JP2017176834A - Artificial cold snow - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide artificial cold snow that can efficiently simulate natural snow properties and can easily be produced and used, and greatly reduces restriction to skiing due to environmental temperature and season, and thereby can greatly improve the profit of a skiing ground, and provide a production method.SOLUTION: Artificial cold snow comprises artificial cold snow particles containing solid particles having magnetism. Residual magnetism of the solid particles is in a range of 1,000-9,000 gauss. Materials capable of changing the surface quality are deposited on the surface of the solid particles. A high polymer material layer or a metal plated layer are deposited on the surface of the solid particles. Also, a production method comprises: a step of crushing magnetic materials into the solid particles by a crushing device (1); a step of sorting the solid particles by a predetermined particle size using a sieve and depositing the material layer capable of changing the surface quality on the surfaces of the solid particles after the sorting; and a step of magnetizing the solid particles after the sorting (3).SELECTED DRAWING: Figure 3

Description

  The present invention relates to artificial cold snow, a manufacturing method thereof, and a ski runway comprising the same. In particular, the present invention relates to artificial snow for skiing that is not limited by season and temperature, and a ski runway comprising the snow. The artificial snow is laid on ski runways with different slopes.

  Skiing is a widely popular sport, but is limited to certain climatic conditions. For example, natural snow cannot be formed unless the environmental temperature is low. Therefore, this sport that uses natural snow is limited by environmental temperature and season. Especially at ski resorts, the environment temperature, the season, and the amount of snow are limited, so the business hours of the ski resort are limited, and the cost and work amount of the ski runway are enormous. Therefore, the impact of these restrictions on the profitability of the ski resort is very large.

  At ski resorts, in order to reduce the environmental temperature and seasonal influence as much as possible to improve the amount of snow, snow is generally produced with water using a snow maker, and a ski runway is formed with the manufactured artificial snow. To do. This method not only consumes a great deal of water and energy, has a long snow production time and is very expensive, but is still quite limited to ambient temperature and season.

  In addition to this mainstream method, there are currently two other methods for solving the problem that there is little natural snow in order to reduce the influence on the ski due to environmental temperature and season and to enjoy skiing easily.

In one method, artificial snow is produced by absorbing and expanding water with organic material particles. In order to improve the similarity between the artificial snow and natural snow, in this method, an organic cross-linking agent is used to improve the aggregation between particles during the production, and the fluidity of the particles using an inorganic substance such as talc. There is also a technical plan to improve this. In this method, a large amount of water is still consumed, the manufacturing process is complicated, the characteristics of the manufactured artificial snow are not ideal, and evaporation of moisture is also a problem.

  In another method, the characteristics of a ski runway made of natural snow are simulated with a solid material rather than water. In this method, there is a technical solution in which organic particles and a solid lubricant are mixed to produce artificial snow, and the solid lubricant gives a certain degree of adhesion and fluidity between the particles. There is also a technical proposal that simulates the feeling of skiing using only artificial equipment such as plastic brushes. In such a technical plan, a brush made of a polymer material such as nylon is widely installed at a position such as an inclined road, and the keyboard slides on the plastic brush. This technical proposal is sometimes called “toothbrush skiing”. There is also a technical solution called “mushroom ski” in which the tip of each brush is formed in an arc shape. These methods are collectively referred to as snowless skis. Compared to natural skiing, there is a considerable difference in the feeling and effect of skiing according to the prior art, and its manufacture and use are complex, and the manufactured ski runway should be used as a ski runway using natural snow I can't.

  At present ski resorts, the mainstream method is to produce snow with water to improve the amount of snow. The range of use of the above two alternative methods is very limited, and a method for producing artificial snow that can be used on a large scale has not yet been invented. Therefore, it is necessary to study the technology that can effectively simulate the characteristics of natural snow, is easy to use and easy to use, and can be used on a large scale instead of the technology of producing snow with water.

  The present invention can effectively simulate the characteristics of natural snow, is easy to manufacture and easy to use, greatly reduces the restrictions on skiing due to environmental temperature and season, and greatly improves the profitability of the ski resort It aims to provide artificial cold snow that can be.

  Therefore, the present invention provides artificial room temperature snow for skiing, which is made of artificial room temperature snow particles including solid particles having magnetism.

  Preferably, the artificial cold snow is used for skiing at a ski resort and is widely laid on ski runways having different slopes.

