RU2505759C1 - Artificial snow generation device - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: device for generation of artificial snow by means of a snow cannon, in which water is atomised by compressed air that is supplied with a compressor to a compressor zone that has an inlet air supply hole to the compressor zone and an outlet compressed air supply hole to the snow cannon. Compressed air is supplied through the primary circuit of the heat exchanger, the secondary circuit of which forms some part of an evaporator in a closed cooling circuit, in which cooling agent circulates by means of a compressor element actuated by an actuator. The device includes a controller to provide the desired temperature or pressure of dew point at the outlet of the primary section of the heat exchanger.

EFFECT: use of this invention allows generating high-quality snow and reducing total snow generation time.

13 cl, 1 dwg

Description

FIELD OF THE INVENTION

This invention relates to a device for the production of artificial snow.

State of the art

Devices for the production of artificial snow are already known; These devices use water and compressed air, with which water is sprayed in the compressed gas and the sprayed water is frozen due to the cooling effect that occurs when the air expands.

The currently known devices for supplying compressed air use a compressor.

It is known that compressed gas, which usually consists of air, can have a very high temperature at the outlet of this compressor and can also have a high moisture content.

Known devices may also include one or more secondary chillers for cooling compressed air, so that moisture in the compressed air condenses as a result of cooling and can be separated in the form of condensate using a water separator or similar device.

These secondary coolers are usually constructed as air-to-air recuperative heat exchangers in which the heated compressed air entering the inlet is cooled by compressed air that has already been cooled.

Known devices are installed in a building with significant dimensions, in which the compressor is located, and with the help of which the compressor is connected to the outside air to supply air to be compressed, while the output of the compressor unit is connected to a snow cannon (snow generator) for supplying compressed air.

The pipelines used to implement the above compounds are sized so as to dissipate heat from the compressed air into the surrounding space in the aforementioned building and to use this heat to heat the sucked-in cold air.

The disadvantage of this installation is that it has a significant size and does not have mobility.

Another disadvantage is that the temperature of the compressed gas at the inlet of the snow cannon is difficult to control.

A related disadvantage is that the quality of the snow produced depends on weather conditions, so that such a device has a relatively low reliability.

Improved installations are also known in which there is an additional heat exchanger installed after the secondary cooler to control the temperature of the compressed air at the outlet.

Their disadvantage is that such a device allows only primary temperature control, so it is impossible in all possible conditions to ensure high quality of the resulting snow.

Another disadvantage is that this heat exchanger cannot prevent moisture condensation in the secondary cooler and its freezing in the secondary cooler.

Another additional disadvantage is that known devices consume a lot of electricity.

Disclosure of invention

The purpose of the present invention is to provide a technical solution to eliminate the above and / or other disadvantages of existing systems by developing a device for producing artificial snow using a snow gun in which water is sprayed with compressed air, the device is equipped with a compressor for supplying compressed air, and this compressor is placed in the compressor zone having an inlet for supplying air from the environment and an outlet for supplying compressed air to the snow cannon using a pipeline, moreover, according to a particular characteristic of the present invention, the aforementioned device includes a heat exchanger having a primary circuit and a secondary circuit, by means of which compressed air from the compressor is directed through the primary circuit, and the aforementioned secondary circuit forms part of an evaporator of a closed cooling circuit in which the refrigerant is circulated by a compressor element driven by a drive, the aforementioned device including a controller for controlling using the aforementioned refrigerant circuit in order to obtain the desired temperature or pressure of the dew point at the outlet of the primary portion of the heat exchanger.

An advantage of the invention is that the temperature of the compressed air at the outlet of the primary circuit of the heat exchanger can be fully adjustable, so that the snow produced is always of very good quality, and the quality of the snow does not depend on weather conditions.

The present invention allows precise control of the refrigerant circuit so that the desired temperature and / or the desired pressure of the dew point of the compressed air are achieved.

Another advantage of this invention is that this device is relatively more compact compared to known devices.

A related advantage is that such a device is cheaper, not only in terms of installation costs, but also in relation to the energy it consumes.

