KR102528852B1 - Dual layer airdome structure - Google Patents

Abstract

The present invention relates to a double membrane air dome structure. An objective of the present invention is to provide the air dome structure. Configuration of the present invention comprises: an interior air dome (120); an exterior air dome (140) disposed at a predetermined interval outside the interior air dome (120); and a spacing space (160) secured between the interior air dome (120) and the exterior air dome (140). An objective of the present invention is to provide the double membrane air dome structure of a new configuration, which allows evacuation to be easily and safely performed.

Description

Dual layer airdome structure}

The present invention relates to a double-membrane air dome structure, and more particularly, because it has a double-membrane structure, it is advantageous in terms of insulation and is advantageous in creating a comfortable indoor environment such as being less affected by external environments such as noise and light. , It relates to a double-membrane air dome structure of a new configuration that can expect desirable results such as improving cooling and heating efficiency by maintaining constant indoor temperature and air, and facilitating evacuation in the event of a fire or disaster.

In general, building structures used for event venues or various leisure and public facilities are constructed by using steel frames or other building materials, so the workmanship and workability of the installation structure are poor. There are disadvantages of not being able to do it, and a lot of time and high-level construction technology are required in terms of workability, so the workability is not good.

Therefore, in recent years, there is a tendency to use a lot of air dome structures with excellent workability and appearance. The air dome has a structure that maintains the structure by sealing it so that the air blown under pressure in the room cannot escape. For example, in order to inject and lift air into the air dome structure, an air conditioner that blows with pressure automatically controls the air pressure while maintaining the air dome structure in a floating structure.

However, the single-layer air dome is disadvantageous in terms of insulation and has difficulty in creating a comfortable indoor environment, as it is greatly affected by external environments such as noise and light. There is a problem in that cooling and heating efficiency is lowered because the indoor temperature and air cannot be kept constant.

In addition, there is a problem in that it is not easy to evacuate in the event of a fire or disaster and it is not possible to evacuate safely because it is not possible to buy evacuation time. There is a problem that is not easy.

Korean Registered Patent No. 10-0788720 (registered on December 18, 2007) Korean Registered Patent No. 10-2197793 (registered on December 28, 2020) Korean Registered Patent No. 10-2298131 (registered on August 31, 2021) Korean Patent Publication No. 10-2022-0016506 (published on February 09, 2022)

The present invention was developed to solve the above problems, and an object of the present invention is to provide a comfortable indoor environment, such as being advantageous in terms of insulation and being less affected by external environments such as noise and light, because it has a double-layer structure. A new double-membrane air dome structure that is advantageous in creating a structure, improves cooling and heating efficiency by maintaining constant indoor temperature and air, and enables easy and safe evacuation as it has a double-membrane structure in the event of a fire or an outbreak of flames. is to provide

According to the present invention for solving the above problems, the inner air dome 120; A double-layer air dome structure is provided, characterized in that it is configured to include; an external air dome 140 arranged to be spaced apart from the outside of the internal air dome 120 at a predetermined interval.

An inner bottom extension 122 is provided at the lower end of the inner air dome 120, and the inner bottom extension 122 is fixed to the ground by an inner anchoring support 130, so that the inner air dome 120 It is fixed to the ground, and at the lower end of the external air dome 140, the external bottom extension 142 is fixed to the ground by an external anchoring support 150, so that the external air dome 140 is fixed to the ground and at the same time It is characterized in that a spacing space 160 spaced at a predetermined interval is secured between the inner surface of the outer air dome 140 and the outer surface of the inner air dome 120.

In the present invention, the inner anchoring support and the outer anchoring support 150 may be composed of anchor bolts.

A flooring material 162 is laid on the bottom surface of the spacing space 160 secured between the inner air dome 120 and the outer air dome 140 so that the spacing space 160 can be used for walkways, exercise tracks , and trees. It is characterized by being configured to satisfy both the effect of temperature reduction due to the planting space and the safe evacuation and maximization of heating effect by earning time to evacuate when the ceiling of the screen collapses due to flames in case of fire.

an internal air conditioner 124 installed in the internal air dome 120; It is characterized in that it is configured to further include; an external air conditioner 144 installed in the spacing space 160 between the internal air dome 120 and the external air dome 140.

