DE19813359A1 - Method and device for producing snow - Google Patents

Abstract

A continuously operating flake ice producer (3) is positioned on a mobile or stationary frame (1), and cooperates with a blower and mixer unit (16) with housing open at the top. The flake-ice producer consists of a cylindrical drum (4) whose inner surface is in the form of a cooling casing moistened with water to form a layer of ice. The layer of ice is continuously scraped off by an ice-scraper rotating on the drum's center lengthwise axis. The ice is removed in the form of flake ice (15). Pressurized air enters by an inlet (20) opposite an outlet (21).

Description

The invention relates to a method and an apparatus for Production of snow according to the generic term of the independent Claims.

So-called snow cannons are known from the prior art Known snow production. Such snow cannons to ensure snow reliability in ski areas used. The disadvantage of the snow cannons known so far is that this only at temperatures around freezing or including being able to produce snow. This is due to the principle of snow production. With snow cannons, water becomes finely atomized and blown out by a blower, whereby this water at a correspondingly low ambient temperature crystallizes and precipitates as snow. disadvantage is, as already indicated above, that such Snow cannons only in the area below freezing work.  

The present invention is based on the object Method and device for producing snow propose with which, essentially independent of the ambient temperature, snow is produced directly on site can be.

The task is set by the characteristic features of the independent claims.

The invention is based on the fact that by means of a suitable Device in a known manner and continuously flake ice is generated, which in a mixing and blowing unit Air is mixed and blown into the environment.

Flake ice production is preferably carried out in an active cooled drum and is essentially of the Ambient temperature independent.

The entire device is preferably a mobile device trained and has sliding shoes or rollers, so that they for snow production can be transported directly on site. Training as a stationary device is also possible.

The flake ice machine preferably consists of a cylindrical drum, the inner surface of which acts as a cooling jacket is formed, which is wetted with water, so that forms a layer of ice, which by means of a Central longitudinal axis of the rotating ice scraper is scraped off continuously and removed as flake ice can be. The thickness (thickness) of the flake ice can be by regulating the water supply and the speed of the Change ice scraper in wide areas.

A significant increase in flake ice production is in a preferred embodiment achieved in that in the At least one drum coaxial to the outer cooling jacket  second, inner cooling jacket is arranged, both on its radially inner as well as its radial external surface is wetted with water. As with the outer cooling jacket, here too ice scraper wet with water assigned which around the central longitudinal axis of the drum rotate and scrape off the ice that forms on the cooling jacket. By using a second, inner cooling jacket the ice production rate is around Increase area ratio factor 3.

The mixing and blowing unit is intended to Crush flake ice and mix with air so that the volume is increased and a blowing out of the "snow" to the environment. To do this, the mixing and Blower unit on an open housing, in which a rotatably driven cellular wheel is arranged. At the bottom There is an injection opening for the area of the housing the supply of compressed air and approximately opposite the Blow-in opening a blow-out opening. Depending on the position of the Cell wheel of the mixing and blowing unit forms between the housing and the webs of the cellular wheel a cavity that compressed air is applied through the injection opening, so that the contained snow flake with air is mixed and blown out through the blow-out opening. This makes it possible to cover the snow Hose lines over 100 m and more, depending Compressor capacity to carry (increased mobility).

In a preferred embodiment, the flake ice by means of a conveyor from the flake ice machine to Mixing and blowing unit transported. Of course it is provided that the mixing and blowing unit directly on the Flake ice machine is arranged so that the The conveyor is not required.  

The cooling jackets are cooled by means of a Refrigerator, which the cooling jackets with refrigerant fluid provided.

Depending on the capacity and size of the snow gun provided the energy supply for driving the Motors, for the generation of compressed air, for driving the Refrigeration generator, etc., as a separate transportable unit to train. The supply is essentially independent from the energy source, e.g. B. voltage from the grid, current generator, Hydraulic power transmission etc. This has the advantage that smaller units are formed, which are also separate easier to transport and station on the ski slope to let.

The main advantage of the invention is the ability to snow too to produce at temperatures above freezing, and the Mobility of the entire system, which means that the snowing area can be positioned. Because the device has an active cooling system and generates snow, for example minus 20 ° Celsius, the consistency of the produced Snow much better than with conventional snow cannons. This means that the snow produced even at higher ones Temperature has a very good durability. A very great benefit of the invention lies in securing the Snow reliability of the ski areas in spring, too warmer temperatures. Loss in sales, e.g. B. because of locked Valley runs can be avoided.

Another area of application is the trend Indoor ski arenas that are inexpensive with such a device can be supplied with high quality snow.