In the most preferred from a practical point of view embodiment of the present invention, the device can be installed in a container, and thus it can be made in the form of a mobile device.

The advantage of this is that the container can be easily transported, so that the device can supply compressed air to produce snow in various places, and accordingly, a relatively large branch piping system is not required for connecting various snow cannons with one centralized device for supplying compressed air.

In a practical embodiment of the present invention, the cooling circuit comprises a second heat exchanger that forms a condenser of the cooling circuit and which is located downstream of the compressor element and upstream of the expander available in the cooling circuit.

In a most practical embodiment of the invention, the refrigerant flowing through this second heat exchanger is cooled by a fan. Preferably, the aforementioned fan is installed so that it blows air through a second heat exchanger up to the compressor zone.

An additional advantage of this technical solution is that the fan distributes warm air in the compressor zone, so that the temperature in the compressor zone is kept above 0 °, which eliminates freezing, and damage caused by freezing can be completely eliminated.

An additional advantage is that there is no need to use excessively large pipelines between the outlet of the primary portion of the heat exchanger and the inlet of the snow cannon.

Preferably, the temperature of the compressed air at the outlet of the primary circuit of the heat exchanger is less than 8 ° C and preferably about 3 ° C.

The advantage is that in this temperature range it is possible to produce high quality snow and the overall snow production time is reduced.

Preferably, compressed air at the outlet of the primary circuit of the heat exchanger is supplied with a pressure of 8 bar or about 8 bar.

Preferably, the air is compressed using a compressor that does not use oil, such as a screw compressor with water injection.

The advantage of this solution is that the compressed air cannot be contaminated with oil particles, so there is no need to pass this compressed air through one or more filters, and this, of course, has a positive effect on the overall cost and overall dimensions of the device.

Thanks to the use of a compressor with water injection, the risk of air pollution itself can be completely avoided.

The implementation of the invention

In order to more clearly demonstrate the characteristics of the present invention, a preferred embodiment is described below, without limiting its scope, based on an example of a device in accordance with this invention with reference to the attached drawing, which shows a device for the production of artificial snow in accordance with this invention.

Device 1 for the production of artificial snow consists primarily of a compressor zone 2 having a housing 3, which has an inlet 4 for supplying air from the environment and an outlet 5 for discharging compressed gas, such as air.

In a practical embodiment of the invention, the housing 3 is formed by a container, which may be mobile or made in the form of a building or similar structure.

The dimensions of the housing 3 can, for example, be limited in terms of 6 m to 6 m, in contrast to existing devices housed in a building whose dimensions are tens of meters in length and width.

There is a protective grill in the wall of the casing 3, which forms an inlet 4 through which the ambient air is sucked in in the direction shown by the arrow L. In the casing 3 there is the aforementioned outlet 5 through which compressed air can be supplied via line 7 to the snow cannon 6.

The snow cannon 6 also has a supply pipe 8 for water, so that water is sprayed with compressed air in a well-known manner at the outlet of the snow cannon 6, resulting in the formation of snow crystals that are ejected from the nozzle of the snow cannon 6.

For the production of compressed air, there is a compressor 9 with a compressor zone 2 having an inlet for suctioning air and an outlet 11 for discharging compressed air.

The aforementioned compressor 9 is driven in a known manner by means of a drive 10, which may be, but not necessarily, an electric motor.

The aforementioned compressor 9 may consist of a single compressor element, as shown in the drawing, but may also be a multi-stage compressor in which air is compressed by a series of compressor elements arranged in series.

In a specific embodiment of the invention, the compressor 9 comprises only water injection compressor elements, secondary coolers may be located between successive stages of discharge. Of course, this invention is not limited only to such a scheme, since a different type of compressor can be used without using oil, or an oil injection compressor equipped with an appropriate filtration system.

In a preferred embodiment of the invention, the compressor 9 is adjusted to a maximum working pressure in the range between 8 bar and 9 bar, and it is preferable that the maximum working pressure be 8.5 bar or close to 8.5 bar.

