DE4423124A1 - Snow cannon for ski slopes - Google Patents

Abstract

The snow cannon (1) consists of a duct housing (2) with an internal motor-driven fan (7) to produce the main air stream (6a). A water nozzle (10) at the exit opening (4) is used to spray water into the main air stream. A support nozzle (11, 11a) in the housing is used to spray ice crystals into the main air stream. The support nozzle carries a diffusion duct in the main air stream with an increasing cross-section. Spring blades in the air stream distribute and atomise the water. A ring-shaped air baffle plate (24) at the end of the duct directs the air flow and allows the mixing of a bypass airstream (6b) with the main air stream.

Description

The invention relates to a snow cannon Preamble of claim 1.

To ensure the ski season and the ability to drive downhill stretch or slopes even in the absence or not Rough snowfall is becoming increasingly common today Snow cannons used. To get enough snow and to be able to produce in good quality is at Snow cannons required by the blower the main airflow generated additional germs, and in the form of small ice particles or ice crystals that then the formation of snow from the airflow bring in, finely divided water particles, and when carrying the water particles in the out airflow emerging from the outlet side of the housing.

Known snow cannons are used to generate the germs special nozzles provided with water and compressed air be acted upon, so that in the out of these nozzles escaping, expanding compressed air from the fine ver divided water to form germs. However, this is disadvantageous u. a. that a to generate the compressed air at the snow cannon Compressor as well as an air cooler are necessary to the to generate the required compressed air. The compressor needs high performance, which is essential for the operation of the snow cannon necessary power increases, what with installed in the area or mobile snow cannons is not desirable. Does that happen Cooling the compressed air to reduce the power required through the air flow generated by the blower of the snow cannon, this results in an increase in the air flow Thermal energy and thus a deterioration in performance or properties of the snow cannon, especially with kri table weather conditions, d. H. at temperatures around the Freezing point.  

The object of the invention is to show a snow cannon, those with reduced energy consumption even with critical ones Weather conditions still produce snow in optimal quality and large amount allowed.

A device is appropriate for solving this task the characterizing part of claim 1 is formed.

The formation takes place in the snow cannon according to the invention the seedlings without a the purchase and operating and Maintenance cost of the snow cannon increasing compressor Surprisingly, in that a partial air flow flow through auxiliary nozzle forms an expansion chamber in which the seedlings by spraying finely divided water (Ice particles or ice crystals), which then on the Outlet side or outlet opening of the auxiliary nozzle or the Expansion chamber through the faster, flowing around the nozzle Main stream entrained and distributed in this main stream will.

The invention avoids additional, energy consuming and / or heat-releasing functional elements, in particular the Air compressor and the air cooler of known snow cannons.

With a variety of "normal" water outlet nozzles in the snow cannon according to the invention preferably one or but several auxiliary nozzles are provided.

Further developments of the invention are the subject of the Unteran claims.

The invention is illustrated below on the basis of the figures Embodiment explained in more detail. Show it:

Figure 1 is a simplified schematic representation of a snow cannon according to the invention.

Figure 2 is an enlarged view of a nozzle assembly for use in the snow gun to produce seedlings.

Fig. 3 in an enlarged view another nozzle arrangement for use in the snow cannon for the production of seedlings.

The snow cannon 1 shown in the figures essentially consists of a tubular housing 2 , which is open at its two end faces 3 and 4 , ie there is essentially only a protective grille, not shown. The housing 2 delimits an air channel narrowing towards the end face 4 and is pivotable or adjustable on a fixed or mobile frame 5 about a horizontal axis perpendicular to the longitudinal axis L of the housing L and a second vertical axis.

Ambient air is drawn in via the open end face 3 . This end face thus forms the suction area of the snow cannon 1 and the housing 2 . On the likewise open end face 4 , the ambient air is blown out and water is sprayed into the air flow 6 to form the artificial snow.

A fan wheel 7 is provided in the interior of the housing 2 , which is rotatably mounted about an axis coaxially with the longitudinal axis L and is driven by an electric motor. In the illustrated embodiment, the main air flow 6 a through the housing 2 generating fan 7 is arranged so that it is closer to the rear end face 3 of the housing 2 than the front end face 4 .

