JPH04131413A - Heat-insulating floor unit for indoor artifitial skiing course - Google Patents

Abstract

PURPOSE:To prevent sliding between members against a slant surface and attach a heat-insulating floor in a short time, by laminating concrete coated with concrete, a heat-insulating material, and a water-proof sheet in the inside of a quadrilateral column frame and containing it therein. CONSTITUTION:A heat-insulating floor member laminated with concrete layers 15 coated with a concrete layer 12 in the lower part, a heat-insulating layer 13 enveloped by aluminum foil 14 at the periphery in the middle, and water- proof sheets 16, 22, 23 in the upper part within a quadrilateral column frame 11 with a deck plate as a bottom plate are fitted respectively to a beam 7 with fixture members 18 and angle-adjusting members 21. In this way, even when this is installed on an inclined face, this does not slide on a floor member and even when water leaks from the water-proof sheets 16, 22, 23, the heat- insulating ability can be prevented from decreasing. And further, since this can be fabricated in a factory, the fitting work can be carried out in a short interval.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] This invention relates to a heat insulating floor unit for forming a heat insulating floor for an indoor ski resort.

[Prior Art] Figure 5 is a diagram showing a cross section (a cross section perpendicular to the inclination direction) of an indoor ski resort 1 constructed with a steel frame structure. It is composed of a floor part 4 formed on an erected pillar 3, wall parts 5 erected on both sides of the floor part 4, and a roof part 6 with a frame extending over the upper end of the wall part 5.

Indoor ski resorts use air conditioners to maintain indoor ski slopes at a low temperature of -3 to 5 degrees Celsius, and create ski slopes by depositing about 50 ml of snow on the floor using a snowmaking machine. Indoor ski resorts have high temperatures (30 to 4 in the summer).
3° C.) In order to insulate the heat input from the outdoors to the indoors, the floor 4, walls 5, and roof need to have a heat insulating structure. In particular, snow mats (artificial turf-like material made of short fibers flocked to a waterproof sheet) and waterproof sheets to form drainage gutters are pasted on the floors of indoor ski resorts to prevent snow from sliding. and pile up snow on top of it. When snow is used for downhill skiing, the surface of the snow gets dirty, so it is necessary to pile up new snow on top of the dirty snow and melt the snow at the bottom to regenerate the snow. Therefore, the top of the snow mat and the waterproof sheet that forms the drainage gutter is always covered with water.
If water leaks from the tarpaulin or vapor barrier layer and enters the insulation material, the insulation ability of the insulation floor will be reduced, so the insulation floor must be moisture-proof.The floor structure of an indoor ski resort suitable for such conditions. has not been published yet.

[Problems to be Solved by the Invention] The following conditions must be satisfied for the insulated floor of an indoor ski resort.

(1) The insulating floor must be installed at an angle, and the inclination must not cause the floor components to slip or collapse.

(21) Even if water leaks from the waterproof sheet or vapor barrier layer pasted on the floor, it must be ensured that the water does not infiltrate the insulation material that makes up the insulated floor.

(3) The insulation floor can be installed in a short period of time.

The object of the present invention is to provide a heat insulating floor for an indoor ski resort that satisfies one or more conditions.

[Means for Solving the Problems] The present invention aims to achieve the above object, and provides a heat insulating material in which a concrete layer is placed at the bottom of a rectangular parallelepiped frame with a deck plate as a bottom plate, and the outer periphery is wrapped in aluminum foil in the middle. The layer consists of a heat insulating floor member laminated with a concrete layer with the top edge, sides and bottom covered with a waterproof sheet, a mounting member provided on the bottom of the rectangular parallelepiped frame, and an angle adjustment member for the heat insulating floor. This is a heat insulating floor unit for an indoor artificial ski resort, in which the floor is attached to a beam using the attachment member and the angle adjustment member.

In the above, the angle adjusting member may be a wedge, and the wedge and the mounting member may be fastened together with a stud bolt and nut fixed to the slope.

Alternatively, the angle adjustment member may be a wedge, and the mounting member may be fastened to a mounting plate erected on a simulated inclined surface using bolts and nuts.

Further, the angle adjustment member can be an adjustment bolt or nut whose head is fixed to the beam.

Further, the angle adjustment member can be an angle adjustment stand made of an inclined plate formed between stop plates erected at both ends of the beam.

[Function] Since the lower concrete layer, intermediate insulation layer, and upper concrete layer are housed inside the rectangular parallelepiped frame with the deck plate as the bottom plate, there is no slippage (slippage) between these floor components even when installed on an inclined surface. ) does not occur.

