KR101377464B1 - Air house - Google Patents

Abstract

The present invention relates to an air house capable of reducing construction period and construction costs and being used as a cultivation facility cultivating crops or as a physical training facility for residents by installing an air roof through which external light passes. The air house comprises: an air roof (100) which has a convex tunnel shape upward by filling the inside thereof with air; an air supplying means (200) supplying air to the outside of the lower part of the air roof (100) or discharging the supplied air to the outside of the upper part of the air roof (100); a shape maintaining means (300) maintaining a shape of an air roof (100) by being fixed to surround the outside of the air roof (100); an external wall (400) forming an inner space (1) therein and erecting on the ground, and having an upper end with which the shape maintaining means (300) is connected and which is located under the air roof (100); and a door (500) formed on one side of the external wall (400) and opening and closing the inner space (1). The air roof (100) includes: multiple tubes (110) which are convex by filling the inside thereof with air and are arranged in parallel by being closely placed from side to side; an air supplying tube (120) which is located between the tubes (110), supplies the supplied air from the air supplying means (200) to the lower part of the outside, and discharges the supplied air to the upper part of the outside; and an air discharging tube (130) discharging the air, supplied from the outside of the air supplying tube (120) to the lower part, from the outside to the upper part.

Description

Air House {AIR HOUSE}

The present invention relates to an air house which is provided with an air roof through which external light is transmitted, takes less construction time and construction costs, and can be used as a cultivation facility for cultivating sports facilities or crops for residents.

Generally, in building a fixed structure, a column is built on the foundation structure to support the building, and a single building is constructed by connecting the beams.

These buildings were used as a sports facility where residents could exercise in the athletics, or as a cultivation facility where light-permeable windows were installed or light was installed inside to cultivate crops.

However, such other building facilities have to be used for a long period of time by securing a certain space inside, so that steel and concrete are used, resulting in a large construction cost and an economical problem that the air can be used for a long time.

In addition, when constructing a vinyl house to grow a crop, the construction costs are low and construction costs are generally used. However, since the structure is not robust, it is damaged by strong winds during rain, and the use period is short due to the characteristics of vinyl. There is a troublesome problem to be solved.

The background art of the present invention is disclosed in Korean Patent Registration No. 10-048006 (Mar. 22, 2005).

An object of the present invention is to provide an air house which can be used as a cultivation facility for cultivating athletic facilities or crops for residents by installing an air roof through which external light is transmitted, .

Air house according to an embodiment of the present invention, the air is filled in the inside of the tunnel-shaped air roof 100 convex upwards, and supplies the air to the bottom outside of the air roof 100 through the air roof 100 Or air supply means 200 for discharging the supplied air to the upper outside of the air roof 100, and the shape maintaining means for maintaining the shape of the air roof 100 is fixed in a state surrounding the outside of the air roof 100 The outer wall 400 and the outer wall (300), the shape maintaining means 300 is connected to the upper end and the upper end is positioned at the lower end of the air roof 100 so as to stand on the ground to form the inner space 1 therein. Is formed on one side of the 400 comprises a door 500 for opening and closing the interior space 1, the air roof 100 is formed by convex by filling the air inside the plurality of tubes arranged side by side close to the left and right ( 110 between the tubes 110 and in the air supply means 200 Air to supply the supplied air to the bottom of the outside, the air supply tube 120 for discharging the supplied air to the top of the outside and the air discharged from the outside of the air supply tube 120 to the bottom from the outside to the top Characterized in that the discharge tube 130.

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Preferably, the tube 110 further includes an inner tube 101 that is inflated by being filled with air in a state accommodated therein, and the inner tube 101 is curved in an arc shape while being curved in an arc shape while being rectangular in shape. It is formed so as to be, the tube 110 is characterized in that the inner side of the inner tube 101 is inserted so that the magic tape 113 is detachably attached to each other.

Preferably, the air supply tube 120 is composed of a transparent synthetic resin so that light is transmitted, it is formed to be bent in a rectangular and arc shape, the air inlet 121 is formed on one side to fill the air therein, the air inlet ( The lower through-hole 122 for discharging the air introduced through the 121 to the lower portion is characterized in that it is formed to communicate with the lower portion.