According to the present invention, a heat exchanger 12 is installed in the compressor zone 2 for cooling the compressed air and having a primary circuit and a secondary circuit, the inlet 13 of the primary circuit of the heat exchanger being connected to the outlet 11 of the compressor 9.

Preferably, the heat exchanger 12 is designed such that the pressure drop of the compressed air passing through the primary circuit is less than 0.2 bar, and preferably less than 0.1 bar, and preferably even less than 0.05 bar.

It is known that as a result of lowering the temperature, the moisture contained in the compressed air will condense.

Preferably, at the outlet 14 from the primary circuit of the heat exchanger 12, a moisture separator 15 is installed, which can remove the condensed water.

According to the present invention, the secondary circuit of the aforementioned heat exchanger 12 forms an evaporator 16 of a closed cooling circuit 17, which is filled with refrigerant or coolant.

As is known, the refrigerant is circulated by the compressor element 18 in the cooling circuit 17, and this compressor element is driven by the drive 19.

In addition, in a closed cooling circuit 17 between the outlet of the compressor element 18 and the secondary circuit of the heat exchanger 12, a condenser 20 and an expander are arranged in series, for example in the form of an expansion valve 21.

In a practical embodiment of the invention, the aforementioned condenser 20 is formed by a second heat exchanger, and this second heat exchanger is cooled by a fan 22, which blows air through the condenser 20, and this air is then blown into the compressor zone 2.

In a most preferred embodiment of the present invention, the rotational speed of the aforementioned fan 22 may be controlled to control the temperature of the refrigerant at the outlet of the condenser 20. To this end, the aforementioned fan may, for example, be driven by a speed-controlled electric motor that is connected to the unit control, to which are also connected measuring instruments for measuring the aforementioned temperature at the output of the capacitor, in the form of a temperature sensor installed in the pipeline between the expansion valve 21 and the condenser 20.

In a practical embodiment of the invention, the expansion valve 21 may be in the form of a thermostatic or electronic valve, and this valve 21 is connected to a temperature sensor 23, which is located at the outlet 14 of the primary circuit.

According to this invention, the device is equipped with a controller 24 for controlling the flow of refrigerant, and the aforementioned controller 24 maintains the desired temperature or pressure of the dew point at the outlet 14 of the primary circuit of the heat exchanger 12.

The controller 24 can, therefore, regulate the speed of rotation of the drive 19, and the drive can be performed, for example, in the form of an electric motor with frequency regulation of the speed of rotation.

The controller 24 can also be used to control the motor of the fan 22 and / or to regulate the expansion valve 21, and possibly to control the drive 10 of the compressor 9.

Obviously, to control the temperature or pressure of the dew point, one of the possibilities is to control the drive 10 of the compressor 9, but other control methods are possible.

Preferably, between the outlet 11 of the compressor 9 and the inlet 13 of the primary circuit of the heat exchanger 12, a secondary cooler 25 and a second water separator 26 are installed.

The method of producing artificial snow by means of the device 1 according to this invention is very simple and is as follows.

A gas, such as air, is sucked into the compressor zone 2 and compressed by the compressor 9. The hot compressed air is first passed through a secondary cooler 25 and a second water separator 26, after which this already partially cooled gas is directed through the primary circuit of the heat exchanger 12, so that the compressed air at the outlet 14 of the primary circuit would have an even lower temperature.

The condensate formed in the secondary cooler 25 and the heat exchanger 12 is separated in the respective dehumidifiers 26 and 15, and then the cooled dehydrated air is supplied to the snow cannon 6 via a pipe 7. In the snow cannon 6, water will be sprayed with cooled compressed air so that snow crystals form .

The cooling of the compressed air in the primary circuit of the heat exchanger 12 is carried out by passing the refrigerant through the secondary circuit of the heat exchanger 12. It is preferable that this refrigerant flows in a direction opposite to the flow of air that flows through the primary circuit of this heat exchanger.

Passing through the secondary circuit of the heat exchanger, the aforementioned refrigerant is heated and then cooled by a condenser 20, which in this case is located immediately downstream of the compressor element 18 in the cooling circuit 17.

