the connecting fitting (2) is connected at the far end of the tubular element (12) with a pipe (4) inside the reflector, and the downstream electric valve (3) and spray the assembly (5) is located under the reflector, and a second reflector (14) is provided with smaller dimensions than the dimensions of the first reflector (13), covering only the spraying assembly (5) and adjacent to the area around the upper edge of the glass (6) or the cooled receiver, this is electric rd valve (3) and a microcontroller reserved in the space between the two reflectors (13) and (14). 2. The system according to claim 1, characterized in that the tubular element (12) includes at least a vertical section (12a) and is bent at a certain height at an angle of 180 ° along at least another curved section (12b ) 3. The system according to claim 1 or 2, characterized in that it optionally has a built-in mechanism for adjusting the distance between the first reflector (13) and the base (11) by means of the vertical displacement of the tubular element (12) and the reflector (13), including, for example, telescopic mechanism. 4. The system according to claim 1 or 2, characterized in that it optionally has a built-in mechanism for adjusting the distance between the first reflector (13) and the base (11) by vertically displacing the platform (11a) of the base (11) on which the glass (6) is placed ) or a cooled receiver, the built-in mechanism including, for example, a platform lifting mechanism. 5. The system according to claim 1, characterized in that the spray unit (5), formed by a flow regulator (7), an extension part (8) and a nozzle (9), contains inside an insulated hose (15) that closes the flow regulator (7 ) and the extension part (8), reaching the height of the spray nozzle (9). 6. The system according to claim 5, characterized in that the insulated hose (15) inside the spray assembly (5) is a teflon-coated hose. 7. The system according to claim 5, characterized in that the outlet of the extension part (8) immediately behind the insulated hose (15) has a narrowing (16), which halves the diameter of the outlet stream of this hose (15) and which passes into a conical expansion element ( 17). 8. The system according to one of claims 1, 5-7, characterized in that the holes (10) in the spray nozzle (9) and in the center are distributed in groups of six in two corner grooves (18) and on the upper pyramidal surface (19) nozzles (9), and the holes (10) obliquely pass through the walls of the nozzle (9) into the interior of the chamber. 9. The system according to claim 8, characterized in that the inner walls of the inner part of the chamber of the spray nozzle (9) have several acute-angled steps (20) that form oblique obstacles for the gas exiting the flow regulator (7). 10. The system according to claim 9, characterized in that for a more uniform distribution of gas and for it to exit the nozzle (9) holes (9) in smaller droplets with the formation of colder fog turning into wet snow, the nozzle chamber (9) equipped with a filter formed by a sintered element or sintered part. 11. The system according to claim 1, characterized in that the pipeline (4) consists of a flexible sleeve (104) formed by a reinforcing steel mesh (105) covering a smooth inner hose (106), preferably made of a thin layer of Teflon, and a junction box (102) is formed by a machined central connecting element (111) with holes and compartments for connecting and placing various connecting and protective elements, and these holes and compartments include:
- the lower compartment (111a) for the bursting plate (112) and the sleeve (113) for fixing this plate, designed to remove gas and remove debris after a possible rupture of the plate,
- four radially extending lateral openings (111b, 111b '), one for the rod (116) and the nut (117) for connecting to the nozzle (114) of the gas bottle, the other for the double pin connector (121) with the pipeline (4), the third for the valve purge (123) and fourth for cork (125), and
- an upper compartment (111c) for connecting a pressure gauge (120), with all openings connected to each other in the center of the connecting element (111), a side opening (111b) with a plug (125) is provided for inputting a temperature sensor or a computerized temperature indicator, the upper compartment (111c) is designed to accommodate, instead of a manometer (120), a pressure sensor or a computerized pressure indicator, and in one of the side holes (111b) of the connecting element (111) there is a sintered disk (115) that works like a filter and is located directly in the central fluid inlet to filter out all microparticles that could damage the electrical valves and the cooling circuit. 12. The system according to claim 11, characterized in that the connecting element (111) has a brass base and is nickelized externally to prevent rust. 13. The system according to claim 11, characterized in that the sleeve (104) forming the pipeline (4) has a protective shell (107), which is attached externally and fixed at least at its ends with washers (108) so that the sheath remained connected to the hose and formed loops (109), one at each end of the hose, with corresponding tensioning devices (110) used to fix the cooling system and the cylinder. 14. The system according to claim 11, characterized in that the burst plate (112) is designed for a maximum burst pressure of 100 bar and includes a brass and copper ring and a microdiaphragm (112a) made of pure nickel, the holes (113a) of the mounting sleeve (113) exit into the lower compartment (111a) of the connecting element (111). 15. The system according to claim 11, characterized in that the sintered disk (115) or filter is located inside the side hole (111b ') in front of the rod (116) connecting the nozzle (114), and the hole (111b') is wider than the other side holes ( 111b) in the central connecting element (111). 16. The system according to claim 11, characterized in that between the rod (116) connecting the nozzle (114) and the nozzle (114) there is an O-ring (118), and inside the connecting rod (116) there is an insulated hose (119) preferably coated with teflon. 17. The system according to claim 11, characterized in that inside the double pin connector (121) with the pipeline (4) there is an insulated hose (122), preferably coated with Teflon. 18. The system according to claim 11, characterized in that the main part of the purge valve (123) is a sealing device with a metal punch, and the valve (123) is connected to the connecting element (111) through a double pin connector (124).

Images