JP4079416B2 - Refrigerator building floor structure - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a floor structure of a refrigerator building, and more particularly to a floor structure that prevents underfloor freezing on the lowest floor of the refrigerator building.
[0002]
[Prior art]
In the refrigerator building, a heat insulating layer is provided on the floor, wall, and ceiling so as not to leak the cold inside.
On the other hand, it is conceivable that the heat insulating performance of the heat insulating layer is lowered due to a change with time.
And when the heat insulation performance of the heat insulation layer provided in the floor deteriorates with time, the internal cold heat is transmitted to the soil under the floor, and the soil under the floor may freeze and push up the floor.
In order to prevent such underfloor freezing, conventionally, double pits are provided under the floor of the refrigerator building, and even if the heat insulation layer provided on the floor changes with time, the cold heat inside the refrigerator building is transmitted to the soil under the floor. I am trying not to.
[0003]
[Problems to be solved by the invention]
However, the above method has the following problems.
(1) Creating a double pit requires excavating the ground, which is disadvantageous for shortening the construction period and reducing costs.
(2) The excavated excavated soil must be disposed, which is disadvantageous in terms of cost reduction.
The present invention has been devised in view of the above circumstances, and an object of the present invention is to provide a floor structure of a refrigerator building that can prevent frosting under the floor while shortening the construction period and reducing costs. It is in.
[0004]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides a floor structure of a refrigerator building, wherein the floor of the building is provided on the first concrete layer and the first concrete layer, and a space is communicated in the horizontal direction. A ventilation layer that spreads in a state, and a second concrete layer provided on the ventilation layer, the ventilation layer is configured by using a spring mat formed of a member having heat insulation properties , The spring mat has a plate portion having an upper surface and a lower surface, and a plurality of leg portions formed with through-holes protruding from the lower surface of the plate portion at intervals and penetrating in the thickness direction of the plate portion , A plurality of convex portions projecting at the same length as the leg portions spaced from the lower surface of the plate portion, and the spring mat has the leg portions and the convex portions mounted on the upper surface of the first concrete layer; The second concrete layer is placed in front Concrete is provided on the upper surface of the plate portion of the spring mat, and the through hole is filled with concrete to be placed when the second concrete layer is constructed, and is filled in the through hole. Concrete legs that support the load on the upper surface of the spring mat are provided by the concrete, and the ventilation layer includes the upper surface of the first concrete layer and the plate of the spring mat around the legs and the protrusions. is formed between the lower surface of the part, furthermore, the ventilation means force a ventilation vent layer provided et al is, the ventilation means, the wall portion of the building, the outside the building ventilation A plurality of sleeves that are horizontally spaced to communicate the layers, and an exhaust that extends horizontally along a lower outer surface of the wall of the building facing the wall provided with the plurality of sleeves Duct and Provided at the end of the exhaust duct, at the lower part of the wall where the exhaust duct extends, are a plurality of sleeves that are penetrated in a horizontal direction so as to communicate the exhaust duct and the ventilation layer. It is characterized by including an exhaust fan .
[0005]
According to the present invention, the spring mat is disposed on the first concrete layer, and the second concrete layer is disposed thereon, thereby venting between the first concrete layer and the second concrete layer. Layers can be easily formed. And by forcedly ventilating this ventilation layer, refrigeration under the floor of the refrigerator building is prevented.
[0006]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 is a cross-sectional view of the floor and wall portion of the refrigerator building, FIG. 2 is a cross-sectional plan view of the ventilation layer portion of the refrigerator building, FIG. 3A is a plan view of the spring mat, and FIG. FIG. 4 shows an explanatory diagram of floor construction.
The refrigerator building 12 includes three refrigerators (refrigeration rooms) 16 that are partitioned from each other by a partition wall 14, and the wall 18 of the refrigerator building 12 includes an outer surface of a concrete wall 1802 and a wall 1802 as shown in FIG. 1. The heat insulating layer 1804 made of glass wool, the moisture-proof layer 1806 made of galvalume steel plate provided on the outer surface of the heat-insulating layer 1804, the square wave iron plate 1808 provided on the outer surface of the moisture-proof layer 1806, and the like. In addition, a heat insulating layer 1812 made of urethane foam, a steel plate 1814 that covers the heat insulating layer 1812, and the like are provided in the lower portion inside the wall 18 to prevent damage to the wall 18 during work by a forklift or the like. Reference numeral 20 in FIG.
