RU2549936C1 - Cleaning of ice pack from undesirable impurities - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: proposed process comprises the steps that follow. ice pack is pre-cleaned of top layer by ice combine to the depth of 0.2-0.4 mm. At least three planing cycles are executed by said ice combines and ice pack ice tracks or field surface ply is filled with water. Every cycle consists of the field three planning and filling. Cycle first and second planing is executed with maximum removal cutting and maximum water consumption by combines. Third cycle is cut to the depth of 0.4 mm and maximum water consumption. At least two planing and filling jobs are performed with the use of the mix cleaned deionization in membrane filter by water reversed osmosis and water cleaned by ion-exchange filter. This process is executed at 50% ratio of every part and with the mix electric conductivity of 90-100 mcCm/cm.

EFFECT: ice pack that allows high skating speed, longer life.

5 cl, 4 dwg

Description

The invention relates to technologies for creating sports grounds with ice cover in closed rooms for training and ice skating, and, in particular, to a method for cleaning the surface layer of an ice mass from undesirable impurities. It can be used when servicing an ice mass in enclosed spaces (skating rinks) during training and competition processes for top-level sports, including the Winter Olympic Games in ice sports.

One of the most important issues when conducting training and competitive processes for top-level sports, including the Winter Olympic Games in ice sports, is the ability to fill and maintain a high-speed array of sports ice on indoor ice rinks. Of particular importance are the technological issues of pouring and servicing a high-speed ice massif for an indoor speed skating center. The specifics of ice skating, in contrast to hockey, ice skaters, ice athletes short track and curling, is that the only assessment of the athlete’s performance is the time taken to complete the distance. The success of the competition determines the number of records set at the rink. Rink records are compared with absolute world records or Olympic records, rink records and personal records of athletes, depending on the rating of the competition.

The performance of skaters to a large extent also depends on atmospheric pressure in the arena of the ice rink. The lower the air pressure in the athlete’s performance zone, the lower the air resistance and the higher the athlete’s results. According to Ten Schiphauver, with an increase in the level of the skating rink for every 100 m, the result of a skater's run, for example, by 1,500 m improves by 0.1 seconds per circle on average. This means that due to the high-altitude location of the skating rink, the result of running for one athlete, all other things being equal, for example, at a distance of 1500 m for the Hamar skating rink (height 130 m) is 0.5 seconds better than Vancouver or Sochi skating rink for Nagano skating rink (height 375 m) the result is better by 1.4 seconds, for Calgary (height 1035 m) - by 3.6 seconds, for Salt Lake City (height 1305 m) - by 4.5 seconds, for Medeo ice rink (height 1691 m) - for 5.7 seconds. This advantage of the high-altitude location of the ice rink explains why the overwhelming number of active world and Olympic records were achieved at the high-mountain rinks of Calgary and Salt Lake City.

It should be noted that all four indoor speed skating centers in Russia are located almost at sea level. Therefore, technology is needed to fill and maintain the ice mass, providing an exceptional influence on the growth of the speed properties of the ice surface. This may allow domestic flat ice rinks to create conditions for training and competition processes that compete with the world's best ice rinks, which is very important for the implementation of Olympic competitions.

The results of athletes are determined to a large extent by both the speed properties of sports ice and the optimal parameters of the air environment in the athlete’s running zone.

The prospect of producing a high-speed ice mass for top-level sports, regardless of the development of natural atmospheric processes, should be taken into account when designing demonstration indoor ice arenas, for example, indoor speed skating centers. As a rule, the technological capabilities of the ice rink are laid down in the project for the technological ventilation of the arena premises to optimize the parameters of the ice mass and the air environment in the athletes ’performance area. But in order to bring the flat ice rink rated to the forefront of the World Indoor Ice Rinks, exclusive technological solutions for high-speed ice are needed.

