FR2914989A1 - SNOW PLANT AND STACK FOR SUCH INSTALLATION. - Google Patents

Abstract

This snowmaking installation is of the type comprising at least one snow cannon (6) connected to a water and air supply network, associated with a housing (3) buried above a portion (7, 7). ') of said supply network, which housing (3) comprises - an upper part (15) provided with a manhole (16) closable by a cover (17), - a side wall belt (14), and - a lower part (18). The housing (3) defines an internal volume (12) which integrates a distributor (9) for controlling the supply of water and air of said associated snow gun (6); this housing (3) also comprises at least one passage (20, 21) for the entry of the water and air ducts (8, 8 ') which supply said distributor (9) and for the outlet of the pipes (11). , 11 ') of water and air from said distributor (9) and feeding said snow gun (6) .Conforming the invention, the distributor (9) is placed in the internal volume (12) of the cubicle (3), this at a depth such that an operator (13) can have access to a pose, maintenance or control, without his body being completely confined within said internal volume (12) said housing (3), the latter further comprising means for maintaining the non-freezing of said dispensing member (9). Preferably, the internal volume of the housing has a maximum depth (h) of 80 cm.

Description

The present invention relates to the general field of installations

  artificial snowmaking; it relates more particularly to an improvement made to the structure of the shelter or the buried box in which is integrated the equipment that allows the control of the supply of water, and possibly air, the associated snow cannon or. Snowmaking facilities generally include several snow cannons located along the ski slope at enneiger, which make artificial snow by spraying an air / water mixture in the form of low ambient air fog. temperature.

  The water and air supply pipes are buried along the ski slope and they are connected to each of the guns by means of control equipment which generally comprises a distributor member (bi-fluid or mono valve) -fluid) regulating the water and air supply of the associated snow gun. In the case of an automatic system, electrical and electronic means control this distributor. The control equipment in question is generally installed in a box or a buried shelter, described for example in the document FR-2 667 681. The corresponding shelter includes support means for the distributor and for the housing which encloses its control means .

  In order to preserve the material from frost and humidity, these shelters generally have a depth of between 1.2 m and 3 m, relative to the surrounding soil surface. To ensure maintenance or control of the integrated equipment, the operators must penetrate entirely into the shelter, through a manhole in the upper part, and descend to the bottom.

  However, this intervention is not without risk for the operator: the confinement in a space where the electricity mixes with the water and where the pressures of water and possibly of air are important is particularly dangerous, in particular in case of mishandling; the particularly humid environment can also be at the origin of falls of the operator likely to lose his supports.

  In addition, the corresponding interventions are not easy to achieve in a small space and where the movements are hindered. In addition, the costs associated with the installation of such shelters are important, particularly because of the depth of digging required and relatively heavy means to implement to ensure their stabilization on the site.

  A first object of the present invention is to improve the safety of operators in the context of their operations of implementation, maintenance and / or control of the distributor member. Another goal is to limit the cost of this type of installation, and in particular the costs associated with its implementation. For this, the present invention proposes - to report the fluid dispenser in their receiving cubicle (or shelter), this to a depth such that an operator can have access to it for a procedure of installation, maintenance or repair. control, without his body being completely confined within said box, and - to equip this box of means to ensure the maintenance frost free of this distributor, that in light of cold conditions assumed most unfavorable, in temperature and duration.

  According to a particularly interesting embodiment, the internal volume of the box has a maximum depth of 80 cm. This particular structure of snowmaking facility gives operators the opportunity to intervene within the manhole of the cubicle, on the distributor and possibly on its electrical and electronic control devices, or by being positioned outside. of said box, for example elongate on the side, or almost only with the legs and the arms integrated in said box, the operator then being seated on the upper edge of the latter and / or with the feet resting on its bottom. This results in ease of handling and a risk of accident significantly lower. In addition, such an installation can be set up very easily and very quickly, without requiring extensive digging. In addition, the dispenser has the ability to operate properly over time, without risk of degradation or frost-related malfunction, despite its relatively high position relative to the ground surface. Preferably, the upper part of the box comes flush with the ground or practically flush with the ground. According to an advantageous characteristic, the housing consists of a peripheral wall provided with a coating of material (x) insulating (s) thermal (s), the upper edge defines a manhole closable by a cover also provided with a coating of thermally insulating material (s).

