WO2020250003A1 - System to realize an artificial snow fall, in particular for a snow cabin, and method to realize an artificial snow fall - Google Patents

Abstract

A system (1) to realize an artificial snow fall, in particular for a snow cabin (100), comprises a snow-making device (2) and a distribution device (3) configured to collect directly the artificial snow generated and to distribute it in an underlying falling area (4) according to a substantially vertical falling direction (C). The distribution device (3) comprises a perforated wall (5) having a first snow collection surface (7) and a second snow release surface (8), and a movement member connected to the perforated wall (5) for moving it according to a movement direction (M) substantially transversal to said falling direction (C) for realizing the snow fall. A further object of the present patent application is a method to realize an artificial snow fall, in particular for a snow cabin (100).

Description

“SYSTEM TO REALIZE AN ARTIFICIAL SNOW FALL, IN PARTICULAR FOR A SNOW CABIN, AND METHOD TO REALIZE AN ARTIFICIAL

SNOW FALL”

DESCRIPTION

Technical Field

The object of the present invention is a system to realize an artificial snow fall.

In particular, the invention relates to a snow cabin comprising a snow making device and a distribution device for the formation of snow directly inside the cabin.

The invention further relates to a method to realize an artificial snow fall.

_{* * * * *}

Prior Art

Currently, within the context of indoor snow, it is known to use special snow-making systems for realizing artificial snowfall in a closed environment or in a specific limited area of interest.

Such snow-making systems can be used in environments with a large surface area for the preparation and fitting out of downhill slopes for skiers and snowboarders, or in rooms with more contained dimensions for therapeutic purposes, such as snow cabins in wellness centres in which a typically winter climate is recreated to offer guests a shiver of revitalizing cold after sauna heat treatments.

In relation to the latter use, an example of the snow-making systems used is provided in document WO2015/097592 filed in the name of the same Applicant.

Generally, traditional snow cabins are defined by a room inside which the snowfall is recreated artificially, generated by a relevant snow-making device arranged on the top of the room and generally comprising nozzles for the generation and throwing of artificial snow.

However, the snow-making systems present to date on the market must be activated with prior warning so as to be able to form a minimum accumulation of snow with which they can simulate the falling of snow flakes. In other words, at the time of their effective use by an operator, current snow-making systems must have already produced a minimum amount of snow accumulated on a support, so that a scraper device can be positioned in contact and perform scraping such as to produce the generation of snow flakes that are free to fall.

This implies larger energy consumptions for the activation of systems for longer than the effective use thereof.

Furthermore, such systems require the scraper device to comprise a complex and movable structure able to adapt its distance from the lot of snow accumulated in an optimal way for generating snow flakes.

Additionally, such systems sometimes envisage that the snowfall takes place starting from snow already compacted in the accumulation phase and that could be partially frozen (and therefore the particles that compose the snow fall are a set of “slivers” and not actually flakes). This leads to a drop in the quality of the snow that is generated below for the fall.

Object of the invention

In this context, the technical task underpinning the present invention is to propose a system for realizing an artificial snow fall, in particular for a snow cabin, which obviates the drawbacks of the prior art cited above.

In particular, an aim of the present invention is that of providing a system for realizing an artificial snow fall with higher quality with respect to the prior art.

Another aim of the present invention is that of providing a system for realizing an artificial snow fall in which the snow produced by the snow making device is directly conveyed towards the distribution device, which is in turn configured to immediately perform the distribution for falling.

The stated technical task and specified objects are substantially achieved by a system to realize an artificial snow fall which comprises the technical features disclosed in the independent claim. The dependent claims correspond to further advantageous aspects of the invention.

It should be highlighted that this summary introduces, in simplified form, a selection of concepts which will be further elaborated in the detailed description given below.

The invention relates to a system to realize an artificial snow fall, in particular for a snow cabin. The system comprises a snow-making device, which is configured to generate artificial snow, and a distribution device associated with the snow-making device and configured to directly collect the artificial snow generated for distributing it according to a substantially vertical falling direction in a snow fall area, at least mainly below the distribution device.

