KR102180897B1 - Cooling structure of ice rink - Google Patents

Abstract

The ice rink cooling structure according to the present invention comprises a foundation support layer 20 disposed outside the lower portion of the dashboard 10 constituting a fence, and ice adjacent to the lower side of the dashboard 10 inside the foundation support layer 20 Includes an ice quality retention structure layer 100 installed to prevent melting of the surface of the ice rink 30, wherein the ice quality retention structure layer 100 includes a cooling coil buried layer disposed directly under the ice rink ice sheet 30 (110); A cooling coil 120 buried in the cooling coil buried layer 110; A gap maintaining unit 130 disposed under the dashboard 10 and disposed between the cooling coil buried layer 110 and the foundation support layer 20; A waterproof layer 140 constituting a lower portion of the cooling coil buried layer 110; A heat insulating layer 150 inserted into the waterproof layer 140; And an anti-frost layer 160 disposed under the waterproof layer 140, wherein the upper and lower ends thereof are coupled to the dashboard 10 and the base support layer 20, respectively. It is characterized.

Description

Cooling structure of ice rink

The present invention relates to a structure for stably maintaining the ice quality of an ice rink, and more specifically, by arranging a cooling pipe on the lower part of the ice rink fence to prevent melting of the ice surface generated around the fence of the ice rink. It relates to a structure to stably maintain the ice sheet state.

In general, an ice rink is a stadium equipped for various ice competitions, and is a place where ice hockey, figure skating, and short track games are generally held. The bottom of the ice rink is composed of an ice plate, and a fence is installed on the edge to separate the ice rink from the audience seats.

The ice plate of the ice rink connects cooling pipes arranged at regular intervals on the indoor or outdoor floor with a freezer to circulate brine or freon gas as a refrigerant inside the cooling pipe, thereby absorbing heat from the refrigerant to the indoor or outdoor floor. The filled water is cooling. On the other hand, in the means for fixing the fence, the fence used for the ice rink forms a boundary with the ice rink, the grandstand, and the player's waiting room, and serves to protect the safety of the player during the game.

1 is a perspective view showing a cooling pipe installed in a conventional ice rink. In a typical ice rink, a main cooling pipe 2 receiving refrigerant from a refrigerator (not shown) installed outside the track 1 is installed, and the main The cooling pipe branch pipe 3 connected to the plurality of holes (not shown) formed in the cooling pipe 2 is formed in a track shape, and the cooling pipe branch pipe 3 is connected to the track 1 to be fixed. Anchor strip (4) is installed.

Between each of the cooling pipe branch pipes 3 installed in the track, a space 5 for maintaining a certain distance in the horizontal direction is installed to maintain a certain distance.

The main cooling pipe 2 receives the refrigerant from the refrigerator and then supplies the refrigerant to the cooler branch pipe 3, and circulates to the refrigerator again to heat exchange with water to cool the refrigerant whose temperature has risen again.

Meanwhile, in the case of an ice rink under construction or in operation in Korea, ice frozen in the fence area on the boundary of the cooler branch pipe (3) and track (1) melts and flows into the corridor outside the track (1) or into the track (1). As a result, there is a problem that it is difficult to maintain the ice surface, such as causing frostbite to the ice rink user, or ice sludge occurring around the boundary surface of the track 1, resulting in a high maintenance cost.

The present invention is to solve the above problems, and when constructing an ice rink bottom, a cooling pipe is buried up to the bottom of the ice rink fence to transmit a cold heat source, and at the same time, a fence on the foundation concrete constituting the ice rink. The purpose is to stably maintain the temperature of the ice rink and the fixing of the fence by installing an anchor that can fix it.

The present invention prevents melting of the ice surface generated around the fence of the ice rink by supplying a cold heat source directly onto the ice through a cooling pipe disposed on the lower part of the ice rink fence, thereby stably maintaining the ice sheet state. .