  Advantageously, the peripheral wall of the housing is constituted by a plastic shell equipped with an insulating coating, which peripheral wall is associated with an articulated cover, comprising a surface wall made of metal or plastic material, equipped with a interior lining of thermal insulating material.

  To ensure the frost-free maintenance of the dispenser, the box may include heating means, for example of the type of heating cartridges, heating cords or radiators. Preferably, in particular to limit the additional costs, these heating means consist of a heat pipe type system having a generally elongated shape, positioned vertically with one of its ends integrated into the ground, and with its other end opening in the internal volume of the box, close to the dispenser, and preferably in physical contact with the dispenser or with the support thereof. Still to preserve this maintenance frost, in replacement or in combination with the aforementioned heating means, the lower portion of the housing is advantageously adapted so that the geothermal flow from the ground penetrates into its internal volume. In this case, the lower part of the box may be constituted by the soil or by an embankment reported. Alternatively, this lower portion of housing has a bottom wall permeable to heat flows, for example in the form of grating or geotextile type BIDIM (trademark).

  According to another feature, in particular to ensure its stability, and also to facilitate the standardization of some of the constituent elements of the installation, the housing includes means for its attachment to the base structure of the associated snow gun, said base being buried. Then, the base structure of the snow gun advantageously comprises a cantilever element, forming a support for the dispenser, said support member being placed within the internal volume of the housing, via an opening arranged in the latter. According to yet another particularity, the base structure of the barrel is in the form of a hollow column delimiting an axial central housing which is intended to receive, over at least part of its height, a portion of the water pipes, and where appropriate air, which feed the associated snow gun; this column of the base structure and the associated box have openings facing which allow the exit of the water pipes and possibly air leaving the distributor and extending to the snow cannon.

  According to yet another characteristic, the base structure of the barrel is provided, at its lower end, with several radiant panels, extending substantially in the same horizontal plane, to optimize its attachment and its retention in the ground. The invention will be further illustrated, without being limited by the following description, associated with the accompanying drawings in which: - Figure 1 is a schematic sectional view illustrating a snowmaking installation according to the present invention; FIG. 2 is a partial perspective view of a possible embodiment of a snowmaking installation according to the invention; - Figure 3 is a general perspective view of a housing of Figure 2, isolated from the rest of the snowmaking facility; FIG. 4 is a general and perspective view of a base structure of the snowmaking installation of FIG. 2, isolated from the rest of the installation and represented in its configuration of implantation in a dig (FIG. that is to say with its radiant panels in deployed configuration); - Figure 5 is a perspective view of the base structure of Figure 4, shown in folded configuration adapted for its transport; FIG. 6 is a perspective view of the base structure of FIG. 4, in its configuration configuration, connected to the water and air inlet ducts; - Figure 7 is a general perspective view of the base structure of Figure 6, on which is properly reported the housing of Figure 3; FIG. 8 is a perspective view of the snowmaking installation once the box has been placed on the base and the excavation is completely backfilled; - Figures 9 and 10 illustrate in two stages the fixing of the box on the base of the associated snow gun. FIG. 1 illustrates a snowmaking installation 1 according to the invention, implanted at the level of a dig 2 excavated beforehand in the ground. This installation consists mainly of a housing 3 secured by connecting means 4 with a structure 5 constituting the base of a snow gun 6. The housing 3 and the base structure 4 of the snow gun 6 are both arranged 2. A complete installation comprises a plurality of snow cannons 6 each associated with a small box 3, distributed along the runway to snow.