In particular, the distribution device comprises a perforated wall that extends at least along a longitudinal direction transversal to the falling direction and having a first snow collection surface and a second snow release surface, the latter opposite the first surface and at least partially facing towards the falling area.

The distribution device further comprises a movement member connected to the perforated wall and configured to move it according to a movement direction substantially transversal to the falling direction at least at a part of the perforated wall in which the snow crosses from the first to the second surface to realize the fall.

The invention further relates to a snow cabin comprising a plurality of side walls and a ceiling, which delimit a compartment that defines a room that can be crossed by a user, and a system for realizing an artificial snow fall described previously. In particular, the compartment is divided into an upper volume and a lower volume according to a snow fall direction. In particular, the snow-making device is arranged at least partially at the upper volume, while the distribution device divides the upper volume from the lower volume in which the snow fall area is comprised. Finally, the invention also has a method for realizing an artificial snow fall, in particular inside a snow cabin, comprising the operating steps of:

providing a system to realize an artificial snow fall previously described;

- generating artificial snow through the snow-making device;

collecting the snow produced artificially directly on the perforated wall of the distribution device;

moving the perforated wall so as to distribute the snow in a falling area, at least mainly below the distribution device, according to a substantially vertical falling direction.

Brief description of the drawings

Further characteristics and advantages of the present invention will become more apparent from the approximate and thus non-limiting description of a preferred, but not exclusive, embodiment of a system to realize an artificial snow fall, in particular for a snow cabin, as illustrated in the appended drawings, wherein:

- figure 1 illustrates a perspective view of a snow cabin in which a system is installed for realizing an artificial snow fall;

- figure 2 illustrates a front schematic view of a section according to a vertical plane of the cabin illustrated in Figure 1 ;

- figure 3 illustrates a perspective view of a first embodiment of the system for realizing an artificial snow fall;

- figure 4 illustrates a perspective view of a different aspect of the distribution device illustrated in figure 3;

- figure 5 illustrates a schematic view of a section according to a transverse plane of the distribution device illustrated in Figure 4;

- figure 6 illustrates a perspective view of a second embodiment of the system for realizing an artificial snow fall;

- figure 7 illustrates a perspective view of a different aspect of the distribution device illustrated in figure 6;

- figure 8 illustrates a perspective view of a section according to a transversal plane of the distribution device illustrated in Figure 7.

With reference to the drawings, they serve solely to illustrate embodiments of the invention with the aim of better clarifying, in combination with the description, the inventive principles at the basis of the invention.

Detailed description of preferred embodiments of the invention

The present invention relates to a system to realize an artificial snow fall, in particular for a snow cabin.

With reference to the figures, the system to realize an artificial snow fall has been generically indicated by the number 1 , while a snow cabin has been generically indicated by the number 100.

The other numerical references refer to technical features of the invention which, barring indications otherwise or evident structural incompatibilities, the person skilled in the art will know how to apply to all the variant embodiments described.

Any modifications or variants which, in the light of the description, are evident to the person skilled in the art, must be considered to fall within the scope of protection established by the present invention, according to considerations of technical equivalence.

Figure 1 and figure 2 illustrate a snow cabin 100 in which a system 1 is installed for realizing an artificial snow fall.

The system 1 comprises a snow-making device 2 configured to generate artificial snow and comprising a ventilation member 21 configured to generate an air flow F, a cooling member 22 associated with the ventilation member 21 and configured to cool the air flow F to temperatures less than 4°C, a nebulizer member 23 configured to dispense a nebulized jet of pressurized water into the flow of air F to trigger the formation of snow within such flow F, and a pipe 24 configured to convey the air flow F and the nebulized water jet G along an emission direction E.