The invention is based on a Embodiment with reference to several Drawing figures explained in more detail.  

It shows:

Fig. 1: A schematic side view of the snow gun with the most important components;

Fig. 2: A cross section through the mixing and blowing unit;

Fig. 3: A longitudinal section through the double-shell broken ice maker;

Fig. 4: A cross section through the double-shell broken ice maker;

Fig. 5: A schematic representation of the transport of the snow gun.

Fig. 1 shows the mobile snow gun, consisting of a frame structure 1 , which is provided with skids 2 or wheels (not shown). This frame structure 1 carries the various assemblies of the device, the frame structure 1 being clad by metal or plastic sheets (not shown) during operation.

The centerpiece of the snow gun is the flake ice maker 3 , which consists of an actively cooled drum 4 , which is supplied with water via a water meter 6 and the water supply 7 . The water supplied freezes to ice on the inner wall of the drum 4 and is released by means of ice scrapers which are driven in rotation by a drive 5 .

A cooling generator 8 is provided as cooling for this drum 4 . This delivers a cooled cooling fluid, which is fed to the flake ice generator 3 via the line 12 and leaves the drum 4 again via the line 11 .

Between the flake ice generator 3 and the cooling generator 8 , a heat exchanger 9 is provided, which cools the cooling fluid before entering the cooling generator 8 . A fan 10 can be provided to support the cooling capacity. If there is an increased cooling requirement, several heat exchangers can also be provided.

The flake ice produced by the flake ice 3 15 exits at the bottom of the drum 4 and falls on a conveyor 14 which conveys the flake 15 in direction 24, and a mixing and blowing unit 16 feeds. As can be seen in FIG. 2, the mixing and blowing unit 16 comprises a housing 22 in which a cellular wheel 17, which is driven to rotate in the direction of rotation 23 , is arranged. The flake ice 15 is fed by the conveyor device 14 and passes through an opening into the housing 22 and into the individual chambers of the cellular wheel 17 . The cellular wheel is driven by a motor 18 . Due to the mechanical action of the cellular wheel 17 , the flake ice 15 is somewhat crushed and reaches the lower region of the housing 22 , where an injection opening 20 is arranged, which is connected to a compressed air generator 19 via a pipeline. The compressed air generated passes through the blowing opening 20 into the lower region of the housing 22 and the corresponding chamber of the cellular wheel 17 , the crushed flake ice 15 being mixed with air and being blown out as snow to the surroundings through a blowing opening 21 opposite the blowing opening 20 . A hose line can be connected to the blow-out opening 21 , so that the snow can be blown specifically to the place of use.

FIGS. 3 and 4 show a longitudinal section and cross section through the double-jacketed 3 Flake ice. The flake ice machine consists of an approximately cylindrical drum 4 , in which an outer cooling jacket 26 and at least one inner cooling jacket 27 are arranged coaxially, through which cooling fluid flows, which is supplied by the cooling generator 8 . The water required for flake ice production passes from the water metering device 6 via the water supply 7 into a water collecting basin 28 and from there via openings 29 to the individual water distributors 30 a, 30 b and 30 c, which are distributed in several over the circumference of the drum. These water distributors end in the upper region of the cooling jackets 26 , 27 and wet the respective surface in that the water runs down along the cooling jackets and freezes to a thin layer of ice. Excess water gets into a collecting trough 31 and is in turn fed to the water metering device 6 . Three surfaces of the cooling jackets 26 , 27 are wetted, namely the inner surface of the outer cooling jacket 26 and the inner and outer surfaces of the inner cooling jacket 27 . The resulting ice layer is scraped off by an ice scraper 32 , 33 , 34 assigned to the surfaces of the cooling jackets 26 , 27 . The ice scrapers are fastened by means of a holding arm 37 to a shaft 25 which is driven in rotation by a drive 5 . Due to the continuous wetting of the surfaces of the cooling jackets 26 , 27 , an ice layer is continuously formed, which is cyclically scraped off by means of the rotating ice scrapers 32 to 34 , so that thin ice flakes, referred to in professional jargon as flake ice, form. As can be seen in FIG. 4, the ice layer on the cooling jackets is freed of excess water by scrapers 35 , 36 before being scraped off by the ice scrapers 32 to 34 . The pullers or the ice scrapers rotate in the direction of rotation 38 .

The drum 4 of the flake ice maker 3 is largely open at the bottom, so that the scraped flake ice 15 falls out of the drum in the direction of arrow 39 and is available for further use.

