KR100276057B1 - Indoor type skiing ground, and method and controller for indoor type skiing ground - Google Patents

Abstract

In an indoor ski resort where an artificial snow of a predetermined thickness is formed on a slope inside a building to form a gelende, a predetermined height range is set as a low temperature region from the surface of the artificial snow, and the upper side is a room temperature region above this low temperature region. A cold air hole is formed on the side wall of the building so as to be located in the area, and a cold air hole is formed so as to be located above the cold air hole.

Description

Control method and control device for indoor ski resort and indoor ski resort {INDOOR TYPE SKIING GROUND, AND METHOD AND CONTROLLER FOR INDOOR TYPE SKIING GROUND}

The present invention relates to an indoor ski resort where a gel ?? nde (ski ski driving range) is formed in a building, a control method and a control apparatus of the indoor ski resort.

With the development and diversification of the leisure industry, it is desired to be able to enjoy skiing in a comfortable environment without being affected by the natural environment. In order to satisfy these demands, indoor ski resorts have been constructed and built in natural ski resorts to enjoy skiing in bad weather as well as in and around the city.

Fig. 27 is a side schematic view showing the inside of a building of a conventional indoor ski resort, and Fig. 28 is a front schematic view showing the inside of a building of a conventional indoor ski resort.

In the conventional indoor ski resort, slopes 002 are formed in the interior of the building 001, as shown in Figs. 27 and 28, and artificial snow 003 has a predetermined thickness on the slopes 002. It is laid down, and the gelende 004 is formed. In the vicinity of the ceiling of the building 001, an air compression pipe 005 is hypothesized, and an air compressor 006 provided outside the building 001 is connected to the air compression pipe 005, A water supply pipe 007 is installed along the air compression pipe 005, and a water supply device 008 provided outside the building 001 is connected to the water supply pipe 007. A plurality of shared spray nozzles 009 are attached to the air compression pipe 005 and the water supply pipe 007 which are parallel to each other. In addition, the side wall of the building 001 passes through a cold air supply pipe 010 for ejecting cold air into the interior of the building 001, and one end of the air discharge pipe 011 for discharging the internal air, and opens in the building 001. The other ends of the cold air supply pipe 010 and the air discharge pipe 011 are connected to the air cooling device 012.

Therefore, cold air of about -10 to -15 ° C is supplied from the air cooling device 012 to blow out the cold air into the building 001 through the cold air supply pipe 010. At the same time, compressed air is supplied from the air compressor 006 to the air compression pipe 005, water is supplied from the water supply device 008 to the water supply pipe 007, and sprayed from each injection nozzle 009. Then, heat exchange is made between the mist-shaped water and the cooled air, and the mist-shaped water becomes artificial snow 003 and flows down to the gelende 004. If this operation is continued for a certain time, snow accumulates on the slope 002 to form a gelende 004.

Then, when the gelende 004 having artificial snow 003 having a predetermined thickness is formed on the slope 002, the supply of compressed air and water to the respective injection nozzles 009 is stopped to stop the production and snow of artificial snow. For this reason, a person who enjoys skiing can enjoy skiing in the gelende 004 having artificial snow with a good snow thickness in a state where snow is not falling.

On the other hand, even when the cold air is always ejected from the cold air supply pipe 010 into the building 001, and the artificial snow is not lowered, the entire interior of the building 001 is about -5 to -10 ° C by this cooling air. Since it is cooled to the vicinity, the quality of artificial snow 003 can be maintained satisfactorily by compressed air and water. That is, in order to maintain the quality of the artificial snow 003 satisfactorily, it is necessary to keep the temperature of the snow surface of the artificial snow 003 below a predetermined temperature (for example, 2 ° C), for example, to maintain the snow surface temperature. In order to maintain it at 2 degrees C or less, air temperature is continuously ejected from -5-10 degreeC, and the whole inside of the building 001 is cooled.

As described above, in the conventional indoor ski resort described above, the air compressor 006 and the water supply device (supplied with cold air of about -10 to -15 ° C are supplied from the air cooling device 012 to the interior of the building 001). By supplying compressed air and water from the 008 and spraying it to the injection nozzle 009, the water in the mist state is made into artificial snow 003 and deposited on the gelende 004 to form the gelende 004. In order to maintain the quality of artificial snow (003) in a good condition, cold air was supplied to the entire interior of the building 001 and cooled to around -5 to -10 ° C.

However, in order to produce artificial snow 003 in the interior of the building 001 and to deposit it on the gelende 004, the entire interior of the building 001 must be cooled, and for supplying cold air into the building 001. The air cooling device 012 requires a large capacity, and there is a problem that the energy cost increases as the device becomes larger. In addition, the cold air supply pipe 010 may be lowered to a lower surface near the snow surface to mainly cool the snow surface. However, in the wide gelende 004, the cold air does not reach the center portion and thus does not cool to an appropriate temperature. Near the outlet of the supply pipe 110, the degree of cooling is considerably strong, and problems such as becoming snow once frozen snow or ice burn (Eisbahn: a frozen ski slope) also occur.

In addition, in order to maintain the snow quality of the gelende 004 satisfactorily, according to the experience and perception of the operator, the cooling air is always supplied to the inside of the building 001 to about -5 to -10 ° C. Although it cooled, it tended to cool too much. As described above, in the conventional indoor ski resort, in order to maintain the quality of the gelende 004 satisfactorily, not only enormous effort is required but also the running cost is high.

And since the whole inside of the building 001 is cooled by the cold air from the cold air supply pipe 010 provided upward, the upper position (for example, of a skier) away from the snow surface of the artificial snow 003 The air in the face) is also below freezing temperature, making it difficult for guests and employees to stay for a long time, and it is not necessarily comfortable.

In addition, in order to maintain the snow quality of the artificial snow 003 of the gelende 004, the cooling air is supplied from the cold air supply pipe 010 to the entire interior of the building 001, and cooled to about -5 to -10 ° C. The artificial snow 003 of the gelende 004 receives heat from illumination, receives radiant heat from the ceiling or side walls, or receives heat by ski skid, so that the quality of the gelende 004 is gradually deteriorated.

Therefore, when the snow quality of the artificial snow 003 of the conventional gelende 004 deteriorates, the artificial snow 003 of the surface of the gelede 004 is scraped out and discharged every predetermined time or every predetermined period, and as mentioned above, A new artificial snow (003) was sprayed all over the surface of the gelende (004) and then smoothed by machine.

However, the artificial snow 003 has a place where the quality of the snow deteriorates and does not deteriorate depending on the location of the gelende 004, and there is no need to spray new artificial snow 003 on the entire surface of the gelende 004. Therefore, when new artificial snow 003 is sprayed on the whole surface of the gelende 004, the whole gelende 004 must be smoothed by a machine, and there exists a problem that a work becomes large.

In the case of crushing and discharging the artificial snow 003 whose deteriorated quality of the gelende 004 is deteriorated, it is necessary to work after closing the gelende 004 and making it prohibit from sliding, and the use period of the gelende 004 is limited. There is a problem that it becomes. In addition, if the work of scraping and discharging the artificial snow (000) of the gelende (004) is performed outside the use time of the gelende (004), there is a problem that the work becomes cumbersome. In addition, in order to shave the artificial snow 003 of a predetermined thickness from the gelende 004, a dedicated machine is required, and a dedicated machine is also required to discharge the shaved snow.

In addition, when the snow quality is renewed while the artificial snow 003 is melted while raising the internal temperature set value of the building 001, melting occurs in the entire surface of the gelende 004, so that the drainage of the snow melted water is properly discharged. It cannot be executed, and the snowfall 003 will be in a sleet state with the increase of the maintenance amount, and will become unable to slide.

SUMMARY OF THE INVENTION The present invention has been made to solve such a problem, and a first object is to maintain a good snow quality of artificial snow without excessive cooling, so that a skier can enjoy skiing in a relatively light outfit.

In addition, the second object is to maintain the quality of the gellende in a simple and inexpensive structure at all times and to reduce the energy cost.

Further, the third object is to reduce energy consumption by improving the control accuracy so that the quality of snow is always kept good and the quality of snow is kept good while keeping the amount of melting of the gelende in a simple and inexpensive structure.

In order to achieve the above object, the indoor ski resort of claim 1 of the present invention is an indoor ski resort in which an artificial snow of a predetermined thickness is sprayed onto a slope inside a building, and a gelende is formed, wherein the surface of the artificial snow is formed on a side wall of the building. Located in the vicinity of the height is characterized in that the cold air hole for ejecting cold air in the building is formed.

The indoor ski resort of claim 2 of the present invention is characterized in that the exhaust hole is formed in the side wall of the building so as to be positioned above the cold air hole.

In the indoor ski resort of claim 3 of the present invention, in the interior of the building, the interior of the building has a low temperature region of a predetermined height range from the surface of the artificial snow, and a normal temperature region above the low temperature region. The cold air hole and the exhaust hole are formed in the area.

The indoor ski resort of claim 4 of the present invention is characterized in that the cold air hole has a long slit shape along the surface of artificial snow.

In addition, the indoor ski resort of claim 5 of the present invention is an indoor ski resort in which an artificial snow of a predetermined thickness is sprayed onto a slope in a building, and a gelende is formed, the snow maker producing artificial snow, and the artificial snow manufactured by the snow maker. Snow storage for temporarily storing the snow; a snow snowing device for conveying artificial snow stored in the snow storage; and artificial snow disposed in the plurality of the gelling devices and conveyed by the snow conveying device. Snow snow spraying device which can be sprayed on the snow and the snow snow spraying device is controlled in accordance with the amount of snow falling on the gellende to spread snow on a predetermined area of the surface of the gellende, thereby forming artificial snow having a predetermined thickness suitable for sliding. A gelene supply amount control means to supply cold air near the surface height of the artificial snow of the gelende It is comprising the cooling apparatus.

The indoor ski resort of claim 6 of the present invention is the snow conveying pipe according to claim 5, wherein the snow conveying apparatus conveys artificial snow stored in the snow reservoir to the geldere by means of a rotary feeder. An eye spray nozzle as the eye spray device is attached to the front end of each of the eye carrier tubes arranged in plural in the gelende.

In the indoor ski resort of claim 7 of the present invention, the heat insulation of the indoor ski area of claim 1 is performed such that the lower surface portion of the artificial snow melts by a predetermined thickness by a through-flow heat through the heat insulating member below the artificial snow that constitutes the gelende. The material and the thickness of the member are set.