In addition, the system 1 comprises a distribution device 3 associated with the snow-making device 2 and configured to collect directly the artificial snow generated and to distribute it in a falling area 4, which is at least mainly below the distribution device 3. In fact, the snow fall from the distribution device 3 preferably takes place by gravity according to a substantially vertical falling direction C.

Advantageously, the distribution device 3 comprises a wall 5 perforated by a plurality of through holes 6 (having, by way of example, a diameter of about 3 mm), which extends along a longitudinal direction L transversal to the falling direction C of the snow. Specifically, the perforated wall 5 has a first snow collection surface 7 and a second snow release surface 8, the latter opposite the first surface 7 and facing at least partially towards the falling zone 4. In other words, therefore, the plurality of holes 6 allows the passage of snow through the perforated wall 5 from the first surface 7 towards the second surface 8 and therefore towards the falling area 4. The distribution device 3 further comprises a movement member (not illustrated) connected to the perforated wall 5 on which the snow is directly deposited. In particular, the movement member is configured to move the perforated wall 5 according to a movement direction M substantially transversal to the falling direction C at least at a first part of the perforated wall 5 in which the snow crosses from the first surface 7 to the second surface 8 to realize the fall.

More precisely, the movement member is configured to make the perforated wall 5 perform a cyclic movement over time. Even more precisely, the movement member moves the perforated wall 5 according to a trajectory that cyclically passes through the same points, describing at regular time intervals the same movement path.

According to a first embodiment of the invention illustrated in figures 3, 4, 5, the perforated wall 5 is folded onto itself about an extension axis A thereof parallel to the longitudinal direction L, so as to form a laterally open cylindrical wall. In other words, the perforated wall 5 defines the side wall of a cylinder in which the circular sides which would define the base and top are missing (in the event in which the cylinder extends vertically). According to such embodiment, the first surface 7 and the second surface 8 define, respectively, an inner cylindrical surface and an outer cylindrical surface.

According to an aspect of the invention, the snow-making device 2 is configured to generate artificial snow directly inside a collection volume defined and delimited by the perforated wall 5 folded onto itself about the extension axis A.

Preferably the extension axis A is substantially horizontal. Even more preferably, the extension axis A extends parallel and consecutive to the emission direction E, as better illustrated below.

According to an aspect of the invention, the movement member is configured to place in rotation the perforated wall 5 about the extension axis A.

Figures 6, 7, 8 illustrate a second embodiment of the invention, alternative to the previous one, wherein the perforated wall 5 has a planar surface extension, preferably parallel to the ground.

According to an aspect of the invention, the movement member is configured to impart onto the perforated wall 5 an alternative linear motion along the movement direction M.

Preferably, the movement direction M is parallel to the surface extension of the perforated wall. Even more preferably, the movement direction is transverse to the longitudinal extension direction L of the perforated wall 5. According to an aspect of the invention visible in figures 4, 5, 7, 8, the system 1 comprises a spatula element 10 associated with the first surface 7 to assist with the distribution of the snow collected through the perforated wall 5 for realizing the fall towards the falling area 4.

According to another aspect of the invention, the spatula element 10 is constrained to a support structure of the system 1 with respect to which the perforated wall 5 moves.

In other words, regardless of whether the perforated wall 5 has a planar or cylindrical conformation, the spatula element 10 is arranged in contact with the first surface 7 in a fixed position so that the induced movement on the perforated wall 5 determines the distribution of snow deposited through the plurality of holes 6 and therefore of the fall towards the falling area 4. According to an aspect of the invention, the spatula element 10 comprises a slat 1 1 having a scraping edge 12 that extends in contact with the first surface 7 of the perforated wall 5 to assist the distribution of the snow collected through the plurality of holes 6.

Preferably, the slat 11 is inclined with respect to an orthogonal plane to a tangent plane to the contact point between the slat 11 and the perforated wall 5. More precisely, the slat 11 is inclined with respect to a vertical direction, as can be seen better in figures 5 and 8.