In the area of the end face 4 , a plurality of distribution lines concentrically enclosing the axis L are provided, of which only two distribution lines 8 and 9 are shown in the illustrated embodiment. The distributor line 8 is located inside the housing and the distributor line 9 outside the housing 2 in each case in the immediate vicinity of the end face 4 and follow one another in the direction of the longitudinal axis L. However, other arrangements of the distribution lines are also possible, for example in the form that at least some of these distribution lines are provided concentrically with one another on the end face 4 outside or inside the housing. Each distributor line 8 and 9 is part of a nozzle arrangement and for this purpose is provided with a multiplicity of water outlet nozzles 10 , which are distributed evenly around the longitudinal axis L on each distributor line or are provided in a different manner. The water outlet nozzles 10 are oriented to the distributor lines 8 and 9 so that they introduce water in finely divided form, ie finely atomized, into the air stream 6 on the end face 4 .

The distribution lines 8 and 9 are connected to a supply line for supplying water under pressure via control or solenoid valves not specified. The valves are preferably controlled by an electronic control device, also not shown.

In conventional snow cannons, in addition to the distribution lines for water, a further distribution line for compressed air is provided, which is connected to a compressed air source (compressor) and via which some air pressure nozzles, which also serve for the exit of water, are simultaneously acted upon by seedlings to form, which are essential so that snow actually forms from the sprayed water within the air flow 6 or within the range of the snow cannon determined by this air flow. The air compressor used requires a lot of energy. Furthermore, complex cooling of the compressed air generated is also necessary in order to be able to produce snow even at relatively high ambient temperatures, for example at temperatures around or slightly above freezing point.

The snow cannon 1 shown in FIG. 1 avoids such a compressor. To form the seedlings from finely divided, frozen water is used in this embodiment form an auxiliary nozzle 11 , which is provided within the housing 2 on the open end face 4 , in which the housing 2 by flowing main air stream 6 a.

The auxiliary nozzle 11 is shown in detail in FIG. 2. It consists in the embodiment shown of a nozzle ring 12 , which has its axis L 'coaxially with the longitudinal axis L of the housing 2 or parallel to this longitudinal axis, but in any case is arranged in the direction of flow A of the main stream and is made of metal. The nozzle ring 12 has, for example, the cross-sectional profile shown in Fig. 2, which is essentially characterized in that the nozzle ring 12 in the sectional plane including the longitudinal axis L 'has a convexly curved inner surface 13 over its entire course such that the inner diameter of the the nozzle ring 12 from that shown in Fig. 2 below Darge set inlet opening at which the partial air stream 6 enters a 'in the of the nozzle ring 12 and the inner surface 13 limited annular diffusion channel 14, a first decreasing diameter and then to that shown in Fig , has a strongly increasing diameter exit aperture shown above. 2 to which the partial air stream 6 exits a 'out of the nozzle ring or from the annular channel 14 again. The diameter is larger at the outlet opening than at the inlet opening. The radius of curvature, which the intersection line of the inner surface 13 with the intersection plane of FIG. 2 has, decreases from the inlet opening to the outlet opening, so that this intersection line has an involute or spiral shape. In the illustrated embodiment, the nozzle ring 12 is also slightly convexly curved on the outer surface 15 , but with a radius of curvature that is substantially larger than the radius of curvature of the inner surface 13 .

In the nozzle ring 12 , a nozzle body 16 is arranged centrally, which is shaped on its outer surface 17 so that the profile of the nozzle body 16 in the sectional plane of FIG. 2 of the inner surface 13 is shaped accordingly and the outer diameter of the nozzle body 16 decreases toward the outlet opening, so that the cross section of the nozzle body 16 enclosing the annular channel 14 from the inlet opening is initially narrowly narrowed and then greatly enlarged, an expansion space 14 'is formed at the outlet opening of the nozzle ring 12 '. In the nozzle body 16 nozzle openings 18 are formed, which open into the expansion space 14 'and are connected to a channel 19 formed in the nozzle body, which is connected to the pressurized water supply line, again via the control valves already mentioned above.