Furthermore, since the outer periphery of the insulation material is wrapped in a waterproof layer with aluminum foil, even if water leaks from the drainage gutter or the waterproof sheet on the underside of the upper concrete, water will not penetrate into the insulation material.

Further, by using a structure in which the angle adjustment member and the mounting member are fastened with bolts and nuts, the heat insulating floor can be easily replaced.

Further, by using the angle adjustment member as an adjustment bolt and nut whose heads are fixed to the beam, the angle adjustment and the replacement of the heat insulating floor become easy.

Furthermore, if the angle adjustment member is an angle adjustment stand made of an inclined plate formed between stop plates erected at both ends of the beam, the heat insulating floor can be replaced more easily.

[Example] Examples of the present invention will be described below based on the drawings.The insulating floor of the present invention has a planar size of 3 to 10 m (vertical)
It was made from 3 to lOm (horizontal), and the beam 7 (
(see Figure 5) and form the slope of the slope. FIG. 6 is a diagram showing a part of the plane of the insulating floor installed on the beam, and a drainage gutter 8 for draining snowmelt water is provided between the insulating floors 10 installed side by side and the adjacent insulating floor 10.

FIG. 8 is a diagram showing a first embodiment of the heat insulating floor unit of the present invention. In FIG.
There is a lower concrete layer 12 inside, a layer 13 of heat insulating material (polystyrene foam, etc.) whose outer periphery is wrapped with a waterproof layer 14 with aluminum foil, and an upper concrete layer (covered with a waterproof sheet) 6 on the top edge, sides and bottom. Alternatively, it is refined by laminating layers of holding concrete (15). Attachment members (lip channel steel) are attached to the two edges of the bottom of the rectangular parallelepiped frame 11.
The upper flange of 18 is fixed. On the other hand, an angle adjustment member 21 (one bolt fixed to the inclined surface of a wedge) is fixed on the beam 7. Then, the heat insulating floor 10 is fixed to the beam 7.7 by passing the stud bolts 19 of the angle adjusting member 21 into the bolt holes of the lower flange of the mounting member 18 and tightening the nuts 20. Therefore, the heat insulating floor 10 is installed on the beam 7.7 with an angle of inclination of the wedge by the angle adjusting member 21. A stepped portion 30 is formed around the entire upper edge of the upper concrete layer 15 of the heat insulating floor 10,
A drainage gutter 8 is formed by attaching a waterproof sheet 22 to the recess formed by the stepped portion 30, 30 adjacent to the heat insulating floor and the upper edge of the upper concrete. In addition, the upper concrete layer 1
A snow mat 17 is attached to the upper surface of the drain gutter 5 and the upper part of the drainage gutter 8. Note that if the waterproof sheet 23 is attached from the stepped portion 30 to the outer periphery of the side wall of the rectangular parallelepiped frame, water ingress into the heat insulating material can be more completely prevented. In addition, external heat is removed by the mounting member 18,
It is transmitted to the bottom of the snowfall through the side wall of the rectangular parallelepiped frame 11, thereby promoting the metabolism of the snowfall.

FIG. 2 is a diagram showing a second embodiment of the insulating floor unit of the present invention. In this example, the bottom plate and side walls of the rectangular parallelepiped frame 11 are formed of deck plates. A mounting member 18 is formed by fixing angle iron to two edges of the bottom surface of the rectangular parallelepiped frame 11. The angle adjustment member 21 is a wedge with a mounting plate 24 erected on the inclined surface thereof, and is fixed onto the beam 7.

and the attachment member 18.1 of the adjacent insulated floor 10.10.
8 with the mounting plate 24 of the angle adjustment member 21 in between, pass the bolt 25 through the bolt hole of the flange and the mounting plate 24, and tighten the nut 20 to fix the insulating floor 10 to the beam 7.7. are doing. Note that the formation of the upper and lower concrete layers and the insulation material layer 13 of the insulation floor 10, the formation of the drainage ii8, and the method of attaching the snow mat 17 are the same as in the first embodiment.

FIG. 3 is a diagram showing a third embodiment of the heat insulating floor unit of the present invention. In this example, the bottom plate and side walls of the rectangular parallelepiped frame 11 are formed of deck plates. An upper flange of channel steel is fixed to the two edges of the bottom of the rectangular parallelepiped 11 to attach the mounting member 18.
It is said that The angle adjustment member 21 includes an adjustment bolt 26 whose head is fixed onto the beam 7 (the angle between the axis of the bolt and the perpendicular line is made to match the angle of inclination of the insulating floor) and a nut 20.
are using. Then, the adjusting bolt 26 is passed through the bolt hole of the lower flange of the mounting member 18, and the nut 20.20 is tightened to fix the heat insulating floor 10 to the beam 7.7. In addition,
Upper and lower concrete layers and insulation layer 13 of the insulation floor 10
, the formation of the drainage gutter 8 and the method of attaching the snow mat 17 are the same as in the first embodiment.