Alternatively, the slat 1 1 is configured to slightly vary its inclination (by a variable angle between 5° and 15°) with respect to its own balance position for adapting to the movement of the perforated wall 5 actuated by the movement member.

According to an aspect of the invention, each hole 6 of the perforated wall 5 has a raised projecting edge with respect to the first surface 7 to increase the scraping effect of the perforated wall 5 on the snow accumulated on the same first surface 7 during the movement performed by the movement member. In this way, during the movement of the perforated wall 5, the snow collected on the first surface 7 is more easily broken up and moved to be conveyed through the holes and then distributed towards the falling zone 4.

Preferably, the plurality of holes 6 is equally distributed on the surface extension of the perforated wall 5 so that the distribution of the snow from the first surface 7 to the second surface 8 takes place in the most uniform way possible. For example, the perforated wall 5 can comprise a net or a thin sheet (with a thickness of about 1.5 mm) and uniformly riddled with holes along its surface extension and can be made of a metal or plastic material.

According to an aspect of the invention illustrated in figures 4, 5, 7, 8 the system 1 comprises at least one brush 13 arranged in contact with the first surface 7 or the second surface 8 of the perforated wall 5. Preferably, the brush 13 is arranged in a position distanced from the perforated wall 5 in which the snow crosses from the first surface 7 to the second surface 8 for falling. In fact, given the low temperatures during which the system 1 is usually operated, it is possible for the snow to get packed inside a hole obstructing it and therefore not allowing the passage of any more snow towards the falling area 4. Advantageously, the use of at least one brush

13 allows the perforated wall 5 to be cleaned during the same movement of the latter actuated by the movement member.

Preferably, the brush 13 is constrained to a support structure of the system 1 with respect to which the perforated wall 5 moves. In other words, therefore, the brush is maintained in a fixed position thereof during the movement of the perforated wall 5 so that it is the movement of the latter that induces the rubbing action of the brush 13 on the first surface 7 or on the second surface 8 for determining the cleaning of the plurality of holes 6 from the blocking of frozen snow.

According to another aspect of the invention, the brush 13 comprises a support rod 14 and bristles 15 connected to the support rod 14. In detail, the support rod 14, which is constrained to the support structure, extends parallel to the longitudinal direction L and to the perforated wall 5.

Preferably, the bristles 15 are rotatably connected about the support rod

14 in contact with the respective surface of the perforated wall 5 (preferably the first surface 7 if the perforated wall 5 is a cylindrical wall, whereas the second surface 8 is preferred if the perforated wall 5 is planar, as can be seen in Figure 8).

According to an aspect of the invention, the system 1 comprises two brushes 13, each arranged in contact with a respective surface 7, 8 of the perforated wall 5 for performing the cleaning of the same perforated wall 5 during the movement actuated by the movement member.

According to another aspect of the invention, the two brushes 13 are arranged on opposite sides with respect to an orthogonal plane to the perforated wall 5. More precisely, as can be seen in figure 5, in the case in which there are two brushes 13 arranged in contact with a respective surface different from the other, they are not arranged facing each other considering the perforated wall 5 as a dividing plane. Therefore, more precisely, between the brushes 13 an orthogonal plane to the perforated wall 5 is interposed. Advantageously, the brushes 13 thus arranged act consecutively on a same portion of the perforated wall 5 to perform improved cleaning and removal of the plurality of holes 6. More precisely, the brushes 13 act on the same plurality of through holes 6, but each on a different surface. Furthermore, the brushes 13, being constrained to the support structure of the system 1 , are not movable, but act consecutively on one another as a consequence of the movement of the perforated wall 5 along a specific orientation of the movement direction M.

According to an alternative aspect of the invention not illustrated, the brushes 13 are arranged aligned but opposite with respect to the perforated wall 5.