Preferably, the air roof 100 is fixed in a closed state at the lower end to divide the inner space (1) into the upper space (2) and the lower space (3), the lower through-pipe of the air supply tube (120) 122 further includes a variable membrane 140 connected to each other, the air supply tube 120 is characterized in that the upper through-pipe 123 for discharging the air inside the upper side is formed in communication with the upper portion. .

Preferably, the air discharge tube 130 is composed of a transparent synthetic resin so that light is transmitted, it is formed to be bent in a rectangular shape and arc, the lower inlet 131 is formed, the air is introduced into the bottom, the air to the upper outside The upper discharge pipe 132 at the time of discharge is characterized in that it is formed in communication with the top.

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The air house of the present invention is provided with an air roof through which external light is transmitted, so that it is not necessary to illuminate the room during the daytime, and the air roof is formed by using the tubes, There is also an advantage that the indoor space can be used as a facility for cultivating sports facilities or crops for the residents.

In addition, since the inner space is divided into the upper space and the lower space by providing the variable film in the inner space, the volume of the upper space and the space of the lower space can be adjusted differently, and the air heated by the sunlight can be efficiently used.

1 is a perspective view of an air house according to an embodiment of the present invention;
2 is a perspective view showing a part of the air house of the present invention.
Figure 3 shows a tube of the present invention.
Figure 4 shows an air supply tube of the present invention.
5 is a view of the air discharge tube of the present invention.
FIG. 6 is a perspective view showing a state in which air is supplied to the internal space in the state where the tubes, the air supply tube, and the air discharge tube of FIG. 5 are installed.
FIG. 7 is a perspective view showing a state in which air is discharged from an inner space to the outside in a state where the tubes, the air supply tube, and the air discharge tube of FIG. 5 are installed.
8 is a schematic view of a controller applied to the present invention.
9 is a view of a tube according to another embodiment of the present invention.
10 is a perspective view showing a state where air is supplied to the lower space of the inner space in the state where the tubes of FIG. 9, the air supply tube and the air discharge tube are installed.
FIG. 11 is a perspective view showing a state in which the outside is introduced into the upper space of the internal space in the state where the tubes of FIG. 9, the air supply tube and the air discharge tube are installed.
FIG. 12 is a sectional view showing a state where air is supplied to the lower space of FIG. 9 and the variable membrane is swollen upward. FIG.
FIG. 13 is a sectional view showing a state in which air is introduced into the upper space of FIG. 9 and the variable membrane is lowered downward; FIG.
14 is a sectional view showing a state in which a heat storage material is sprayed upward by the operation of a supply member provided in the heat storage member of the present invention.
15 is a sectional view showing a state where a heat storage material or air is supplied to the ground by the operation of a supply member provided in the heat storage member of the present invention.
Fig. 16 is a view showing the first rope of the shape maintaining means applied to the present invention being wound around tubes, an air supply tube and an air discharge tube, respectively. Fig.
Fig. 17 shows a state in which a second rope and a third rope are bundled in a first rope; Fig.
Fig. 18 shows a state in which a fourth rope and a fifth rope are bound to the second rope and the third rope, respectively. Fig.
Fig. 19 is a perspective view showing the state before the air roof is bundled by the first to fifth ropes and bound to the fixing member of the outer wall; Fig.
20 is a view showing a state in which an air roof is bundled by a first rope to a fifth rope so as to be bound to a fixing member of an outer wall;
21 is a cross-sectional view of an air discharging member installed in a wall of the present invention in an exploded state;
22 is a sectional view showing a state in which the air discharging member of Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figure 1 and 2, the air house according to an embodiment of the present invention,

Tunneled air roof 100 and the air is filled in the upper convex,

Air supply means 200 for supplying air to the lower outer side of the air roof 100 through the air roof 100 or to discharge the supplied air to the upper outer side of the air roof 100,

Form holding means 300 is fixed in a state surrounding the outside of the air roof 100 to maintain the shape of the air roof 100,

Outer wall 400, the form maintaining means 300 is connected to the upper end and the upper end is located at the bottom of the air roof 100, standing on the ground to form the inner space (1) inside,

It is formed on one side of the outer wall 400 includes a door 500 for opening and closing the interior space (1).

3 to 5, the air roof 100 is

A plurality of tubes 110 are arranged side by side while being filled with air inside the convex form and close to the left and right,

An air supply tube 120 positioned between the tubes 110 to supply air supplied from the air supply means 200 to the bottom of the outside, and to discharge the supplied air to the top of the outside;

It consists of an air discharge tube 130 for discharging the air supplied from the outside of the air supply tube 120 to the bottom to the top.