The double-membrane air dome structure of the present invention has a double-membrane structure equipped with an inner air dome and an outer air dome, so that evacuation is easy and it is possible to safely evacuate by earning evacuation time. Since it is kept constant, it is possible to maximize cooling and heating efficiency, it is easy to prepare for safety accidents, and the external membrane and the internal membrane are distinguished so that the inner and outer membranes can be replaced separately during replacement, so durability and cost reduction and maintenance are maintained. It has the effect of easy maintenance.

In the case of the existing single-membrane structure, in the event of a fire, the single-membrane air dome rapidly descends and there is no time to evacuate, which can be a burden for safety accidents. It is effective to safely evacuate by securing enough.

If the air dome has a double membrane structure, the outer membrane uses a sun-resistant product to improve durability, and the inner membrane uses an eco-friendly product, which has excellent effects on the human body as well as agricultural products, increasing production and freeing from heavy metals during exercise. Even in the case of membrane replacement, only the membrane installed inside or outside can be replaced separately, so it can be replaced while protecting existing agricultural products or facilities, which has the advantage of cost reduction.

Effects according to the present invention are not limited by the contents exemplified above, and more various effects are included in the present invention.

1 is a perspective view of a double membrane air dome structure according to the present invention;
Figure 2 is a plan view of Figure 1;
3 is a front cross-sectional view showing a state in which a double-membrane air dome structure according to the present invention is installed;
Figure 4 is an exploded perspective view showing a modified embodiment of the inner anchoring support, which is the main part of the present invention;
5 is a front sectional view showing a state before the inner anchoring bolt, which is the main part shown in FIG. 4, is lowered into the inner anchoring sleeve;
6 is a front cross-sectional view showing a state in which the inner anchoring bolt shown in FIG. 5 descends into the inner anchoring sleeve and spreads the inner wedge piece;
Figure 7 is an exploded perspective view showing a modified embodiment of the external anchoring support, which is the main part of the present invention;
8 is a front cross-sectional view showing a state before an external anchoring bolt, which is a main part shown in FIG. 7, is lowered into an external anchoring sleeve;
9 is a front cross-sectional view showing a state in which the outer anchoring bolt shown in FIG. 8 descends into the outer anchoring sleeve and spreads the outer wedge piece;
10 is a front cross-sectional view showing a state before the inner anchoring bolt and the outer anchoring bolt of the inner anchoring support and the outer anchoring support shown in FIGS. 4 to 9 are lowered into the inner anchoring sleeve and the outer anchoring sleeve;
11 is a front cross-sectional view showing a state in which an inner inner air dome and an outer air dome are installed by the inner anchoring support and the outer anchoring support shown in FIG. 10;
12 is a plan view schematically showing a state in which pipes for geothermal heating are buried in the ground where the double-membrane air dome structure according to the present invention is installed;
13 is a front cross-sectional view schematically showing a state in which pipes for geothermal heating are buried in the ground where a double-membrane air dome structure according to the present invention is installed;
14 is a perspective view showing a state in which a plurality of internal ejection pipes are installed inside an internal air dome, which is a main part of a double membrane air dome structure according to the present invention;
15 is a perspective view showing a state in which a plurality of external ejection pipes are installed inside an external air dome, which is a main part of a double membrane air dome structure according to the present invention;
16 is a front cross-sectional view showing a state in which a plurality of internal ejection pipes are installed inside an internal air dome, which is a main part of a double membrane air dome structure according to the present invention;
17 is a front cross-sectional view showing a state in which a plurality of external ejection pipes are installed inside an external air dome, which is a main part of a double membrane air dome structure according to the present invention;
18 is a longitudinal cross-sectional view schematically illustrating a process of spraying water for fire suppression through an internal ejection hole of an internal ejection pipe to an internal air dome classification sector where a fire occurs among a plurality of internal ejection pipes shown in FIG. 16 when a fire occurs; ,
FIG. 19 is a longitudinal cross-sectional view schematically illustrating a process of spraying water for fire suppression through an external ejection hole of an external ejection pipe to an external air dome classification sector where a fire occurs among a plurality of external ejection pipes shown in FIG. 17; ,
20 schematically shows a state in which an internal air dome, which is a main part of the present invention, is divided into a plurality of internal air dome division sectors by a plurality of internal ejection pipes and an internal fire detection sensor is installed in each internal air dome division sector. Floor plan,
21 schematically shows a state in which an external air dome, which is a main part of the present invention, is divided into a plurality of external air dome division sectors by a plurality of external ejection pipes and an external fire detection sensor is installed in each external air dome division sector. Floor plan,
22 is a view schematically showing a coupling structure between an internal fire detection sensor and a control unit installed in a plurality of internal air dome division sectors of an internal air dome, which is a main part of the present invention, and an internal ejection pump and an internal ejection pipe;
23 is a view schematically showing a coupling structure between an external fire detection sensor installed in a plurality of external air dome division sectors of an external air dome, which is a main part of the present invention, a control unit, an external ejection pump, and an external ejection pipe.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Objects, features and advantages of the present invention will be more easily understood by referring to the accompanying drawings and the following detailed description. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