In order to solve the above problems, the ice rink cooling structure according to the present invention includes a foundation support layer 20 disposed outside the lower portion of the dashboard 10 constituting a fence, and the dashboard inside the foundation support layer 20 ( 10) An ice rink ice plate 30 adjacent to the lower side includes an ice quality maintenance structure layer 100 installed to prevent melting of the surface,

The ice retention structure layer 100 may include a cooling coil buried layer 110 disposed directly under the ice rink ice plate 30; A cooling coil 120 buried in the cooling coil buried layer 110; A gap maintaining unit 130 disposed under the dashboard 10 and disposed between the cooling coil buried layer 110 and the foundation support layer 20; A waterproof layer 140 constituting a lower portion of the cooling coil buried layer 110; A heat insulating layer 150 inserted into the waterproof layer 140; And an anti-frost layer 160 disposed under the waterproof layer 140, wherein the upper and lower ends thereof are coupled to the dashboard 10 and the base support layer 20, respectively. It is characterized.

The spacing maintaining part 130 is a 90 degree conversion type of H section having a pair of upper and lower horizontal beams arranged along the horizontal direction on the upper and lower ends of the vertical beam based on the vertical beams arranged along the vertical direction, and the The inner space of the spacing part 130 includes an inner spacing part adjacent to the cooling coil buried layer 110 and an outer spacing part facing the base support layer 20 based on the stringer.

The waterproof layer 140 is a state in which a plurality of waterproof cloth member layers each having the insulating layer 150 embedded therein are stacked.

The cooling coil 120 is installed in the cooling coil buried layer 110 at regular intervals and heights through the coil support unit 125, and the coil support unit 125 covers the lower end of the cooling coil buried layer 110 It includes a fixing part welded to a supporting plate and a receiving part for supporting the cooling coil 120, and the coil support 125 has a structure in which a'U' shape is continuously connected through the fixing part, and the accommodation The part has a'M' shape as a whole centering on the'U' shape.

In the present invention, when constructing the ice rink bottom, a cooling pipe is buried to the bottom of the ice rink fence to deliver a source of cooling heat and at the same time an anchor capable of fixing the fence on the foundation concrete constituting the ice rink is installed. Through this, the fence is fixed and the temperature of the ice rink is stably maintained.

The present invention maintains the ice surface by omitting the structure of supplying cold air through an additional method on the ice surface that is melted through the process of providing a cold heat source directly on the ice surface in contact with the fence in a state where the cooling pipe is installed to the bottom of the fence. Reduce costs.

1 is a perspective view showing a cooling pipe installed in a conventional ice rink.
2 is a schematic diagram of a cooling structure of an ice rink according to an embodiment of the present invention.
FIG. 3 is an enlarged view of the ice rink of FIG. 1 centered on a space maintaining part.
4 is a schematic diagram of an ice rink cooling structure according to another embodiment of the present invention.
It is a diagram showing the coupling structure of the cooling pipe with the center of the lower part of the fence of the ice rink.
Figure 5 shows a specific coupling structure of the coil support for supporting the cooling coil.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, only the present embodiments make the disclosure of the present invention complete, and the scope of the invention to those of ordinary skill in the art. It is provided to be fully informed. Like reference numerals in the drawings refer to the same elements.

1 is a schematic diagram of an ice rink cooling structure according to an embodiment of the present invention, in which a foundation support layer 20 made of concrete is formed on the lower outside of the dashboard 10 constituting the fence. In the ice rink, an ice quality maintenance structure layer 100 is formed on the inner side of the base support layer 20 to prevent melting of the ice sheet surface adjacent to the lower side of the dashboard 10.

It has a structure in which water is stored in the ice rink by forming a predetermined jaw with the foundation support layer 20 to freeze water by a cooling pipe.

The ice retention structure layer 100 is disposed on the inside of the dashboard 10 constituting the fence and under the ice rink 30 having a frozen state with an even thickness. A kick plate 50 having a plastic material made of polyethylene is disposed between the inside of the dashboard 10 and the ice rink 30.

The ice retention structure layer 100 is a cooling coil buried layer 110 disposed directly under the ice rink ice plate 30, a cooling coil that allows cooling material such as cooling water to flow in a state buried in the cooling coil buried layer 110 120, a gap maintaining unit 130 disposed between the cooling coil buried layer 110 and the foundation support layer 20 while being disposed under the dashboard 10, and constituting the lower portion of the cooling coil buried layer 110 It includes a plurality of waterproof layers 140, a heat insulating layer 150 inserted into the plurality of waterproof layers 140, and an anti-frost layer 160 disposed under the plurality of waterproof layers 140.

The cooling coil 120 is installed in the cooling coil buried layer 110 at regular intervals and heights through the coil support hole 125.