  Preferably, in order to enjoy various sensations when skiing, the residual magnetism of the particles may be any numerical value within a range of 1000 to 9000 gauss. Specifically, it is 2000 to 9000 Gauss, and more specifically 2000 to 2300 Gauss. When the solid particles are ferrite, the residual magnetism is preferably 2000-2300 gauss.

  The present invention further provides a ski runway comprising the artificial cold snow of the present invention.

  Preferably, the ski runway further includes a ferromagnetic layer composed of a plurality of permanent magnet blocks, and the permanent magnet blocks are arranged on the base of the ski runway so as to have the same polarity, and below the artificial normal temperature snow. A ferromagnetic layer is formed.

  The present invention simulates the characteristics of natural snow by the magnetism of the magnetic material. Most importantly, artificial snow can solve the following two problems. (1) Aggregability. That is, the snow particles gather like natural snow and have a stable distribution in a predetermined shape, and adhere to ski runways with different slopes. (2) Attenuation dispersibility. That is, artificial snow that aggregates into a predetermined shape is easily deformed by external force like natural snow, and is shaped and dispersed so as to attenuate, and further dispersed into smaller aggregates or single particles. This is a necessary characteristic when skiing, and can provide the skier with resistance for deceleration, direction control or braking.

  In addition to the solid particles having magnetism, the surface properties of the solid particles having magnetism can be changed by attaching a material layer capable of changing the surface properties of the solid particles, such as a polymer material layer or a metal plating layer. . Provides lubricity to the surface of the particles, reduces the frictional force between the particles and the skateboard, and further simulates the interaction between the natural snow particles and between the natural snow and the skateboard .

The present invention
(1) producing solid particles containing a magnetic material with a non-magnetic material as a main body;
(2) selecting the solid particles with a predetermined particle size by a sieve;
(3) magnetizing the solid particles after sorting;
Further, a method for producing artificial room temperature snow including is provided.

  Preferably, the method further includes a step of attaching a material layer capable of changing the surface properties of the solid particles to the surface of the solid particles after the sorting between the sorting step and the magnetizing step.

  Preferably, the material layer is a polymer material layer.

  Preferably, the method further comprises the step of coloring the material layer adhering to the solid particles.

On the other hand, the present invention
(1) producing solid particles containing a magnetic material;
(2) selecting solid particles containing a magnetic material with a predetermined particle size by a sieve;
(3) magnetizing the solid particles after sorting;
Further, a method for producing artificial room temperature snow including is provided.

  Preferably, the method further includes a step of attaching a material layer capable of changing a surface property to the surface of the solid particles after the sorting between the sorting step and the magnetizing step.

  Preferably, the method further comprises the step of coloring the material layer adhering to the solid particles.

  Preferably, the step of producing the solid particles containing the magnetic material comprises mixing the pulverized or melted magnetic material and the main body material of the melted solid particles into particles, and then converting the solid particles containing the magnetic material into particles. Forming.

  Preferably, the step of manufacturing the solid particles including the magnetic material with the non-magnetic material as a main body magnetizes the main body material while being melted, and automatically arranges the magnetic material included in the main body by the strong magnetic force of the magnetic field. Or having the same polar orientation.

The present invention is an original invention that simulates natural snow and has the following advantages.
1. It can effectively simulate the characteristics of natural snow, is easy to manufacture and easy to use, and can form a ski runway instead of natural snow on a large scale.
2. Not only can a ski runway consisting of only artificial cold snow be formed, but also a ski runway can be formed with natural snow.
3. The business hours of the ski resort can be greatly extended, the production cost of snow can be greatly reduced, and the profit of the ski resort can be greatly improved. Use of the artificial cold snow of the present invention is not limited by time and temperature. By laying in summer, covering with natural snow in winter, and mixing with natural snow during the transition of the season to form a ski runway, the time of the ski season can be extended and extended over the four seasons You can also. In particular, it is possible to improve the current situation in which it takes a lot of time and cost to manufacture artificial snow at a ski resort in an area where the amount of natural snow is small. And by the artificial snow of this invention, the formation operation of a ski runway can be simplified and a manpower cost and time cost can be reduced.