A preferred embodiment of the invention, illustrated in figures 1 and 2, envisages that the system described above is installed in a snow cabin 100, for generating inside the latter a snow fall such as to recreate the typically winter climate and thus offer the user a shiver of revitalizing cold after heat treatments such as, for example, a sauna.

The snow cabin 100 comprises a plurality of side walls 101 and a ceiling 102 delimited by a compartment 103, that defines a room that can be crossed by a user. The compartment 103 of the room, according to a falling direction C, is divided between an upper volume W and a lower volume V. In particular, the snow-making device 2 is arranged at least partially at the upper volume W and the distribution device 3 divides the upper volume W from the lower volume V in which the snow fall area 4 is comprised.

More precisely, the pipe 24 of the snow-making device 2 extends between an inlet opening 25 thereof and an outlet opening 26 thereof arranged in flow communication with the compartment 103, and specifically with the upper volume W of the compartment 103.

The inlet opening 25 of the pipe 24 is, instead, arranged in flow communication with the lower volume V of the compartment 103 for sucking the air inside the room and conveying it towards the outlet opening 26. The moisture of the air in the lower volume V of the room tends to increase because of the melting of the snow and the presence of any users. Therefore, advantageously, the pipe is able to collect such moist air and convey it through the cooling member 22 to reduce the temperature thereof again before re-introducing it into the upper volume W with the water jet G added, useful for the formation of snow.

According to an aspect of the invention visible in figure 2, the system 1 comprises a siphon 27 interposed along the pipe 24 in proximity to the inlet opening 25 to block the channelling along the pipe 24 of any amount of snow sucked by the compartment 103.

According to another aspect of the invention, along the pipe 24, downstream of the siphon 27, the ventilation member 21 , the cooling member 22 and the nebulizing member 23 are arranged.

The ventilation member 21 , generally an impeller or a turbine, is configured to generate the air flow F sucked by the inlet opening 25 and conveyed towards the outlet opening 26. The air flow F is conveyed through the cooling member 22 and the nebulizing member 23.

The cooling member 22, preferably a heat exchanger, is configured to lower the air temperature to values less than 0°C, preferably less than - 5°C.

The nebulizing member 23 is preferably arranged at the outlet opening 26. More precisely, the nebulizing member 23 comprises a nucleator element, preferably a nozzle, configured to emit along the emission direction E a water jet G combined with compressed air. The emission with volumetric expansion of the compressed air and water jet G causes rapid lowering of the temperature of the water particles, which freeze immediately being conveyed into the air flow F at a temperature less than 0°C. Advantageously, the snow or sleet formed is conveyed towards the distribution device 3 to be collected and distributed into the compartment 103.

According to an aspect of the invention, the movement member comprises an electric transmission motor configured to move the perforated wall 5 along the movement dimension M. If the perforated wall 5 is conformed like a cylindrical wall, the rotation frequency imposed is generally, by way of example, about 10 rpm. Otherwise, if the perforated wall 5 is planar, the average movement speed is about 2 metres per minute.

According to a further aspect of the invention, regardless of whether the perforated wall 5 is planar or folded onto itself in a cylindrical form, the system 1 comprises a pair of idle support rollers (not illustrated), which are arranged in contact with the second surface 8 of the perforated wall 5. Preferably, the support rollers extend along a respective axis of rotation parallel to the longitudinal direction L. In particular, the rollers are configured to rotate in an idle way about the respective axis of rotation during the movement of the perforated wall 5 actuated by the movement member. In other words, the rollers support the perforated wall 5 and, because of the movement of the latter, they are also able to rotate to reduce friction with the second surface 8.

According to an aspect of the invention, in the event in which the perforated wall 5 is folded onto itself, the rollers are arranged parallel to one another at a shorter distance than a diameter of the cylindrical wall 5. Preferably and by way of example, according to this embodiment, the perforated wall 5 has a diameter of about 700 mm. The rollers, being positioned in contact with the second surface 8 at a distance less than 700 mm (and therefore being positioned below the perforated wall 5), are able to support the perforated wall 5 and allow the movement thereof thanks to their idle rotation.