The temperature of the refrigerant will then decrease due to its flow through the aforementioned condenser 20, since the fan 22 blows air through this condenser 20.

The air blown through the condenser 20 by the fan 22 is heated.

Since this heated air is distributed throughout the compressor zone 2, the temperature in the compressor zone 2 will always remain above the freezing point.

The refrigerant that exits the condenser 20 is then sent through an expansion valve 21 and then fed back to the input of the secondary circuit of the heat exchanger 12.

For the heat exchanger 12 and the cooling circuit 17 connected to it via the controller 24, a conventional cooling dryer may be used if necessary, however, in this case, an air-air recuperative heat exchanger, which is usually used in such a cooling dryer, can be dispensed with.

The advantage is that the device can be made on the basis of a compressor connected to a suitable cooling dryer, which is always commercially available.

The present invention is by no means limited to the embodiment described herein by the example shown in the drawing, and the artificial snowmaking device 1 can be implemented in a wide variety of ways, without going beyond the scope of the present invention.

Claims (13)

1. Device for producing artificial snow using a snow cannon (6), in which water is sprayed using compressed air, this device includes a compressor (9) for supplying compressed air, and a compressor (9) is located in the compressor zone (2 ) with an inlet for supplying air from the environment and an outlet for supplying compressed air to the snow cannon (6) through a pipe (7), characterized in that the aforementioned device (1) includes a heat exchanger (12) with a primary circuit and a secondary contour when than the compressed air from the compressor (9) is directed through the primary circuit, and the aforementioned secondary circuit forms part of the evaporator (16) in a closed cooling circuit (17), in which the refrigerant is circulated by the compressor element (18), which is driven by the drive (19) ), the aforementioned device including a controller (24) for regulating the aforementioned cooling circuit in order to obtain the desired temperature or pressure of the dew point at the outlet (14) from the primary circuit of the heat exchanger (12). 2. The device according to claim 1, characterized in that at the outlet (14) from the primary circuit of the heat exchanger (12) a moisture separator (15) is installed, designed to remove condensed water. 3. The device according to claim 1, characterized in that the cooling circuit (17) comprises a heat exchanger (20) located downstream of the compressor element (18), the heat exchanger (20) forming a condenser of the cooling circuit (17) and this heat exchanger ( 20) is cooled by a fan (22), blowing air through a heat exchanger (20) in the compressor zone (2). 4. The device according to claim 1, characterized in that the compressor (9) compresses the air that is drawn in from the compressor zone (2). 5. The device according to claim 1, characterized in that the controller (24) controls so that the temperature at the outlet (14) from the primary portion of the heat exchanger is in the range from 3 ° C to 8 ° C, and preferably in the range from 3 ° C to 5 ° C. 6. The device according to claim 1, characterized in that the controller (24) controls so that the temperature at the outlet (14) of the primary circuit of the heat exchanger is 3 ° C or about 3 ° C. 7. The device according to claim 1, characterized in that the controller (24) controls in such a way that it maintains the pressure of the dew point to obtain a temperature of 3 ° C. 8. The device according to claim 1, characterized in that the compressor (9) is configured to provide a maximum operating pressure of 8.5 bar. 9. The device according to claim 1, characterized in that the heat exchanger (12) is designed in such a way that the differential pressure of compressed air in the primary circuit of the heat exchanger is less than 0.2 bar, and preferably less than 0.1 bar, and preferably less than 0, 05 bar. 10. The device according to claim 1, characterized in that the device (1) is mobile and is placed inside the container. 11. The device according to claim 1, characterized in that the device (1) includes a conventional cooling dryer without a regenerative heat exchanger. 12. The device according to claim 1, characterized in that a secondary cooler is installed between the outlet (11) of the aforementioned compressor (9) and the inlet (13) of the aforementioned primary circuit of the heat exchanger (12). 13. The device according to claim 12, characterized in that a second dehumidifier (26) is installed immediately downstream of the secondary cooler (25).

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