The present invention relates to a nucleation nozzle for forming freezing nuclei for devices for making artificial snow.
The present invention further relates to a method for forming freezing nuclei.
In particular, the present invention is aimed at the field of nucleation nozzles used in devices for generating artificial snow, commonly known by the term “snow cannons” or “snow lances”.
For the sake of simplicity, we will make reference hereinafter to the preferred embodiment, in which the apparatus is used for a snow cannon. In accordance with the prior art, a snow cannon comprises a tubular body having an inlet port and an outlet port. A passage area is defined inside the tubular body and is in fluid communication with the outside through the inlet port and the outlet port.
Furthermore, a blowing means is usually installed inside the tubular body to draw in air from the inlet port and generate an outflow of air from the outlet port.
In particular, the blowing means comprises a motor and a fan connected to the motor. Furthermore, the snow cannon comprises a plurality of nebulising nozzles positioned around the outlet port for the delivery of water.
In addition, the cannon comprises nucleation nozzles suitable for forming the freezing nuclei that constitute the germ on which the snowflake is constructed following the deposit of the liquid nebulised by the nebulising nozzles.
In general, compressed air and water flow into the nucleation nozzles in such a way that the particles (drops) of water that are expelled from the nucleation nozzles freeze immediately on being introduced into the outside environment as a result of expansion when exiting the nozzle.
Furthermore, the nebulised liquid particles (expelled from the nebulising nozzles) accumulate on the freezing nuclei to form snowflakes.
Examples of structures of such nucleation nozzles are known from the prior documents JPH02208471 and CA2276016.
Using the so-called Laval effect in nucleation nozzles is also known. An example of such an application is provided in document EP2071258.
This document envisages the joint acceleration of both the compressed air and the water particles.
However, such nozzles require a large energy input and in any case require rather rigid temperatures in order to function in an optimal manner. In this situation, the object of the present invention is to provide a nucleation nozzle and a method for forming freezing nuclei capable of remedying the aforementioned drawbacks.
In particular, it is an object of the present invention to provide a nucleation nozzle and a method for forming freezing nuclei which enable freezing nuclei to be produced while optimising energy resources and generating greater amounts of snow and which is of higher quality, i.e. finer.
It is a further object of the present invention to provide a nucleation nozzle and a method for forming freezing nuclei which enable snow to be generated at higher temperatures.
The specified objects are substantially achieved by a nucleation nozzle and a method for forming freezing nuclei as disclosed in the appended claims.
Additional features and the advantages of the present invention will become more apparent from the following detailed description of some preferred, but not exclusive embodiments.
This description will be given below with reference to the attached drawings, provided solely for illustrative and therefore non-limiting purposes, in which:
With reference to the aforementioned figures, the reference number 1 denotes in its entirety a nucleation nozzle for forming freezing nuclei starting from a jet of liquid under pressure.
The present invention is preferably applied on devices 100 for producing artificial snow which can comprise devices called “snow cannons” (as illustrated in
In addition, the device 100 comprises a blowing means 105 operatively associated with the tubular body 102 so as to generate an air flow 106 along an air flow direction that goes from the inlet port 103 to the outlet port 104.
The blowing means 105 comprises a fan 107 which draws in air from the outside environment and blows it into the tubular body 102 towards the outlet opening 104.
Furthermore, the device 100 comprises a plurality of nebulising nozzles 108 operatively associated with the tubular body 102 so as to spray liquid towards the air flow 106. The nebulising nozzles 108 are preferably positioned around the outlet port 104 and are directed towards the air flow 106. One or more nucleation nozzles 1, preferably up to eight nucleation nozzles 1, are likewise provided at the outlet opening 104.
In particular, the nucleation nozzle 1 comprises a compressed air duct 2 having an inlet opening (not illustrated) and an outlet opening 3. F indicates the compressed air flow defining the flow direction of the compressed air from the inlet opening to the outlet opening 3.
Furthermore, the nucleation nozzle 1 comprises at least one water duct 4 having an inlet opening (not illustrated) and an outlet opening 5. F′ indicates the water flow defining the flow direction of the water from the inlet opening to the outlet opening 5.
The outlet opening 5 forms a nozzle (separate from the nebulising nozzles 108 previously described) for nebulising the outlet water so as to nebulise the water to form a plurality of water particles.
The water duct 4 is separate from the compressed air duct 2. In particular, the water duct 4 extends alongside the compressed air duct at least up to the outlet opening 5 of the water duct 4 and the outlet opening 3 of the compressed air duct 2. Preferably, the water duct 4 is positioned around the compressed air duct 2. In this manner, the particles of nebulised water are involved by the accelerated flow of compressed air exiting the opening 3. For this purpose, the outlet opening 5 can be directed toward the air flow exiting the opening 3.