It should also be noted the significant influence of the relative humidity on the velocity properties of the surface layers of the ice mass. The moisture condensate of the air falling in the form of hoarfrost on the surface of the ice massif increases the coefficient of friction of the metal (ridge blades) on ice. The speed properties of ice deteriorate and to maintain the speed properties of ice it follows, as shown in patent RU 2416058 (publ. 10.04.2011) or as published, for example, M.V. Zagainov, G.P. Yakovlev, S.A. Ershov "Sports ice - from quality to records." Magazine "World of Construction and Real Estate" No. 34 for 2009, pp. 46-49 .:

1. “Maintain the relative humidity of the arena’s air above the treadmills at a level at which the formation of condensate on the surface of the ice mass does not develop intensively enough to affect a significant increase in the coefficient of friction. Condensation on the surface of the ice mass does not occur if the surface temperature is higher than the dew point temperature for the parameters of the air above the ice surface. For example, when the ice surface temperature is -6 ° C, the air temperature above the ice surface is + 10 ° C, the relative humidity is 30%, the dew point temperature is about -6.7 ° C. As the relative humidity of the air increases, the dew point temperature rises and the process of condensation on the surface of the ice mass begins.

 2. Maintain the relative humidity of the arena’s air above the treadmills at a level at which skating athletes do not feel discomfort affecting the athlete’s potential on treadmills due to the low relative humidity of the air in the breathing zone. Minimize this discomfort. ”

Typically, relative humidity in the skater’s area is maintained at about 35%.

Also known is the invention relating to the formation of a universal ice mass: patent RU 2413909 (publ. 10.03.2011). The use of this patent will not provide a noticeable effect on the growth of the speed properties of the ice mass to the level already achieved in the arenas of the leading domestic indoor speed skating centers.

The absolute moisture content of the air at a height of 1.5 m above the surface of the ice paths is determined by the parameters of the air environment and is not directly set and regulated by the automatic control system of the technological air conditioners of the arena’s premises during operation of the ice rink. According to the technical conditions of the highest speed skating competitions, the air temperature at the level of 1.5 m above the ice level is set at 13-14 ° C or 14 ± 0.5 ° C. Relative humidity at the indicated level is set at 35 ± 3%. In this case, the absolute moisture content will be about 3.5 g / kg. A change in any of the two indicated parameters of the air environment (temperature and relative humidity) will cause an instantaneous corresponding change in the absolute moisture content.

The temperature of the process water used to fill the ice mass and its maintenance is selected for hose filling from the range of 10-45 ° C, and for combine filling from the range of 40-70 ° C. An important scheme is the use of water temperature values, which is not considered in the mentioned patents.

The surface temperature of the ice mass is selected from the expediency for the type of ice sport. For example, (see MV Zagainov, GP Yakovlev, SA Ershov “Sports ice - from quality to records.” Magazine “World of Construction and Real Estate” No. 34 for 2009, pp. 46-49 ) for figure skating -3 ÷ -4.5 ° C, for ice hockey -4.5 ÷ -6 ° C. Harder choice for speed skating.

In the work “Superfast ice: illusions and reality”. Magazine "Refrigeration business" No. 11 for 2004 shows the dependence of the friction force of the ridge on ice on the surface temperature of the ice (Figure 1). Evaluation of the effect of ice surface temperature on its speed properties, performed by the authors of this work on the experimental data of Figure 1, showed that the minimum friction force of the ridge on the ice surface is 0.008 at an ice surface temperature of 7 ° C. These conditions should provide a higher speed skater. At an ice surface temperature of -6 ° C, this force increases to 0.009, and the ridge sliding conditions on ice worsen, and at an ice surface temperature of 5 ° C this friction force increases to 0.01. Thus, maintaining a temperature of 6 ° C on the ice surface worsens the speed properties of ice by 12.5%, and maintaining a temperature of 5 ° C on the ice surface worsens the speed properties of ice by 25%.

The optimum temperature of the ice surface for speed skating according to research from the University of Amsterdam lies in the range of -5 ° C ÷ -7 ° C, which, in principle, coincides with the results of the above domestic works. An air temperature comfortable for skaters is around 1.5 m above the ice massif + 13 ° C ± 1 ° C. Relative humidity at 1.5 m for high-speed ice should be lowered to 35%. The absolute moisture content of air at an air temperature of 14 ° C and a relative humidity of 35% will be 3.5 g / kg d.v. at a dew point temperature of -1.7 ° C.