Also, terms such as first, second, A, B, (a), and (b) may be used in describing the components of the present invention. These terms are only used to distinguish the component from other components, and the nature, order, or order of the corresponding component is not limited by the term. When an element is described as being “connected,” “coupled to,” or “connected” to another element, that element is directly connected or connectable to the other element, but there is another element between the elements. It will be understood that elements may be “connected”, “coupled” or “connected”.

In addition, specific structural or functional descriptions in the present invention are merely illustrated for the purpose of explaining embodiments according to the concept of the present invention, and embodiments according to the concept of the present invention may be implemented in various forms and may be implemented in this specification or application It should not be construed as being limited to the embodiments described above.

1 is a perspective view of a double-membrane air dome structure according to the present invention, FIG. 2 is a plan view of FIG. 1, and FIG. 3 is a front cross-sectional view showing a state in which the double-membrane air dome structure according to the present invention is installed.

The double-membrane air dome structure according to the present invention includes an inner air dome 120 and an outer air dome 140 disposed outside the inner air dome 120 at a predetermined interval.

The present invention further includes a spacing space 160 secured between the inner air dome 120 and the outer air dome 140.

An inner bottom extension 122 is provided at the lower end of the inner air dome 120, and the inner bottom extension 122 is fixed to the ground by an inner anchoring support 130, so that the inner air dome 120 It is firmly fixed to the ground.

In addition, at the lower end of the external air dome 140, the external bottom expansion part 142 is fixed to the ground by the external anchoring support 150, so that the external air dome 140 is firmly and fixedly installed on the ground. At the same time, a space spaced at a predetermined interval is secured between the inner surface of the outer air dome 140 and the outer surface of the inner air dome 120 . A space spaced at a predetermined interval between the inner surface of the outer air dome 140 and the outer surface of the inner air dome 120 becomes the spacing space 160 .

In the present invention, both the inner air dome 120 and the outer air dome 140 are configured in a dome shape by injecting air at a certain pressure therein.

In the present invention, the inner anchoring support and the outer anchoring support 150 may be composed of anchor bolts. The anchor bolt coupled to the inner bottom expansion part 122 of the inner air dome 120 is anchored in the ground to firmly fix the inner air dome 120 to the ground, and the outer bottom extension of the outer air dome 140 By anchoring the anchor bolt coupled to the part 142 to the ground, the external air dome 140 can also be firmly fixed to the ground. In the present invention, the inner anchoring support and the outer anchoring support 150 are the inner anchor bolt 132 and the outer anchor bolt 152, respectively.