Merely by way of example, the perforated wall 5 has a variable longitudinal extension between 1.5 m and 2 m (and a transversal width of about 2 m if planar).

Advantageously, the system 1 comprises support flanges (not illustrated) configured to strengthen the structure of the perforated wall 5. The support flanges are connected to the second surface 8 and extend transversally to the longitudinal direction L for at least part of the transversal extension of the perforated wall 5, with a curved progression if the latter is folded onto itself.

According to a further aspect of the invention, the perforated wall 5 may have a greater longitudinal extension than the values previously introduced. In that case, the system 1 envisages providing two snow making devices 2 opposite each other and associated with the same distribution device 3 interposed between each other. In this way each snow-making device 2 is configured to produce snow to be distributed across about half of the perforated wall 5.

With regard to an operating example of the system 1 to realize an artificial snow fall, it derives directly from what is described above and which is referred to below.

After preparing the system 1 previously described, the snow-making device 2 is activated to generate artificial snow to be conveyed towards the distribution device 3 for subsequently performing the distribution in a predefined area such as, for example, inside a snow cabin 100.

Therefore, more precisely, inside the pipe 24 the ventilation member 21 generates an air flow F that is subsequently cooled by the cooling member 22 and a pressurized water jet G is added through the nebulizing member 23. The emission of the water jet G into the air flow F having a temperature less than 0°C produces artificial snow pushed along the emission direction E towards the distribution device 3.

The perforated wall 5 of the distribution device 3 directly collects the artificial snow produced on the first surface 7 thereof.

The activation of the distribution device 3 implies the movement thereof along a movement direction M (circular or linear alternating in two orientations as a function of the conformation of the perforated wall 5) to shift the deposited snow, preventing it from solidifying and allowing it to pass along the falling direction C through a plurality of holes 6 from the first surface 7 towards the second surface 8 and therefore into the falling area 4.

Advantageously, the system 1 allows the snow-making device 2 and the distribution device 3 to be activated simultaneously; to obtain the distribution by falling, it is not necessary to wait for an accumulation of snow to be formed on the perforated wall 5.

Claims

1. A system (1 ) to realize an artificial snow fall, in particular for a snow cabin, comprising:

a snow-making device (2) configured to generate artificial snow; a distribution device (3) associated with said snow-making device (2) and configured to directly collect the artificial snow generated and to distribute the snow in a snow falling area (4), at least mainly below the distribution device, according to a substantially vertical falling direction (C), characterized in that said distribution device (3) comprises:

a perforated wall (5) extending at least along a longitudinal direction (L) transversal to said falling direction (C); said perforated wall (5) having a first snow collection surface (7) and a second snow release surface (8) opposite said first surface (7) and at least partially facing towards said falling area;

a movement member connected to said perforated wall (5) onto which the snow is directly deposited and configured to move said perforated wall (5) according to a movement direction (M) substantially transversal to said falling direction (C) at least at a first part of the perforated wall (5) in which the snow crosses from the first surface (7) to the second surface (8) to realize the fall.

2. The system (1 ) according to claim 1 , wherein said perforated wall is folded onto itself about an extension axis (A) parallel to said longitudinal direction (L) so as to form a cylindrical wall; said first surface and said second surface respectively defining a cylindrical inner surface and a cylindrical outer surface.

3. The system (1 ) according to claim 2, wherein said snow-making device is configured to generate snow artificially within a collection volume defined and delimited by the perforated wall folded about said extension axis (A).

4. The system (1 ) according to claim 2 or 3, wherein said movement member is configured to place in rotation said perforated wall about said extension axis (A).

5. The system (1 ) according to any one of claims 2 to 4, wherein said extension axis (A) is substantially horizontal.

6. The system (1 ) according to claim 1 , wherein said perforated wall has a planar surface extension, preferably parallel to the ground.

