KR20240048153A - A snow removal apparatus for an air dome equipped with a heat collecting membrane and a heat supply pipe - Google Patents

Abstract

The present invention relates to a snow removal device for an air dome equipped with a heat collection membrane and a heat supply pipe. More specifically, the present invention relates to a snow removal device for an air dome equipped with a heat collection membrane and a heat supply pipe. More specifically, the present invention relates to a snow removal device for an air dome by operating an electric heat blower with a self-emergency generator in preparation for a power outage and electricity supplied to the air dome air conditioning room. By continuously supplying heat at a certain temperature through a heat supply piping hose connected to the surface foundation anchor line and the outer surface of the air dome to the snow section at the top, water is not used by using an electric heat blower, so water for snow removal is secured and continuously supplied. Not only is there no need to worry about problems, but there is no need to secure additional space for water storage tanks, sufficient snow removal can be done in the air dome for a long time, and the operating time of the electric heat blower for snow removal during heavy snowfall and the temperature of the supplied heat can be adjusted accordingly. As it can be adjusted at any time, the installation cost as well as the operation cost are much cheaper than the sprinkler method, so there is no burden on the operation of the snow removal device, and snow removal is stopped midway due to interruption of the supply of snow removal water or blockage due to freezing of the nozzle. It is possible to prevent this from occurring, and by continuously supplying heat through the heat supply piping hose installed on the lower and upper surfaces of the air dome in the form of displacement due to the irregular flow of the air dome, flexibility is always maintained by heat at a certain temperature. In addition to the fact that there is no risk to the air dome membrane material, sufficient snow removal is possible without freezing even in low temperatures and cold waves during the winter and it is manufactured to fit the size of the expected snow cover area based on structural shape analysis of the air dome. The heat supply piping hose is inserted inside the heat collection membrane installed as a cover on the upper surface of the air dome, and heat at a certain temperature is continuously blown out and supplied through the hole machined in the inserted heat supply piping hose. Snow falling on the capture membrane can be removed immediately without snow accumulation, and the heat supply piping hose installed along the entire edge along the anchor line on the lower side is connected to the heat supply piping hose that enters the heat capture membrane on the upper side of the air dome. The heat supplied to all located heat supply piping hoses is circulated and the continuous supply of heated heat can remove snow falling on the upper surface of the air dome and snow accumulating on the lower surface. Since snow removal water and calcium chloride are not used, it is used for load distribution in the air dome. Not only is there no corrosion of cables and foundation anchors, as well as contamination of the surrounding area, but continuous and sufficient snow removal is possible without the fear of freezing or interruption of the supply of snow removal water even in the event of any cold wave or heavy snowfall. Compared to sprinkler devices, the equipment and operating method of electric heat blowers are possible. Because it is simple and simple, there is no burden on maintenance, and it is easy to control automatic operation and stop in relation to operating time and temperature of supplied heat, so there is no need for facility managers to stand by all night even during heavy snowfall, thereby reducing labor and facility costs and operating costs. It is inexpensive and effective.

Description

{A snow removal apparatus for an air dome equipped with a heat collecting membrane and a heat supply pipe}

The present invention operates an electric heat blower with electricity supplied to the air dome air conditioning room and a self-emergency generator in preparation for a power outage, and provides a constant heat supply piping hose connected to the basic anchor line on the lower surface of the air dome and the snow section at the top of the outer surface of the air dome. By continuously supplying heat at any temperature, there is no need to worry about securing and continuously supplying water for snow removal since water is not used by using an electric heat blower, and there is no need to secure additional space for water storage tanks. The air dome can be used to remove sufficient snow for a long time, and the operation time of the electric heat blower for snow removal and the temperature of the supplied heat can be adjusted at any time depending on the situation, so the installation cost as well as the operation cost are much cheaper than the sprinkler method for snow removal. There is no burden on the operation of the device, and it is possible to prevent snow removal from stopping in the middle due to interruption of the supply of snow removal water or blockage due to freezing of the nozzle. The lower part of the air dome follows the shape of the displacement due to the irregular flow of the air dome. By continuously supplying heat through the heat supply piping hoses installed on the surface and upper surface, it is always flexible due to heat at a certain temperature, so there is no risk to the air dome membrane material, and it cannot operate due to freezing even in low temperatures and cold waves during the winter. Sufficient snow removal is possible without any dangerous situations occurring, and it is manufactured to match the size of the expected snow area based on the structural shape analysis of the air dome. A heat supply piping hose enters the inside of the heat collection membrane installed as a cover membrane on the upper surface of the air dome. By allowing heat at a certain temperature to be continuously ejected and supplied through the hole machined in the incoming heat supply piping hose, snow falling on the heat collection membrane can be immediately removed without snow accumulation, and a border along the anchor line on the lower side The heat supply piping hoses installed throughout are connected to the heat supply piping hoses that enter the heat collection membrane on the upper surface of the air dome, so that the heat supplied to all the heated heat supply piping hoses is circulated and the heated heat is continuously supplied to the upper part of the air dome. It can remove snow that falls on the surface and snow that accumulates on the lower surface, and because it does not use snow water or calcium chloride, there is no corrosion of the air dome load distribution cable and foundation anchor, as well as no contamination of the surrounding area, and it does not freeze or freeze under any cold waves or heavy snow. Continuous and sufficient snow removal is possible without the worry of stopping the supply of snow removal water. Compared to the sprinkler system, the equipment and operation method of the electric heat blower is simple, so there is no burden on maintenance, and it operates automatically in relation to the operating time and temperature of the supplied heat. This is a technology for a snow removal device for an air dome equipped with a heat capture membrane and heat supply piping that reduces labor and facility costs and has low operating costs because the stop control is easy and facility managers do not have to wait all night even during heavy snowfall.