It is drawing which shows one snow particle of one Example of the artificial normal temperature snow of this invention. It is drawing which shows one Example of the solid particle contained in one snow particle of the artificial normal temperature snow of this invention. The solid particles include a magnetic material with a nonmagnetic material as a main body. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a partial cross-sectional view showing a ski runway according to a first embodiment made of artificial room temperature snow according to the present invention. Among them, natural snow covers the artificial cold snow of the present invention. It is a partial sectional view showing a ski runway according to a second embodiment consisting only of artificial room temperature snow of the present invention. It is a partial sectional view showing a ski runway according to a third embodiment made of artificial room temperature snow of the present invention. Among them, a permanent magnet block is laid under the artificial normal temperature snow of the present invention.

The examples described herein are specific, specific embodiments of the present invention, which illustrate, interpret and illustrate the concepts of the present invention and limit the embodiments of the present invention and the scope of the present invention. Cannot be considered. Other than the embodiments described herein, those skilled in the art can adopt other obvious technical solutions based on the contents of the claims and the specification of the present application. These technical solutions include technical solutions that make any obvious replacements and modifications based on the embodiments described herein.

  The drawings of the present invention are schematic, illustrating the concept of the present invention, and schematically showing the shapes and interrelationships of the parts. Also, for ease of browsing and drawing creation, the proportion of the size shown may be enlarged or reduced. Similar parts are indicated by the same reference numerals.

  FIG. 1 is a drawing schematically showing one snow particle 1 of artificial room temperature snow according to the present invention. In one preferred embodiment of the present invention, artificial cold snow is used for skiing and consists of a plurality of snow particles 1. The snow particles 1 include solid particles 2 having magnetism, and a material 3 capable of changing the surface properties is attached to the surface of the solid particles 2, and the material is white on the surface of the solid particles 2. The attached material layer 3 capable of changing the surface properties is, for example, a polymer material layer or a metal plating layer.

The particle size of the solid particles 2 having magnetism can be set according to actual needs. For example, solid particles 2 having different particle sizes may be used at different positions on the ski runway. The particle size of the solid particles 2 may be larger than 4 mm or 0.1 to 4 mm. More preferably 1-3
It may be mm. Even more preferably, it is 2 mm. Artificial room temperature snow made of the above solid particles having different particle size ranges and sizes has different characteristics, in particular, the particle size range of 1 to 3 mm is most widely applied, and the performance is relatively excellent. If necessary, the solid particles 2 may be manufactured in an arbitrary shape such as a sphere, an ellipse, a triangle, a square, or an irregular polygon.

  The solid particles of artificial room temperature snow in the above preferred embodiment have a surface coating layer for changing the surface properties, but the present invention must adhere a material layer for changing the surface properties to the solid particles. Not necessarily.

  Since the solid particles 2 constituting the artificial normal temperature snow have magnetism, there is a significant absorption force due to the magnetic force between these solid particles. Thus, these solid particles have not only a collectability but also a damped dispersibility. These two characteristics are the most important characteristics for simulating natural snow. The collectability is a characteristic that the snow particles 1 gather like a natural snow and have a stable distribution in a predetermined shape, and can adhere to ski runways with different slopes. Attenuation and dispersibility means that artificial snow that aggregates into a predetermined shape is easily deformed by external forces, like natural snow, and is shaped and dispersed so as to attenuate, and further disperse into smaller aggregates or single particles. It is a characteristic. This is a necessary characteristic when skiing, and can provide the skier with resistance for deceleration, direction control or braking.

  The magnetic solid particles 2 may be magnetic material particles shown in FIG. 1 (the solid particles 2 shown in FIG. 1 are made of only a magnetic material), or particles containing a magnetic material with a nonmagnetic material as a main body. Good. FIG. 2 is a drawing showing another embodiment of the solid particles 2. This solid particle 2 is a particle containing a magnetic material 5 with a nonmagnetic material 4 as a main body. When the solid particles 2 having magnetism are particles containing a nonmagnetic material as a main body and containing a magnetic material, the nonmagnetic material 4 of the solid particles is any one selected from metals, organic materials, and inorganic nonmetallic materials. It may be a material. The magnetic material 5 may be distributed within the solid particle body 4, fitted into the solid particle body 4, or surrounded by the solid particle body 4. As described above, the present invention does not necessarily require a material layer that changes the surface properties to be attached to the surface of the solid particles. For example, when the main body of the solid particles is an organic polymer material, as will be apparent, further attaching an organic polymer material to the surface of the solid particles is only a matter that can be appropriately selected, and the metal plating layer is Adhering is only a matter that can be selected as appropriate. According to a specific embodiment of the present invention, it is possible to appropriately select whether or not to attach a material layer that changes the surface properties to the surface of solid particles.