In the indoor ski resort of claim 8 of the present invention, in the seventh aspect, the gelende includes the heat insulating member attached to an upper surface of a bottom portion, a concrete floor attached to an upper surface of the heat insulating member, and an upper surface of the concrete floor. It is characterized by consisting of artificial grass laid in.

Further, in the indoor ski resort of claim 9 of the present invention, in the upper surface of the concrete floor, a watermelt groove is formed at least along the inclined direction of the slope, and at the same time, the artificial snow on the artificial grass The molten melted water is characterized in that a plurality of through-holes are formed to flow into the melted groove.

Moreover, the indoor ski resort of Claim 10 of this invention WHEREIN: The partition member which divides the internal space of the said building into two spaces of the top and bottom of a ceiling side space and the said gallede side space in the inside of the said building. It is characterized by the arrangement.

In the indoor ski resort of claim 11 of the present invention, a cold air hole for ejecting cold air near the surface height of the artificial snow is formed in the upper part of the slope, while the surface of the artificial snow is formed in the lower part of the slope. An exhaust hole for discharging cold air near the height is formed.

The indoor ski resort of claim 12 of the present invention is a plurality of indoor ski resorts according to claim 1, which are opened at the upper surface of the slope and in the lower portion of the snow cover, and blow out cold air at high speed toward the snow surface through the artificial snow on the slope. It is characterized by providing a spout.

In the indoor ski resort of claim 13 of the present invention, the plurality of jet ports are located in the central portion of the gelende according to claim 12.

Moreover, in the indoor ski resort of Claim 14 of this invention, the telescoping-extension tube is provided in the hole formed in the said slope, The cold air which ejects cold air in the upper end part of this telescoping tube near the surface height of the said artificial snow. It is characterized in that the jet nozzle is provided.

The indoor ski resort of claim 15 of the present invention is the cold air jet nozzle of claim 14, wherein the cold air jet nozzle has a lid that closes the hole on a top surface thereof.

The indoor ski resort of claim 16 of the present invention is the cold air jet nozzle according to claim 14, characterized in that it has a snow hole opening unit that forms a communication hole communicating with the upper portion of the artificial snow.

In addition, according to the control method of the indoor ski resort of claim 17 of the present invention, an artificial snow of a predetermined thickness is sprayed onto a slope inside a building to form a gelende, and melted at the lower surface portion of the artificial snow that constitutes the gelende, while the artificial By replenishing by spraying artificial snow on the upper surface of the snow, it is characterized in that the thickness of the artificial snow of the gelende is always kept constant.

The control method of the indoor ski resort according to claim 18 of the present invention is the radiation heat from the ceiling and walls of the building, the sliding load heat from the ski gelende, and the heat of illumination of the interior of the building. I), the heat of intrusion below the bottom of the slope from below the slope, the heat of snow cooling by cold air supplied to the space above the snow part, and the latent heat of evaporation from the snow part as the control factors. By adjusting the temperature of the cold air supplied to the upper space of the snow portion controlling the snow surface cooling heat to balance the snow surface cooling heat and the latent heat of evaporation against the radiant heat, the slide load heat, the light input heat and the intrusion heat below the slope bottom. The thermal resin is kept at a constant value.

In the method for controlling an indoor ski resort of claim 19 of the present invention, the ceiling and wall radiant heat according to claim 18, wherein the ceiling and wall radiant heat are selected by the ceiling inner surface temperature and the wall inner surface temperature of the building, Obtained from the calorie change model, the slide load heat is obtained from the number of entrances to the ski gelende and the working intensity as the heat generation index at the time of the slide, the heat input of the light is obtained from the lighting power consumption, and the intrusion heat under the slope floor is the snow cover. It is calculated | required as a heat-through flow rate from the temperature measurement value in the negative upper and lower surfaces, and the said latent heat of evaporation is calculated | required from the quantity of the condensed water of the reflux airflow of cold air supplied to the upper space of the said snow part.

Further, the control device of the indoor ski resort of claim 20 of the present invention is melted at the lower surface portion of the snow portion of the ski gelende with respect to the ski gelende formed by spraying artificial snow of a predetermined thickness on the slope inside the building, In an indoor ski area where the thickness of the snow cover is always kept constant by spraying and supplementing artificial snow on the upper surface and supplying cold air from the cold air to the space above the snow cover, from the ceiling and walls of the building. Radiant heat, slide load heat from the ski gelende, heat input of lighting inside the building, intrusion heat below the bottom of the slope from below the slope, snow heat of cooling by cold air from the cold air fan, and latent heat of evaporation from the snow section. As a control factor, the ceiling / wall radiant heat, the slide load heat, the illumination heat input, It is characterized in that the snow surface air flow control means for controlling the snow surface cooling heat by adjusting the cold air temperature ejected from the cold air fan to balance the snow surface cooling heat and the latent heat of evaporation against the heat intrusion below the bottom of the slope.

1 is a schematic side view showing the inside of a building showing a cooling apparatus of an indoor ski resort according to a first embodiment of the present invention;

2 is a front schematic view showing the inside of a building of an indoor ski resort of the present embodiment;

Figure 3 is a side schematic view showing the interior of the building showing a cooling device of an indoor ski resort according to a second embodiment of the present invention,

4 is a front schematic view showing the inside of a building of an indoor ski resort of the present embodiment;

5 is a side schematic view showing a system of an entire dome to which an indoor ski resort according to a third embodiment of the present invention is applied;

6 is a schematic view showing an air conditioning and snow control mechanism of an indoor ski resort;

7 is a cross-sectional view taken along the line VII-VII of FIG. 5,

8 is a schematic view showing a snow maker, a snow reservoir and a snow conveying device,

9 is a cross-sectional view showing a gelende structure of an indoor ski resort;

10 is a longitudinal sectional view showing a gelende structure of an indoor ski resort;

11 is a schematic diagram showing an internal structure of an indoor ski resort according to a fourth embodiment of the present invention;

12 is a schematic cross-sectional view of an indoor ski resort according to a fifth embodiment of the present invention;

13 is a cross-sectional view showing a gelende structure of an indoor ski resort;

14 is a plan view showing the arrangement of cold air jets in a slope of a gelende;

15 is a plan view showing the arrangement of cold air jets in a modified example of the gelende structure of an indoor ski resort;

16 is a schematic cross-sectional view of an indoor ski resort according to a sixth embodiment of the present invention;

17 is a sectional view showing a gelende structure of an indoor ski resort;

18 is a partial sectional view showing a modification of the expansion pipe with a cold air jet nozzle in an indoor ski resort;

19 is a sectional view showing an operating state of the expansion pipe with a cold air jet nozzle;

20 is a schematic diagram showing a system of an entire dome to which an indoor ski resort according to a seventh embodiment of the present invention is applied;

21 is a graph showing the heat penetration rate at the bottom of the slope bottom with respect to the temperature change,

22 is a graph showing the ceiling temperature for daily changes,

23 is a graph showing the ceiling temperature against seasonal changes,

24 is a graph showing the amount of snow melt with respect to the calorific value;

25 is a graph showing the amount of snow melt against the temperature difference between a roof and a ceiling;

26 is a graph showing a calorific value and a snowmelt amount with respect to a cold air jet temperature;

27 is a side schematic view showing the inside of a building of a conventional indoor ski resort;

Fig. 28 is a front schematic view showing the inside of a building of a conventional indoor ski resort;

Explanation of symbols for the main parts of the drawings

11: building 13, 28: snow maker

14: artificial snow 15, 29: snow cellar

16, 30: snow conveying device 17, 32: cold air hole

18, 33: exhaust hole 25: slope

27: Glende 34: Snow surface air flow control device

38: air flow control device 80: cold air supply pipe

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

First embodiment

In the indoor ski resort of the present embodiment, as shown in FIGS. 1 and 2, the interior of the building 11 has a slope on the lower surface thereof, and artificial snow having a predetermined thickness is sprayed on the slope to form a gelede surface 12. It is.

In this indoor ski resort, artificial snow 14a is manufactured by the snow maker 13, and the manufactured artificial snow 14a is stored in the snow storage 15 once. And the artificial snow 14a stored in the snow storage 15 is conveyed (air conveyance etc.) to the gellende surface 12 by the snow conveying apparatus 16, and artificial snowfall 14 on the gellende surface 12 is carried out. ) To form. When artificial snowfall 14 having a predetermined thickness suitable for skiing is formed, the conveyance and supply of artificial snow 14a to the gelende surface 12 is stopped.

On the other hand, the side wall 11b of the building 11 has a plurality of cold air holes 17 for ejecting cold air in the building 11 and an exhaust hole 18 for discharging air in the building 11. have. Among these, each cold air hole 17 is arrange | positioned so that the height position may be located in the vicinity of the surface height of the artificial snowfall 14 of predetermined thickness (thickness suitable for skiing). Moreover, each exhaust hole 18 is arrange | positioned so that the height position may be located in the upper position rather than the height position of the cold air hole 17. As shown in FIG. The cold air holes 17 and the exhaust holes 18 have a long slit shape along the surface of the artificial snowfall 14.

The refrigerator 19 is cooled to a necessary temperature (for example, a temperature on snow surface of -5 to 0 ° C. according to the number of users) which does not reach below 5 ° C. to the extent that the snow quality of the artificial snowfall 14 can be maintained satisfactorily. The existing cold air is supplied to the plurality of cold air holes 17. This cold air is supplied from each cold air hole 17 toward the snow surface of the artificial snowfall 14. For this reason, the surface of the artificial snowfall 14 is cooled by the cold air supplied from the cold air hole 17, the snow quality is maintained satisfactorily by the cold air without melt | dissolving snow, and the amount of air required is also small.

The cold air supplied toward the surface of the artificial snowfall 14 cools the surroundings (artificial snowfall 14 and the like) and heat exchanges the temperature. This temperature-rise cold air (air) is separated from the surface of the artificial snowfall 14 and rises upward (increasing airflow), and is discharged from the exhaust holes 18 to the outside of the building 11. Therefore, only the space below the exhaust hole 18 is cooled by cold air, so that the air temperature inside the building 11 becomes cold in the lower side and warm in the upper side, so that a so-called temperature stratification state is achieved and good cooling is achieved. .