The tube 110 is made of a transparent synthetic resin so that light is transmitted therethrough. The tube 110 is formed to be bent in an arc shape while being rectangular, and an injection port 111 is formed at one side so that air is filled therein. Here, the injection port 111 can be opened and closed by the stopper 112.

In addition, the tube 110 further includes an inner tube 101 that is filled with air and swells up while being accommodated therein.

It is preferable that the inner tube 101 is formed of a rubber having a rectangular shape and being warped in an arc shape and excellent in stretchability, and is formed to be bent in an arc shape. Here, the inner tube 101 is formed with an inner injection port 102 communicating with the injection port 111 of the tube 110 so as to inject air. At this time, it is preferable that a magic tape 113, which is detachably attached to one side of the tube 110 while being opened to insert the inner tube 101, is installed. When the inner tube 101 is expanded in a state where it is embedded in the tube 110, it can be protected by external pressure.

The air supply tube 120 is made of a transparent synthetic resin so that light is transmitted therethrough. The air supply tube 120 is formed in a rectangular shape and warped in an arc shape. An air inlet 121 is formed at one side so that air is filled in the air supply tube 120, And a lower pipe tube 122 for discharging the air introduced through the lower pipe to the lower portion. Here, the lower supply pipe 122 may be composed of a flexible synthetic resin, a vinyl or rubber or a corrugated pipe. The air supply pipe 220 of the air supply means 200 is connected to the air inlet 121 and the air supply pipe 220 is connected to the air inlet 121 through the finish cloth 360.

The air discharge tube 130 is made of a transparent synthetic resin so that light is transmitted therethrough. The air discharge tube 130 is formed in a rectangular shape and warped in an arc shape. A lower inlet 131 through which air flows into the lower portion is formed. And an upper discharge pipe 132 is formed so as to communicate with the upper portion. The upper discharge pipe 132 is provided with an air valve 230 for discharging the air or shutting off the air discharge, and is fixed in a state of passing through the finishing cloth 360 described later.

Accordingly, the air supply tube 120 and the air discharge tube 130 are convexly formed by the shape maintaining means 300 while being arranged in close contact with the air-injected tubes 110 in advance. At this time, when the air compressor 230 of the air supply means 200 is operated and air is supplied while the upper discharge pipe 132 is closed by the operation of the air valve 230, air is supplied through the air supply pipe 220 The air is introduced into the air inlet 121 and is supplied to the lower portion of the air roof 100 through the lower supply pipe 122 while being charged into the air supply tube 120.

In contrast, when the upper discharge pipe 132 is opened by the operation of the air valve 230 while the operation of the air compressor 210 is stopped, air discharged to the lower portion of the air roof 100 flows into the air discharge tube 130, And is discharged to the outside of the air roof 100 through the upper discharge pipe 132. [

As described above, since the internal space 1 of the air roof 100 can always be maintained at a constant air pressure by the air supply of the air compressor 210, the fresh air And can provide fresh air to the crops to be cultivated in the interior space 1. Of course, the air in the inner space 1 can be discharged to the outside through the air discharge tube 130 according to the operation of the air valve 230, so that the air in the inner space 1 can be prevented from being overcharged, It is possible to prevent the air roof 100 from being damaged by air pressure.

As shown in Figure 6 and 7, the air supply means 200 is

An air compressor 210 for forcibly supplying external air;

An air supply pipe 220 connected to the air roof 100 to charge the air supplied from the air compressor 210 to the internal space 1 through the air roof 100,

An air valve 230 installed in the air roof 100 so that air filled in the inner space 1 of the air roof 100 is discharged to the outside;

An air pressure sensor 240 provided in the inner space 1 of the air roof 100 to measure an internal pressure;

The controller for operating the air compressor 210 while closing the air valve 230 according to the detection of the air pressure sensor 240, or opening the air valve 230 while stopping the operation of the air compressor 210. 250.

In FIG. 8, the controller 250 is

A reference value setting unit 260 for setting a reference value,

Sensing value recognition unit 270 for recognizing the sensing value of the air pressure sensor 240,

When the sensing value is lower than the reference value by comparing the reference value and the sensing value, the air compressor 210 is operated while closing the air valve 230. When the sensing value is higher than the reference value, the air compressor 230 is operated while operating the air compressor 210. It includes an air operation unit 280 for opening the operation.