For ice sports with high demands on the speed properties of the ice massif (speed skating and curling), deionized water is used to fill and maintain the ice massif in the reverse osmosis membrane filter. The use of softened water in an ion-exchange filter is not desirable, since the salts contained in the water rise in the upper layer of the ice mass and affect the decrease in the speed properties of the ice mass. The use of water softened in an ion-exchange filter is allowed for a short time in limited volumes to solve related technological problems. For other types of ice sports, the use of water softened in an ion-exchange filter is allowed.

The temperature of the concrete technological slab - the support of the ice massif - is an intermediate value and cannot be set as an adjustable technological parameter. The technological resulting parameter is the surface temperature of the ice. And the set parameter is the temperature of the coolant entering the screen pipes of the concrete slab. The temperature of the concrete slab or at the concrete – ice interface is an intermediate temperature, which depends on many parameters, including the thickness of the ice mass, the temperature of the coolant, the temperature of the air above the ice surface and heat inflows to the massif. During operation of the ice rink, it is necessary to select the temperature of the coolant taking into account the thickness of the ice mass, the temperature of the coolant, the temperature of the air above the ice surface and the real heat influx to the ice mass to obtain the desired surface temperature of the ice mass.

As a prototype can be selected invention RU 2414655 (publ. 20.03.2011). The essence of the invention is the formation of a surface layer of an ice mass using water softened in an ion exchange filter or a mixture of water consisting of water softened in an ion exchange filter and water deionized in a reverse osmosis membrane filter, while the proportion of said water softened in ion exchange filter, makes up at least 25% of the total volume of said water mixture.

The disadvantages of this invention is that it does not allow to sufficiently exclude all undesirable impurities that have fallen into the surface layer of the ice mass and worsen the slip. In particular, if the surface layer of the ice mass is added with an excessive amount of a chemical modifier, this method will not completely eliminate the consequences of such an undesirable result.

The accumulation of surfactants and composite in the surface layers of the massif in combination with the exhaust products of internal combustion engines used in the premises of the arena of mechanisms, traces of organic matter and surfactants lead to the appearance on the surface of the moire massif - a small or large pattern of irregularities in the ice surface. View of the surface of the ice having microroughnesses - moire with a fine pattern (embossing) is shown in Figure 2. A view of the surface of the ice having macro-irregularities — moire with a large pattern (embossing), is shown in FIG. 3.

Ice with microroughnesses is a moire with a fine pattern (embossing), as a rule, with high speed properties. It makes you feel like embossed on the surface. Running the skate on such ice is accompanied by a vibration that causes irritation in the athlete. Therefore, naturally, such ice is in no way suitable for competitions. It’s uncomfortable to ride on such ice, which was expressed by the coaches of the country's leading athletes. Ice with macro-irregularities cannot be used even for training processes. With the appearance of moiré, ice requires special technological operations - treatments consisting in dry planing of the surface of the massif and a decrease in the concentration of accumulated substances in the surface layers. In practice, the introduction of inventions in the preparation of competitions leads to the fact that during the training and rolling of athletes the quality of ice meets all high requirements, and during the competition, which lasts, as a rule, 3-5 days, problems with the moire create difficulties with the competition, leading to risk of disruption to the competition.

The present invention will allow to obtain the desired speed properties of the ice mass, to eliminate the consequences of the use of excessive amounts of chemical modifier, as well as impurities trapped in the surface layer of the ice mass.