Flooring 162 is laid on the bottom surface of the spacing space 160 secured between the inner air dome 120 and the outer air dome 140 to use the spacing space 160 as a walking trail or exercise track. can

The present invention further includes an internal air conditioner 124 installed inside the inner air dome 120 and an external air conditioner 144 installed in the spacing space 160 between the inner air dome 120 and the outer air dome 140. include

The internal air conditioner 124 is installed inside the internal air dome 120 by the internal installation frame 126 to purify the air inside the internal air dome 120 by performing air conditioning inside the internal air dome 120 And, the external air conditioner 144 is installed in the spacing space 160 by the external installation frame 146, so that the air conditioning of the spacing space 160 is achieved, so that the internal air dome 120 and the external air dome 140 ) It is possible to purify the air in the spacing space 160 between.

The use of the double membrane structure of the present invention is a sports facility (soccer field, baseball field, futsal field, multi-purpose stadium, etc.). It can be used as an alternative to a plastic greenhouse for cultivation of agricultural products and mushrooms, a waste disposal site, a golf driving range, a substitute facility for a gym, and an earthquake and disaster evacuation site. The double membrane structure means that the present invention is formed of an inner air dome 120 and an outer air dome 140.

The air dome structure of the present invention is formed of a double-layer air dome, so it is easy to evacuate, and it is possible to safely evacuate by earning evacuation time. It is easy to prepare for safety accidents, and it is distinguished from the outer membrane and the inner membrane, so that the inner and outer membranes can be replaced respectively, so there is an effect of durability, cost reduction, and maintenance. The membrane on the outside is the external air dome 140 and the membrane on the inside is the internal air dome 120.

In the case of the existing single-membrane structure, in the event of a fire, the single-membrane air dome rapidly descends and there is no time to evacuate, which can be a burden for safety accidents. It is effective to safely evacuate by securing enough. The inner membrane and the outer membrane are the inner air dome 120 and the outer air dome 140, respectively.

At least 1 meter is secured between the external air dome 140 and the internal air dome 120 to primarily block cold air from the outside, and it can be used as a space utilization and emergency exit.

In addition, by installing a track, it can also be used as a walking trail and a place for exercise. By installing a track at the bottom of the space between the inner air dome 120 and the outer air dome 140, it can be used as a walking trail or a place where you can exercise.

The material of the air dome uses different materials for the inner air dome 120 and the outer air dome 140, but the outer air dome 140 uses a material resistant to the sun and the inner air dome 120 uses an eco-friendly product to avoid heavy metals. It not only frees you from exposure, but also improves durability.

In addition, when an emergency occurs by installing an auxiliary device, the auxiliary device is used to safely use the air dome even if the air conditioning system is out of power or an emergency occurs. It is possible as the best place to evacuate safely. Auxiliary devices include a rechargeable battery that can be temporarily operated when the air conditioning system is stopped, and an emergency air conditioner that can be operated with the power of the rechargeable battery connected to the rechargeable battery. However, it is possible to safely use the air dome due to the operation of the emergency air conditioner operated by the rechargeable battery.

In addition, when cultivating agricultural products or mushrooms, the inside of the air dome always creates a constant temperature and smooth air due to the operation of the air conditioning system, improving the quality of crops and increasing the growth rate, which can help increase income.