The coil supporters 125 are installed and fixed on the support plate 111 forming the lower end of the cooling coil buried layer 110, respectively. That is, the coil support 125 is firmly fixed to the support plate by welding or the like.

Referring to FIG. 4, the coil support unit 125 includes a fixing portion 126 welded to the support plate and a receiving portion 127 supporting the cooling coil 120.

The coil support 125 has a structure in which a'U' shape is continuously connected through the fixing part 126 as a whole, and accordingly, the receiving part 127 is approximately'M' around the'U' shape. 'It is made in a shape.

That is, in the cooling coil 120, the fixing part and the receiving part are integrally formed, the fixing part is fixed to the support plate, and the receiving part extends from the fixing part, and the shape is formed in an approximately'M' shape.

The inside of the receiving portion is formed with the same curvature as the cooling coil 120, and the upper end portion is formed with a curvature greater than that of the cooling coil 120. This receiving portion is formed in a'U' shape so that the cooling coil 120 is accommodated and not separated from the outside.

When the cooling coil 120 is placed on the coil support 125, the cooling coil 120 is seated in the center of the receiving portion formed with the same curvature. The cooling coil 120 is connected to a refrigerator, and the cooling coil 120 is cooled to a certain temperature or less by a refrigerant provided from the refrigerator.

Since the cooling coil 120 is cooled while seated in the receiving portion of the coil support unit 125, heat is transferred to the central portion of the receiving portion and heat is transferred to the upper portion of the receiving portion. As the cooling coil 120 is cooled, the entire receiving portion of the coil support unit 125 is cooled, so that the cooling coil 120 and the upper end of the coil support unit 125 are cooled to more evenly cool the frozen state of the ice sheet. Accordingly, the frozen state of the ice sheet surface remains evenly frozen.

The spacing maintenance part 130 enables maintenance of a certain distance between the foundation support layer 20 and the cooling coil buried layer 110 on the lower portion of the dashboard 10 and serves as a direct support function for the dashboard 10.

Referring to FIG. 2, a shape of the space maintaining unit 130 according to an embodiment will be described as follows.

The gap maintaining unit 130 may be a steel structure having an H-shaped cross section adjacent to the lower end of the dashboard 10 along the fence of the ice rink. A steel material having an H cross-sectional shape is used, and it is fixed using anchor bolts 40 to the foundation support layer 20 by penetrating through the waterproof layer 140 and the insulating layer 150 at the bottom. That is, the gap maintaining unit 130 may be fixed on the foundation support layer 20 by placing a plurality of anchor bolts for fixing at a predetermined position.

Specifically, the spacing part 130 has a shape in which the H section is rotated by 90 degrees, and the horizontal direction is defined on the upper and lower ends of the vertical beams based on the vertical beams 131 arranged along the vertical direction. It is a form having a pair of horizontal beams arranged along the upper crossbeam 132 and the lower crossbeam 133. That is, the space between the upper and lower horizontal beams includes an inner spacing part 130a adjacent to the cooling coil buried layer 110 and an outer spacing part 130b facing the base support layer 20 based on the vertical beam. The dashboard 10 may have a structure in which its lower end is tightly coupled to the upper crossbeam 132 of the spacing part 130 through an anchor bolt coupling or riveting process.

The edge portion of the cooling coil buried layer 110 is inserted and disposed on the inner spacing part. That is, by configuring the cooling coil included in the cooling coil buried layer 110 to reach the inner spacing part, the cooling heat supplied from the cooling heat source easily reaches the direct lower part of the dashboard 10. The dashboard 10 is preferably disposed on the upper side of the inner spacing part of the spacing part 130.

It is preferable that a waterproof member in which a heat insulating component is embedded on the inner surface of the inner spacing part is disposed. A waterproof member is positioned between the edge portion of the cooling coil buried layer 110 and the inner surface of the inner spacing part.

That is, when the ice rink ice plate 30 is melted, there is a possibility of leakage to the outside of the dashboard 10 through the lower portion of the dashboard 10 and the cooling coil buried layer 110, and functions to block this in advance. .

The plurality of waterproof layers 140 and the heat insulating layer 150 are disposed under the gap maintaining unit 130 and the cooling coil buried layer 110, and block the vertical movement of the heat source and the vertical movement of moisture based on this Do it.

