BE1019114A3 - DEVICE FOR MAKING ARTIFICIAL SNOW. - Google Patents

Abstract

Apparatus (1) for making artificial snow by means of a snow cannon (6) in which water is atomized with compressed air, compressed air being supplied by a compressor (9) in a compressor room (2) with an inlet (4) for supplying of air and an outlet (5) for discharging compressed air to the snow cannon (6), passing compressed air through the primary part of a heat exchanger (12), the secondary part of which is the evaporator (16) in a closed cooling circuit (17) in which coolant is circulated by a compressor element (18) driven by a drive (19), a control (24) being provided to obtain a desired temperature or pressure dew point at the outlet (14) of the primary section.

Description

Device for making artificial snow.

The present invention relates to a device for making artificial snow.

Devices for artificially producing snow on the basis of water and compressed air are already known, in which water is sprayed in compressed gas and in which the sprayed water freezes due to the cooling effect of the air expansion.

A compressor is used in the known devices for supplying compressed gas.

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

The known devices therefore also contain one or more aftercoolers for cooling the compressed air, whereby the moisture condenses from the compressed air through cooling and can be separated as condensate by means of a water separator or the like.

These aftercoolers are usually in the form of air-to-air regeneration heat exchangers, the incoming, hot compressed air being cooled by means of already cooled, compressed air.

The known devices are accommodated in a building of considerable dimensions in which the compressor is accommodated and in which the inlet of the compressor is connected to the outside air for sucking in the air to be compressed, while the outlet of the compressor installation is connected to a snow cannon for supplying the compressed air.

The tubes provided for realizing the aforementioned connections are bulky with the intention of being able to release heat from the compressed air to the space in the aforementioned building and to utilize this heat for heating the cold air drawn in.

A disadvantage is that this installation is quite bulky and rather stationary.

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

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

Improved devices are therefore known in which an additional heat exchanger is provided behind the aftercooler, the purpose of which is to control the temperature of the outgoing compressed gas.

A disadvantage is that such a device only allows rudimentary control of the temperature, so that it is not possible to produce high-quality snow under all circumstances.

Another disadvantage is that the heat exchanger cannot prevent moisture from condensing and freezing in the aftercooler.

Another disadvantage is that the known devices are energy-intensive.

The present invention has for its object to provide a solution to one or more of the aforementioned and / or other disadvantages in that it provides a device for making artificial snow by means of a snow cannon in which water is sprayed by means of compressed air, wherein this device is provided with a compressor for supplying compressed air, which compressor is arranged in a compressor room with an entrance for supplying air from the environment and an outlet for discharging the compressed air to the snow cannon via a conduit, wherein , according to the specific feature of the invention, the aforementioned device comprises a heat exchanger with a primary portion and a secondary portion, wherein compressed air from the compressor is passed through the primary portion and wherein said secondary portion forms part of the evaporator of a closed cooling circuit in which a coolant is circulated controlled by means of a compressor element driven by a drive and wherein the above-mentioned device comprises a control for controlling the above-mentioned cooling circuit, in order to obtain a desired temperature or pressure dew point at an output of the primary part of the heat exchanger.

An advantage is that the temperature of the compressed air at the exit of the primary part of the heat exchanger can be properly controlled, so that the snow produced is always of very good quality and the quality of the snow is not subject to the weather conditions. .

After all, the invention allows the control of the cooling circuit to be accurately controlled so that the desired temperature and / or the desired pressure dew point of the compressed air is achieved.

Another advantage is that the device is relatively compact with respect to the known devices.

An associated advantage is that the device is cheaper, not only in terms of installation costs but also in terms of energy consumption.

In the most practical embodiment, the device can be arranged in a container and thus be manufactured as a mobile device.

An advantage hereof is that the container can easily be transported, such that the device can supply compressed air for the production of snow at different places and, consequently, a relatively large tubing system is not required to connect different snow cannons from a centrally located location. device for supplying compressed air.

In a practical embodiment of the invention, the cooling circuit comprises a second heat exchanger which forms the condenser of the cooling circuit and which is located downstream of the compressor element and upstream of expansion means provided in the cooling circuit.

In the most practical embodiment, the coolant flowing through this second heat exchanger is cooled by means of a fan. The aforementioned fan is preferably arranged such that it blows air over the second heat exchanger into the compressor space.

An advantage hereof is that the fan distributes hot air in the compressor space, all this in such a way that the temperature in the compressor space is higher than 0 ° and thus freezing is avoided and thus damage due to freezing is completely excluded.

Another advantage is that no extra-large tubes have to be provided between the exit of the primary part of the heat exchanger and the entrance of the snow cannon.

Preferably, the temperature of the compressed air at the exit of the primary portion of the heat exchanger is less than 8 ° Celsius and most preferably about 3 ° Celsius.

An advantage is that good quality snowflakes can be made in this temperature range and that the total production time for producing the snow is shorter.

Preferably, the compressed air at the outlet of the primary part of the heat exchanger has a pressure of 8 bar or nearly 8 bar.