  The various guns 6 of the track are supplied with water and air from general pipes 7, 7 'buried in the ground. From these general lines, so-called secondary pipes 8, 8 'extend to a distributor member 9 (of the bi-fluid valve type), controlled by electrical / electronic means 10 housed in a housing 10', for suitably feed the associated gun 6, through the pipes 11, 11 '(this according to a flow rate and a defined air / water ratio). The control means 10 may in some cases be formed in a housing 10 'secured to the casing of the dispenser 9. The housing 3 has the essential function of protecting within its internal volume 12 the dispenser member 9 and its means of piloting 10.

  According to the invention, the housing 3 is shaped to allow an operator 13 to intervene on the distributor member 9 and on its control means 10, without having to penetrate fully within its internal volume 12. L distributor member 9 and its control means 10 are located at shallow depth relative to the surface of the ground S (in particular a depth of between 40 and 80 cm maximum). In this way, the installation, maintenance or control operations can be performed: - by the operator 13 lying on the side of the cubicle 3, - by the operator 13 sitting on the edge of the cubicle 3, - either again, as illustrated in FIG. 1, by the operator 13 resting on the bottom of the box 3 (leaning forward or squatting). For this and in particular within the context of this latter possibility, the internal volume 12 of the stall 3 preferably has a maximum height h of 80 cm. Still preferably, this height h is of the order of 70 cm.

  As the dispensing member 9 is at a level fairly close to the surface of the ground S, the housing 3 is specially shaped and structured to ensure its protection against freezing. Thus, the housing 3 comprises a suitable thermal insulation; in addition, it optionally incorporates heating means and / or its bottom is structured to best benefit geothermal flow. A possible embodiment of this housing 3 is illustrated in Figures 2 and 3. In this case, in these two figures, the housing 3 is in the general form of a parallelepiped. It consists mainly of a belt of lateral peripheral walls 14 (four juxtaposed walls) whose upper edge 15 delimits a manhole 16 closable by a cover (or hood) 17. The sidewall belt 14 is advantageously under the shape of a body made of recyclable thermoplastic material, for example recyclable polyethylene type.

  This plastic body consists of a one-piece piece or two one-piece pieces in the general shape of U; in the latter case, each U-shaped part comprises a panel forming one side of the wall belt 14, extended by two panels each forming half of another wall (the half-walls of a U-shaped part forming the front and rear walls of the housing 3 in association with the half-complementary walls of the other U-shaped part).

  These parts can be obtained, for example, by rotational molding or by thermoforming; they can be single or double skin. The inner face of the plastic body, or where appropriate the space between the double skin, is advantageously equipped with a layer of thermal insulating coating, for example of glass wool or polystyrene type, and preferably hemp or cork. The cover member 17 is hingedly mounted on the peripheral edge 15 of the wall belt 14. This cover 17 advantageously consists of a rigid outer plate, for example of steel-type metal or plastic, provided with a thermal insulating lining (identical or similar to that of the sidewall belt 14). The structure of this cover 17 is advantageously adapted to withstand operations allowing the release of snow or ice (interventions with the pickaxe in particular); more preferably, its shape is adapted to avoid hurting animals in pasture.

  A bottom wall 18 is attached at the lower edge of the wall belt 14 to form the bottom portion of the housing 3. This bottom wall 18 is here in the general form of plastic grating. Such a structure defines a stable and clean background. Its multiple openings give it properties of high permeability geothermal flows, that is to say that the internal volume 12 of the box 3 can thus benefit at best from a heat input from the ground, to ensure, or to less participate in the frost protection of the distributor 9 and its control means 10. As an alternative embodiment, the bottom wall 18 may consist of a geotextile structure of BIDIM type (registered trademark) In a large part of geographical areas to be equipped (according to the conventional meteorological conditions of these areas), the thermal permeability of the bottom wall 18, combined with the thermal insulation characteristics of the rest of the box 3 (in particular of its wall belt 14 and its cover 17) allows effective freeze-free maintenance of the internal volume 12, without requiring the use of additional heating means.