Accordingly, by appropriately operating the air compressor 210 and the air valve 230 according to the sensing of the air pressure sensor 240 by the controller 250, the internal space 1 ) Can always be maintained at a constant pressure. Particularly, the air compressor 210 is provided outside the air roof 100 so as to forcibly supply fresh air outdoors through the air supply pipe 220, so that the inhabitants or the internal space 1 operating in the internal space 1, Lt; RTI ID = 0.0 > cultivated < / RTI >

On the other hand, configurations added to the air roof 100 and the air supply means 200 of the present invention as shown in Figs. 9 to 14 will be described.

First, the air roof 100 is fixed at its lower end in a closed state to divide the internal space 1 into the upper space 2 and the lower space 3, and the lower air tube 122 of the air supply tube 120 And a variable membrane 140 covering the lower inlet 131 of the air exhaust tube 130. The variable membrane 140 may be formed of a metal or the like.

The air supply tube 120 is formed so that an upper pipe tube 123 for discharging the air inside the upper portion is communicated to the upper portion.

The air supply means 200 is installed in the air roof 100 so that the air filled in the internal space 1 of the air roof 100 is discharged to the outside and the additional air valve 231 operated by the controller 250, . That is, the additional air valve 231, which discharges air to the upper pipe tube 123 or blocks air discharge, is fixed through the finishing cloth 360.

Here, the controller 250 operates the air compressor 210 while the air control unit 280 opens the air valve 230 and closes the additional air valve 231, and stops the operation of the air compressor 210 The air control unit 290 controls the air control unit 280 so as to open the air valve 230 and the additional air valve 231 while allowing the air control unit 280 to open. That is, the user can control the air control unit 280 by controlling the air control unit 290.

When the air valve 230 is supplied with air through the lower pipe tube 122 by the operation of the air compressor 210 while the upper discharge pipe 132 of the air discharge tube 130 is opened, The variable membrane 140 swells upward. At this time, the lower pipe tube 122 of the air supply tube 120 is contracted. The air in the upper space 410 flows through the lower inflow port 131 and is discharged to the outside of the air roof 100 through the opened upper discharge pipe 132 so that the inflatable membrane 140 swells more easily, The volume of the space 410 is reduced and the volume of the lower space 3 is enlarged.

On the contrary, if the air valve 230 and the additional air valve 231 are opened while the operation of the air compressor 210 is stopped and the air supply is interrupted, the variable membrane 140 is struck down by its own weight The air in the lower space 3 is sucked to the inside of the air supply tube 120 through the lower tube tube 122 and discharged to the outside through the upper tube tube 123. At this time, air located outside the air roof 100 flows into the air discharge tube 130 through the upper discharge pipe 132 and is supplied to the upper space 2 through the lower inlet 131, The variable membrane 140 is more easily struck down and the volume of the lower space 3 is reduced.

As described above, the volume of the upper space 2 and the space of the lower space 3 can be adjusted differently as the variable membrane 140 is convex upward or concave downwardly. Accordingly, in the daytime, the volume of the lower space 3 is enlarged so that the air in the lower space 3 is heated by the radiant heat of the sun to flow in the upper part of the air roof 100, It is possible to prevent the direct delivery to the crop and to reduce the volume of the lower space 3 before the temperature changes due to the sun so that the heated air can be delivered directly to the inhabitants at night or to the cultivated crop have. That is, it is possible to provide a constant temperature air to the residents or cultivated crops in the interior space 1 of the air roof 100 during daytime or nighttime.

In addition, as shown in FIGS. 13 to 16, the air roof 100 further includes a heat storage member 150 provided in the internal space 1 to heat heat energy of solar light transmitted from the outside during the day and emit the light at night. . The heat storage member 150

A heat storage tube 151 standing up in the internal space 1 of the air roof 100,

A heat storage material 152 filled in the heat storage tube 151 and heated by light transmitted from the outside;

The lower end is fixed to the upper end of the heat storage tube 151 and the upper end is fixed to the variable membrane 140 in a penetrating state. It includes.

The heat storage tube 151 may be made of a transparent hard acrylic tube or a synthetic resin tube so that light is transmitted therethrough.