Preferably, the air is compressed by means of an oil-free compressor such as a water-injected screw compressor.

An advantage is that the compressed air cannot be contaminated by oil particles, so that this compressed air does not necessarily have to be passed through one or more filters, which of course has a favorable effect on the cost price and size of the device.

In the case of a water-injected compressor, the risk of air pollution is even completely excluded.

With the insight to better demonstrate the characteristics of the invention, a preferred embodiment of a device according to the invention is described below, as an example without any limiting character, with reference to the accompanying drawing, in which a diagram of a device according to the invention is given. invention for making artificial snow.

The device 1 for making artificial snow mainly comprises a compressor room 2 with a housing 3 in which an input 4 for supplying air from the environment is provided and an output 5 for supplying compressed gas such as air is provided.

In a practical embodiment of the invention, the housing 3 is formed by a container that can be mobile or by a building or the like.

The dimensions of the housing 3 can for instance be limited to a floor plan of six meters by six meters, this in contrast to the existing devices where buildings are used with dimensions that are tens of meters long and wide.

Provided in a wall of the housing 3 is a grid which forms the entrance 4 through which ambient air is drawn in in the direction of arrow L.

The above-mentioned outlet 5 is furthermore provided in the housing 3, with which a snow cannon 6 can be provided with compressed air via a pipe 7.

The snow cannon 6 is furthermore provided with a supply line. 8 for water, such that at the exit of the snow cannon 6 water is sprayed in known manner by the compressed air so that snow crystals are formed that spread from the mouth of the snow cannon 6.

For the production of the compressed air, a compressor 9 is provided in the compressor room 2 with an inlet for sucking in air and an outlet 11 for discharging the compressed air.

The aforementioned compressor 9 is thereby driven in known manner by means of a drive 10 such as, for example, but not necessarily, an electric motor.

The aforementioned compressor 9 can consist of a single compressor element, as shown in the figure, but can also be in the form of a multi-stage compressor in which the air is compressed by several consecutive compressor elements.

In a special embodiment, the compressor 9 comprises only water-injected compressor elements and it is also not excluded to provide intercoolers between successive pressure stages. The invention is of course not limited as such, since another type of oil-free compressor can be used, or an oil-injected compressor provided with suitable air filtering.

In a preferred embodiment of the invention, the compressor 9 is adjusted to a maximum operating pressure between 8 bar and 9 bar, and most preferably to a maximum operating pressure of 8.5 bar or substantially 8.5 bar.

According to the invention, a heat exchanger 12 is provided in the compressor space 2 for cooling the compressed air, with a primary part and a secondary part, the input 13 of the primary part being connected to the output 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 portion is less than 0.2 bar, more preferably less than 0.1 bar and preferably even less than 0.05 bar.

It is known that due to the lowering of the temperature, the moisture in the compressed air will condense.

At the outlet 14 of the primary part of the heat exchanger 12, therefore, a liquid separator 15 is preferably provided which can drain the condensed water.

According to the invention, the secondary part of the aforementioned heat exchanger 12 forms the evaporator 16 of a closed cooling circuit 17 that is filled with a coolant or cooling fluid.

As is known, the coolant is thereby circulated by means of a compressor element 18 in the cooling circuit 17, which compressor element 18 is driven by a drive 19.

Furthermore, in the closed cooling circuit 17 between the outlet of the compressor element 18 and the secondary part of the heat exchanger 12, a condenser 20 and expansion means, for example in the form of an expansion valve 21, are provided.

In a practical embodiment, the aforementioned condenser 20 is formed by a second heat exchanger and this second heat exchanger is cooled by means of a fan 22 which blows air over the condenser 20 and further blows this air into the compressor space 2.

In the most practical embodiment of the invention, the speed of the aforementioned fan 22 is adjustable in order to be able to control the temperature of the coolant at the outlet of the condenser 20. To this end, the aforementioned fan can be driven, for example, by means of a speed-controlled motor which is connected to a control unit to which also measuring means are connected for measuring the above-mentioned temperature at the output of the condenser, for example in the form of a temperature sensor in the line part between the expansion valve 21 and the condenser 20.

In a practical embodiment of the invention, the expansion valve 21 can be in the form of a thermostatic or electronic valve and this valve 21 is coupled to a temperature sensor 23 arranged at the output 14 of the primary circuit.

According to the invention, the device is provided with a control 24 for controlling the flow of the cooling fluid and the aforementioned control 24 provides for the realization of a desired temperature and / or pressure dew point at the outlet 14 of the primary part of the heat exchanger 12.

The control 24 can thereby control the speed of the drive 19, wherein, for example, a drive is used in the form of a frequency-controlled motor.

The control 24 can also be used to control the motor of the fan 22 and / or to control the expansion valve 21, as well as, if necessary, to control the drive 10 of the compressor 9.

It is clear that for controlling the temperature or pressure dew point, controlling the drive 10 of the compressor 9 is one of the possibilities, but other controls are also possible.

