NL1007187C2 - Method and device for preparing snow. - Google Patents

Description

Method and device for preparing snow

The present invention relates to a method of preparing snow, in particular in a hall intended for winter sports, comprising the steps of: bringing the hall to a temperature below freezing point; supplying a liquid to be frozen to the hall and atomizing the liquid by means of a gas in the hall. Such a method is known from US patent 5,102,044.

This patent describes a method for preparing snow in which a mixture of water and compressed air is supplied to a number of nozzles, in which water and the compressed air are apparently mixed, and the water is atomized so that it is in the form of drops in the hall is sprayed, the droplets freezing in the hall due to the low temperature and descending in the form of snow crystals. It is stated that this method would give satisfactory results at air / water ratios between 300 and 3000 Nm3 / m3 (1 Nm3 = 1 m3 gas at normal ambient pressure and temperature), but specific examples are not given.

Although this method has the advantage over other known modes of snow preparation, where, for example, the atomized liquid is frozen by contacting it with a cryogenic medium, such as nitrogen, that the costs are relatively low, while in addition the risks of operating with such a cryogenic liquid in an enclosed space, this known method proves to be not entirely satisfactory in practice. For example, the atomization of the liquid at a gas / liquid ratio in the vicinity of the lower limit mentioned in this patent in the specification of this patent has been found to lead to very coarse, porous snow, while the energy costs for bringing the hall to the desired low temperature and generating the gas pressure required in practice are relatively high.

The object of the invention is therefore to provide an improved method of the type described above. According to the invention this is achieved in that gas is supplied for atomizing under a pressure of at most 12 barg (measured (over) pressure, 1 barg = 2 bar absolute), and a volume ratio between the gas and the liquid is between 125 and 2000 Nm3 / m3. Surprisingly, it has been found that even when use is made of a gas, generally air under such a relatively low pressure, the liquid is still atomized in an efficient manner, and is useful in practice even at relatively low gas / liquid ratios, that is, relatively loose snow with relatively small crystals are obtained. Moreover, the snow preparation at such a low pressure requires relatively little power, while still obtaining a sufficient capacity.

The volume ratio between the gas and the liquid is preferably between 150 and 1200 Nm3 / m3 and more preferably between 165 and 500 Nm3 / m3. Very useful snow can be prepared in this area with a relatively small amount of gas under pressure. In this case, the gas is preferably supplied under a pressure of at most 8 barg, and more preferably at most 6 barg, whereby sufficiently small droplets are nevertheless formed with little power and a considerable snow-making capacity is also achieved.

The average size of the atomized liquid particles is preferably at most 75 μτη (SMD), more preferably at most 55 μπι (SMD) and most preferably at most 35 μπι (SMD), where SMD stands for the Sauter Mean Diameter, defined as the

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'ί Λ' S '3 diameter of a drop that shows the same surface to volume ratio as exists between the surface of all drops together and the volume of all drops. Such relatively small liquid particles lead to relatively small snow crystals, which guarantee good snow quality.

The temperature in the hall is preferably lowered to less than -1 ° C, and more preferably to -3 ° C. To achieve a very high snow-making capacity, it is preferable to reduce the temperature in the hall to less than - Decrease by 5 ° C. This temperature can be lowered by introducing cold air into the hall, whereby the liquid mist is then preferably introduced into the hall substantially transversely of the direction of flow of the cold air. Hereby an intensive contact between the liquid mist and the cold air is achieved, which results in a rapid freezing of the liquid mist.

Preferably, the liquid mist is distributed evenly in the hall, both in terms of surface area and time. As a result, a snow layer of uniform thickness is formed in the hall, which is therefore relatively flat, while the maximum cooling capacity required for preparing the snow remains relatively low by applying the snow layer distributed over time. The hall for preparing snow can be divided into compartments and snow can be prepared in one compartment at a time. In this way, the air conditions (in particular the temperature) in that part of the hall where snow production takes place can be optimally adjusted.