  Alternatively, the bottom of the box 3 may be open, without grating or a particular wall. In this case, it is the earthy soil or an embankment reported that constitutes the bottom portion of the internal volume 12 of the box 3. Depending on the conditions necessary to ensure the frostproofing of sensitive materials 9, 10, the cubicle 3 may be equipped with complementary heating means, for example electric heating means, or heat pipe type. In Figures 2 and 3, we note that the housing 3 has two openings 20 formed in the central portion of the wall member on which is hinged cover 17. These openings 20 will allow the passage of water supply pipes and in air from the snow cannon, as explained later. On the other hand, a reservation or passage 21 is provided in the lower part, in the same wall element and in the grating 18 (Figure 3); the function of this passage 21 will be explained later.

  The base 5 of the snow gun 6, shown in detail and in isolation in Figure 4, is made of metal sheets, for example stainless steel or galvanized. This base 5 mainly comprises a hollow column 22 of vertical axis, generally parallelepiped shaped, composed of four side walls 23, defining a vertical axial housing 24 opening in the upper part through an orifice 5a. One of the walls 23 of this column 22 (marked 23 'and referred to arbitrarily as the front wall) is provided with: an insert member 25, in the form of a horizontal plate extending cantilevered, intended to serve as a support member for the distributor member 9, and - one or two openings 26, located just above said support member 25, serving for the passage of the air and water pipes 11 and 11 '(from the distributor 9 and for feeding the barrel 6). The base 5 is further equipped with radiant panels 27, at its lower end 5b, whose function is to optimize its positioning and its stability in the bottom of the excavation 2, and also its maintenance, once the whole covered by the embankment. These radiant panels 27 are four in number, arranged in a cross in the extension of each of the side walls 23 of the column 22, and this substantially in the same horizontal plane. They are each formed of a plate of metallic material (for example steel), and each have a generally rectangular shape.

  In addition, gussets 28 are interposed between the column 22 and each radiant panel 27, to strengthen the structure. The base 5 can be made of several dismountable parts and / or hinged to each other, so that it can be prepared in the factory, transported in the most compact manner possible and mounted very quickly on the implantation site. Thus, the various radiant panels 27 can be mounted articulated on the lower edge of their respective support panels 23; on the other hand, the reinforcement gussets 28, as well as the cantilever support member 25, can be detachably mounted via suitable mechanical connection means. For example, the gussets 28 and the support member 25 may be equipped with slit ears 29 adapted to catch on appropriate openings 30 provided in the walls 23 of the column 22 and in the radiant panels 27. Thus, as illustrated in FIG. 5, the radiant panels 27 can be folded against their side walls 23 facing the column 22; the reinforcing gussets 28 may be pressed against one or more of said lateral walls 23 and the support element 25 housed within the internal orifice 24 of the column 22, the assembly being held by fast connection means, The type of screw / wing nuts 31. This compact presentation substantially limits the size of the base 5 and 20 facilitates its transport and handling before laying on the site. Starting from this compact configuration, the preparation of the base 5 for its implementation consists first of all to separate the various parts by removing the screw / nut systems 31. The panels 27 are deployed radially, then the reinforcing gussets 28 are each fixed between a radiant panel 27 and a side wall 23 opposite by means of the aforementioned removable fastening systems of the ears type 29 / lights 30. The establishment of the assembly base 5 / box 3 on the implantation site is detailed below in connection with FIGS. 6 to 8. The corresponding implantation consists first of all in digging a dig in the ground, close to the main water and air supply network. This excavation must be provided sufficiently large to accommodate the base structure 5 and the box 3. It is also hollowed out so as to allow the laying of the secondary supply lines 8, 8 'intended to extend between the main lines 7, 7 'and the cubicle 3.