FIG. 5 illustrates the mobility of the snow generator 41 according to the invention, which is equipped with runners 2 or wheels and can thus be pulled to the place of use by a suitable tractor 40 , in the example of a snow groomer. In order to ensure better mobility of the unit, the energy generation for the snow generator 41 can be carried out by a separate unit 42 . In the case of snow generators of lower capacity, this energy generation 42 can also be integrated.

Reference list

1

Frame arrangement

2nd

Skid

3rd

Flake ice machines

4th

drum

5

drive

6

Water dispenser

7

Water supply

8th

Refrigeration equipment

9

Heat exchanger

10th

fan

11

management

12th

management

13

management

14

Conveyor

15

Flake ice

16

Mixing and blowing unit

17th

Cell wheel

18th

drive

19th

Compressed air generator

20th

Injection opening

21

Discharge opening

22

casing

23

Direction of rotation

24th

Direction of conveyance

25th

wave

26

Cooling jacket (outside)

27

Cooling jacket (inside)

28

Pool

29

openings

30th

ac water distributor

31

Collecting trough

32

Ice scraper

33

Ice scraper

34

Ice scraper (outside)

35

Puller

36

Puller (outside)

37

Holding arm

38

Direction of rotation of the scraper, puller

39

Arrow direction

40

tractor

41

Snow gun

42

Energy producer

Claims (16)

1. A method for producing snow, characterized in that flake ice is produced in a known manner and continuously by means of a suitable device, which is mixed with air in a mixing and blowing unit and blown out. 2. The method according to claim 1, characterized in that the snow is generated directly at the place of use. 3. The method according to any one of claims 1 or 2, characterized characterized in that a generation of snow also at Ambient temperatures above freezing is possible. 4. The method according to any one of claims 1 to 3, characterized characterized in that depending on the position of the cellular wheel Mixing and blowing unit between the housing and the webs of the cellular wheel forms a cavity which over a Injection opening is pressurized with compressed air, so that the Flake ice mixed with air and through a blow-out opening is blown out. 5. Apparatus for producing snow, characterized by a frame arrangement ( 1 ) with a flake ice generator ( 3 ) arranged thereon for the continuous production of flake ice and a blowing and mixing unit ( 16 ) for crushing, mixing with air and blowing out the flake ice. 6. The device according to claim 5, characterized in that the frame arrangement ( 1 ) is mobile or stationary. 7. Apparatus according to claim 5 or 6, characterized in that the flake ice generator ( 3 ) consists of a cylindrical drum ( 4 ) whose inner surface is designed as a cooling jacket ( 26 ) which is wetted with water, so that an ice layer forms , which is scraped off continuously by means of an ice scraper ( 34 ) rotating about the central longitudinal axis of the drum ( 4 ) and can be removed as flake ice ( 15 ). 8. Device according to one of claims 5 to 7, characterized in that in the drum ( 4 ) coaxially to the outer cooling jacket ( 26 ) at least one inner cooling jacket ( 27 ) is arranged, both on its radially inner and on its radially outer Surface is wetted with water. 9. Device according to one of claims 5 to 8, characterized in that the radially inner and the radially outer surface is assigned an egg scraper ( 32 , 33 ) which rotates about the central longitudinal axis of the drum ( 4 ) and forms flake ice ( 15 ) . 10. Device according to one of claims 5 to 9, characterized in that the mixing and blowing unit ( 16 ) has an open-topped housing ( 22 ) in which a rotatingly driven cellular wheel ( 17 ) is arranged. 11. Device according to one of claims 5 to 10, characterized in that in the lower region of the housing ( 22 ) an injection opening ( 20 ) is arranged for the supply of compressed air and approximately opposite the injection opening ( 20 ) has a blow-out opening ( 21 ). 12. Device according to one of claims 5 to 11, characterized in that the mixing and blowing unit ( 16 ) is arranged directly below the flake ice machine ( 3 ). 13. Device according to one of claims 5 to 11, characterized in that a conveyor ( 24 ) is arranged below the flake ice generator ( 3 ), which receives the flake ice produced ( 15 ) and transports it to the mixing and blowing unit ( 16 ). 14. Device according to one of claims 5 to 13, characterized in that a cooling generator ( 8 ) is provided which supplies the cooling jackets ( 26 , 27 ) with cooling fluid. 15. Device according to one of claims 5 to 14, characterized in that the frame arrangement ( 1 ) is designed as a trailer with rollers and / or runners ( 2 ). 16. The device according to one of claims 5 to 15, characterized in that a separate energy generator ( 42 ) is provided for supplying the device with energy.