On the other hand, Figure 5 is a front cross-sectional view showing a state before the inner anchoring bolt, which is the main part shown in Figure 4, is lowered into the inner anchoring sleeve, Figure 6 is the inner anchoring bolt shown in Figure 5 to the inside of the inner anchoring sleeve. 7 is an exploded perspective view showing a modified embodiment of an external anchoring support, which is a main part of the present invention, and FIG. 8 is an external anchoring bolt, which is a main part shown in FIG. A front cross-sectional view showing a state before lowering into the anchoring sleeve, Figure 9 is a front cross-sectional view showing a state in which the external anchoring bolt shown in Figure 8 descends into the external anchoring sleeve and spreads the external wedge piece, Figure 10 is A front cross-sectional view showing a state before the inner anchoring bolt and the outer anchoring bolt of the inner anchoring support and the outer anchoring support shown in FIGS. 4 to 9 are lowered into the inner anchoring sleeve and the outer anchoring sleeve, FIG. 11 is shown in FIG. 12 is a front cross-sectional view showing a state in which the inner inner air dome and the outer air dome are installed by the inner anchoring support and the outer anchoring support shown, FIG. A plan view schematically showing the state, Figure 13 is a front cross-sectional view schematically showing a state in which pipes for geothermal heating are buried in the ground where the double-membrane air dome structure according to the present invention is installed, Figure 14 is a double-membrane air dome structure according to the present invention A perspective view showing a state in which a plurality of inner ejection pipes are installed inside an inner air dome, which is a main part, and FIG. 16 is a front sectional view showing a state in which a plurality of internal ejection pipes are installed inside the inner air dome, which is the main part of the double membrane air dome structure according to the present invention, and FIG. 17 is a double membrane air dome structure according to the present invention. 18 is a front cross-sectional view showing a state in which a plurality of external ejection pipes are installed inside an external air dome, which is a main part, and FIG. 19 is a longitudinal cross-sectional view schematically showing a process of spraying water for fire suppression through an internal ejection hole of a pipe, and FIG. 20 is a longitudinal cross-sectional view schematically showing a process of spraying water for fire suppression through an external ejection hole of an ejection pipe, and FIG. A plan view schematically showing a divided state and a state in which an internal fire detection sensor is installed in each internal air dome classification sector. FIG. 22 is a plan view schematically showing a state divided into sectors and a state in which external fire detection sensors are installed in each external air dome classification sector. 23 is a view schematically showing a coupling structure between a detection sensor, a control unit, an internal ejection pump, and an internal ejection pipe, and FIG. It is a drawing schematically showing the coupling structure between the external ejection pump and the external ejection pipe.

In the present invention, the internal anchoring support is an internal anchor bolt 132, an internal tapered block 134 provided on an outer circumferential surface of the internal anchor bolt 132 and whose outer diameter gradually increases toward the upper end of the internal anchor bolt 132, the An inner anchoring screw hole 135 extending from the lower end of the inner taper block 134 to the upper end of the inner anchor bolt 132 by a certain depth and having a tubular shape with a hollow inside and buried in the ground An inner anchoring sleeve ( 136) and a plurality of internal wedge pieces 137 formed in the internal anchoring sleeve 136 by at least one internal cutout portion 137CP extending from the upper end to the lower end of the internal anchoring sleeve 136 by a certain depth, It is provided inside the inner anchoring sleeve 136 and includes an inner anchoring screw shaft to which an inner anchoring screw hole 135 inside the inner anchor bolt 132 is coupled. The inner anchor bolt 132 is screwed to the inner anchoring screw shaft coupled to the inner anchoring sleeve 136, and when the inner anchor bolt 132 is bolted about the inner anchoring screw shaft, the inner anchor bolt 132 is rotated. The anchor bolt 132 and the inner taper block 134 can be lifted from the top of the inner anchoring sleeve 136 .

The internal anchoring sleeve 136 rotates the internal anchor bolt 132 based on the internal anchoring screw shaft coupled to the inside of the internal anchoring sleeve 136 in a state of being buried in the ground, so that the internal anchoring sleeve 136 is formed. As the inner anchor bolt 132 is lowered toward the lower end, the inner taper block 134 spreads the plurality of inner wedge pieces 137, so that the plurality of inner wedge pieces 137 are hung in the ground in an open state, and the inner The anchor bolt 132 and the inner anchoring sleeve 136 are firmly anchored in the ground, so that the inner bottom expansion part 122 provided at the lower end of the inner air dome 120 is firmly fixed to the ground. Since it is configured to, there is an effect that the inner air dome 120 can be easily and quickly fixed to the ground.