  The base 5 suitably deployed is placed in the bottom of the excavation, the depth thereof being adapted so that the upper portion 5a of the base is in the plane or substantially in the plane of the surface of the surrounding soil S. The free ends of the secondary pipes 8, 8 'which extend from the main pipes 7, 7' are then suitably attached to the base 5 and fixed on the support element 25, by means of suitable connectors serving the In addition, as can be seen in FIG. 2, an attached heating element 32, of the heat pipe type, is also placed close to the column 22. This heat pipe 32 is in the form of an elongated structure, its lower end being housed in the ground, and its upper end being secured to the distributor member 9, via a suitable fastening flange. On the other hand, an electric cable (not shown) is also attached near the column 22, to provide power to the cubicle 3.

  The construction site is then secured by a first embankment (not shown) cast in the excavation, the surface of this embankment extending just below the support element 25. This embankment covers the radiant panels 27 of the base 5 and the pipes secondary 8, 8 'posed in the bottom of the search. The implantation is continued by fixing the housing 3 on the base 5, as illustrated in FIGS. 9 and 10. For this, the housing 3 is positioned so that the wall element in which its openings are formed. 20 and reservation 21 comes opposite the front wall 23 'of the base 5 (Figure 9); then it is moved vertically to fit its upper pin 33 in a suitable opening 34 formed in the upper part of the base 5 (Figure 10). Once the housing 3 properly in place, its openings 20 are positioned opposite the openings 26 of the base 5. On the other hand, the support member 25 is placed in the reservation 21 of the box, or just above this one; this reservation 21 thus serves for the passage of the pipes 8, 8 'which join the distributor 9.

  This fastening 4 by the tenon / mortise structure 33, 34 ensures the earth stability of the housing 3. It also ensures its correct and constant positioning relative to the base 5, which allows the standardization of certain components of the housing. installation, in particular connecting lines 11 and 11 '.

  Then, the excavation 2 is filled by the final embankment (FIG. 8), to completely bury the assembly (stool 3 / base 5. The upper end 5a of the base structure 5 and the upper rim 15 of the stool 3 come then position itself flush with the ground, it is then possible to place the snow gun 6 on the upper end 5a of the base 5, for example by means of a flange 35 (only the lower end of the boom of the barrel 6 is shown in Figure 8.) The flange 35 for fixing the barrel 6 may be provided with insulation means ensuring a thermal break, to limit the heat transfer of cold from the barrel 6 to the assembly base 5 / cubicle 3. The lines 11 and 11 'connecting the distributor 9 and the barrel 6 transit within the vertical housing 24 of the base 5 through the passages 20, 26 of the housing 3 and the front wall of the base 23', and coming out of this housing 24 by the end 5a top of the base 5. The dispensing member 9 and the housing 10 'of its control means 10 are positioned last. The distributor member 9 is fixed on its support 25 and is suitably connected to the various air and water lines 8, 8 ', 11, 11'. The housing 10 'is either placed on a suitable support formed in the internal volume 12 of the housing 3, or directly attached to the inner face of the wall belt 14, or directly attached to the distributor 9. The latter operations can be implemented quickly and easily by a qualified operator, and this safely through the manhole 16 of the housing 3. The various electrical connections required are also made simply and quickly. To improve safety, it will be appreciated that means may be provided, in the form of a switch, capable of ensuring that the power supply is cut off as soon as the lid element 17 is opened. On the other hand, although Of course, if the evolution of the snow cannons allows their operation from only a water supply line, the air supply line can be removed without changing the principle of installation structure as described above.