FIG. 4 is a diagram showing a fourth embodiment of the heat insulating floor unit of the present invention. In this example, the bottom plate and side walls of the rectangular parallelepiped frame 11 are formed of deck plates. An upper flange of channel steel is fixed to the two edges of the bottom of the rectangular parallelepiped 11 to attach the mounting member 18.
It is said that The angle adjusting member 21 is constructed by installing an inclined plate 28 on stop plates 27 and 27 which are erected at both ends of the beam 7. The heat insulating floor 10 is attached to the beam 7.7 by placing the mounting member 18.18 of the heat insulating floor 10 on the inclined plate 28.28 of the angle adjustment member 21.21. At this time, the lower flange of the upper (right side in the figure) mounting member 18 is connected to the stop plate 2 of the upper angle adjusting member 21.
7 (on the left side in the figure), and the downward movement of the heat insulating floor 10 is prevented. Between the stop plates 27 and 27 of the angle adjustment member 21, there are two mounting members 18 of the adjacent insulating floor 10.10.
．． 18 is inserted and the heat insulating floor 10 is fixed. In addition,
Upper and lower concrete layers and insulation layer 13 of the insulation floor 10
, the formation of the drainage gutter 8 and the method of attaching the snow mat 17 are the same as in the first embodiment.

[Effects of the Invention] Since the present invention is configured as described above, the following effects can be obtained.

(1) Since the floor components including the concrete layer and the heat insulating layer are housed inside the rectangular parallelepiped frame, no slippage occurs between the floor components even when installed on an inclined surface.

(2) Since the outer periphery of the insulation material is wrapped with a sheet waterproof layer with aluminum foil, even if water leaks from the drainage gutter or the waterproof sheet on the upper concrete, water will not enter the insulation material and the insulation ability of the insulation material will not decrease. .

(3) Since the insulating floor unit can be manufactured in a factory, the insulating floor can be installed in an indoor ski resort in a short period of time.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing a first embodiment of the heat insulating floor unit of the present invention, Section 2 is a diagram showing a second embodiment of the heat insulating floor unit of the present invention, and FIG. 3 is a diagram showing the heat insulating floor unit of the present invention. FIG. 4 is a diagram showing a fourth embodiment of the insulated floor unit of the present invention, FIG. FIG. 6 is a partial plan view of an inclined surface made with the heat insulating floor unit of the present invention. 7... Beam, 8... Drain gutter, 10... Insulated floor, 11...
・Rectangular parallelepiped frame, 12... Lower concrete layer, 13...
・Insulating material layer, 14...Sheet waterproof layer with aluminum foil, 1
5... Upper concrete layer, 16... Waterproof sheet,
17...Snow mat, 18...Mounting member, one piece.
- Studded bolt, 20... Nut, 21... Angle adjustment member, 22. 23... Waterproof sheet, 24... Mounting plate, 25... Bolt, 26... Adjustment bolt, 27...
- Stopping plate, 28... inclined plate. Figure 1

Claims (5)

[Claims] (1) Inside a rectangular parallelepiped frame with a deck plate as the bottom plate, there is a concrete layer at the bottom, an insulating layer in the middle whose outer periphery is wrapped in aluminum foil, and a concrete layer at the top with a waterproof sheet covering the top edge, sides, and bottom. A heat insulating floor for an indoor artificial ski resort, consisting of a heat insulating floor member made of laminated materials, a mounting member provided on the lower surface of a rectangular parallelepiped frame, and an angle adjusting member for the heat insulating floor, the heat insulating floor being attached to a beam by the mounting member and the angle adjusting member. unit. (2) The heat insulating floor unit for an indoor artificial ski resort according to claim 1, wherein the angle adjusting member is a wedge, and the wedge and the mounting member are fastened together with stud bolts and nuts fixed to the wedge slope. (3) The heat insulating floor unit for an indoor artificial ski resort according to claim 1, wherein the angle adjusting member is a wedge, and the mounting member is fastened with bolts and nuts to a mounting plate provided upright on the wedge slope. (4) The heat insulating floor unit for an indoor artificial ski resort according to claim 1, wherein the angle adjustment member is an adjustment bolt and nut whose heads are fixed to the beam. (5) The heat insulating floor unit for an indoor artificial ski resort according to claim 1, wherein the angle adjusting member is an angle adjusting table comprising an inclined plate formed between stop plates erected at both ends of the beam.