Therefore, in the indoor ski resort of the present embodiment, it is possible to effectively perform cooling sufficient to maintain the snow quality of the artificial snowfall 14 without excessively cooling the entire interior of the building 11. In addition, the temperature of the cold air supplied from the refrigerator 19 is a temperature of about 0 degrees C or less, but it does not reach -15 degrees C or less, and the object of cooling not the whole building 11 but the surface of the artificial snowfall 14. Since it is narrowed down, the amount of air required is small, and the refrigerator 19 can employ | adopt the model with small freezing capacity. Thereby, while operating cost of the refrigerator 19 can be reduced, the installation space of the refrigerator 19 can be reduced.

Moreover, since cold air is supplied from the cold air hole 17 toward the surface of the artificial snowfall 14, the upper position away from the snow surface of the artificial snowfall 14 (for example, the face of a skier). Because the air is not extremely cold, it is a pleasant environment for skiers. In addition, since the cold air hole 17 has a long slit shape along the surface of the artificial snowfall 14, it is possible to supply cold air to every corner along the surface of the artificial snowfall 14, for example, cylindrical cold air. Compared with the hole, the air inflow amount in the vertical direction of the cold air hole 17 is suppressed to improve the cooling efficiency.

Here, the explanation is further made that the cooling efficiency is improved by forming the exhaust hole 18. As described above, in the present embodiment, the cold air supplied from the cold air hole 17 flows along the snow surface of the artificial snowfall 14 initially, but the temperature rises due to heat exchange with the surroundings, resulting in an upward airflow. It will separate from the eye surface. The cold air (air) separated and raised from the snow surface is discharged from the exhaust hole 18 to the outside of the building 11.

In addition, in the present embodiment, as heat input to the artificial snowfall 14 on the gelende surface 12, in addition to the internal air temperature of the building 11 described above, the human body heat generated by skiing, the heat of the slide, and the ceiling 11a. Radiant heat or illumination radiation, and the temperature of the cold air ejected from the cold air hole 17 is offset in consideration of such heat input conditions, so that the surface of the artificial snowfall 14 is cooled by cold air to keep the snow quality well. Doing.

Second embodiment

In the indoor ski resort of the present embodiment, the cold air space is further limited, and as shown in FIGS. 3 and 4, a slope-like gelende surface 12 is formed inside the building 11. In this indoor ski resort, artificial snow 14a is produced by the snow maker 13 and stored in the snow storage 15, and the artificial snow 14a is polished by the snow conveying device (snow conveying pipe) 16 ( 12), artificial snowfall 14 is formed on the gelende surface 12.

On the other hand, the side wall 11b of the building 11 has a plurality of cold air holes 17 for ejecting cold air into the building 11 and an exhaust hole 18 for discharging air in the building 11. It is formed up and down side by side. Each cold air hole 17 is located in the vicinity of the surface height of the artificial snowfall 14 whose height position is predetermined thickness (thickness suitable for skiing), and each exhaust hole 18 has the cold air hole ( It is located slightly above the height position of 17, and the cold air hole 17 and the exhaust hole 18 have a long slit shape along the surface of the artificial snowfall 14.

The refrigerator 19 connected to each cold air hole 17 can supply the cold air required for the temperature (for example, -5-0 degreeC temperature) of the grade which can maintain the snow quality of the artificial snowfall 14 favorably. The cold air is supplied from each cold air hole 17 toward the snow surface of the artificial snowfall 14, and the surface of the artificial snowfall 14 is cooled by this cold air, and the snow quality is satisfactorily without melting the snow. maintain.

The cold air supplied toward the surface of the artificial snowfall 14 cools the surroundings (artificial snowfall 14 or air) to be heat exchanged to increase the temperature, and the exhaust hole 18 immediately above the cold air hole 17. Is discharged to the outside of the building (11). Therefore, only the space below the exhaust hole 18 is cooled by cold air to become the low temperature region C, and the space above the exhaust hole 18 becomes the normal temperature region H. The so-called temperature stratified state, which becomes warm on the side, becomes clear and good cooling is achieved.

Therefore, in the indoor ski resort of the present embodiment, without cooling the entire interior of the building 11, only the low temperature region C near the surface of the artificial snowfall 14 is cooled, so as to reduce the amount of air required and the freezer. By reducing the capacity of (19), cooling sufficient to keep the snow quality of the artificial snowfall 14 good can be performed effectively. In addition, since only the low-temperature region C is cooled, the upper space (air near the ceiling) away from the snow surface of the artificial snowfall 14 becomes higher than the snow surface, and the temperature difference with the outside air becomes smaller than before, Reduction of heat passing through is made possible.

In each of the above-described embodiments, the exhaust hole 18 is formed at a position close to the ceiling 11a, or is formed in the low temperature region C directly above the cold air hole 17, and the formation position thereof is limited thereto. Instead of adjusting the position in the vertical direction, the thickness of the cold air (low temperature region C: height in the vertical direction of the cold air existing from the snow surface of the artificial snowfall 14 to the exhaust hole 18) is controlled. Also good. In addition, the exhaust hole 18 may be concentrated on the end surface of the upper surface of the gelende 12 so as to maintain the low temperature region C in accordance with the amount of cold air blown out from the cold air hole 17 without providing the side wall portion. .

As described above, according to the indoor ski resort of the present invention, an artificial snow of a predetermined thickness is sprayed on the slope of the building to form a geleden surface, and the cold side air is blown into the building by being located near the surface height of the artificial snow on the side wall of the building. Since a cold air hole is formed, the surface of the artificial snow is well cooled by the cold air supplied from the cold air hole to the inside of the building, and the cooling target is narrowed to the surface of the artificial snow, and the temperature of the cold air is reduced to the quality of the artificial snow. By reducing the amount of air required by maintaining the temperature at a level that can maintain the satisfactory temperature, the refrigerating capacity of the refrigerator can be reduced, the cooling efficiency can be improved, and the blower of the freezer or the cooling wind can be improved. The original operation cost can be reduced and the installation space of the refrigerator can be reduced.

In addition, according to the indoor ski resort of the present invention, since the exhaust hole is formed on the side wall of the building so as to be located above the cold air hole, the cold air supplied from the cold air hole into the building cools the surface of the artificial snow. The temperature rises due to heat exchange with air, and the warmed air (air) becomes an upward airflow and rises upward and is discharged from the exhaust hole to the outside of the building, so that only the surface of artificial snow can be cooled efficiently, and artificial snow The quality of snow can be kept good.

In addition, according to the indoor ski resort of the present invention, the interior of the building is a low temperature region of a predetermined height range from the surface of the artificial snow, and a normal temperature region above the low temperature region, and cold air holes and exhaust holes are formed in the low temperature region. Therefore, it is possible to realize a temperature stratification in which only the space below the exhaust hole is cooled in the air inside the building, thereby improving the cooling efficiency, and the temperature of the upper position away from the snow surface becomes extremely low. Enjoy skiing in a comfortable environment.

Further, according to the indoor ski resort of the present invention, since the cold air hole has a long slit shape along the surface of the artificial snow, it is possible to suppress the inflow of air from the outer periphery of the cold air hole and to supply the cold air to every corner along the surface of the artificial snow. Can improve the cooling efficiency.

Third embodiment

The dome of this embodiment has a normal temperature space area used for a theme park, a shopping center, etc., and a low temperature space area used for a ski resort. That is, as shown in FIGS. 5 to 7, the dome 21 has an elliptical shape in plan view, and a semicircular ceiling 23 is formed with respect to the bottom surface portion 22, thereby providing a large space 14. It is. Inside the dome 21, one side (left side in FIG. 5) is a room temperature space area M such as a theme park or a shopping center, and the other side (right side in FIG. 5) is a low temperature space area C of an indoor ski resort. It is. In this low temperature space region C, the slope 25 is formed in the lower surface, the artificial snow 26 is laid in this slope 25 by predetermined thickness, and the gelende 27 is formed.

In this indoor ski resort, artificial snow 26 is manufactured by the snow maker 28, and the manufactured snow 26 is once stored in the snow storage 29. As shown in FIG. Then, the artificial snow 26 stored in the snow reservoir 29 is conveyed (air conveyed or the like) to the gelende 27 by the eye conveying device 30 so as to form artificial snow on the gelende 27. have. Moreover, the water which melt | dissolved the artificial snow 26 of the gelende 27 collects, returns to the eye maker 28, and the artificial snow 26 is manufactured again.

On the other hand, an air dam 31 is formed in the bottom surface portion 22 of the dome 21 so as to divide the normal temperature space region M and the low temperature space region C with a step. On the sidewall of the dome 21 on the indoor ski resort side, a plurality of cold air holes 32 are formed at the upper and side portions of the gelende 27 and blow out cold air in the dome 21, and the gelende 27 is formed. In the side of the air dam 31 as a lower part of the s), an exhaust hole 33 for discharging the internal air of the dome 21 is formed. Each of the cold air holes 32 and the exhaust holes 33 are arranged such that their height positions are located near the surface height of the artificial snow 26 of a predetermined thickness (thick to ski), and the shape thereof is artificial snow. It has a long slit shape along the surface of (26).

The surface-cooling airflow control device 34 has a heat exchanger 34a and a fan 34b, and does not reach a temperature (-10 to -15 ° C) that is sufficient to maintain snow quality of the artificial snow 26. For example, the cold air cooled to -5 to 10 ° C can be supplied to the plurality of cold air holes 32. The cold air is supplied from each cold air hole 32 toward the surface of the gelende 27, and the surface of the artificial snow 26 is cooled by the cold air supplied from the cold air hole 32, so that the quality of the snow is not melted. Keeps good. The cold air supplied toward the surface of the gelende 27 cools the surroundings (artificial snow 24 or air) to be heat exchanged to increase the temperature, and is discharged from the exhaust holes 33 to the outside of the dome 21. If it is, it returns to the cold airflow control device 34, and as mentioned above, heat exchange (cooling) is performed and it is supplied from the cold air hole 32 to the gelende 27 again.

In addition, a slit-shaped spray nozzle 35 is provided at a high position (or near the top) of the air dam 31, and the jetting direction of the jet flow from the spray nozzle 35 is determined by the gelende 27. Direction, and the blowing temperature is 20 ° C to 30 ° C. The jet from the spray nozzle 35 rises through the cold air flowing through the surface of the gelende 27 and flows along the ceiling 23 of the dome 21 to the room temperature space region M, whereby the dome 21 It is supposed to circulate in me. The ceiling 23 of the dome 21 is provided with a discharge hole 36 for discharging air in the dome 21 to the outside, and the airflow control device 37 includes a heat exchanger 37a and a fan 37b. The air in the dome 21 discharged from the discharge hole 36 is collected, heat exchanged (cooled), and can be jetted as a jet from the injection nozzle 35.