7. The system (1 ) according to claim 6, wherein said movement member is configured to impart on said perforated wall an alternative linear motion along said movement direction (M).

8. The system (1 ) according to claim 6 or 7, wherein said movement direction (M) is parallel to the surface extension of said perforated wall.

9. The system (1 ) according to any one of the preceding claims, comprising a spatula element associated with said first surface to assist the distribution of the snow collected through said perforated wall.

10. The system (1 ) according to claim 9, wherein said spatula element is fixed with respect to a support structure of the system with respect to which the perforated wall is movable.

11. The system (1 ) according to claim 9 or 10, wherein said spatula element comprises a slat having a scraping edge extending in contact with said first surface of said perforated wall to assist the distribution of the snow collected through said perforated wall.

12. The system (1 ) according to claim 1 1 , wherein said slat is inclined with respect to a vertical direction.

13. The system (1 ) according to any one of the preceding claims, wherein each hole of said perforated wall has a raised edge projecting with respect to said first surface for increasing the scraping effect of the perforated wall on the snow accumulated on the first surface during the movement of the perforated wall itself.

14. The system (1 ) according to any one of the preceding claims comprising at least a brush in contact with said first surface or said second surface of said perforated wall in a distanced position from the part of said perforated wall in which the snow passes from the first to the second surface; said brush being configured to perform the cleaning of said perforated wall during the movement actuated by said movement member.

15. The system (1 ) according to claim 14, wherein said at least one brush comprises a support rod and bristles connected to said support rod; said support rod extending parallel to said longitudinal direction (L) and to said perforated wall.

16. The system (1 ) according to claim 15, wherein said bristles are rotatably connected about said support rod and in contact with the respective surface of said perforated wall.

17. The system (1 ) according to any one of claims 14 to 16, comprising two brushes each in contact with a respective surface of said perforated wall to perform the cleaning of said perforated wall during the movement actuated by said movement member.

18. The system (1 ) according to claim 17, wherein said two brushes are arranged on opposite sides with respect to an orthogonal plane to the perforated wall positioned between them.

19. The system (1 ) according to any one of the preceding claims, comprising support flanges connected to said second surface and extending transversally to said longitudinal direction (L) for at least part of the transversal extension of said perforated wall.

20. The system (1 ) according to any one of the preceding claims, wherein said movement member comprises an electric transmission motor.

21. The system (1 ) according to any one of the preceding claims, comprising a pair of idle support rollers in contact with said second surface of said perforated wall for supporting it.

22. The system (1 ) according to claim 21 , wherein said support rollers extend along a respective axis of rotation parallel to said longitudinal direction (L); said rollers being configured to rotate about the respective axis of rotation during the movement of said perforated wall actuated by said movement member.

23. The system (1 ) according to claim 22, when dependent on any claim from 2 to 4, wherein said rollers are arranged parallel to each other at a shorter distance than a diameter of said cylindrical wall defined by said folded perforated wall.

24. A snow cabin () comprising:

a plurality of side walls () and a ceiling () delimited by a compartment () that defines a room that can be crossed by a user;

a system (1 ) for realizing an artificial snow fall according to any claim from 1 to 23,

characterized in that said compartment is divided between an upper volume and a lower volume according to said snow fall direction; said snow-making device being arranged at least in part at said upper volume and said distribution device dividing said upper volume from said lower volume in which said snow fall area is comprised.

25. Method for realizing an artificial snow fall, in particular inside a snow cabin, comprising the operating steps of:

providing a system (1 ) for realizing an artificial snow fall according to any claim from 1 to 23;

generating snow artificially through said snow-making device;

- collecting the snow produced artificially directly on said perforated wall of said distribution device;

moving said perforated wall so as to distribute the snow in a falling area (), at least mainly below the distribution device, according to a substantially vertical falling direction (C).

26. The method according to claim 25, wherein said step of generating snow artificially and said step of moving said perforated wall are actuated simultaneously.