Claims (15)

  - 1.- Snowmaking installation comprising at least one snow cannon (6) connected to a water supply network, and possibly in air, and associated with a housing (3) buried over a portion ( 7, 7 ') of said supply network, which housing (3) comprises - an upper part (15) provided with a manhole (16) closable by a cover (17), - a side wall belt ( 14), and - a lower part (18), which housing (3) defines an internal volume (12) which integrates a distributor (9) for controlling the supply of water, and possibly air, said gun to snow (6) associated, and which housing (3) further comprises at least one passage (20, 21) for the entry of the pipes (8, 8 ') of water and, if appropriate, of air supplying said distributor ( 9) and for the outlet of the pipes (11, 11 ') of water and, if appropriate, of air coming from said distributor (9) and feeding said snow gun (6), characterized in that said dispenser (9) is placed in the internal volume (12) of the box (3), this to a depth such that an operator (13) can have access to a pose, maintenance or control , without his body being totally confined within said internal volume (12) of said housing (3), the latter further comprising means for maintaining off-gel said distributor member (9).   2. A snowmaking facility according to claim 1, characterized in that the internal volume (12) of the box (3) has a height (h) maximum of 80 cm.   3. A snowmaking facility according to any one of claims 1 or 2, characterized in that the upper part (15) of the box (3) is flush with the ground or practically flush with the ground.   4. A snowmaking installation according to any one of claims 1 to 3, characterized in that the housing (3) consists of a peripheral wall (14) provided with a coating of material (x) insulating (s) ) thermal (s), the upper edge (15) defines the manhole (16) closable by the cover (17) also provided with a coating of material (s) insulating (s) thermal (s).   5.- snowmaking installation according to claim 4, characterized in that the peripheral wall (14) of the housing (3) consists of a shell of plastic material equipped with an insulating coating, which peripheral wall (14) is associated with an articulated lid (17) made of metal or plastic, equipped with an insulating coating.   6. A snowmaking facility according to any one of claims 1 to 5, characterized in that the housing (3) incorporates heating means (32) to maintain its internal volume (12) frost.   7.- snowmaking installation according to claim 6, characterized in that the heating means of the housing (3) are heat pipe type (32) having a generally elongate shape, positioned vertically with one of its ends integrated into depth, and with its other end opening into the internal volume (12) of said housing (3), near the distributor (9) and preferably in physical contact with the latter or with its support (25).   8. Snow-making plant according to any one of claims 1 to 7, characterized in that the lower part (18) of the box (3) is adapted so that the geothermal flow from the ground penetrates into its internal volume ( 12) so as to preserve the latter frost protection.   9.- snowmaking installation according to claim 8, characterized in that the lower part of the box (3) is constituted by the ground or by an embankment reported.   10. A snowmaking facility according to claim 8, characterized in that the lower portion of the housing (3) comprises a bottom wall (18) permeable to heat flows, for example in the general form of grating or geotextile structure, this in particular to allow the entry of the geothermal flow within the internal volume (12) of said housing (3).   11. A snowmaking facility according to any one of claims 1 to 10, characterized in that the housing (3) comprises means (4) for securing it to a base structure (5) of the snow gun ( 6) associated, said base (5) being intended to be buried.   12. A snowmaking plant according to claim 11, characterized in that the base structure (5) of the snow gun (6) comprises a cantilever element (25) forming a support for the distributor (9). , said support member (25) being placed within the internal volvulus (12) of the housing (3) via an opening (21) formed therein.   13.- snowmaking installation according to any one of claims 11 or 12, characterized in that the base structure (5) is in the form of a hollow column (22) defining an axial central housing (24) which is intended to receive, over at least part of its height, a portion of the pipes (11, 11 ') of water and, if appropriate, of air, which feed the associated snow cannon (6), which column hollow (22) and which abutment (3) associated have openings facing (20, 26) for the output of said pipes (11, 11 ') from the distributor (9) and extending to the snow gun (6). ). 35   14. A snowmaking plant according to any one of claims 11 to 13, characterized in that the base structure (5) is provided at the lower end (5a) of several radiant panels (27), extending substantially in the same horizontal plane, to optimize its fixation and its maintenance in the ground.   15.- Log for a snowmaking installation according to any one of claims 1 to 14.