The specified technical result is provided by the application of a method for cleaning the surface layer of an ice mass from undesirable impurities. The method comprises the following steps, in which: pre-clean the ice mass by performing dry planing of the surface layer of the ice mass by an ice harvester to a depth of 0.2-0.4 mm; carry out at least three planes of planing with ice combines and pouring the surface layer of the ice massif of running ice paths or fields, each cycle consists of three planing and fillings of the field, and in each cycle the first and second planing is performed with a minimum cutting of the layer and the maximum flow of water by the combines and the third - with cutting to a depth of 0.4 mm and maximum water flow; at least two planing and pouring with an ice machine are carried out using a mixture of purified water by deionization in a reverse osmosis membrane filter as water and water purified by an ion exchange filter in a ratio of 50% of each part with the electrical conductivity of the resulting mixture 90-100 μS / cm.

In particular, at least three cycles of planing by ice combines and pouring the surface layer of the ice mass of the ice tracks or fields are carried out by two ice combines at the same time, and in each cycle, during the first and second planing, chips are collected into the hopper of the ice processor from 1/3 to 1/2 the volume of its hopper, and with the third planing - a full hopper.

In particular, the layer is poured at a flow rate of 800 to 1000 l and the above planing and pouring by an ice machine are performed using a mixture of purified water by deionization in a reverse osmosis membrane filter and water purified in an ion exchange filter with a decrease in the proportion of water purified in an ion-exchange filter, up to 25%, 15% and 0% of the total volume with each subsequent filling.

An ice pack can be prepared as follows. A rough ice mass is poured with increasing ice hardness on a clean, fat-free and dried concrete slab, the surface of which is cooled to a temperature of -6 ÷ -7 ° C. Pouring rough ice is performed in 9-12 layers of hose filling using two or four hoses. Hoses are usually used with nozzles without sprays. At least the first three layers are filled with a hose method with a water temperature of 10-20 ° C. For pouring, water purified by deionization in a reverse osmosis membrane filter is used. Water consumption in the fill hose spilling one layer per square treadmills ice rink arena is 8 m layer ^of ± 5%. The time between pouring layers is determined by the duration of freezing of the layer, the duration of the preparation of process water for pouring the next layer and the duration of lowering the temperature of the surface of the array to a predetermined temperature of -6 ÷ -7 ° C. The temperature of the coolant supplied to the screen tubes of the cold supply system of the technological plate should be reduced by 0.5 ° C to the value at the beginning of the filling of the current layer.

The next three to four layers are also filled with a hose method with a water temperature of 25-35 ° C. For pouring, water purified by deionization in a reverse osmosis membrane filter is used. The water consumption for pouring one layer of hose spill, calculated on the area of the treadmills of the arena ice field, is 8 m ³ / layer ± 5%. The time between pouring layers is determined by the duration of freezing of the layer, the duration of the preparation of process water for pouring the next layer and the duration of lowering the temperature of the surface of the array to a predetermined temperature of -6 ÷ -7 ° C. The temperature of the coolant supplied to the screen tubes of the cooling system of the technological plate should be reduced by 0.5 ° C.

At least the next three layers are also filled with a hose method with a water temperature of 35-45 ° C. For pouring, water purified by deionization in a reverse osmosis membrane filter is used. The water consumption for pouring one layer of hose spill, calculated on the area of the treadmills of the ice field of the arena, is 8 m ³ / layer ± 5%. The time between pouring layers is determined by the duration of freezing of the layer, the duration of the preparation of process water for pouring the next layer and the duration of lowering the temperature of the surface of the array to a predetermined temperature of -6 ÷ -7 ° C. The temperature of the coolant supplied to the screen tubes of the cooling system of the technological plate should be reduced by 0.5 ° C.

Finishing the draft ice is completed by planing the last layer with an ice harvester to a depth of 0.35 mm with a combine pouring a layer of water (cleaning after reverse osmosis) with a temperature of 40-55 ° C.

Next, pouring fine or working ice by pouring from 10 to 12 layers. At least the first two layers are filled with a hose method with a water temperature of 10-20 ° C. For pouring, water purified by deionization in a reverse osmosis membrane filter is used. The water consumption for pouring one layer of hose spill, calculated on the area of the treadmills of the ice field of the arena, is 8 m ³ / layer ± 5%. The time between pouring layers is determined by the duration of freezing of the layer, the duration of the preparation of process water for pouring the next layer and the duration of lowering the temperature of the surface of the array to a predetermined temperature of -6 ÷ -7 ° C. The temperature of the coolant supplied to the screen tubes of the cooling system of the technological plate should be reduced by 0.5 ° C.