Here, the snow maker 28, the snow storage 29, and the snow conveyance apparatus 30 for forming artificial snow on the gelende 27 are demonstrated in detail. As shown in FIG. 8 and FIG. 9, in the present embodiment, the inside of the eye maker 28 is an eye reservoir 29, and the cold air supply pipe 41 and the internal air discharge pipe 42 are provided on the side of the eye maker 28. Is mounted, and the cold air of a predetermined temperature can be ejected from the jet port 43 in the snow maker 28 to the whole inside. On the other hand, the snow maker 28 is connected with the pressurized water supply pipe 44 and the erection compressed air supply pipe 45, and the front-end | tip part of each supply pipe 44 and 45 is located in the vicinity of the jet port 43 of cold air. Therefore, the pressurized water is fed from the pressurized water supply pipe 44 while blowing cold air of a predetermined temperature from the jet port 43 in the snow maker 28, and the compressed air is blown out from the compressed air supply pipe 45 for laying snow. As a result, heat exchange is performed between the water in the mist state and the cooled air, and the water in the mist state becomes artificial snow and can be stored in the snow storage 29.

In the eye conveying apparatus 30, the compressed air supply pipe 46 for laying snow is piped adjacent to the eye maker 28 (snow reservoir 29), and the flowmeter 47, the pressure regulating valve 48, and the pressure gauge ( 49), the eye conveyance pipe 51 is connected via the rotary feeder 50. As shown in FIG. On the other hand, the screw conveyor 52 is arrange | positioned in the snow container 29, and the artificial snow in the snow storage 29 can be supplied to the rotary feeder 50. As shown in FIG. And this eye conveyance pipe | tube 51 is arrange | positioned in the whole interior of the calendar 27, as shown in detail in FIG. 6, and the eye-spraying nozzle 54 is attached to the some conveyance switching apparatus 53, respectively. Therefore, when compressed air is supplied from the compressed air supply pipe 46 for laying snow to the eye conveying pipe 51, and artificial snow in the snow storage 29 is supplied to the rotary feeder 50, artificial snow is gelled by this compressed air. By operating the conveying switching device 53 of the position to be sprayed by the eye conveyance pipe 51 of (27), it is possible to spray artificial snow from the eye spray nozzle 54 to the predetermined position of the gelende 27. Do.

In this case, as shown in FIG. 5, the conveyance switching apparatus 53 is connected with the gelende snowfall amount control device 55, and this gelende snowfall amount control device 55 is predetermined according to the amount of snowfall throughout the gelende 27. By operating the conveyance switching device 53, artificial snow is sprayed from the snow spray nozzle 54 to a predetermined position of the gelende 27.

By the way, in the indoor ski resort of this embodiment, while melting from the lower surface of the artificial snow 26 constituting the gelende 27, the artificial snow 26 is sprayed and replenished on the upper surface of the artificial snow 26 to make the gelende ( The thickness of the artificial snow 26 of 27) is always kept constant so as to obtain good snow quality. That is, as shown in FIGS. 9 and 10, the bottom surface portion 22 of the dome 21 is made of concrete, and on the bottom surface portion 22, the concrete floor 62 is passed through a urethane heat insulating material 61 as a heat insulation member. Is formed. Artificial grass 63 is laid on the concrete floor 62, and artificial snow 26 having a predetermined thickness is laid on the artificial grass 63. In addition, on the upper surface of the concrete floor 62, the melter groove 64 is formed in the lower side of the artificial turf 63 along the inclination direction of the slope 25, and the melter groove 64 in the artificial turf 63. A plurality of through holes 65 are formed in communication with each other. Moreover, the lower part of the bottom surface part 22 formed from concrete becomes the machine room 66 as a heat source. In Fig. 9, reference numeral 67 denotes a duct for supplying cold air from the snow surface airflow control device 34 to the cold air hole 32, and reference numeral 68 denotes a chamber of cold air.

Therefore, the through-flow heat from the machine room 66 acts on the lower surface part of the artificial snow 26 through the bottom surface part 22, the urethane heat insulating material 61, the concrete floor 62, and the artificial turf 63, and this artificial snow 26 melt | dissolves in the lower surface part side, this molten water reaches the molten groove 64 from the through-hole 65 of the artificial turf 63, and flows downward along this molten groove 64. As shown in FIG. In this case, the thickness of the urethane heat insulating material 62 is set in accordance with the amount of snow melting of the lower surface of the artificial snow 26 in the gelende 27, and the heat of the through flow from the machine room 66 is provided at the lower surface of the artificial snow 26. It is set in consideration of the thermal conductivity transferred.

In the dome 21 of the present embodiment configured as described above, as shown in FIGS. 5 and 6, the snow surface cold airflow control device 34 can maintain the snow quality of the artificial snow 26 satisfactorily, for example, from -5 to Since cold air of -10 ° C is supplied from the plurality of cold air holes 32 toward the surface of the gelende 27, and the surface of the artificial snow 26 is cooled by this cold air, the surface is not melted and the snow quality is satisfactory. maintain. Then, the cold air supplied toward the surface of the gelende 27 flows downward along the surface of the gelende 27, is heat exchanged to increase the temperature, and returns to the cold air flow control device 34 through the respective exhaust holes 33. Here, heat exchange (cooling) takes place and is again supplied from the cold air hole 32 to the gelende 27.

On the other hand, the airflow control device 37 injects a jet of 20 ° C. to 30 ° C. from the plurality of injection nozzles 35 to the gelende 27 side where the inside of the dome 21 is at room temperature. Ascending through the cold air flowing through the surface of the gelende 27, circulating along the ceiling 23 of the dome 21, the inside of the dome 21 into the room temperature space region (M) and the low temperature space region (C) Compartment. Then, a part of the airflow flowing through the ceiling 23 of the dome 21 is returned to the airflow control device 37 through each discharge hole 36, where heat exchange (cooling) is performed and from the injection nozzle 35 again. It is injected to the gelende 27 side as jetting.

In the interior of the indoor ski slope, as shown in FIG. 10, the urethane heat insulating material 62 has a thickness set in accordance with the amount of snow melting at the lower surface of the artificial snow 26, and the thickness from the machine room 66 is reduced. Through-flow heat acts on the lower surface portion of the artificial snow 26 via the bottom surface portion 22, the urethane insulation 61, the concrete floor 62, and the artificial grass 63, and the artificial snow 26 melts on the lower surface side. do. And the snow melt of the artificial snow 26 flows from the through-hole 65 of the artificial turf 63 to the snow melt groove 64, and flows downward through this snow melt groove 64. FIG.

On the other hand, when the water is sprayed by the pressurized water and the compressed air while blowing cold air from the jet port 43 into the inside by the snow maker 28, heat exchange is performed between the water in the mist state and the cooled air. It is manufactured and stored in the eye storage 29. And when compressed air is supplied to the eye conveyance pipe 51 by the snow conveying apparatus 30, and artificial snow in the snow reservoir 29 is supplied to the rotary feeder 50 by the screw conveyor 52, this compression is carried out. Artificial snow is conveyed to the eye conveyance pipe 51 of the gelende 27 by air, and artificial snow is sprayed on the gelende 27 from the eye spray nozzle 54.

In this case, the artificial snow 26 of the gelende 27 is melt | dissolved from the lower surface part side by the through-flow heat, and the gelende snowfall control apparatus 55 is predetermined conveyance switching apparatus 53 according to the snowfall amount of each position of the gelende 27. The artificial snow is sprayed and replenished to the predetermined position of the gelende 27 from the eye spray nozzle 54 by the operation of) so that the thickness of the artificial snow 26 of the gelende 27 can be kept constant at all times.

In addition, in the above-mentioned embodiment, the structures of the eye maker 28, the eye storage 29, and the eye conveyance apparatus 30 are not limited to this structure, According to an installation place or installation conditions, it can change suitably. .

As described above, according to the indoor ski resort of the present invention, the artificial snow, which is manufactured by the snow maker and stored in the snow storage once, is conveyed to the gelende by the snow conveying device and sprayed by the snow spraying device, and the snow inside the building. It is not necessary to manufacture a cooling device, and the cooling agent can supply cold air in the vicinity of the surface height of the artificial snow so that the cooling device can be reduced in size, and the energy cost can be reduced. Therefore, it is possible to apply artificial snow only to a predetermined area of the gelende, so that it is always possible to maintain the artificial snow of the desired predetermined thickness. In addition, new snow is always supplied to the required location of the gelende where good snow quality is desired, and by supplying cold air to the gelende, it is possible to prevent snow from agglomerating and becoming frozen snow, without cooling the entire space. It can effectively maintain snow quality well.

In addition, according to the indoor ski resort of the present invention, it is possible to form a gellende by spraying artificial snow of a predetermined thickness on the slope inside the building, and artificially formed by the through-flow heat through the heat insulating member on the lower side of the artificial snow that constitutes the gelende. Since the thickness of the heat insulating member is set so that the lower surface portion of the snow melts by a predetermined thickness, a machine for scraping artificial snow that has degraded the quality of the surface of the gelende, a conveyer for conveying the shaved snow, and the like are unnecessary. There is no need to block and prevent sliding, and it is possible to maintain good quality of the gellende at all times with a simple and inexpensive structure.

Fourth embodiment

In the indoor ski resort of the present embodiment, as illustrated in FIG. 11, a snow surface 72 serving as a gelende is formed on the floor inside the building 71 in an inclined state. The building 71 is formed with the ceiling 71a which is a dome-shaped roof, and the side wall 71b. The partition member 73 is arrange | positioned and inserted in this building 71. As shown in FIG. The partition member 73 divides the indoor space inside the building 71 into two upper and lower spaces of the upper space A1 on the ceiling 71a side and the lower space A2 on the snow surface 72 side. have. As the partition member 73, a metal plate, a woven fabric, a thin plate formed of an organic material or an inorganic material can be adopted.

Moreover, it cools so that the airflow temperature of lower space A2 may be 0-5 degreeC, and the temperature of upper space A1 may be 5-10 degreeC. That is, unlike the prior art, the spaces A1 and A2 are not cooled to be lower than the temperature of the snow surface 72 (for example, at -2 to -5 ° C). In addition, in midsummer, the temperature of the outer surface of the ceiling 71a becomes 30-50 degreeC, but the temperature of the inner surface of the ceiling 71b is cooled by the air of the upper space A1, and is 20-30 degreeC.