The plurality of waterproof layers 140 may be in a state in which a plurality of waterproof cloth member layers each having a heat insulating layer 150 embedded therein may be stacked, and the waterproof layer 140 may be for protecting the heat insulating material forming the heat insulating layer 150 have.

The anti-frost layer 160 has a configuration surrounded by sand particles in a state in which the anti-frost pipe 165 is installed therein. The anti-frost pipe 165 means a heating coil. That is, a cooling coil is disposed in the cooling coil buried layer 110 while a heating coil is disposed in the frost protection layer 160.

Meanwhile, referring to FIG. 3, a separate mortar concrete layer 115 is disposed on the lower portion of the cooling coil buried layer 110 to protect the heat insulating layer 150 and maintain the level of the cooling pipe 120.

In addition, a protective mortar layer 170 and a designated waterproof layer 180 disposed under the protective mortar layer 170 may be further included under the anti-frost layer 160 to protect the heat insulating layer 150.

A buffer plate is fixed to one side of the dashboard 10 to buffer the impacts that players collide with, and the buffer plate may be made of a polyethylene plastic named kick plate.

A viewing window for securing a spectator's view may be formed on the upper side of the dashboard 10.

The dashboard 10 is installed on the outside of the ice rink and is a plate material having a certain height and length. The dashboard 10 is made of a buffer material so that the impact is buffered when a person collides. Since the dashboard 10 is installed in the same shape as the ice rink, it is formed in a straight line or arc shape.

The dashboard 10 is installed between the ice rink and the grandstand, and an entrance door or the like is installed in the section connected to the player's access or rest space.

As described above, according to the present invention, in the case of constructing the ice rink bottom, the cooling pipe is buried to the bottom of the ice rink fence to transmit the cold heat source and at the same time, the fence can be fixed on the base concrete constituting the ice rink Through the state where the anchor is installed, the fence is fixed and the temperature of the ice rink ice plate is stably maintained.

Although the preferred embodiment of the present invention has been described above, the present invention is not limited to the specific embodiment described above. That is, a person of ordinary skill in the technical field to which the present invention pertains can make a number of changes and modifications to the present invention without departing from the spirit and scope of the appended claims, and all such appropriate changes and modifications It should be considered that equivalents are also within the scope of the present invention.

Claims (4)

Prevents melting of the surface of the ice rink ice plate 30 adjacent to the lower side of the dashboard 10 toward the inside of the foundation support layer 20 disposed outside the lower and outer sides of the dashboard 10 forming the fence, and the foundation support layer 20 In the ice rink cooling structure including the ice retention structure layer 100 installed to,
The ice retention structure layer 100,
A cooling coil buried layer 110 disposed directly under the ice rink ice plate 30;
A cooling coil 120 buried in the cooling coil buried layer 110;
A spacing part 130 disposed below the dashboard 10 and disposed between the cooling coil buried layer 110 and the foundation support layer 20;
A waterproof layer 140 constituting a lower portion of the cooling coil buried layer 110;
A heat insulating layer 150 inserted into the waterproof layer 140; And
Including; an anti-frost layer 160 disposed under the waterproof layer 140,
The gap maintaining part 130 has its upper and lower ends respectively coupled to the dashboard 10 and the base support layer 20,
The spacing maintaining part 130 is a 90 degree conversion type of H section having a pair of upper and lower horizontal beams disposed along the horizontal direction on the upper and lower ends of the vertical beams based on the vertical beams disposed along the vertical direction,
The inner space of the spacing maintaining part 130 includes an inner spacing maintaining part adjacent to the cooling coil buried layer 110 and an outer spacing maintaining part facing the base support layer 20 based on the stringer,
Ice rink cooling structure.
delete The method of claim 1,
The waterproof layer 140 is a state in which a plurality of waterproof cloth member layers each having the insulating layer 150 embedded therein are stacked,
Ice rink cooling structure.
The method of claim 3,
The cooling coil 120 is installed at regular intervals and heights through the coil support hole 125 inside the cooling coil buried layer 110,
The coil support unit 125 includes a fixing unit welded to a support plate forming a lower end of the cooling coil buried layer 110 and a receiving unit supporting the cooling coil 120, and the coil support unit 125 is'U'. The'shape is a structure that is continuously connected through the fixing portion, and the receiving portion is a'M' shape as a whole centering on the'U' shape
Ice rink cooling structure.

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