  The magnetic material of the solid particles 2 shown in FIGS. 1 and 2 may be ferrite, a ferromagnetic material such as Fe, Co, or Ni, or a rare earth permanent magnet material. Since the amount of magnetic material required for the present invention is large, a low-cost material such as a ferrite magnet material or a neodymium magnet-based rare earth permanent magnet material is preferably used. The residual magnetism of the solid particles 2 can be set according to actual needs so that the ski runway meets the requirements for the collectability and damping dispersibility of the snow particles 1. For example, the remanence of the solid particles 2 may be set within a range of 1000 to 9000 gauss (Gs), specifically, may be set within a range of 2000 to 9000 gauss (Gs), for example, 3000 gauss, Or it may be 4000 Gauss. The stronger the residual magnetism, the stronger the absorbing power between the snow particles 1, and the greater the attenuation due to attenuation dispersion. When the magnetic material is ferrite, the residual magnetism is preferably 2000 to 2300 gauss, and the collectability and attenuation dispersibility of the snow particles 1 can be utilized.

  The magnetic material of the snow particles may be a mixture of different magnetic materials, such as a mixture of ferrite and rare earth permanent magnet material. In the embodiment of the solid particle 2 shown in FIG. 2, the plurality of magnetic materials 5 included in the nonmagnetic material body 4 may be the same kind of magnetic material particles, or a ferrite and a neodymium magnet-based rare earth permanent magnet material. It may be a mixture of different magnetic materials such as a mixture. Since the residual magnetism of the rare earth permanent magnet material can be larger than the residual magnetism of ferrite, the residual magnetism of the solid particles can be increased by mixing the ferrite and the rare earth permanent magnet material. That is, the absorbing power between the solid particles 2 is increased, and the artificial normal temperature snow generates stronger attenuation when dispersed. In order to increase the absorbing power between the solid particles 2, the solid particles 2 shown in FIG. 2 may be formed so that the polar orientations of the magnetic materials 5 are matched.

  As described above, the material layer 3 capable of changing the surface properties of the solid particles attached to the surface of the solid particles may be a polymer material layer or a metal plating layer. The polymer material is a plastic, a paint, or a polymer matrix composite material. More specifically, the polymer material is polyethylene (PE), polypropylene (PP), polyvinyl chloride (PVC), or polyurethane. The polymeric material layer may be a baked varnish. By attaching a material layer that can change the surface properties of the solid particles to the outside of the solid particles, the surface properties of the solid particles having magnetism can be changed. Provides lubricity to the surface of the particles, reduces the frictional force between the particles and the skateboard, and further simulates the interaction between the natural snow particles and between the natural snow and the skateboard .

  In addition to white, the artificial normal temperature snow of the present invention may be produced in other colors. In particular, by using a polymer material, it is easy to reliably color, and the particles have various colors such as red, blue, and green. Thereby, the applicability of artificial snow is improved, and the visual sense of the skier can be improved and the enjoyment can be improved.

  The artificial cold snow of the present invention is very convenient to store and use, and may form a ski runway alone or may form a ski runway with natural snow. The artificial room temperature snow according to the present invention does not use water and does not use an unstable material, which is very friendly to the environment.

FIG. 3 is a partial cross-sectional view showing the ski runway according to the first embodiment of the present invention made of artificial cold snow and natural snow. In FIG. 3, natural snow 6 covers the artificial cold snow 7 of the present invention, and the artificial cold snow 7 of the present invention is stacked on the base portion 8. Examples of the base portion 8 include a natural site or an artificial site. As shown in the figure, since the slope has a undulating slope, the natural snow 6 and the artificial cold snow 7 constitute a ski runway with a slope. The natural snow 6 and the artificial cold snow 7 constitute ski runways having different gradients including 0 degrees. In the ski runway of this example, instead of natural snow 6, a large amount of artificial normal temperature snow 7 was used, and the amount of natural snow 6 used was greatly reduced, but compared to a ski runway consisting only of natural snow, The feeling when skiing is almost the same. Further, by forming the ski runway with the artificial normal temperature snow 7 as compared with the prior art, the operation of forming the ski runway is greatly simplified and becomes convenient.