The partial air flow 6 a flowing through the nozzle ring 12 'expands in the expansion space 14 ', thereby undergoes cooling, so that water emerging from the nozzle openings 18 and atomized in the air flow in the expansion space 14 'or in the partial air flow 6 a' has a large number of Germs or ice crystals 20 is generated, which is then swirled by vortex formation in the faster main air stream 6 a flowing past the auxiliary nozzle 11 and carried along finely distributed in this main air stream, which in turn is narrowed by the cross section narrowing from the end face 3 to the end face 4 of the housing 2 to which the air flow 6 is bundled and accelerated in the required manner.

Fig. 3 shows as a further possibility an auxiliary nozzle 11 a with a nozzle body 16 a, which corresponds in its outer shape to the nozzle body 16 , but consists of several in the longitudinal direction L 'of this auxiliary nozzle 11 a adjoining rotationally symmetrical elements 21 , between each two adjoining elements 21 a longitudinal axis L 'concentrically enclosing annular gap 22 is formed, each of which is connected to the nozzle channel 16 and forms the nozzle opening. In the embodiment shown, a total of four annular gaps 22 are provided. It is understood that the number of these annular gaps and their arrangement can also differ from the embodiment shown in FIG. 3. On the circumference of the nozzle body 16 a, a plurality of tongues 23 made of a resilient material, for example made of spring sheet metal, are also provided, which are clamped or fastened at one end to the nozzle body 16 a, for example in an annular gap 22 , and otherwise over the peripheral surface of the nozzle body 16 stand away.

The mechanical characteristics of the tongues 23 , that is, their length, mass, spring constant, etc. are so matched that the tongues 23 are violently set into natural vibrations (resonant vibrations) by the partial flow 6 a ', so that the vibrating tongues 23 from the nozzle openings or annular gaps 22, water which is already finely distributed in any case is additionally atomized particularly finely by the vibrating tongues 23 by being smashed. The auxiliary nozzle 11 a in turn is used to generate germs or ice crystals len 20 in the main stream 6 a.

In Fig. 1 is indicated with 6 b, a secondary air flow, which is generated in that in the area of the outlet side or end face 4 of the snow cannon 1 a in the flow direction A following the opening of the end face, designed as a frustoconical ring air baffle 24 is provided which is arranged concentrically to the axis L and has a diameter which decreases in the flow direction A.

The air baffle 24 is further arranged so that an annular air inlet opening 25 is formed between it and the housing 2 , ie between the end of the air baffle 24 with a larger diameter and the end face 4 of the housing 2 , through which a side stream 6 b flows, the together with the main stream of the air flow 6 a. 6 In the area of the opening 25 there are further nozzles, for example nozzles corresponding to the water outlet nozzles 10 or the auxiliary nozzles 11 or 11 a.

With 26 still a lattice or lamellar air guide or distributor element is referred to, which is arranged inside the casing 2 perpendicularly to the longitudinal axis L between the fan 7 and the auxiliary nozzle 11 and serves as uniform as possible distribution of the air flow on the whole cross-section of the To reach the housing or in particular also in the vicinity of the longitudinal axis L, ie where the auxiliary nozzle 11 is provided, to achieve a sufficiently high air flow.

The invention has been described above using exemplary embodiments describe. It is understood that changes as well as variance lungs are possible without thereby of the invention underlying inventive concept is left.

Reference list

1 snow cannon
2 housings
3 , 4 end face
5 frame
6 airflow
6 a main current
6 a ′ partial flow
6 b partial flow
7 fan wheel
8 , 9 distribution line
10 water outlet nozzle
11 , 11 a auxiliary nozzle
12 nozzle ring
13 inner surface
14 ring channel
14 ′ expansion room
15 outer surface
16 , 16 a nozzle body
17 outer surface
18 nozzle opening
19 channel
20 seedling
21 element
22 Annular gap
23 tongue
24 air baffle
25 opening
26 air guide or distributor element

Claims (15)