In addition, in the present invention, the external anchoring support 150 is provided on the external anchor bolt 152 and the outer circumferential surface of the external anchor bolt 152, the outer diameter of which gradually increases toward the upper end of the external anchor bolt 152 External taper block (154), an external anchoring screw hole 155 extending a certain depth from the lower end of the external taper block 154 to the upper end of the external anchor bolt 152, and a tubular shape having a hollow externally and buried in the ground A plurality of external wedge pieces formed on the external anchoring sleeve 156 by an external anchoring sleeve 156 and at least one external cutout 157CP extending a certain depth from the upper end to the lower end of the external anchoring sleeve 156 157 and an external anchoring screw shaft provided outside the external anchoring sleeve 156 and coupled to the external anchoring screw hole 155 inside the external anchor bolt 152. The external anchor bolt 152 is screwed to an external anchoring screw shaft coupled to the outside of the external anchoring sleeve 156, and when the external anchor bolt 152 is bolted to rotate about the external anchoring screw shaft, the external anchor bolt 152 is screwed to the outer anchoring screw shaft. An anchor bolt 152 and an external taper block 154 may be lifted from above the external anchoring sleeve 156 .

The external anchoring sleeve 156 rotates the external anchor bolt 152 based on the external anchoring screw shaft coupled to the outside of the external anchoring sleeve 156 in a state where it is buried in the ground, so that the external anchoring sleeve 156 As the outer anchor bolt 152 is lowered toward the lower end, the outer taper block 154 spreads the plurality of outer wedge pieces 157, so that the plurality of outer wedge pieces 157 are hung in the ground while being open to the outer The anchor bolt 152 and the external anchoring sleeve 156 are firmly anchored in the ground, so that the external bottom expansion part 142 provided at the lower end of the external air dome 140 is firmly fixed to the ground. Since it is configured to, there is an effect that the external air dome 140 can be easily and quickly fixed to the ground.

Meanwhile, the present invention includes a plurality of internal ejection pipes 170 arranged to face the inner surface of the internal air dome 120, a plurality of internal ejection holes 172 formed in the internal ejection pipe 170, and the internal An internal ejection valve 173 that controls to inject water at a constant pressure through an ejection hole 172, an internal ejection case 174 connected to the internal ejection pipe 170 and connected to an external water supply unit, An internal ejection pump 175 disposed in a connecting pipe between the internal ejection case 174 and the internal ejection pipe 170 is further included. The internal ejection valve 173 is embedded in the internal ejection case 174 and connected to the internal ejection pipe 170 .

In addition, the present invention includes a plurality of external ejection pipes 180 arranged to face the inner surface of the external air dome 140, a plurality of external ejection holes 182 formed in the external ejection pipe 180, and the external An external ejection valve 183 that controls to eject water at a constant pressure through an ejection hole 182, an external ejection case 184 connected to the external ejection pipe 180 and connected to an external water supply unit, An external ejection pump 185 disposed in a connecting pipe between the external ejection case 184 and the external ejection pipe 180 is further included. The external ejection valve 183 is embedded in the external ejection case 184 and connected to the external ejection pipe 180 .

In the present invention, the internal air dome 120 is divided into a plurality of internal air dome classification sectors (AST) based on the number of internal ejection pipes 170, and the external air dome 140 is separated by a plurality of external ejection pipes 180. ) is divided into a plurality of external air dome classification sectors (BST), and a plurality of internal fire detection sensors (ISE) are provided on the inner surface of the internal air dome 120 so as to be disposed in a plurality of internal air dome classification sectors (AST) do. The internal fire detection sensor (ISE) may be installed inside the internal air dome 120 by fixing means such as brackets and bolts.

In addition, a plurality of external fire detection sensors (OSE) are provided on the inner surface of the external air dome 140 to be disposed in the plurality of external air dome classification sectors (BST). The external fire detection sensor (OSE) may be installed inside the external air dome 140 by fixing means such as brackets and bolts.

A fire occurred in the inner air dome 120 and the internal fire detection sensor (ISE) of the inner air dome classification sector (AST) in which the fire occurred among the internal air dome classification sectors (AST) detected the occurrence of a fire, and the fire occurred. The internal ejection valve 173 installed on the internal ejection pipe 170 adjacent to the internal air dome partition sector (AST) is opened, and the internal ejection pump 175 supplies water for fire suppression from the external water supply unit to the internal ejection system. It is configured to extinguish the fire by pumping into the pipe 170 and spraying water for fire suppression at a certain pressure through the internal ejection hole 172, and a fire occurs in the external air dome 140, causing the external air The external fire detection sensor (OSE) of the external air dome classification sector (BST) where the fire occurred among the dome classification sectors (BST) detects the occurrence of a fire, and the external ejection pipe ( 180) by opening the external ejection valve 183, and pumping water for fire suppression from the external water supply unit to the outside of the external ejection pipe 180 by the external ejection pump 185 to the external ejection hole ( 182) to extinguish the fire by spraying water for fire suppression at a certain pressure.