Between the outlet 11 of the compressor 9 and the inlet 13 of the primary part of the heat exchanger 12, an aftercooler 25 and a second water separator 26 are preferably also provided.

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

In the compressor space 2, a gas such as air is sucked in and compressed by the compressor 9. The hot compressed air is first sent through the aftercooler 25 and the second water separator 26, after which this already partially cooled gas is passed through the primary part of the heat exchanger 12, so that the compressed air at the outlet 14 of the primary part is even lower. temperature.

Condensate formed in the aftercooler 25 and the heat exchanger 12 is separated in the respective liquid separators 26 and 15 and the cold, less moist air is then fed to the snow cannon 6 via a line 7. In the snow cannon 6 the water will be atomized by means of the cooled compressed air so that snow crystals are formed.

The cooling of the compressed air in the primary part of the heat exchanger 12 is achieved by passing a cooling fluid through the secondary part of the heat exchanger 12. This cooling fluid preferably flows in counterflow with the air flowing through the primary part of this heat exchanger.

The aforementioned cooling fluid is heated upon passage through the secondary part and then cooled by the condenser 20. which in this case is provided immediately downstream of the compressor element 18 in the cooling circuit 17.

The temperature of the cooling fluid will decrease as it flows through the latter condenser 20 as the fan 22 blows air over this condenser 20.

The air blown over the condenser 20 by the fan 22 warms up.

Because this warm air spreads through the entire compressor space 2, the temperature in the compressor space 2 will always remain above the freezing point.

The coolant leaving the condenser 20 is then passed through the expansion valve 21 and thus again to the entrance of the secondary portion of the heat exchanger 12.

For the heat exchanger 12 and the cooling circuit 17 connected thereto with the control 24, use may be made, if appropriate, of a conventional cooling dryer, of which, however, the air-air recovery heat exchanger, which is presently present in such cooling dryer, has been omitted.

An advantage is that the device can be built up in a simple manner from a compressor which is coupled to a modified cooling dryer that is commercially available.

The present invention is by no means limited to the exemplary embodiment and shown in the figure, but a device 1 according to the invention, for making artificial snow, can be realized in all shapes and sizes, without departing from the scope of the invention steps.

Claims (12)

Device for making artificial snow by means of a snow cannon (6) in which water is sprayed by means of compressed air, said device being provided with a compressor (9) for supplying compressed air, which compressor (9) is arranged in a compressor room (2) with an inlet (4) for supplying air from the environment and an outlet (5) for discharging the compressed air to the snow cannon (6) via a line (7), characterized by said device (1) comprising a heat exchanger (12) with a primary portion and a secondary portion, wherein compressed air from the compressor (9) is passed through the primary portion and wherein said secondary portion forms part of the evaporator ( 16) of a closed cooling circuit (17) in which a coolant is circulated by means of a compressor element (18) that is driven by a drive (19) and that the aforementioned device g comprises a control (24) for controlling said cooling circuit, in order to obtain a desired temperature or pressure dew point at an output (14) of the primary part of the heat exchanger (12). Device according to one of the preceding claims, characterized in that a liquid separator (15) is provided at the outlet (14) of the primary part of the heat exchanger (12) for discharging condensed water. Device according to one of the preceding claims, characterized in that the cooling circuit (17) downstream of the compressor element (18) comprises a heat exchanger (20) which forms the condenser of the cooling circuit (17) and that this heat exchanger (20) by means of a fan (22) is cooled by blowing air over the heat exchanger (20) in the compressor room (2). Device according to one of the preceding claims, characterized in that the compressor (9) compresses air that is sucked in from the compressor space (2). Device according to one of the preceding claims, characterized in that the control (24) is such that temperature at the output (14) of the primary part is between 3 ° and 8 ° Celsius, more preferably between 3 ° and 5 ° Celsius. Device according to one of the preceding claims, characterized in that the control (24) is such that the temperature of the output (14) of the primary part is 3 ° Celsius or approximately 3 ° Celsius. Device according to one of the preceding claims, characterized in that the control (24) is such that a pressure dew point of the order of magnitude of 3 ° Celsius is realized. Device according to one of the preceding claims, characterized in that the compressor (9) is adjusted to a maximum operating pressure of 8.5 bar. Device according to one of the preceding claims, characterized in that the heat exchanger (12) is designed such that the pressure drop of the compressed air over the primary part is lower than 0.2 bar, more preferably lower than 0.1 bar and is preferably lower than 0.05 bar. Device according to one of the preceding claims, characterized in that the device (1) is mobile and arranged in a container. Device according to one of the preceding claims, characterized in that the device (1) comprises a traditional cooling dryer without recuperation heat exchanger. Device according to one of the preceding claims, characterized in that there is an aftercooler (25) between an outlet (11) of the aforementioned compressor (9) and an inlet (13) of the aforementioned primary part of the heat exchanger (12) to provide. Device according to claim 12, characterized in that a second liquid separator (26) is provided just downstream after the aftercooler (25).