1. Snow cannon with at least one open-ended air duct housing ( 2 ), with a fan arranged in the air duct and driven by a motor ( 7 ) for generating a main air flow ( 6 a) through the housing, with at least one water outlet nozzle ( 10 ) in Air duct, preferably at or in the area of an opening ( 4 ) on the air duct side, for bringing water in finely divided form into the main air stream ( 6 a) generated by the blower ( 7 ), and with at least one auxiliary nozzle ( 11 , 11 a) for introducing seedlings or ice crystals ( 20 ) produced in expanding air from water into the main air stream ( 6 a), characterized in that the auxiliary nozzle ( 11 , 11 a) at least one of a partial air stream ( 6 a ') of the main air stream ( 6 a) has a diffusion channel ( 14 ) through which there is at least one expansion chamber ( 14 ') opening into the main or air flow with an increasing Qu section forms, and that at least one nozzle opening ( 18 , 22 ) is provided for the finely divided introduction of water into the diffusion channel or into the expansion space ( 14 '). 2. Snow cannon according to claim 1, characterized in that several forming a common expansion chamber Diffusion channels are provided. 3. Snow cannon according to claim 1 or 2, characterized in that the at least one expansion space ( 14 ') forming diffusion channel ( 14 ) has at least one inlet opening for the partial flow ( 6 a'). 4. Snow cannon according to one of claims 1-3, characterized in that the at least one diffusion channel ( 14 ) with the expansion space ( 14 ') are formed in a nozzle ring ( 12 ). 5. Snow cannon according to claim 4, characterized in that the nozzle ring ( 12 ) has an inner cross section which extends at least over part of the axial length of the nozzle ring ( 12 ) to form the expansion space ( 14 ') in the flow direction (A) of the partial streams ( 6 a ′) enlarged. 6. Snow cannon according to claim 4 or 5, characterized in that the inner surface of the nozzle ring ( 12 ) in the axis of the nozzle ring enclosing cuts is convex, preferably such that the radius of curvature with increasing distance from the air inlet opening of the nozzle ring ( 12 ) enlarged to the air outlet opening of this ring. 7. Snow cannon according to one of claims 1-6, characterized in that the nozzle ring ( 12 ) on its outer surface ( 15 ) in the longitudinal axis (L ') enclosing cuts is convex. 8. Snow cannon according to one of claims 1-7, characterized in that the diffusion channel is an annular channel ( 14 ). 9. Snow cannon according to one of claims 1-8, characterized marked by a nozzle ring ( 12 ) enclosed nozzle body ( 16 , 16 a), on which the nozzle openings ( 18 , 22 ) are provided. 10. Snow cannon according to one of claims 1-9, characterized in that the nozzle body ( 16 , 16 a) has a decreasing external cross section in the flow direction (A) of the partial flow ( 6 a '). 11. Snow cannon according to one of claims 1-10, characterized in that the nozzle ring ( 12 ) and / or the nozzle body ( 16 , 16 a) are rotationally symmetrical to a longitudinal axis (L ') of the auxiliary nozzle ( 11 , 11 a). 12. Snow cannon according to one of claims 1-11, characterized in that on the outer surface of the nozzle body ( 16 ) a plurality of resilient elements, for example resilient tongues ( 23 ) are provided, which are set into vibrations by the partial flow ( 6 a ') and effect a distribution or atomization of the water emerging from the nozzle openings ( 18 , 22 ). 13. Snow cannon according to one of claims 1-12, characterized in that the at least one auxiliary nozzle ( 11 , 11 a) is arranged coaxially with the central axis (L) of the housing ( 2 ). 14. Snow cannon according to one of claims 1-12, characterized in that at least one auxiliary nozzle ( 11 , 11 a) with respect to the axis (L) of the housing ( 2 ) is arranged radially offset. 15. Snow cannon according to one of claims 1-14, characterized in that at least one water outlet nozzle ( 10 ) and / or an auxiliary nozzle ( 11 , 11 a) in one at the outlet opening ( 4 ) of the snow cannon from the side into the main stream incoming partial stream ( 6 b) is arranged.