The control unit 190 is connected between the internal fire detection sensor (ISE) and the internal ejection pump 175, so that the internal fire detection sensor (ISE) is connected to the external air dome where a fire occurs among the external air dome classification sectors (BST). The external fire detection sensor (OSE) of the division sector (BST) detects the occurrence of a fire and transmits a fire outbreak signal to the control unit 190, and the control unit 190 opens the internal ejection valve 173 and simultaneously opens the internal ejection pump 175 is operated to discharge fire extinguishing water at a certain pressure through the plurality of internal ejection holes 172 of the internal ejection pipe 170.

In addition, the control unit 190 is connected between the external fire detection sensor (OSE) and the external ejection pump 185, so that the external fire detection sensor (OSE) is connected to the outside where a fire has occurred in the external air dome classification sector (BST). The external fire detection sensor (OSE) of the air dome classification sector (BST) detects the occurrence of a fire and transmits a fire outbreak signal to the control unit 190, thereby opening the external ejection valve 183 by the control unit 190 and simultaneously opening the external The ejection pump 185 is operated to discharge fire extinguishing water at a certain pressure through the plurality of external ejection holes 182 of the external ejection pipe 180 .

Therefore, when a fire occurs in the internal air dome 120 or the external air dome 140, extinguishing water is sprayed at a certain pressure through the internal ejection hole 172 of the internal ejection pipe 170 to the corresponding sector where the fire occurred. can be extinguished quickly, and there is an effect of preventing the fire from spreading as quickly as possible due to rapid fire suppression.

In addition, in the present invention, the inner air dome 120 and the outer air dome 140 are buried in the ground under the fixed ground to radiate geothermal heat to the inner space of the inner air dome 120 so that heating is performed with geothermal heat It further includes a pipe 200 for geothermal heating. Preferably, hot water is circulated into the geothermal heating pipe 200 by a hot water supply unit 202 such as an external boiler to further increase geothermal efficiency.

In addition, a geothermal conductive sheet 204 is further provided above the geothermal heating pipe 200, and the geothermal conductive sheet 204 more smoothly conducts geothermal heat to the ground to the inside of the inner air dome 120. By more smoothly radiating geothermal heat to the space, geothermal heating can be achieved more reliably, and by more smoothly radiating geothermal heat to the spacing space 160 between the inner air dome 120 and the outer air dome 140, Make heating more reliable. The geothermal conduction sheet 204 is composed of a sheet of a material with high thermal conductivity, and conducts geothermal heat through the ground and the interior of the inner air dome 120 and the interior of the outer air dome 140 (ie, the spacing space 160 ) to make the geothermal condensate more smoothly.

In the above, specific embodiments of the present invention have been described in detail. However, the spirit and scope of the present invention is not limited to these specific embodiments, and it is common knowledge in the technical field to which the present invention belongs that various modifications and variations are possible without changing the gist of the present invention. Anyone who has it will understand.

Therefore, since the embodiments described above are provided to completely inform those skilled in the art of the scope of the invention to which the present invention pertains, it should be understood that it is illustrative and not limiting in all respects, The invention is only defined by the scope of the claims.