  FIG. 4 is a partial cross-sectional view showing a ski runway according to a second embodiment consisting only of artificial room temperature snow according to the present invention. The difference from the embodiment shown in FIG. 3 is that the natural snow is not used at all in the second embodiment, and the artificial cold snow 7 is stacked on the base portion 8 to constitute the ski runway. Such a ski runway is not limited in time and temperature.

  In the embodiment shown in FIG. 3, the natural snow 6 covers the artificial normal temperature snow 7 to form the ski runway. However, the natural snow 6 and the artificial normal temperature snow 7 are mixed uniformly or non-uniformly to form the ski runway. May be configured. That is, there are various embodiments in which the ski runway is formed by natural snow and artificial room temperature snow of the present invention, and the proportion and laying method of natural snow and artificial room temperature snow can be set according to necessity and actual situation.

  FIG. 5 is a partial sectional view showing a ski runway according to a third embodiment of the present invention made of artificial cold snow.

Compared to the embodiment shown in FIG. 3, the ski runway of the third embodiment includes a ferromagnetic layer composed of a plurality of permanent magnet blocks 9, and the permanent magnet block 9 has the same polarity as the ski runway. A ferromagnetic layer is formed on the base portion 8 and below the artificial normal temperature snow 7. The snow particles 1 constituting the artificial normal temperature snow 7 can be automatically aligned in polarity due to the strong magnetic force of the permanent magnet block 9 so that the polar orientation of the snow particles 1 matches as much as possible. Therefore, the absorption power between the snow particles 1 is increased, and a stronger dispersion resistance force can be generated between the snow particles 1. As described above, the attenuation dispersibility is one of the most important characteristics simulated by the artificial cold snow of the present invention.
A stronger dispersion resistance between the two can satisfy the demand for greater attenuation dispersibility. The size of the ferromagnetic layer comprising the permanent magnet block 9 may be substantially the same as the size of the ski runway surface, and may be smaller than the size of the ski runway surface as necessary. The permanent magnet block 9 may be a square of 10 cm × 10 cm, for example.

  Hereinafter, the Example regarding the manufacturing method of the artificial normal temperature snow of this invention is described.

The artificial room temperature snow of the present invention in which the solid particles 2 are made of only a magnetic material can be manufactured by a method including the following steps. That is,
(1) crushing the magnetic material into solid particles with a crusher;
(2) selecting solid particles with a predetermined particle size by a sieve;
(3) attaching a material layer capable of changing the surface properties to the surface of the solid particles after sorting;
(4) magnetizing solid particles to which the material layer is attached;
Is a method for producing artificial room temperature snow.

  In addition, when it is not necessary to adhere the material layer which can change the surface property to the surface of a solid particle, the said method does not include said step (3).

  The material layer is preferably a polymer material layer, and may be a metal plating layer.

  Further, the method may include the step of coloring the material layer attached to the solid particles.

When the artificial cold snow solid particles 2 of the present invention are particles containing a magnetic material with the nonmagnetic material as a main body, the manufacturing method includes the following steps. That is,
(1) producing solid particles containing a magnetic material with a non-magnetic material as a main body;
(2) a step of selecting solid particles containing a magnetic material with a nonmagnetic material as a main body with a predetermined particle size by a sieve;
(3) magnetizing the solid particles after sorting;
Is a method for producing artificial room temperature snow.

  Further, when it is necessary to change the surface properties of the manufactured solid particles, the above-described method is a material layer capable of changing the surface properties on the surface of the solid particles after the sorting between the sorting step and the magnetizing step. May be included.

  Further, the method may include the step of coloring the material layer attached to the solid particles.

  When manufacturing the solid particles 2 containing a magnetic material with a nonmagnetic material as a main body, the main body of the solid particles may be a material selected as necessary from a metal, an organic material, and an inorganic nonmetallic material. Preferably, it is a solid particle containing a magnetic material with a nonmagnetic material as a main body, which is formed by mixing a pulverized or melted magnetic material and a melted main material and then granulating it. When the main body of the solid particles is an organic polymer material, referring to the above description, it is not necessary to attach a material layer whose surface properties can be changed to the surface of the solid particles after sorting.