In the present embodiment, since the partition member 73 is disposed, the radiant heat of the ceiling 71a is blocked by the partition member 73 and does not reach the snow surface 72. For this reason, melting of the snow surface 72 resulting from the radiant heat from the ceiling 71a can be prevented. Therefore, the quality of the snow surface 72 can be kept favorable by setting the temperature of the lower space A2 to 0-5 degreeC (higher than the temperature of the snow surface 72).

As described above, in the present embodiment, since the temperatures of the indoor spaces A1 and A2 do not need to be cooled to be lower than the temperature of the snow surface 72, that is, the airflow temperature of the lower space A2 is set to 0 to 5 ° C. Since the airflow temperature of the upper space A1 may be 5 to 10 ° C, the freezing capacity can be reduced. In particular, since the upper space A1 may be set to 5 to 10 ° C, the freezing capacity as a whole can be reduced. In addition, even if the freezing capacity is reduced in this manner, since the temperature of the lower space A2 is set to 0 to 5 ° C., the quality of the snow surface 72 can be maintained satisfactorily and the number of times to replenish new eyes can be reduced. have.

Moreover, since the partition member 73 is also cooled, it is not necessary to select the thing made of the special material with a small emissivity as the partition member 73, and universal articles, such as a metal plate, can be used. In addition, the ceiling 71a does not need to be made of a special material having a small emissivity, and a general-purpose product conventionally used can be used. Also in this respect, this embodiment can be realized at low cost. In addition, since the partition member 73 can be easily installed, this technique can be easily applied to existing ski resorts as well as new indoor ski resorts.

Here, a comparative examination is made with respect to the prior art and the present invention focusing on the action of radiant heat.

In general, radiant heat occurs between materials of different temperatures and involves heat exchange regardless of distance. When the heat exchange amount per unit area is q, the heat exchange amount q is expressed by the following equation.

[Equation 1]

q = ε ₁ · ε ₂ · σ (T ₁ ⁴ -T ₂ ⁴ )

Where ε ₁ and ε ₂ are the emissivity of both materials

σ is the Boltzmann integer

T ₁ , T ₂ are the surface temperatures of both materials.

The emissivity of the snow surface 72 is close to one near the emissivity of the black object. In order to make this emissivity small, the emissivity of the material which opposes the snow surface 72 may be made small, or the temperature may be made equal.

As a technique of reducing the emissivity of a material facing the snow surface 72, it corresponds to the technique of selecting the material of the ceiling 71a which has been examined conventionally as having a low emissivity. However, even if it is going to do this, as mentioned above, it has a deterioration of age and a bad influence on illumination, and was not able to be satisfied in reality. In addition, as a technique of equalizing the temperature of the snow surface 72 and the substance which opposes, in the conventional technique, the indoor space is overcooled and the temperature of the ceiling 71a or the side wall 71b is equal to snow surface temperature. It is considerable. However, this requires a very large freezing capacity.

In the case of this embodiment, the heat transfer represented by the above formula (1) occurs between the ceiling 71a and the partition member 73 and between the partition member 73 and the snow surface 72. In this case, the partition member 73 is cooled by the cold air of the spaces A1 and A2, and the temperature difference between the temperature of the snow surface 72 and the lower space A1 is only a few degrees Celsius (10 degrees C or less), The snow melting of the snow surface 72 is extremely small.

As described above, according to the indoor ski resort of the present invention, a partition member for dividing the indoor space of a building having a snow surface formed on the floor into two spaces above and below the ceiling side space and the snow surface side of the building is disposed inside the building. Therefore, radiant heat from the ceiling is blocked by the partition member, and snow melting of the snow surface due to the radiant heat can be prevented. Moreover, since the said radiant heat is interrupted | blocked by a partition member, it is not necessary to overcool the temperature of indoor space, and a freezing capacity can be made small. Of course, the quality of the snow can be maintained well.

Fifth Embodiment

In the indoor ski resort of the present embodiment, since the basic structure is the same as that of the indoor ski resort of the third embodiment described above, members having the same functions as those described in the third embodiment are given the same reference numerals and redundant descriptions are omitted.

In the present embodiment, as shown in FIG. 12, the indoor ski slope dome 21 has a semi-circular ceiling 23 formed with respect to the rope 25, whereby the room temperature space M of the upper side and the lower side are formed. It has a low-temperature space area C, and the artificial snow 26 is deposited by predetermined thickness on the slope 25 of this low-temperature space area C, and the gelende 27 is formed. And this indoor ski resort is equipped with the snow maker 28, the snow storage 29, and the snow conveying apparatus 30. As shown in FIG.

In this indoor ski resort, a concrete floor 62 is formed on the bottom surface portion 22 made of concrete via a urethane insulation 61, and artificial grass 63 is placed on the concrete floor 62. ) Is placed, and artificial snow 26 having a predetermined thickness is laid on the artificial grass 63 to form a gelende 27. In addition, the upper surface of the concrete floor 62, the melted groove 64 is formed along the inclined direction of the slope 25, the artificial turf 63 has a plurality of through holes 65 in communication with the melted groove 64 Formed.

On the other hand, the snow surface cold airflow control device 34 has an air regulator with a heat exchanger (not shown) and a fan, and has a temperature (for example, -5 to -10 ° C) at which the snow quality of the artificial snow 26 can be maintained well. By supplying the cool air cooled by) to the surface of the gelende 27, the surface of the artificial snow 26 is cooled, the snow melt is minimized, and the snow quality is maintained satisfactorily.

That is, the lagging main pipe which distributes cold air from the cold air supply pipe 80 of the snow surface cold airflow control device 34 below the bottom surface part 22 of the gelende 27 as shown to FIG. 12-14. (Main pipe) 81 is arranged via a pressure regulating valve 82, and a plurality of air guns in the central portion of the gelende 27 via a branch pipe 83 connected to the main pipe 81 air gun) branch pipe 84 is branched. This jet pipe 84 penetrates the bottom surface part 22, the urethane heat insulating material 61, and the concrete floor 62, and snow is blown off by opening the jet port 85 in the lower surface of the artificial turf 63. FIG. Do not enter (84). The cold air from this jet port 85 is pressurized (for example, about 2 kg / cm <2>), penetrates the artificial turf 63, penetrates the artificial snow 26 above, and blows on snow surface, and covers snow surface. As a result, the surface of snow, which is heated by lighting or skiers, is cooled to about 2 ° C. Since the blowoff pipe 84 is an air gun type, the hole opened to the gelende 27 is small, and it does not become an obstacle in skiing. In addition, the main pipe 81 and the branch pipe 83 can be piped on the concrete floor 62 in addition to the above.

On the other hand, on the side wall along the gelende 27 of the indoor ski slope dome 21, a separate series of lagging auxiliary pipes 86 for distributing the cold air from the cold air supply pipe 80 of the snow surface air flow control device 34. The long slit along the surface of the artificial snow 26 is provided with a plurality of cold air holes 32 which are piped and blow out cold air toward the snow surface on the mother pipes 87 of both side walls connected to the lagging auxiliary pipe 86. It is installed in the shape. Moreover, the exhaust hole 33 which discharges the air inside a dome is formed in the side wall of the gelende 27. As shown in FIG. The height position of this exhaust hole 33 is that the cold air blown out from the jet port 85 and the cold air hole 32 becomes the air flow on the snow surface, and the surface of the artificial snow 26 is cooled, and then the surface of the exhaust hole 33 passes through the return pipe 88. It is slightly higher than the cold air hole 32 so as to be recovered by the cold air flow control device 34. The cold air jet from the main pipe 81 is controlled to increase the cold air pressure in the main pipe 81 by the pressure regulating valve 82 because the jet resistance is larger than that of the cold air from the sub pipe 86.

Therefore, the snow surface cold airflow control device 34 supplies the cold air to the jet port 85 and the cold air hole 32 to the extent that the snow quality of the artificial snow 26 can be maintained well, and supplies it toward the surface of the gelende 27. The surface of the artificial snow 26 is cooled to minimize snow melting and maintain the snow quality well. Then, the cold air supplied toward the surface of the gelende 27 flows along the surface of the gelende 27 as a snow-like airflow while cooling the surroundings (artificial snow 26 or air) and exchanging heat, and then each exhaust hole 33 ) Is returned to the cold air flow control device 34 via the return pipe 88, where heat exchange (cooling) is performed, and is again supplied from the jet port 85 or the cold air hole 32 to the gelende 27. Reference numeral 89 denotes a heat source for supplying a coolant to the heat exchanger of the snow surface airflow control device 34.

As described above, in the present embodiment, cold air is penetrated through the artificial snow 26 on the slope 25 from the plurality of jets 85 opened on the lower surface of the artificial turf 63 and ejected toward the snow surface. Since the cold air is ejected toward the snow surface also from the cold air hole 32 provided in the side wall, a thin cold air layer is formed on the snow surface, and the cold air layer blocks the heat input of the internal space heat of the dome 21 by the gelende. The amount of snow melt of (27) can be reduced, and snow quality can be kept favorable. In addition, since the entire air inside the dome 21 does not need to be cooled like in winter, a skier can enjoy skiing in a relatively light outfit and at the same time suppress energy consumption. In addition, it is possible to supply the cold air at a necessary place at an appropriate time without causing inconvenience to the skier.

In addition, in the present embodiment, the supply of cold air can be diversified, and depending on the situation, it is possible to supplementally supply cold air from the cold air holes 32 having a small ejection resistance arranged along the slope side.

In addition, in the above-described embodiment, the surface of the artificial snow 26 is cooled by supplying cold air from the jet port 85 and the cold air hole 32 toward the surface of the gelende 27 by the snow surface cold air flow control device 34. The quality of the snow can be maintained satisfactorily, or the cold air hole 32 that ejects cold air from the side may be omitted. That is, as shown in FIG. 15, the ejection pipe (over the entire surface of the gelende 27 via the plurality of branch pipes 83 to the lagging main pipe 81 branched from the cold air supply pipe 80 of the snow surface cold air flow control device 34). 84 is connected, and the jet port 85 is formed in the upper end of this jet pipe 84. As shown in FIG. Accordingly, the jet port 85 is arranged over almost the entire surface of the gelende 27, and the piping configuration can be simplified by omitting the lagging sub-pipe, the main pipe, and the pressure regulating valve. The main pipe 81 and the branch pipe 83 are piped between the artificial grass and the concrete floor, so that the blow pipe 84 can be made very short, or the blow pipe 85 can be formed directly in the branch pipe 84.