[0007]
The floor 22 on the lowermost floor of the refrigerator building 12 includes a first concrete layer 24, a ventilation layer 26 provided on the first concrete layer 24, and a second layer provided on the ventilation layer 26. A ventilation means 30 for forcibly ventilating the concrete layer 28 and the ventilation layer 26 is provided.
The first concrete layer 24 is formed by placing concrete on the ground. In the present embodiment, a polyethylene film F is laid on the ground, and concrete is cast on the film F to form a first concrete layer 24. When cracking occurs, the film F prevents moisture from rising from the ground.
[0008]
The ventilation layer 26 is formed using a spring mat 32.
The spring mat 32 is a commercial product that is used for the treatment of the spring under the basement floor. In the present embodiment, as the spring mat 32, “drain foam” manufactured by Uchiyama Engineering Co., Ltd. is used. The spring mat 32 is made of expanded polystyrene and has heat insulation properties.
The spring mat 32 is disposed on the upper surface of the first concrete layer 24, whereby the ventilation layer 26 is formed so that the space extends in a state where the space communicates in the horizontal direction.
As shown in FIGS. 3 (A) and 3 (B), the spring mat 32 has a flat plate portion 3202 having an upper surface and a lower surface, and is projected from the lower surface of the plate portion 3202 with a space therebetween. The leg portion includes a plurality of leg portions 3206 formed with through holes 3204 penetrating in the thickness direction of the plate portion 3202 and a plurality of convex portions 3208 protruding from the lower surface of the plate portion 3202 with a space therebetween. The protruding lengths of 3206 and convex portion 3208 are formed with the same dimension.
The leg portions 3206 and the convex portions 3208 are arranged in a grid pattern as shown in FIG. 3A, and a square is formed by vertical and horizontal rows of the plurality of convex portions 3208, and corners of the squares are formed. Legs 3206 are disposed so as to be positioned.
[0009]
Then, as shown in FIGS. 4A and 4B, a plurality of spring mats 32 having such a configuration are laid on the entire area of the first concrete layer 24, and are placed on each floor 22 of the three refrigerators 16. A spring mat 32 is laid throughout the corresponding location.
The spring mat 32 is disposed on the upper surface of the first concrete layer 24 with legs 3206 and protrusions 3208 placed thereon. Therefore, the ventilation layer 26 is in a state where the space is communicated in the horizontal direction between the upper surface of the first concrete layer 24 and the lower surface of the plate portion 3202 of the spring mat 32 around the leg portion 3206 and the convex portion 3208. It is formed to spread.
[0010]
Next, as shown in FIG. 4C, concrete is placed on the upper surface of the plate portion 3202 of the spring mat 32 to form the second concrete layer 28.
At the time of placing the concrete, the through hole 3204 of the leg 3206 is filled with concrete, and the concrete leg 2802 is formed by the concrete filled in the through hole 3204, and the load on the spring mat 32 is a plurality of loads. The concrete legs 2802 are supported on the first concrete layer 24.
When the second concrete layer 28 is formed, as shown in FIG. 1, a heat insulating layer 34 is formed on the second concrete layer 28 using a stariloform, and further on the heat insulating layer 34. Concrete is cast and a concrete floor surface 36 is formed.
[0011]
The ventilation means 30 performs forced ventilation of the ventilation layer 26. As shown in FIG. 2, the ventilation means 30 includes first to fourth sleeves 3002A, 3002B, 3002C, 3002D, an exhaust duct 3004, an exhaust fan 3006, and the like. Has been.
The first sleeve 3002A is penetrated through the wall 18 of the refrigerator 16 located at one end of the three refrigerators 16 so as to communicate the ventilation layer 26 with the outside of the building.
The second sleeve 3002B is penetrated through the refrigerator 16 located at the end and the partition wall 14 portion of the refrigerator 16 located in the middle so as to allow the ventilation layer 26 to communicate with each other, and the third sleeve 3002C is located in the middle. The ventilation layer 26 is penetrated through the refrigerator 16 located at the other end and the partition wall 14 portion of the refrigerator 16 located at the other end.
The fourth sleeve 3002D is penetrated through the wall 18 portion of the refrigerator 16 located at the other end so as to communicate with the ventilation layer 26.
[0012]
A plurality of the first to fourth sleeves 3002A, 3002B, 3002C, and 3002D are provided at intervals in the horizontal direction. The three sleeves 3002B and 3002C are provided at a finer pitch than the first and fourth sleeves 3002A and 3002D. Therefore, the number of the second and third sleeves 3002B and 3002C is larger than that of the first and fourth sleeves 3002A and 3002D. It is increasing.