With a view to reducing the total cold power required for the hall during snow preparation, the preparation preferably takes place in a period with reduced outside temperatures, such as at night. This has the additional advantage that such a winter sports hall will generally be closed at night, so that no heat is brought into the hall by visitors.

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In addition, a large number of energy consumers such as the lighting, lift systems and the like will be switched off, so that extra power is available for preparing the snow.

The invention also relates to a device for preparing snow, in particular in a hall intended for winter sports, provided with refrigerants for bringing the temperature in the hall below freezing point, means for supplying a temperature to the hall. freeze liquid and means connected to the liquid supply means for atomizing the liquid with the aid of a gas in the hall. Such a device is also known from US patent 5,102,044. The object of the invention is now to adapt this device such that the method described above can be carried out therewith. According to the invention this is achieved in that the atomizing means are connected to a source of gas under a pressure of at most 12 barg and are arranged for atomizing the liquid at a gas / liquid ratio between 125 and 2000 Nm3 / m3.

The atomizing means preferably comprise at least one spray nozzle connected to the liquid supply means and the source of gas under pressure. In this spray head, the liquid can be mixed with the gas and atomized simultaneously due to its high pressure. Preferably, the spray head furthermore exhibits mechanical atomizing means, for example in the form of a target surface, whereby the jet of liquid flowing into the spray head is already broken into small drops before it is further atomized by the gas flow.

When the spray head is movable, the liquid atomized thereby can be distributed evenly throughout the hall.

The refrigerants are preferably adapted to blow a stream of cold air into the hall, the spray head preferably being oriented transversely to the direction of flow of the cold air in order to ensure optimum contact between the atomized liquid and the cold air flow.

Preferably, several alternately controllable spray nozzles are arranged in the hall, so that snow can be prepared uniformly and with a relatively low power throughout the hall. In order to prevent heating of the hall at the place where snow is prepared as much as possible, movable separating elements can be arranged in the hall between the spray heads, so that more cold can be supplied locally.

The invention is now elucidated on the basis of an example, with reference being made to the attached drawing, in which: figure 1 shows a schematic perspective view of a hall for winter sports with a snow-making device according to the invention, figure 2 shows a cross-section through a nozzle for use in the snow-making device according to the invention, figure 3 shows a diagram showing the operating range of the snow-making device, and figure 4 shows a diagram of the power demanded during normal use of the hall and during snow-making.

A hall 1 for practicing winter sports, such as skiing, snowboarding and the like, is provided with a slope 2, which is slightly stepped in the usual manner. In order to maintain a low temperature in hall 1, two cooling machines 3 are placed on either side of hall 1, each of which draws air in accordance with the arrow I, and the air after it has cooled to below freezing point via a roof 5 pipe 4 suspended from hall 1 with a number of longitudinally distributed blow-out openings 6 in hall 1. The cold air flows in! 0071 8 7 6 first into the hall 1 according to the arrows C, to be finally extracted on one of the short sides 7 of the hall 1 by fans 11, whereby a cold air flow in the longitudinal direction of the hall 1 is established. The extracted cold air is recirculated by the fans to the associated refrigeration machine 3, where it is cooled again to the desired temperature. Incidentally, it will be clear that the device according to the invention can also be used in combination with other arrangements of the discharge and extraction openings. For example, the blow-out openings could be arranged on the short sides of the hall, and extraction could take place centrally in the hall. In this way, for example, an air flow in the longitudinal direction of the hall can also be generated.

For the preparation of snow in the hall 1, nozzles 9 are provided on the long sides 8 thereof. In the example shown, these spray heads 9 are movable in both vertical and horizontal direction according to arrows V and H, in order to obtain a uniform spray image. The spray nozzles 9 are each connected to a liquid supply line and a source of pressurized gas, generally compressed air (not shown here). In the spray heads 9, the supplied liquid, usually water, is atomized under the influence of the compressed air and the internal shape of the spray head 9, after which the atomized liquid is sprayed in the form of a cone 10 in the hall 1. There, the liquid particles freeze due to the low temperature, and fall down in the form of snow crystals.