  In order to increase dispersion damping between solid particles containing a magnetic material with a non-magnetic material as a main body, that is, to increase the absorption between solid particles, the magnetic material that has been ground or melted and melted In the step of mixing with the main body material and then granulating, preferably, the main body material is magnetized while being melted, and the magnetic material contained in the main body is automatically arranged by the strong magnetic force of the magnetic field, or the polar The orientation is the same.

  In the above two types of manufacturing methods, the sieve mesh may be set according to the required particle size of the solid particles. For example, it may be 4 to 10 eyes, more specifically, 5, 8, 9 eyes, and the like.

  The artificial cold snow of the present invention can effectively simulate the characteristics of natural snow, is easy to manufacture and easy to use, simplifies the work of forming the ski runway, and ski skiing on a large scale instead of natural snow A path can be formed. Therefore, the restriction on skiing due to environmental temperature and season can be greatly reduced, and the operating hours of the ski resort can be extended to greatly improve the profit of the ski resort.

  The embodiment of the artificial normal temperature snow of the present invention has been described above. As described above, specific features such as the shape and size of the artificial cold snow of the present invention can be set by the action of the above features. All such settings are matters that can be performed by those skilled in the art. Moreover, those skilled in the art only need to be able to change the combination of the features of the above-described embodiments to realize the object of the present invention. The protection scope of the present invention conforms to the claims of the present application.

Claims (17)

Artificial cold snow for skis, consisting of artificial cold snow particles containing magnetic solid particles,
The remanence of the solid particles is in the range of 1000 to 9000 Gauss,
A material capable of changing the surface properties is attached to the surface of the solid particles,
A polymer material layer or a metal plating layer is attached to the surface of the solid particles,
Artificial cold snow characterized by that.   The artificial room temperature snow according to claim 1, which is used for skiing at a ski resort and is widely laid on a ski runway with different slopes.   The artificial room temperature snow according to claim 1, wherein the residual magnetism of the solid particles is in a range of 2000 to 9000 Gauss.   The artificial room temperature snow according to claim 1, wherein the polymer material layer is made of plastic, paint, or polymer matrix composite material.   The artificial room temperature snow according to claim 4, wherein the polymer material layer is polyethylene, polypropylene, polyvinyl chloride or polyurethane, or the polymer material layer is a baked varnish.   The artificial room temperature snow according to claim 5, wherein the polymer material layer has a color other than white.   The solid particles are ferrite, a ferromagnetic material, or a rare earth permanent magnet material, and the rare earth permanent magnet material is preferably a neodymium magnet-based rare earth permanent magnet material. Artificial cold snow described in 1.   The artificial normal temperature snow according to any one of claims 1 to 6, wherein the solid particles have a particle size of 0.1 to 4 mm. (1) crushing the magnetic material into solid particles with a crusher;
(2) selecting solid particles with a predetermined particle size by a sieve, and attaching a material layer whose surface properties can be changed to the surface of the solid particles after selection;
(3) magnetizing the solid particles after sorting;
Including
The remanence of the solid particles is in the range of 1000 to 9000 Gauss,
The material layer is a polymer material layer or a metal plating layer,
The manufacturing method of the artificial normal temperature snow characterized by the above-mentioned.   The method for producing artificial room temperature snow according to claim 9, further comprising a step of coloring the material layer adhering to the solid particles.   The method for producing artificial room temperature snow according to claim 9, wherein the residual magnetism of the solid particles is in a range of 2000 to 9000 Gauss.   A ski runway comprising the artificial cold snow according to any one of claims 1 to 8.   It includes a ferromagnetic layer composed of a plurality of permanent magnet blocks, and the permanent magnet blocks are arranged on the base of the ski runway so as to have the same polarity, and a ferromagnetic layer is formed below the artificial normal temperature snow. The ski runway according to claim 12.   The artificial normal temperature snow according to claim 1, wherein the residual magnetism of the solid particles is in a range of 2000 to 2300 gauss.   The artificial normal-temperature snow according to claim 1, wherein the solid particles have a particle size of 1 to 3 mm.   The artificial normal temperature snow according to any one of claims 1 to 8, wherein the solid particles have a particle size of 2 mm.   The method for producing artificial room temperature snow according to claim 9, wherein the residual magnetism of the solid particles is in a range of 2000 to 2300 gauss.

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