The exhaust duct 3004 extends in the horizontal direction along the lower outer surface of the wall 1802 of the refrigerator 16 located at the other end, and the end of each fourth sleeve 3002D is connected to the exhaust duct 3004.
The exhaust fan 3006 is provided at the end of the exhaust duct 3004. Then, by driving the exhaust fan 3006, outside air is sucked into the ventilation layer 26 of the refrigerator 16 located at one end through the first sleeve 3002A, and the outside air remains through the second to fourth sleeves 3002B, 3002C, 3002D. After passing through the ventilation layer 26 of the two refrigerators 16, the air is sucked into the exhaust duct 3004 and released to the atmosphere. In this way, the ventilation layer 26 inside the floors 22 of the three refrigerators 16 is forcibly ventilated.
[0013]
According to the present embodiment, the ventilation layer 26 is provided between the first concrete layer 24 located on the ground and the second concrete layer 32 located above the first concrete layer 24. Since the ventilation layer 26 is forcibly ventilated, the transmission of the cold heat of the refrigerator 16 from the first concrete layer 24 to the ground can be effectively prevented by the ventilation layer 26, and thus the soil under the floor is frozen. It is possible to prevent so-called underfloor freezing on the floor.
Further, the ventilation layer 26 can be easily formed by using a commercially available spring mat used for the spring treatment under the underground floor, and the work of excavating the soil and the remaining soil treatment can be omitted. This is extremely advantageous for shortening the construction period and reducing costs.
Moreover, in this Embodiment, since the spring mat 32 which has heat insulation was used, transmission of the cold heat | fever of the refrigerator 16 to the ground can be blocked more effectively, therefore, it is more effective in preventing underfloor freezing. Is advantageous.
[0014]
In addition, the structure of the spring mat used by this invention is not limited to what was used in embodiment, The thing of the various structures marketed can be used.
[0015]
【The invention's effect】
As apparent from the above description, according to the method of the present invention, a ventilation layer is provided on the floor of the refrigerator building by using the spring mat, so that the frost heaving under the floor while shortening the construction period and reducing the cost. Can be prevented.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of a floor and wall portion of a refrigerator building.
FIG. 2 is a cross-sectional plan view of a ventilation layer portion of a refrigerator building.
3A is a plan view of a spring mat, and FIG. 3B is a front view of the same section.
FIG. 4 is an explanatory diagram of floor construction.
[Explanation of symbols]
12 Refrigerator building 16 Refrigerator 22 Floor 24 First concrete layer 26 Ventilation layer 28 Second concrete layer 30 Ventilation means 32 Spring mat

Claims (1)

A refrigerator building floor structure,
The floor of the building is provided with a first concrete layer, a ventilation layer provided on the first concrete layer and extending in a state where a space is communicated in a horizontal direction, and a second layer provided on the ventilation layer. With a concrete layer,
The ventilation layer is constituted by using a spring mat formed of a member having heat insulation properties ,
The spring mat has a plate portion having an upper surface and a lower surface, and a plurality of leg portions formed with through-holes protruding from the lower surface of the plate portion at intervals and penetrating in the thickness direction of the plate portion , A plurality of convex portions projecting at the same length as the leg portions at intervals from the lower surface of the plate portion ;
The spring mat is placed by placing the leg and the convex on the upper surface of the first concrete layer,
The second concrete layer is provided by placing concrete on the upper surface of the plate portion of the spring mat,
The through hole is filled with concrete to be placed when the second concrete layer is constructed, and concrete legs are provided to support the load on the upper surface of the spring mat by the concrete filled in the through hole,
The ventilation layer is formed between the upper surface of the first concrete layer and the lower surface of the plate portion of the spring mat around the leg portion and the convex portion ,
Furthermore, ventilation means provided et been performed forced ventilation of the ventilation layer,
The ventilation means is
A plurality of sleeves that are penetrated at intervals in the horizontal direction so as to allow communication between the outside of the building and the ventilation layer in the wall portion of the building;
An exhaust duct extending in a horizontal direction along a lower outer surface of the wall of the building facing the wall provided with the plurality of sleeves;
A plurality of sleeves penetrated at intervals in the horizontal direction so as to communicate the exhaust duct and the ventilation layer at a lower portion of the wall from which the exhaust duct extends;
An exhaust fan provided at an end of the exhaust duct.
The floor structure of a refrigerator building characterized by that.

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