A water supply pipe 154 for supplying water from the outside to the inside is formed on one side of the heat storage pipe 151. A water supply valve 155 for regulating the water supply amount or shutting off the water supply is provided in the water supply pipe 154, Can be installed. That is, when the water supply valve 155 is opened, water can be supplied to the inside of the heat storage tube 151 through the water supply pipe 154 and filled therein.

The heat storage material 152 may be composed of water that is widely applied to a heater to absorb heat. Therefore, it is possible to absorb heat energy transmitted through the expansion pipe (153) and through the heated air while absorbing the heat energy of the sunlight transmitted through the heat storage tube (151). In addition, the heat storage material 152 may include nutrients or nutrients to be supplied to plants.

The expansion and contraction pipe 153 may be composed of a transparent corrugated tube through which light is transmitted or a flexible vinyl pipe. Accordingly, when the air is inwardly sucked in and contracted in the upper space 2 of the variable membrane 140 when it is extended, the air filled in the variable membrane 140 can be expanded and contracted by the variable membrane 140 The upper space 2 is opened. In particular, the expansion and contraction pipe 153 is connected to the variable membrane 140 to absorb heat energy of the hottest air flowing in the upper portion of the inner space 1.

If the heat is accumulated in the heat storage material 152 of the heat storage member 150, which gradually changes in temperature from air, the heat is released from the heat storage material 152 at night, so that the greenhouse effect can be maintained for a long time at night.

The heat accumulating member 150 further includes a supply member 160 for circulating or supplying the heat accumulating material 152 to the ground. Supply member 160 is

A pump 161 provided inside the heat storage pipe 151 to pump the heat storage material 152;

A suction pipe 162 protruding from the upper portion of the pump 161 to suck the heat storage material 152 or air,

A supply pipe 163 which protrudes to the lower portion of the pump 161 while being opposed to the suction pipe 162 and supplies the heat storage material 152 to the ground in a state buried in the ground;

A discharge pipe 164 protruding to the side of the supply pipe 163 so that the end is raised upward and sprays the heat storage material 152 upward;

The supply pipe 164 and the supply pipe 163 is installed in the portion connected to the supply three-way valve 165 for controlling the supply direction of the heat storage material 152 or air.

The pump 161 may be composed of a pump that operates in the water, which is the heat storage material 152.

It is preferable that the suction pipe 162 is formed to be shorter than the discharge pipe 164 so as to be immersed in the water as the heat storage material 152.

In addition, the suction pipe 162 is

Branch pipe 167 protruding laterally from the bottom and

It is installed in the branch pipe 167 and the suction pipe 162 is connected to include a three-way valve 168 for adjusting the suction direction of the heat storage material 152 or air.

The suction pipe 162 is formed to protrude through the water surface of the heat storage material 152 and the branch pipe 167 is formed below the suction pipe 162 so as to be submerged in the heat storage material 152. At this time, when the pump 161 is pumped in the state where the suction pipe 162 is closed by the operation of the suction three-way valve 168, the heat storage material 152 is sucked through the branch pipe 167.

On the other hand, when the pump 161 is pumped in the state where the branch pipe 167 is closed by the operation of the suction three-way valve 168, air is sucked through the suction pipe 162. At this time, the air sucked through the suction pipe 162 can be supplied to the ground through the supply pipe 163. Therefore, since the ground is not frozen by the hot air supplied to the ground, the crop is not suffered from the cold damage, and the oxygen contained in the air supplied to the ground is supplied to the soil. Oxygen supplied with air can be supplied to microorganisms. Especially, when the heated air is supplied to the soil, the aerobic microorganisms can be easily activated, so that the soil can be improved by the microorganisms.

The supply pipe 163 may be vertically embedded in the ground and may be formed with a plurality of nozzles 166 spaced apart from each other at an outer side while being bent horizontally. In other words, the heat storage material 152 can be uniformly and uniformly supplied over a wide range of the ground by the nozzles 166. Therefore, water, which is the heat storage material 152 supplied to the ground, can be supplied to the crop planted on the ground.

In this state, when the pump 161 is pumped in the state that the supply pipe 163 is closed by the operation of the supply three-way valve 165, water is sucked through the suction pipe 162, (Not shown). At this time, the water as the heat storage material 152 to be sprayed contacts the heated air inside the heat storage tube 151 to absorb heat energy. Thus, by pumping the pump 161 for a long time in the daytime, the water as the heat storage material 152 is continuously brought into contact with the warm air, so that the heat energy can be stored by being heated.