At least the next four layers are filled with a hose method with a water temperature of 25-35 ° C. For pouring, water purified by deionization in a reverse osmosis membrane filter is used. The water consumption for pouring one layer of hose spill, calculated on the area of the treadmills of the ice field of the arena, is 8 m ³ / layer ± 5%. The time between pouring layers is determined by the duration of freezing of the layer, the duration of the preparation of process water for pouring the next layer and the duration of lowering the temperature of the surface of the array to a predetermined temperature of -6 ÷ -7 ° C. The temperature of the coolant supplied to the screen tubes of the cooling system of the technological plate should be reduced by 0.5 ° C.

Next, planing the last layer with a combine to a depth of 0.35 mm with filling with water (cleaning after reverse osmosis) with a temperature of 40-55 ° C is performed.

Subsequent at least three layers are filled with a hose method with a water temperature of 35-45 ° C. For pouring, water purified by deionization in a reverse osmosis membrane filter is used. The water consumption for pouring one layer of hose spill, calculated on the area of the treadmills of the ice field of the arena, is 8 m ³ / layer ± 5%. The time between pouring layers is determined by the duration of freezing of the layer, the duration of the preparation of process water for pouring the next layer and the duration of lowering the temperature of the surface of the array to a predetermined temperature of -6 ÷ -7 ° C. The temperature of the coolant supplied to the screen tubes of the cooling system of the technological plate should be reduced by 0.5 ° C.

The filling of the finished or working ice is completed by planing the last layer with an ice harvester to a depth of 0.35 mm with a combine filling the layer with water (cleaning after reverse osmosis) with a temperature of 55-70 ° C.

As a result, an ice mass is obtained with a thickness of 25-30 mm, which is the optimal value for the implementation of training and competitive processes of speed skating.

Then, on a formed ice massif, a single chemical modification of the surface layer of the ice massif is carried out. This action is carried out by an ice harvester planing to a depth of 0.3 mm with a combine pouring a layer of water with a temperature of 55-70 ° C, which contains polyvinylpyrrolidone (PVP) in the amount of 0.000524% ± 0.000055% by weight of water and glycerin in the amount of 0 , 00262% ± 0.00039% of the mass of water. Two ice harvesters make planing at the same time, the consumption of technological water of each combine is taken within 640-700 liters. The rest of the water from the tanks of the combines is discharged into the sewer.

The ice paths of the arena field are ready for the training and competition processes of skaters. Ice tracks are served according to the schedule of competitions or training.

During operation, the modifier can and will be washed out of the surface layer of the ice mass. Studies conducted by the authors of this invention showed that the optimal (total = PVP + glycerin + organic layer pollutants) content of modifying organic matter in the surface layer of the ice mass should be in the range 0.005-0.009% of the mass of water forming the ice layer. At an organic concentration of less than 0.001%, there is no technological effect on the growth of the speed properties of the ice massif, and at an organic concentration above 0.01%, the intensive development of moire formation processes begins. The schedule for washing out the modifying additive from the surface layer of the ice mass is shown in FIG. 4.

It should also be noted that it is possible to conduct repeated single chemical modifications of the surface layer of the ice mass after at least one day of a training or competition process. Polyvinylpyrrolidone (PVP) (in the amount of 0.000524% ± 0.000055%) and glycerin (in the amount of 0.00262% ± 0.00039% of the mass of water) used together with process water are used as a chemical modifier of the surface layers of the ice massif. tanks of ice combines used to fill the last layers of the ice mass. Planing to a depth of 0.3 mm will be performed by the ice harvester on the surface of the ice massif with the combine pouring a layer of water (cleaning after reverse osmosis) with a temperature of 55-70 ° C and the corresponding content of modifying organics. Two ice harvesters will also be planing at the same time; the consumption of technological water for each combine is taken within 640-700 liters. The rest of the water from the tanks of the combines is discharged into the sewer. The ice paths of the arena field are ready for the training and competition processes of skaters.