In order to make it possible to prepare snow only in certain parts of the hall 1, movable partitions, for example in the form of insulating curtains 31, are arranged at different places in the hall 1. Hall 1 can hereby be divided into compartments 12, and snow can be prepared in one compartment at a time. This is important because the freezing heat of the 1007187 7 spray drops is released when snow is being prepared. As a result, the temperature in the relevant compartment 12 increases. By closing off all cold air blow-out openings 6 located outside the relevant compartment 12, all available cold air can be concentrated in the compartment where the snow is prepared, so that heating of that compartment can be prevented. This is particularly effective when the outside temperatures are relatively high, as will be the case in summer.

The spray head 9 can be formed by a housing 13 which has a connection 14 for a liquid supply line L, as well as a connection 15 for an air supply line A. The two connections 14, 15 are respectively via a passage 17 and an annular chamber 18 with radial openings 19 connected to a mixing chamber 16. In this mixing chamber 16, the liquid L is atomized and then sprayed in the form of a spray of very fine droplets with an evenly distributed size through a number of openings 22 in the wall of the spray head 9.

Because the device according to the invention as described above is extremely simple in construction, it is very suitable for retrofitting in existing winter sports halls, for instance as a replacement for a snow preparation device based on nitrogen. As a result, large savings can be achieved with regard to the raw materials used, since nitrogen is used little efficiently as a cold generator for snow preparation and is therefore relatively expensive. This is due to the fact that the snow preparation works with an evaporation temperature on the order of -10 ° C, while the nitrogen used in liquid form will have a temperature of about -200 ° C. In addition, working conditions in the hall during snow production are significantly improved by replacing nitrogen with compressed air.

As mentioned, the preparation of the snow preferably takes place when the outside temperatures are relatively low, ie usually at night. As can be seen in figure 4, the power required to maintain the temperature in hall 1 at the desired value (surface 28) is considerably lower than during the day (surface 25). The power surplus 21 of the chiller 3, which is after all dimensioned for the power requirement during the day, can then be used for snow preparation. As a result, no additional cooling capacity needs to be installed for preparing the snow. The snow preparation at night has the additional advantage that other energy consumers, such as the lighting and the ski lifts (surface 26), as well as the electricity supply for secondary commercial spaces, such as a catering facility (surface 27), will also be switched off, so that the total installation of the power grid involved amount of power at that time will be less. This power surplus 20 can then also be used for snow preparation, without this leading to additional peak loads on the network and the associated costs for the user.

The examples below indicate some operating points of the snow-making device according to the invention, showing how relatively large amounts of high-quality snow can be made with relatively low pressures and small amounts of air.

EXAMPLE 1

Air is started from at a temperature of 24 ° C and a pressure of 7.5 barg. This compressed air is supplied to the spray head 9 and used to atomize water supplied at a temperature of 12 ° C. The air / water ratio is set at 600 Nm3 / m3 · The temperature in hall 1 is - 4.5 ° C. Under these conditions, a mist is created with an average droplet size of 30 μπι (SMD).

When freezing this mist, snow crystals form which can be referred to as "powder snow", and which are very suitable as a top layer.

10 0 7 1 Q 7 9 EXAMPLE 2

Now air is used with the same temperature of 24 ° C, but with a pressure of 7.0 barg. This compressed air is again supplied to the spray head 9 and used to atomize water supplied at a temperature of 14 ° C. The air / water ratio is now set to 250 Nm3 / m3. The temperature in Hall 1 is -2.0 ° C. Under these conditions, a mist is created with an average droplet size of 50 μ, να. (SMD), which, when freezing, forms snow crystals which may be referred to as "compact snow". This type of snow is also well suited to act as a top layer.

EXAMPLE 3

In this example, air at a temperature of 26 ° C and a pressure of 6.4 barg is supplied to the spray head 9 and used to atomize water which is again supplied at a temperature of 14 ° C. The air / water ratio is hereby set at 140 Nm3 / m3. The temperature in hall 1 is lowered to -3.0 ° C. Now a mist is formed with an average droplet size of 65 μιη (SMD) which, upon freezing, forms snow crystals which can be referred to as "gruel snow". This snow is suitable to serve as a substrate, and is therefore made especially at the start of a snow preparation cycle, in order to apply the thickest possible snow layer to the substrate in a relatively short time.