Conversely, when the pump 161 is pumped in the state in which the discharge pipe 164 is closed by the operation of the supply three-way valve 165, water or air, which is the heat storage material 152 sucked through the suction pipe 162, (163). ≪ / RTI >

As described above, when the water as the heat storage material 152 is supplied to the soil in the ground, it is used as a nutrient of the plant, so that it is not necessary to supply water separately. In addition, as the oxygen is supplied to the soil in the soil with the air, microorganisms are activated and the light layer of the oven is destroyed, so that the roots of the crops can be easily lowered, so that the growth of the crops can be promoted. In other words, water and oxygen are supplied to the soil, so hydroponic cultivation using the soil is possible.

As shown in Figure 16 to 20, the shape maintaining means 300 is

A plurality of first ropes 310 having one end and the other end tied together to form a ring shape, spaced at equal intervals, and wound around the tube 110 to support it;

A second rope 320 positioned in the longitudinal direction of the tube 110 outside the upper portion of the tube 110 and tied to an upper portion of the first ropes 310;

Third, which is located in the longitudinal direction of the tube 110 in the lower outer side of the tube 110 and tied to the lower portion of the first ropes 310, but tied at a smaller interval than the interval bound to the upper portion of the first rope (310) Rope 330,

A fourth rope 340 positioned at an upper outer side of the tubes 110 in a state orthogonal to the longitudinal direction of the tube 110 and bundled at predetermined intervals for each of the second ropes 320;

It includes a fifth rope 350 which is located on the lower outer side of the tubes 110 in a state orthogonal to the longitudinal direction of the tube 110 and tied to each of the third ropes 330 at predetermined intervals.

Accordingly, the outer surface of the tube 110 is entirely supported by the first rope 310, the second rope 320, and the third rope 330, so that the outer shape of the tube 110 can be maintained while the expansion of the tube 110 is prevented. At this time, the second ropes 320 are bundled at a predetermined interval D1 on the first ropes 310 and spaced apart from the first ropes 310 by a distance D2, the third rope 330 is tied to the bottom of the first ropes 310, so that the tube 110 maintains an upward convex arc shape.

The fourth rope 340 and the fifth rope 350 are connected to the second rope 320 and the third rope 330 in a direction crossing the longitudinal direction of the tube 110 at the top and bottom of the tube 110, The tubes 110 holding the arc shape by the first rope 310, the second rope 320 and the third rope 330 are arranged side by side in tight contact with each other to form an air roof 100).

Here, the ropes may be constructed of nylon ropes, wires, or piano wires.

As such, the air roof 100 forms a roof by the ropes tied to each other, so that even if one tube 110 is damaged, the roof shape can be firmly maintained.

2, the shape retaining means 300 further includes a finishing cloth 360 covering and covering the upper portion of the air roof 100. As shown in FIG. The finishing cloth 360 is made of a transparent synthetic resin and is fixed to the fixing member 430 of the outer wall 400 to be described later so as to prevent the tubes 110 of the air roof 100 from protruding, . At this time, it is preferable that the finishing cloth 360 is sealed (sealed 0) and fixed so as to prevent air from being lost to the fixing member 430 of the outer wall 400. Here, the finishing cloth 360 may be installed so that the air supply pipe 220 of the air supply means 200 and the upper discharge pipe 132 of the air discharge tube 130 are inserted. Of course, it is preferable to finish sealing (sealing) so that air is not lost around the perforated periphery.

In addition, the shape retaining means 300 may further comprise a netting 370 covering the closure fabric 360 to prevent lifting. Since the mesh net 370 supports and supports the end cloth 360 evenly and uniformly over the entire surface of the air roof 100, it can be firmly held in close contact with the upper surface of the air roof 100 to prevent the air roof 100 from swelling and rupture It can withstand typhoons in the rain.

As shown in FIGS. 1 and 2, the outer wall 400 is

A plurality of struts 410 which are spaced apart at predetermined intervals along the rim of the air roof 100 while the lower end is inserted into the ground and stands on the ground;

A wall 420 standing up while closing between the pillars 410 and

Positioned horizontally along the top of the wall 420 is installed on the upper end of the support 410 includes a fixing member 430 is fixed to the lower side of the air roof 100.