As described above, according to the indoor ski resort of the present invention, the cold air is blown out at a high speed toward the snow surface through the snow on the slope through a plurality of ejection openings opened at the lower part of the snow while the upper surface of the slope, thereby forming a cold air layer on the snow surface. Therefore, cold air is ejected toward the snow surface through a plurality of blowout openings opened in the lower part of the snow cover, and a thin cold air layer can be formed on the snow surface, and thus the heat input of the space heat inside the building is prevented by the cold air layer. By blocking, the amount of melting of the gelende can be reduced, and the quality of snow can be maintained well. In addition, since the entire air inside the building does not need to be cooled like in winter, skiers can enjoy skiing in relatively light clothes, while reducing energy consumption. In addition, it is possible to supply the cold air at a necessary place at an appropriate time without causing inconvenience to the skier.

Sixth embodiment

In the indoor ski resort of the present embodiment, since the basic structure is the same as the indoor ski resort of the third and fifth embodiments described above, the members having the same functions as those described in each of these embodiments are given the same reference numerals, and overlapped. The description is omitted.

As shown in FIG. 16 and FIG. 17, the lagging which distributes the cold air from the cold air supply pipe 90 of the snow surface cold airflow control device 34 below the gelende 27 bottom surface portion 22 of the indoor ski resort dome 21. The main pipe 91 is arranged via the pressure regulating valve 92, and the expansion pipe 94 with a plurality of cold air jet nozzles in the central portion of the gelende 27 via the engine 93 connected to the main pipe 91. Is branched. The expansion and contraction pipe 94 is arranged at substantially equal intervals throughout the gelende 27, and when not in use, a hole 95 penetrating the bottom surface portion 22, the urethane insulation 61, and the concrete floor 62. Stored in a contracted state. On the other hand, at the time of cold air supply, as shown by the solid line in FIG. 17, the expansion-contraction tube 94 is extended by the expansion | extension operation of the expansion-contraction operation cylinder 96, and the cold air jet nozzle 97 of the top end is installed by snow. Protrudes close to the snow surface through the hole 95 of (26), and blows cold air from the nozzle 97 onto the snow surface to cover the snow surface with a thin layer of cold to block radiant heat from the roof, side walls, and the like. Cool to about 2 ° C. The cover 98 which is larger than the hole 95 is attached to the top surface of the nozzle 97 by attaching artificial grass. The operating rod 96a of the telescopic working cylinder 96 fixed in the machine room 66 extends through the sealing tube 94 from below the branch pipe 93 and extends through the sealing member to the nozzle 97. It is.

On the other hand, the side wall along the gelende 27 of the indoor ski slope dome 21 is provided with a separate series of lagging auxiliary pipes 99 for distributing the cold air from the cold air supply pipe 90 of the snow surface air flow control device 34. In the mother pipe of both side walls connected to the lagging auxiliary pipe 99, a plurality of cold air holes 32 for ejecting cold air toward the snow surface are provided in a long slit shape along the surface of the artificial snow 26. Moreover, the exhaust hole 33 which discharges the air inside a dome is formed in the side wall of the gelende 27. As shown in FIG.

Therefore, the snow surface cold airflow control device 34 supplies the cold air to the nozzle 97 and the cold air hole 32 to the extent that the snow quality of the artificial snow 26 can be maintained satisfactorily. Proper use of the nozzle 97 and cold air hole 32 generally provides strong low temperature cold air only from the cold air hole 32 during daytime operations, and the low temperature cold air only from the nozzle 97 during non-business hours such as night time. By supplying, the whole snow surface of the gelende 27 is kept at 2 degrees C or less. Conventionally, energy consumption is prevented while preventing the occurrence of ice snow and ice burn compared to the case where the cooling is performed by a strong low temperature cold from the cold air supply pipe in order to cool the center of the gelende 27 even during non-business hours, such as at night. Can also significantly reduce. In the case of the wide gelende 27, it may be enclosed with a skier protective cover and then protruded with a sparse nozzle 97 in the center of the gelende to be used during the daytime operation. In the case where the nozzle 97 is disposed at the middle portion and not at the gelende side, it is also possible to supply weak low temperature cold air from the cold air hole 32 at night and use it together with the nozzle 97 at the middle portion.

The cold air is supplied from the nozzles 97 and the cold air holes 32 toward the surface of the gelende 27, and the surface of the artificial snow 26 is cooled to minimize snow melting, thereby maintaining the quality of snow. And the cold air supplied toward the surface of the gelende 27 flows along the surface of the gelende 27 as a surface-like airflow while cooling and heat-exchanging the surroundings (artificial snow 26 or air), and then each exhaust hole 33 When passing through the return pipe (100) to the cold air flow control device 34, the heat exchange (cooling) is performed as described above, and is again supplied from the nozzle 97 or the cold air hole 32 to the gelende 27 do. Reference numeral 101 denotes a heat source for supplying cooling water to the heat exchanger of the snow surface cold air flow control device 34.

As described above, in the present embodiment, cold air is ejected onto the snow surface from the nozzle 97 protruding on the slope 25 as needed, and at the same time, the snow surface is also provided from the cold air holes 32 provided in the side wall along the gelende 27. Since cold air is ejected toward the surface, a thin cold air layer is formed on the surface of the snow, and the cold air layer can block the heat input of the space heat in the dome 21 to reduce the amount of snow melting of the gelende 27, Can be kept good. In addition, since the entire air inside the dome 21 does not need to be cooled like in winter, the skier can enjoy skiing in a relatively light outfit and at the same time suppress the energy consumption. In addition, it is possible to supply cold air at a necessary place at an appropriate time without causing inconvenience to the skier.

In addition, in the present embodiment, the supply of cold air can be diversified, and depending on the situation, it is possible to supplementally supply cold air from the cold air holes 32 having a small ejection resistance arranged along the slope side.

Moreover, in the above-mentioned embodiment, although the lid | cover 98 larger than the hole 95 was attached to the top surface of the nozzle 97, as shown in FIG. 18 and FIG. 19, the top end of the telescopic telescopic tube 94 is shown. A snow hole opening unit may be mounted. That is, at the top end of the expansion pipe 94, a plurality of blade-shaped conical cutters 102 are rotatably mounted on the upper surface of the nozzle 97 via a bearing, and the eyes cut between the blades of the cutter 102. It forms the notch which falls down. The actuating rod 96a which expands and contracts this expansion pipe 94 is extended into the expansion pipe 94 from the lower side of the branch pipe 93 through the sealing member, and moves the nozzle 97 up and down in the thrust part. At the same time, it is rotationally driven by the reversible rotation motor 103 fixed to the machine room 66, and is simultaneously moved up and down in the rotational direction by the spiral guide portion of the motor 103.

Therefore, when the motor 103 is operated from the storage state shown in FIG. 18 to the use state shown in FIG. 19, the operating rod 96a is moved upward by the spiral guide portion and the nozzle 97 is moved upward. In addition, the cutter 102 is rotated to cut the snow and open the hole. Although the cutter 103 has a notch, it also functions as a cover of the hole 95. And in order to make a storage state from this use state, the motor 103 is rotated reversely. As another modification, the electric heater may be mounted on the nozzle 97 as the snow hole opening unit, and the expansion tube 94 may be bellows type or corrugated type instead of the telescope type.

As described above, according to the indoor ski resort of the present invention, since the cold air jet nozzle is installed at the upper end of the flexible pipe that is elastically installed in the hole formed in the slope, the number of skiers and the surface of the skier can be viewed at a time or place where necessary. Create a hole by maneuvering with a snow scoop on the snow, and extend the expansion tube from the hole in the slope to near the snow surface to cool the snow itself, and cool air from the nozzle installed at the upper end to the snow on the slope. You can blow off. As a result, it is possible to reduce the amount of snow in the gelende and keep the snow quality satisfactorily, while it is not necessary to cool the entire air inside the building, so that skiers can enjoy skiing in relatively light clothes. In addition, energy consumption can be reduced.

And since the cool air is also supplied from the plurality of jets arranged along the slope on at least one side of the slope, even if the jet of the lower part of snow cover is clogged, it can supplementally supply cool air from the jets arranged along the slope side part. . In addition, since the cold air jet nozzle is provided with a cover that closes the hole on its top surface, it is possible to completely prevent snow from entering the hole and to secure the expansion and contraction operation of the expansion pipe. In addition, since the cold air jet nozzle is provided with a snow-opening hole opening unit that can close the hole at its top end, when the cold air is not ejected, the cold air jet nozzle can be stored in a state where snow does not enter the hole of the slope, and the cold air is jetted. In this case, it is possible to automatically make a hole in the snow without any trouble by the snow hole opening unit such as a turning hole opening tool or a heating hole opening tool.

Seventh embodiment

In the indoor ski resort of the present embodiment, since the basic structure is the same as the indoor ski resort of the third embodiment, the same reference numerals are given to members having the same functions as those described in the third embodiment, and redundant descriptions are omitted. .

In the present embodiment, as shown in FIG. 20, the dome 21 has a large space 24 formed by the bottom surface portion 22 and the ceiling 23, and one side of the large space 24 is a room temperature space. It is the area | region M, and the other side becomes the low temperature space area C of an indoor type ski resort, and the slope 25 is formed in the lower surface of the low temperature space area C, and the artificial snow 26 is formed in this slope 25. Predetermined thickness is formed and the gelende 27 is formed. And this indoor ski resort is equipped with the snow maker 28, the snow storage 29, and the snow conveying apparatus 30. As shown in FIG.

Meanwhile, an air dam 31 is formed in the bottom surface portion 22 of the dome 21 so as to divide the room temperature space region M and the low temperature space region C with a step, and the upper side of the gelende 27 is formed on the side wall. A plurality of cold air holes 32 are formed at the side to blow out cold air, and exhaust holes 33 are provided at the side portions of the air dam 31 at the side and the bottom of the gelende 27 to discharge air therein. The exhaust hole 33 is formed at a position slightly higher than the cold air hole 32. The surface-cooling airflow control device 34 supplies cold air at a temperature such that the quality of the snow of the artificial snow 26 can be maintained to the surface of the gelende 27 from each of the cold air holes 32, and the surface of the artificial snow 16 Cooling is kept to a minimum to minimize snow melting, thereby keeping the snow quality satisfactory.