The measurement points described above are shown in the diagram of Figure 3, which clearly shows that the "looseness" of the snow, which is of course closely related to the average size of the atomized droplets, increases with increasing gas / liquid ratio and with decreasing temperature. In addition, the shaded areas 23 and 24 show those combinations of parameters whereby powder snow or compact snow are obtained, respectively, while the values of the parameters in the area on the left and 1 r. r- 7 1 o 7 10 the top of line 29 correspond to the preparation of porridge snow.

Although the invention has been elucidated above on the basis of a number of examples, it will be clear to the skilled person that it is not limited thereto. The scope of the invention is therefore exclusively determined by the following claims.

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Claims (19)

1. P 7 * o 7 is lowered by introducing cold air into the hall, and the liquid mist is introduced into the hall substantially transversely of the flow direction of the cold air. A method for preparing snow, in particular in a hall intended for winter sports, comprising the steps of: bringing the hall to a temperature below freezing point, · supplying a liquid to be frozen to the hall and filling it with atomization of the liquid by means of a gas in the hall, characterized in that for the atomization gas is supplied under a pressure of at most 12 barg, and a volume ratio between the gas and the liquid is between 125 and 2000 Nm3 / m3 . 2. Method as claimed in claim 1, characterized in that the volume ratio between the gas and the liquid is between 150 and 1200 Nm3 / m3 and preferably between 165 and 500 Nm3 / m3. Method according to claim 1 or 2, characterized in that the gas is supplied under a pressure of at most 8 barg and preferably at most 6 barg. A method according to any one of the preceding claims, characterized in that the average size of the atomized liquid particles is at most 75 µm (SMD). Method according to claim 4, characterized in that the average size of the atomized liquid particles is at most 55 μτη (SMD) and preferably at most 35 μτη (SMD). Process according to any one of the preceding claims, characterized in that the temperature in the hall is lowered to less than -1 ° C and preferably to less than -3 ° C. Method according to claim 6, characterized in that the temperature in the hall is lowered to less than -5 °. Method according to any one of the preceding claims, characterized in that the temperature in the hall A method according to any one of the preceding claims, characterized in that the liquid mist is distributed evenly in the hall. Method according to any one of the preceding claims, characterized in that the hall for preparing the snow is divided into compartments, and snow is prepared in one compartment at a time. Method according to any one of the preceding claims, characterized in that the preparation takes place at low outside temperatures, and preferably at night. A method according to claim 11, characterized in that energy-consuming and heat-generating equipment present in the hall is switched off during the preparation of the snow. 13. Apparatus for preparing snow, in particular in a hall intended for winter sports, comprising refrigerants for bringing the temperature in the hall below freezing point, means for supplying a liquid to be frozen to the hall and containing the liquid supply means connected means for atomizing the liquid with the aid of a gas in the hall, characterized in that the atomizing means are connected to a source of gas under a pressure of at most 12 barg and are adapted for atomizing the liquid at a gas / liquid ratio between 125 and 2000 NmVnv *. Snow-making device according to claim 12, characterized in that the misting means comprise at least one spray head connected to the liquid supply means and the source of gas under pressure. Snow-making device according to claim 14, characterized in that the spray head has mechanical misting means. 10u7187 Snow-making device according to claim 14 or 15, characterized in that the spray head is movable. Snow-making device according to any one of claims 12 to 14, characterized in that the refrigerants are adapted to blow a cold air flow into the hall, and the spray nozzle is directed substantially transversely of the flow direction of the cold air. Snow-making device according to any one of claims 14 to 17, characterized in that a plurality of alternately operable spray heads are arranged in the hall. Snow-making device according to claim 18, characterized in that movable separating elements are arranged in the hall between the spray heads. 1007137