The strut 410 may be composed of an H beam pushed together with concrete and a lower end buried in the ground.

The wall 420 may be a concrete wall formed by being inserted between the pillars 410. The wall 420 may be provided with a heat insulating material for preventing the flow of the internal temperature and the inflow of the external temperature. The wall 420 may be directly connected to the lower portion of the air roof 100 in a state in which no air is lost in a portion where the fixing member 430 is not installed.

21 and 22, the wall 420 is formed to penetrate the female screw member 421, and is detachably installed in the female screw member 421, And an air discharging member (450) for discharging air. Here, the female screw member 421 may be formed of a nut embedded in the concrete.

The air discharging member 450 includes an air discharging pipe 451 which is threadably coupled to the female screw member 421 of the wall body 420 while one end of the air discharging member 45 is detachably connected to the air discharging pipe 451, A cap 452 for discharging the air to be perfused through the air discharge pipe 451 to the outside, an elastic body 453 which is one end supported by the cap 452 and built in the air discharge pipe 451, A valve body 454 which opens one end of the air discharge pipe 451 while compressing the elastic body 453 by a predetermined air pressure flowing through the air discharge pipe 451 in a state where one end of the air discharge pipe 451 is closed by the air discharge pipe 451 .

The air discharge pipe 451 is formed with male threads 455 on the outer circumferential surface at one end and the other end, respectively. Therefore, the air discharge pipe 451 is screwed to the female screw member 421 of the wall 420 at one end, and the stopper 452 is screwed at the other end. Further, at one end of the air discharge pipe 451, an air pressure inflow hole 456 having a diameter smaller than the diameter of the valve body 454 is formed. That is, the air pressure inflow hole 456 is opened and closed by the valve body 454.

The cap 452 is formed in a cap shape and has a female thread 457 formed on the inner circumferential surface thereof to be screwed to a male screw thread 455 formed at the other end of the air discharge tube 451, An air pressure discharge hole 458 having a diameter is formed. The stopper 452 supports the elastic body 453 while being screwed to the other end of the air discharge pipe 451 and discharges the air flowing through the air discharge pipe 451 to the outside through the air pressure discharge hole 458 .

The stopper 452 can adjust the elastic force of the elastic body 453 by tightening or loosening the stopper 452 while being screwed to the other end of the air discharge pipe 451 to adjust the air pressure to be filled in the inner space 1 of the wall body 420 . That is, since the elasticity of the elastic body 453 is controlled by the user, the amount of air discharged from the inner space 1 of the wall 420 can be adjusted, It is possible to control the air pressure in a state suitable for the growth of the plant cultivated in the plant (1).

Therefore, when air is overcharged in the internal space 1 of the wall body 420 while the air pressure inflow hole 456 is closed by the valve body 454, the pressure is increased so that the air pushes the valve body 454. The valve body 454 compresses the elastic body 453 and opens the air pressure inflow hole 456 so that the predetermined air in the internal space 1 of the wall body 420 flows through the air inflow hole 456 through the air pressure inflow hole 456 451, and is discharged to the outside through the air pressure discharge hole 458. Then, after the predetermined air is discharged, the valve body 454 closes the air pressure inflow hole 456 again by the elasticity of the elastic body 453.

Since the air discharging member 450 discharges air that is overcharged in the inner space 1 of the wall body 420 at regular intervals, fresh air is continuously supplied to the inner space 1 of the wall body 420 And the internal pressure of the inner space 1 of the wall 420 can be kept constant at all times.

19 and 20, the fixing member 430 is composed of an H beam horizontally positioned on the upper portion of the wall body 420 and fixed to the upper portion of the support column 410 by bolting or welding. In addition, the fixing member 430 may be formed of a channel of 'U' type or an angle of 'L' type. Therefore, the lower end of the air roof 100 can be inserted and fixed. A through hole 440 may be formed in the fixing member 430. Therefore, the ends of the second rope 320 and the third rope 330, which bundle the tubes 110 of the air roof 100, can be bundled through the through holes 440. That is, the air roof 100 is fixed to the upper portion of the outer wall 400.

As shown in FIGS. 1 and 2, the high door 500 is installed to open and close one side of the wall 420, and a packing for preventing air leakage along the rim may be installed. Therefore, the door 500 can be opened to allow workers to move into the interior space 1 together with the cultivated crop.