In addition, the air dam 31 is provided with many injection nozzles 35, and the injection direction of the jet from this injection nozzle 35 is the direction of the gelende 27, and the blowing temperature is 20 degreeC-30 It is in degrees Celsius. The jet from the spray nozzle 35 rises through the cold air flowing through the surface of the gelende 27, and flows through the normal temperature space region M along the ceiling 23 of the dome 21, whereby the dome ( 21) It is designed to circulate in me.

In the snow surface cold airflow control device 34 of the present embodiment, in order to maintain the quality of the gelende 27 satisfactorily, it is melted at the lower surface portion of the artificial snow 26 constituting the gelende 27, while the upper surface portion is melted. By spraying and replenishing the new artificial snow 26, the thickness of the artificial snow 26 of the gelende 27 is always constant, and the gelende is blown out by the cold air ejected from the snow surface air flow control device 34 to the upper surface of the gelende 27. The artificial snow 26 of (27) is kept in good snow quality. In this case, in order to minimize the amount of snow melting of the gelende 27, the upper surface of the gelende 27 is balanced so that the heat input and the heat output to the artificial snow 26 of the gelende 27 are balanced. The temperature of the cold air blown off is adjusted and controlled, and the thermal resin in the gelende 27 is kept to a fixed value.

Hereinafter, details of the control of the snow surface cold air flow control device 34 will be described. First, considering the snow melting factor of artificial snow 26 in the gelende 27, the radiant heat from the ceiling and the wall of the dome 21, the slide load heat that slides the gelende 27, and the illumination inside the dome 21 There are heat input, heat of infiltration below the bottom of the slope acting on the gelende 27 from the lower side of the slope 25, heat of snow cooling by cold air supplied to the upper space of the gelende 27, and latent heat of evaporation from the gelende 27. In this case, the ceiling and wall radiant heat, the slide load heat, the light input heat, and the intrusion heat below the slope floor act to warm the artificial snow 26, while the snow surface cooling heat and latent heat of evaporation act to cool the artificial snow 26. Therefore, these calorie conversion calories and each snow melting factor have the following relationship from a heat storage formula.

Heat equivalent to snow melting = Ceiling and wall radiant heat + Slide load heat + Light input heat + Intrusion heat below slope floor-Snow cooling heat-Evaporative latent heat

Among these factors, the ceiling, wall radiant heat, slide load heat, light input and snow cooling heat are variable factors depending on the number of visitors, season or time, but the heat of infiltration and latent heat of evaporation under the slope floor are constant factors. Therefore, the heat input from the snow surface of the gelende 27 to the artificial snow 26 by this fluctuation factor (ceiling, wall radiant heat + slide load heat + light input heat-snow cooling heat) is aimed at 7 kca1 / m 2 h or less. In the snow surface cold airflow control device 34 which sets this snow surface cooling heat, the gelende 27 is controlled by adjusting the blowing temperature T ₀ of the cold air supplied from the cold air hole 32 toward the surface of the gelende 27. The airflow temperature (T _c ) flowing along the surface of is to be kept constant.

Here, the ceiling / wall radiant heat, which is a variation factor, can be obtained by actually measuring the inner temperature of the ceiling 23 and the inner wall temperature of the ceiling 23 with a temperature sensor. Since θ = 0.7 to 5.7 ° C, it is limited to Δq = 1.10 to 9.216 kcal / m 2h when actual temperature is converted into load variation, and several temperature and calorie change models are set and pattern controlled based on the actual temperature. Also good. In addition, the slide load heat is calculated | required from the work intensity | strength used as the number of entrances to the gelende 27, and the calorie index | index at the time of a slide, and illumination input heat is calculated | required from the power consumption of illumination.

On the other hand, consider the heat of intrusion under the slope floor, a factor. The gelende 27 is formed on the bottom surface portion 22 of the dome 21 by urethane insulation, concrete floor, artificial grass, and artificial snow 26 having a predetermined thickness, and the lower surface of the artificial grass is measured point A. The lower surface part 22 (the ceiling surface of a machine room) is made into the measurement point B. From the result of temperature measurement at these two measurement points A and B, the heat penetration rate k1 = 0.083 kcal / m 2 h ° C. (at a temperature of 10 ° C.) at the bottom of the slope 25 can be obtained. The heat of penetration is obtained from this heat flow rate. In this heat penetration flow rate, the load fluctuation range according to the season or daily temperature change is as shown in Fig. 2L, and the change amount is small because the heat insulating performance is high. In addition, latent heat of evaporation can be determined from the amount of condensed water in the heat exchanger of the snow surface cold airflow control device 34 by the snow quality maintenance control of the gelende 27, and can be calculated | required by a fixed value.

By the way, when the measurement of snow surface cooling heat, which is a variation factor, requires measurement devices such as thermocouples to be installed on the gelende 27, in practice, it becomes an obstacle to sliding. In addition, it is also possible to measure the amount of snow melt as the amount of snow melt converted and to control the heat of cooling by setting the balance of the conversion equation, but even in this case, it is difficult to install a measuring device of snow melt on the slope 25. At the same time, measurement delay occurs with respect to heat input, and reliability decreases.

Thus, in the present embodiment, when the blowing temperature T ₀ of the cold air from the cold air hole 32 is made constant, the airflow temperature T _{c on the} surface of the gelende 27 is supplied into the dome 21 to prevent internal fluctuations. Since it changes accordingly, it controls so that air flow temperature T _c may be kept constant by controlling this blowing temperature T _c . The fluctuation factors of the airflow temperature (T _c ) are classified into rough external fluctuation factors and internal fluctuation factors, and the external fluctuation factors include ceiling / wall radiant heat f according to daily changes and ceiling and wall radiant heat due to seasonal changes ( g), and the internal fluctuation factor is the fluctuation factor represented by the human body heat generation, that is, the gelende population density (slide load heat) h.

The ceiling and wall radiant heat f according to the daily change and the ceiling and wall radiant heat g according to the seasonal change as the external fluctuation factors may be models shown in FIGS. 22 and 23, respectively. For the f function and the g function, measuring the external fluctuation factor and reflecting it in the airflow temperature (T _C ) will cause trouble in measurement and control. Therefore, the internal temperature of the ceiling 23 in the daily change and seasonal change is After roughly examining the variation characteristic, the control is simplified by pattern control using a predetermined numerical value.

As a support for simplifying this control, the fluctuation of external load in seasonal change is assumed to be 686 persons.

Summer conditions: 531,500kca1 / h

Winter conditions: 381,000kcal / h

Shall be. In addition, when the heat penetration flow rate of the roofing material obtained by the heat penetration flow rate analysis is k = 0.159644 kcal / m 2 h ° C., the load variation Δq when the temperature difference between the outside air temperature and the dome internal temperature increases by 1 ° C. is determined by the roof. When the area is set to 27,098 m 2, Δq = 4,323 kca 1 / h, which is about 1% of the total value.

In addition, when the external variation error is examined, as a calorific difference with respect to the f function, for example, when the temperature difference between the roof and the ceiling varies by ± 10 ° C,

Δq = (Δθ = ± 10 ° C) = ± 43,230kca1 / h

If this is the amount of snow melt,

d '= ± 43230/14500/80/500 × 24 × 1000 = ± 1.79mm / day

The relationship between the temperature difference between the roof and the ceiling and the amount of snow melt is as shown in FIG. Thus, even if the f function is estimated and set, the error factor is considered to be minute. Therefore, for the f function, a numerical value is determined (feed forward) for the prediction, and the snow air ejection temperature (T ₀ ) from the cold air hole 22 of the next day is confirmed by confirming the amount of snow melted measured on a daily basis for the g function. (Feedback) with the setup parameter.

In addition, when the calorie change with respect to the change of the cold air jet temperature T ₀ from the cold air hole 32 is examined with respect to the f function, the cold air from the cold air hole 32 to -10 ° C over the whole of the dome 21 is examined. If the required amount of heat when ejected and the required amount of heat at the time of -5 degreeC are shown,

-10 ℃ condition: 840,000kca1 / h

-5 ℃ condition: 362,000kca1 / h

If this is converted into the amount of snow,

D = (840,000-362,000) / 14500/80/500 × 24 × 1000 = 20mm / day

As described above, the change in calorie value due to the change in the number of people is approximately 155,722 kcal / h, and when the blowing temperature T ₀ = -10 ° C in the summer conditions is set, the cold air from the cold air hole 22 due to the change in the number of people variation in the ejection temperature (T ₀₎ is set to an average 1.5 ℃, it is as shown in Fig.

On the other hand, about the gelende number of people (sliding load heat) (h), for example, if the number of people in the gelende capacity is 686, and the calorific value of the human body heat is calculated as the work intensity 8, it is regarded as 227 kca 1 / h. The calorific value q7 according to the human body heat generated by the capacity

q7 = 227 × 686/14500 = 10.74kca1 / ㎡h

It can be obtained, and the heat change according to the change in the number of people in the gelende as shown in FIG. In this case, the amount of snowfall d7 is

d7 = 10.74 / 80/500 × 24 × 1000 = 6.44 mm / day

Is obtained.

Here, when the internal variation error is examined, the correlation between the number of visitors, the amount of heat generated and the amount of snow melt is as shown in Table 1 below. The f function is set by manually inputting the setting according to the change in the number of the visitors, and the cooling air is controlled according to the load change.

Passenger (person) 0 50 100 150 200 250 300 Calorific Value (kcal / ㎡h) 0 0.78 1.57 2.35 3.13 3.91 4.70 Snowfall (mm / day) 0 0.47 0.94 1.41 1.88 2.35 2.82 Passenger (person) 350 400 450 500 550 600 686 Calorific Value (kcal / ㎡h) 5.48 6.26 7.04 7.83 8.61 9.39 10.74 Snowfall (mm / day) 3.29 3.76 4.22 4.70 5.17 5.63 6.44

In addition, the temperature change of the surrounding environment caused by fluctuations in the internal load caused by the human body is also expected to fluctuate around 1.5 ° C. as described above, so that the temperature change of the surrounding environment is changed from the cold air blowing temperature T ₀ from the cold air hole 32. Determines the h function as a parameter for the setting of.

Here, the control and measurement items are summarized as follows.

1) Predict radiant heat amount by temperature measurement of ceiling 23, and use measured value as correction value of daily change and seasonal change (setting of f function and g function)

2) The temperature difference at the two measurement points A and B at the bottom of the slope 25 is measured to measure the amount of heat intrusion under the bottom of the slope.