The next single modification of the surface layer of the ice massif is possible after the concentration of the organic modifier decreases below 0.002%. The duration of operation of the ice tracks can be selected taking into account the data shown in Figure 4.

In the case of mistakenly introducing into the surface layer of the ice massif the amount of modifying additive substantially exceeding that recommended in this application (the actual concentration of the content of modifying organics in the surface layer of the ice massif is higher than 0.01%), it is necessary to carry out the following actions on the night before the next training or competition day according to the present invention:

perform dry planing of the surface layer of the ice massif to a depth of 0.2-0.4 mm. Conduct a minimum of 3-5 cycles of combine planing and filling the surface layer of the ice mass. Each cycle should consist of three combine planing and casting. At the same time, in each cycle, the first and second planing is performed with a minimum trimming of the layer (chip collection into the hopper of each of the two combines from 1/3 to 1/2 of the hopper volume). The layer is poured at a maximum flow rate of 800 to 1000 liters. The third planing is performed to a depth of 0.4 mm with a fence of a full hopper by each combine and a water flow rate of 800 to 1000 liters. The interval between planing is determined by the time of rising of ice and preparation of the combine 30-60 minutes;

to carry out 2-3 combine planing and casting using as a process water a mixture purified by deionization in a reverse osmosis membrane filter of water and water purified in an ion exchange filter in a ratio of 50% of each part with the electrical conductivity of the resulting mixture 90-100 μS / cm .

In the case of mistakenly introducing into the surface layer of the ice massif a quantity of modifying additive that is much higher than recommended in the application (the actual concentration of the content of modifying organics in the surface layer of the ice mass is higher than 0.013%), carry out the following actions on the night before the next training or competition day according to the present invention:

to carry out 2-3 combine planing and casting using as a process water a mixture purified by deionization in a reverse osmosis membrane filter of water and water purified in an ion exchange filter with a decrease in the proportion of water purified in an ion exchange filter to 25%, 15% and 0% of the total volume for each subsequent fill. This treatment of the surface layer of the ice mass is recommended to be used only in case of a mistake by technical personnel with the calculation of the concentrations of modifying additives.

Although the specific values of the individual parameters are indicated in this description, all of them are illustrative only and not limiting the scope of the present invention, which is defined only by the attached claims.

Claims (5)

1. A method of cleaning the surface layer of an ice mass from undesirable impurities, comprising stages in which:
- pre-clean the ice mass by performing dry planing of the surface layer of the ice mass by an ice harvester to a depth of 0.2-0.4 mm;
- carry out at least three cycles of planing by ice harvesters and pouring the surface layer of the ice massif of running ice paths or fields, each cycle consists of three planing and fillings of the field, with each cycle the first and second planing being performed with a minimum trimming of the layer and the maximum water consumption by combines, and the third - with cutting to a depth of 0.4 mm and maximum water consumption;
- carry out at least two planing and pouring with an ice machine using water as a mixture purified by deionization in a reverse osmosis membrane filter of water and water purified in an ion exchange filter in a ratio of 50% of each part with a 90- 100 μS / cm ³ . 2. The method according to claim 1, characterized in that at least three cycles of planing with ice combines and pouring the surface layer of the ice mass of ice tracks or fields are carried out by two ice combines at the same time. 3. The method according to claim 1 or 2, characterized in that in each cycle, during the first and second planing, chips are taken into the bunker of the ice processor from 1/3 to 1/2 of the volume of its bunker, and in the third planing, a full bunker. 4. The method according to claim 1 or 2, characterized in that the layer is filled at a water flow rate of from 800 to 1000 liters. 5. The method according to claim 1 or 2, characterized in that the said planing and pouring by an ice machine are performed using a mixture of purified water by deionization in a reverse osmosis membrane filter and water purified in an ion exchange filter with a decrease in the proportion of water, purified in an ion-exchange filter, up to 25%, 15% and 0% of the total volume with each subsequent filling.

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