120. Inner air dome 122. Inner bottom extension
124. Internal air conditioner 126. Internal mounting frame
130. Internal anchoring support 132. Internal anchor bolt
134. Internal taper block 135. Internal anchoring screw hole
136. Inner anchoring sleeve 137. Inner wedge piece
137 CP. Internal cutout 140. External air dome
142. External bottom extension 144. External air conditioner
146. External mounting frame 150. External anchoring support
152. External anchor bolt 154. External taper block
155. External anchoring screw hole 156. External anchoring sleeve
157. External wedge piece 157CP. external cutout
160. Spacing space 162. Flooring
170. Inner ejection pipe 172. Inner ejection hole
173. Internal ejection valve 174. Internal ejection case
175. Internal ejection pump 180. External ejection pipe
182. External ejection hole 183. External ejection valve
184. External ejection case 185. External ejection pump
AST. Internal Air Dome Separation Sector ISE. internal fire sensor
BST. External air dome division sector OSE. External fire detection sensor
190. Controller 200. Piping for geothermal heating
202. Hot water supply unit 204. Geothermal conduction sheet

Claims (4)

an inner air dome 120;
An external air dome 140 disposed outside the internal air dome 120 at a predetermined interval,
An inner bottom extension part 122 is provided at the lower end of the inner air dome 120, and the inner bottom extension part 122 is fixed to the ground by an inner anchoring support 130, so that the inner air dome 120 It is fixed to the ground, and at the lower end of the external air dome 140, the external bottom expansion part 142 is fixed to the ground by the external anchoring support 150, and the external air dome 140 is fixed to the ground and at the same time A spacing space 160 spaced at a predetermined interval is secured between the inner surface of the outer air dome 140 and the outer surface of the inner air dome 120,
A flooring material 162 is laid on the bottom surface of the spacing space 160 secured between the inner air dome 120 and the outer air dome 140 to use the spacing space 160 as a walking trail or exercise track. constituted,
The inner anchoring support 130 includes an inner anchor bolt 132, an inner tapered block 134 provided on an outer circumferential surface of the inner anchor bolt 132 and whose outer diameter gradually increases toward the upper end of the inner anchor bolt 132, An inner anchoring screw hole 135 extending a certain depth from the lower end of the inner taper block 134 to the upper end of the inner anchor bolt 132, and a tubular shape having a hollow part therein, and an inner anchoring sleeve buried in the ground 136, and a plurality of internal wedge pieces 137 formed in the internal anchoring sleeve 136 by at least one internal cutout portion 137CP extending from the upper end to the lower end of the internal anchoring sleeve 136 by a predetermined depth, , It is provided inside the inner anchoring sleeve 136 and includes an inner anchoring screw shaft to which an inner anchoring screw hole 135 inside the inner anchor bolt 132 is coupled, and the inner anchor bolt 132 is It is screwed to the inner anchoring screw shaft coupled to the inner anchoring sleeve 136, and when the inner anchor bolt 132 is rotated in a bolt-like manner based on the inner anchoring screw shaft, the inner anchor bolt 132 and the inner taper block (134) is configured to be liftable above the inner anchoring sleeve (136),
The external anchoring support 150 includes an external anchor bolt 152, an external tapered block 154 provided on an outer circumferential surface of the external anchor bolt 152 and whose outer diameter gradually increases toward the upper end of the external anchor bolt 152, An external anchoring screw hole 155 extending a certain depth from the lower end of the external taper block 154 toward the upper end of the external anchor bolt 152 and a tubular shape having a hollow externally and buried in the ground External anchoring sleeve 156, and a plurality of external wedge pieces 157 formed on the external anchoring sleeve 156 by at least one external cutout 157CP extending from the upper end to the lower end of the external anchoring sleeve 156 by a predetermined depth, , An external anchoring screw shaft provided on the outside of the external anchoring sleeve 156 and coupled with an external anchoring screw hole 155 inside the external anchor bolt 152, wherein the external anchor bolt 152 is an external anchoring sleeve (156) It is screwed to the external anchoring screw shaft coupled to the outside, and when the external anchor bolt 152 is bolt-type rotated with respect to the external anchoring screw shaft, the external anchor bolt 152 and the external taper block 154 ) Is configured to be lifted from above the outer anchoring sleeve 156, characterized in that the double membrane air dome structure.
delete delete According to claim 1,
an internal air conditioner 124 installed in the internal air dome 120;
The double-membrane air dome structure, characterized in that it is configured to further include; an external air conditioner 144 installed in the spacing space 160 between the internal air dome 120 and the external air dome 140.

Images