Thus, the present invention can be used as a facility capable of performing physical activities indoors, irrespective of snow or rain, and can be used as a crop cultivation facility capable of cultivating crops therein. It is a very useful invention that can be widely applied to neighboring facilities or agricultural lands.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is to be understood, therefore, that the above description is intended to be illustrative, and not restrictive, and that the scope of the present invention will be defined by the appended claims rather than the foregoing description, All changes or modifications that come within the scope of the equivalent concept are to be construed as being included within the scope of the present invention.

1: interior space
2: upper space 3: lower space
100: air roof 101: inner tube
102: inner injection port 110: tube
111: inlet 112: plug
113: Velcro tape 120: Air supply tube
121: Air inlet 122: Lower feed pipe
123: upper pipe tube 130: air tube
131: lower inlet port 132: upper outlet pipe
140: variable membrane 150: heat storage member
151: Heat storage tube 152: Heat storage material
153: Extension tube 154: Water supply tube
155: water supply valve 160: supply member
161: Pump 162:
163: supply pipe 164: discharge pipe
165: Supply 3 way valve 166: Nozzle
167: branch pipe 168: suction three-way valve
200: air supply means 210: air compressor
220: air supply pipe 230: air valve
231: Additional air valve 240: Air pressure sensor
250: controller 260: reference value setting section
270: sensing value recognition unit 280: air control unit
300: shape retaining means 310: first rope
320: second rope 330: third rope
340: fourth rope 350: fifth rope
360: Cloth 370: Cloth
400: outer wall 410: upper space
410: column 420: wall
421: female screw member 430: fixing member
440: Through hole 450: Air exhaust member
451: air discharge pipe 452: stopper
453: elastic body 454: valve body
455: male thread 456: air pressure inlet hole
457: female threads 500: door

Claims (22)

delete The air roof 100 having an upwardly convex tunnel shape filled with air and the air supplied to the outside of the lower part of the air roof 100 through the air roof 100 or the air supplied to the upper part of the air roof 100 A shape retaining means 300 for retaining the shape of the air roof 100 by being fixed in a state wrapping the outside of the air roof 100 and a shape maintaining means 300 for holding the shape of the air roof 100, An outer wall 400 formed on one side of the outer wall 400 and having an upper end connected to the upper end of the air roof 100 and rising on the ground to form an inner space 1 on the inner side, And a door 500 for opening /
The air roof (100)
A plurality of tubes 110 are arranged side by side while being filled with air inside the convex form and close to the left and right,
An air supply tube 120 positioned between the tubes 110 to supply air supplied from the air supply means 200 to the bottom of the outside, and to discharge the supplied air to the top of the outside;
Air house, characterized in that consisting of an air discharge tube 130 for discharging the air supplied from the outside of the air supply tube 120 to the bottom to the top.
The method of claim 2, the tube 110 further includes an inner tube 101 is inflated by being filled with air in a state accommodated therein,
The inner tube 101 is rectangular and curved in an arc shape while being curved in an arc shape,
Tube 110 is an air house, characterized in that the magic tape 113 is installed to be detachably attached to each other while opening the inner tube 101 is inserted into one side.
The method according to claim 2,
Air supply tube 120 is composed of a transparent synthetic resin so that light is transmitted, it is formed to be bent in a rectangular and arc shape, the air inlet 121 is formed on one side to fill the air therein,
An air house, characterized in that the lower through-pipe 122 for discharging the air introduced through the air inlet 121 to the lower portion in communication with the lower portion.
The method of claim 4,
The air roof 100 is fixed at the bottom in a closed state to divide the inner space 1 into the upper space 2 and the lower space 3, and the lower through-hole 122 of the air supply tube 120 is Further comprising a variable membrane 140 connected to be penetrated,
Air supply tube 120 is an air house, characterized in that the upper through-pipe 123 for discharging the air inside the upper side is formed in communication with the top.
The method according to claim 2,
The air discharge tube 130 is composed of a transparent synthetic resin so that light is transmitted, it is formed to be bent in the shape of a rectangle and arc,
A lower inlet 131 through which air is introduced is formed,
Air discharge, characterized in that the upper discharge pipe 132 for discharging the air to the upper side is formed in communication with the upper portion.
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