3) The f function artificially determines the variation curve in advance.

4) The g function measures snowfall in daily units for correction.

5) The function h depends on the number of entrances

6) For the correction of the h function, the amount of change in the cold air jet temperature T ₀ from each cold air hole 22 is about 1.5 ° C.

In the dome 21 of the present embodiment configured as described above, as illustrated in FIG. 20, the snow surface cold airflow control device 34 can maintain the snow quality of the artificial snow 26 satisfactorily, for example, -5 to -10. Cold air at degrees C is supplied from the plurality of cold air holes 32 toward the surface of the gelende 27, and the surface of the artificial snow 26 is cooled by this cold air so that the surface of the artificial snow 26 is not melted and the quality of the snow is maintained well. . Then, the cold air supplied toward the surface of the gelende 27 flows downward along the surface of the gelende 27, is heat-exchanged to increase the temperature, and returns to the cold airflow control device 34 through the respective exhaust holes 33. Here, heat exchange (cooling) takes place and is again supplied from the cold air hole 32 to the gelende 27.

On the other hand, the airflow control device 37 injects a jet of 20 ° C. to 30 ° C., which is inside the dome 21 at room temperature, from the plurality of injection nozzles 35 to the gelende 27 side. It rises through the cold air which flows through the surface of (27), it circulates along the ceiling 23 of the dome 21, and the inside of the dome 21 is divided into the normal temperature space area M and the low temperature space area C. . A part of the airflow flowing through the ceiling 23 of the dome 21 is returned to the airflow control device 37 through each discharge hole 36, where heat exchange (cooling) is performed, and then again from the injection nozzle 35. It is injected to the gelende 27 side as jetting.

Moreover, in the gelende 27 of an indoor ski resort, the artificial snow 26 melt | dissolves in the lower side part, and melt water returns to the snow maker 18 through the snow groove which is not shown in figure, and this snow maker 18 is tap water. The snow snow 26 is properly manufactured and stored in the snow cellar 29 using the snow melt, and the snow conveying device 30 according to the amount of snow snow is stored in the snow cell 29 up to the gelende 27. ) Is spread and sprayed onto the gelende 27.

In addition, the snow surface cold airflow control device 34 ejects cold air from the respective cold air holes 32 to the upper surface of the artificial snow 26 of the gelende 27, and the artificial snow 26 does not melt the surface portion due to the cold air. Is maintained. Then, as described above, the cold air ejection temperature T ₀ ejected from the cold air hole 32 to the gelende 27 is, as described above, the ceiling and wall radiant heat, the slide load heat, the light input heat, the intrusion heat below the slope bottom, the heat of snow cooling, and the latent heat of evaporation. Is controlled or measured by using as a control factor, and the temperature is adjusted so that the heat balance becomes a constant value by setting the amount of heat of melting according to the amount of snow melting, that is, the heat input and output heat are balanced.

As described above, according to the indoor ski resort of the present invention, the ceiling, wall radiant heat, slide load heat, light input heat, intrusion heat under the slope floor, and snow cooling heat and latent heat of evaporation are supplied as control factors, so that the heat is supplied to the upper space of the snow section to balance each heat. By adjusting the temperature of the cold air to control the heat of cooling, the heat resin is kept at a constant value, so there is no need to scrape artificial snow that has degraded the quality of the snow on the surface of the gelende, or to return the cut snow. It is not necessary to block and prevent sliding, and it is possible to keep the quality of the gellende always good while suppressing the energy consumption more precisely. As a result, it is possible to keep the quality of the snow always good while reducing the amount of melting of the gelende.

In addition, the ceiling and wall radiant heat are obtained from a temperature and calorie change model in constant relation with those selected by the ceiling inner surface temperature and the wall inner surface temperature of the building, and the slide load heat is used as the number of entrances to the ski gelende and the heat generation index. From the work intensity, the light input heat is obtained from the lighting power consumption, the intrusion heat under the slope floor is calculated as the heat penetration rate from the temperature measurement values on the upper and lower surfaces of the snow, and the latent heat of evaporation is supplied to the reflux of the cold air supplied to the upper space of the snow. Since it is calculated | required from the amount of condensate of airflow, it is always possible to maintain snow quality well by the existing apparatus, without having to arrange a separate measuring instrument etc. in a ski gelende.

Claims (20)

In the indoor ski slope where artificial snow of predetermined thickness is sprayed on the slope inside the building, An indoor ski resort, wherein a cold air hole is formed in the side wall of the building, located near the surface height of the artificial snow, and blows cold air into the building. The method of claim 1, An indoor ski resort, characterized in that the exhaust hole is formed on the side wall of the building so as to be located above the cold air hole. The method of claim 2, The interior of the building has a low temperature region of a predetermined height range from the surface of the artificial snow, and a normal temperature region above the low temperature region, wherein the cold air hole and the exhaust hole are formed in the low temperature region. . The method of claim 1, The cold air hole is an indoor ski slope, characterized in that the long slit shape along the surface of the artificial snow. In the indoor ski slope where artificial snow of predetermined thickness is sprayed on the slope inside the building, A snow maker for producing artificial snow, an eye reservoir for temporarily storing the artificial snow produced by the snow maker, an eye conveying device for conveying the artificial snow stored in the snow reservoir, and a plurality of the snow cells, Snow spraying device which can spray artificial snow conveyed by a conveying device to the whole area of the surface of the gelende, and the snow spraying device is controlled according to the amount of snow that is snowed on the gelende to apply artificial snow to a predetermined area of the surface of the gelende. An indoor ski resort comprising: a gelende snowfall control means for forming artificial snowfall having a predetermined thickness suitable for sliding by spraying; and a gelende cooling device for supplying cold air near the surface height of the artificial snow of the gelende. The method of claim 5, The said eye conveying apparatus is an eye conveying tube which conveys the artificial snow stored in the said eye reservoir to the said gelende by a rotary feeder, The eye spray nozzle as the said eye spraying apparatus in the front-end | tip of each said eye conveying tube arrange | positioned in multiple at the said gelende. Indoor ski resort, characterized in that each is equipped with. The method of claim 1, The indoor ski resort, characterized in that the material and the thickness of the heat insulating member is set so that the lower surface portion of the artificial snow melts by a predetermined thickness by the through-flow heat through the heat insulating member directed to the lower side of the artificial snow constituting the gelende. The method of claim 7, wherein The gelende comprises an indoor ski resort comprising the heat insulating member laid on an upper surface of a bottom surface portion, a concrete floor laid on an upper surface of the heat insulating member, and artificial grass laid on an upper surface of the concrete ground. . The method of claim 8, On the upper surface of the concrete floor is formed at least in the inclined direction of the slope of the melting groove, at the same time, the artificial grass characterized in that the plurality of through holes through which the melted snow melted the artificial snow flows into the molten groove is formed ski resort. The method of claim 1, An indoor ski resort, wherein a partition member for dividing the interior space of the building into two spaces above and below the ceiling and spaces is arranged inside the building. The method of claim 1, An indoor ski resort, wherein a cold air hole for ejecting cold air is formed in the upper part of the slope near the surface height of the artificial snow, and an exhaust hole is formed in the lower part of the slope for exhausting cold air near the surface height of the artificial snow. . The method of claim 1, An indoor ski resort provided with a plurality of jet openings that open from the upper surface of the slope to the lower portion of the snow, and blow out cold air at high speed toward the snow surface through the artificial snow on the slope. The method of claim 12, The indoor ski resort, characterized in that the plurality of jet holes are located in the central portion of the gelende. The method of claim 1, An indoor-type ski resort, wherein a stretchable tube is provided in a hole formed in the slope, and a cold air jet nozzle for ejecting cold air near the surface height of the artificial snow is provided at an upper end of the stretch tube. The method of claim 14, The cold air jet nozzle has an indoor ski resort, which has a cover that closes the hole on a top surface thereof. The method of claim 14, The cold air jet nozzle has a snow hole opening unit that forms a communication hole communicating with an upper portion of the hole in the artificial snow. Artificial snow of the gelende is formed by spraying artificial snow of a predetermined thickness on the slope inside the building to melt from the lower surface of the artificial snow that constitutes the gelene, and by spraying and supplementing artificial snow on the upper surface of the artificial snow. A control method for an indoor ski resort, wherein the thickness of the snow is kept constant at all times. The method of claim 17, Radiant heat from the ceiling and walls of the building, sliding load heat from the ski gelende, heat input of lighting inside the building, intrusion heat below the slope floor from below the slope, and cold air supplied to the upper space of the snow section. The snow surface cooling heat and the latent heat of evaporation from the snow portion as a control factor, so that the snow surface cooling heat and the latent heat of evaporation are balanced against the ceiling / wall radiant heat, the slide load heat, the heat of illumination and the intrusion heat below the slope floor. The control method of the indoor ski resort characterized in that the thermal resin is maintained at a constant value by adjusting the temperature of the cold air supplied to the upper space of the snow portion to control the snow surface cooling heat. The method of claim 18, The ceiling and wall radiant heat are obtained from a temperature and calorie change model in constant relation with those selected by the ceiling inner surface temperature and the wall inner temperature of the building, and the slide load heat is determined by the number of entrances to the ski gelende and the time of sliding. The heat input of the illumination is obtained from the lighting power consumption, the intrusion heat below the bottom of the slope is obtained as the heat penetration rate from the temperature measurement values on the upper and lower surfaces of the snow portion, and the latent heat of evaporation is A control method for an indoor ski resort, which is obtained from the amount of condensed water in reflux flow of cold air supplied to an upper space. The ski gelende formed by spraying artificial snow of a predetermined thickness on the slope inside the building is melted from the lower surface of the snowing part of the skiing gelende, and supplemented by spraying artificial snow on the upper surface of the snowing part. In the indoor ski resort control device, by supplying cold air to the upper space of the part, the thickness of the snow part is always kept constant. Radiant heat from the ceiling and walls of the building, sliding load heat from the ski gelende, heat input of illumination inside the building, intrusion heat below the slope floor from below the slope, and heat of snow cooling by cold air from the cold air fan, Using the latent heat of evaporation from the snow cover as a control factor, the cold snow blows out from the cold air blower so that the snow surface cooling heat and the latent heat of evaporation are balanced against the ceiling / wall radiant heat, the slide load heat, the illumination heat input, and the intrusion heat below the slope bottom. An indoor ski resort control device, characterized in that the snow surface air flow control means for controlling the snow surface cooling heat by adjusting the cold air temperature is provided.