In addition, for each nucleation nozzle 1, there are several water ducts 4. Preferably, per each nucleation nozzle 1, there are several water ducts 4 positioned around the air duct 2.
Furthermore, the outlet opening 5 of the water duct 4 is positioned close to the outlet opening 3 of the compressed air duct 2. Preferably, the outlet opening 5 of the water duct 4 is positioned slightly retracted relative to the outlet opening 3 of the compressed air duct 2 in the flow direction F of the compressed air from the inlet opening to the outlet opening. However, in other embodiments not illustrated in the appended figures, the outlet opening 5 of the water duct 4 could be set in a slightly forward position or flush with the outlet opening 3 of the compressed air duct 2 in the flow direction F of the compressed air.
A first stretch 2a of the compressed air duct 2 has a cross section which decreases in the flow direction F. Furthermore, the first stretch 2a is followed by a second stretch 2b having a cross section which increases in the flow direction F so as to form a convergent-divergent path.
In particular, the inner surface of the compressed air duct 2 is continuous (without steps or interruptions) and curved at least at the passage from first stretch 2a to the second stretch 2b (preferably the surface is completely continuous) so as to create a continuous guide for the air flow in transit inside the duct 2.
In other words, the two stretches 2a and 2b together form a nozzle having a constriction, so that the air flow accelerates. In still other words, the two stretches 2a and 2b together define a one-sheeted hyperboloid shape of the inner surface of the compressed air duct 2.
In the preferred embodiment, the two stretches 2a and 2b define a Laval nozzle, or more commonly a convergent-divergent nozzle, which enables air to be accelerated up to supersonic speeds.
It should be noted that the incoming compressed air has a value of pressure such as to create, downstream of the narrowing, an acceleration in the air flow to a supersonic level. In detail, the pressure and temperature of the incoming compressed air are set on the basis of the pressure and temperature characteristics of the air outside the nozzle.
For example, the pressure of the incoming air has a higher pressure value than the air downstream of the narrowing.
In particular, the air flow at the smallest cross section of the duct 2 (hence at the narrowing) has a Mach number equal to 1.
Preferably, the pressure of the incoming air flow is such that at the outlet section of the nozzle (downstream of the constriction) the air flow has a Mach number greater than 1 (supersonic acceleration).
Preferably the water duct 4 extends alongside the compressed air duct 2 at least in a stretch close to the respective outlet openings.
Furthermore, the outlet opening 5 of the water duct 4 is facing the outside, like the outlet opening 3 of the compressed air duct 2. In particular, the outlet opening 5 of the water duct 4 is facing the same side of the nucleation nozzle 1 as the outlet opening 3 of the compressed air duct 2.
In particular, the water outlet openings 5 are positioned on the outside relative to the two stretches 2a and 2b and are not interposed between the two stretches.
As it is illustrated for example in
It should be noted that the nucleation nozzle 1 is defined by a single piece, which the water duct 4 and compressed air duct 2 are hollowed out of.
The present invention further relates to a method for forming freezing nuclei in a device 100 for producing artificial snow. The method derives directly from what has been described above, which is therefore referenced in its entirety.
In, particular, the method comprises supplying compressed air along the compressed air duct 2, thus generating an acceleration by narrowing and widening the cross section of the compressed air duct in the flow direction F of the compressed air from an inlet opening to an outlet opening and supplying water along a water duct 4 separate from the compressed air duct 2 and having an outlet opening 5 positioned close to the outlet opening 3 of the compressed air duct 2. In particular, the inner surface of the compressed air duct 2 is continuous and curved at least at the narrowing so as to create a continuous guide for the air.
The present invention achieves the set objects.
In particular, the present invention enables water to be fragmented so as to obtain particles of a size such as to freeze more rapidly on contact with the outside atmosphere. In fact, as the compressed air is accelerated by means of the Laval effect, the compressed air is greatly slowed outside the nozzle, thus generating a pressure wave that further nebulises the particles of water and makes them even finer. The reduced size of the water particles enables faster freezing with a smaller energy input. In other words, in the outlet area located just after the outlet opening 3 the maximum possible acceleration is reached by the air which involves the particles of nebulised water.
As a further consequence, it is possible to generate a larger amount of snow, which is also of higher quality, i.e. finer. Furthermore, it is possible to generate snow at higher temperatures compared to conventional snow-making devices.
The nucleation nozzle according to the present invention thus enables higher energy efficiency.
As an alternative to what has been described and illustrated, the device for producing artificial snow can define a snow lance comprising at least one nucleation nozzle 1 and one or more nebulising nozzles.
Number | Date | Country | Kind |
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102016000015257 | Feb 2016 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2017/050746 | 2/10/2017 | WO | 00 |