An air dome (air membrane structure) is a special membrane structure without pillars that creates a large indoor space by blowing outside air into the indoor space inside the sealed air dome membrane and levitating the membrane. It has structural characteristics of irregular flow. Due to heavy snowfall, a concentrated load is applied to the membrane surface due to the pressure of the snow accumulated on the outer upper surface of the air dome and the snow that flows down to the bottom and accumulates on the foundation anchor line, causing the structure to collapse due to fracture due to collapse of the membrane material.

Therefore, the air dome must set a snowfall limit at which the structural membrane can maintain its safest form as much as possible during heavy snowfall and reflect it in the air dome structural shape analysis and structural calculations. However, if the average snow load in the area where the air dome is installed is higher than this limit, A snow removal device must be installed to immediately remove snow accumulated on the upper surface of the outside of the air dome and snow that flows down and accumulated on the foundation anchor line of the lower surface to prevent collapse accidents due to rupture of the membrane material.

The air dome has the structural characteristics of an irregular fluid without pillars like an inflated balloon, so the snow removal material installed on the outer surface of the air dome must be a flexible material that can effectively respond to the irregular flow of the air dome. In addition, it must be possible to sufficiently remove the snow accumulated on the estimated snow area of the upper surface of the air dome based on analysis of the air dome's structural shape and the snow that flows down and accumulated on the lower surface.

However, until now, snow accumulation on the upper surface of the air dome has been removed by connecting water stored in a water tank installed around the air dome structure to a pump and a rubber hose, placing the rubber hose on the upper surface of the air dome, and installing a spray nozzle. The method was to remove snow by spraying water through a machined hole, but when heavy snow falls for a long time, water spraying is often interrupted due to the limit of the water stored in the water tank and the inability of water supply vehicles to enter the site, so ensuring sufficient water for snow removal. and supply is virtually impossible.

In addition, due to low temperatures and cold waves during the winter, the spraying hose, spraying nozzles, and holes freeze, making spraying impossible. There have also been accidents where the sprayed water freezes and flows down into chunks of ice, breaking the membrane and causing the air dome to collapse. Since it is impossible to remove snow from the lower surface where snow has accumulated, there have been accidents in which the air dome collapses due to the membrane rupture due to the pressure of the snow accumulated on the lower surface.

In addition, in order to prevent freezing when spraying storage water for snow removal, a mixture of calcium chloride or liquid calcium chloride was sprayed, but during heavy snowfall, not only was there a huge supply cost, but there was also a limit to the supply amount, making sufficient spraying and snow removal impossible.

In addition, in order to secure sufficient water for spraying, many storage water tanks must be installed. Even if the facility cost is borne and the facility area is added, there is a limit to snow removal, and the water sprayed with calcium chloride solution is used as an air dome load distribution cable. This also accelerated corrosion of the lower anchor, causing safety accidents and contaminating the surrounding area.

Therefore, there is a limit to the continuous supply of sprinkler water for snow removal, snow removal is stopped due to freezing and blockage of the sprinkler nozzle due to low temperatures and cold waves in winter, and frozen or unmelted snowballs flow down and tear the membrane material or accumulate on the lower surface, resulting in fracture of the membrane material. There is an urgent need for the development of a snow removal device for air domes equipped with a heat capture membrane and heat supply piping that solves problems such as air dome collapse accidents and has a new snow removal method that enables continuous and complete snow removal.

KR 10-2019-0108657(2019. 9. 3)

Accordingly, the present invention was conceived to solve the above problems, and operates an electric heat blower as a self-emergency generator in preparation for electricity and power outages introduced into the air dome air conditioning room, and connects the basic anchor line of the lower surface of the air dome and the upper surface of the air dome to the outer surface of the air dome. By continuously supplying heat at a constant temperature through a heat supply piping hose connected to the snow-covered section, there is no need to worry about securing and continuously supplying water for snow removal since no water is used using an electric heat blower, as well as water for water storage. The purpose is to provide a snow removal device for the air dome equipped with a heat capture membrane and heat supply piping that can sufficiently remove snow from the air dome for a long period of time without the need to secure additional space for the tank.

Another object of the present invention is that the operating time of the electric heat blower for snow removal during heavy snowfall and the temperature of the supplied heat can be adjusted at any time according to the situation, so the installation cost as well as the operation cost are much cheaper than the sprinkler method, so the operation of the snow removal device is burdensome. The aim is to provide a snow removal device for an air dome equipped with a heat collection membrane and a heat supply pipe that can prevent snow removal from being stopped in the middle due to an interruption in the supply of snow removal water or a blockage due to freezing of the nozzle.

Another object of the present invention is to continuously supply heat through the heat supply piping hose installed on the lower and upper surfaces of the air dome in the form of displacement due to the irregular flow of the air dome, so that the air dome is always flexible due to heat at a certain temperature. In addition to the fact that there is no danger to the air dome membrane, the aim is to provide a snow removal device for the air dome equipped with a heat collection membrane and heat supply piping that can sufficiently remove snow without causing a situation in which operation is impossible due to freezing even in low temperatures and cold waves in the winter.

Another object of the present invention is to manufacture the air dome according to the size of the expected snow area based on the structural shape analysis. A heat supply piping hose is introduced into the heat collection membrane installed in the form of a cover on the upper surface of the air dome, and the introduced heat supply is supplied. An air dome snow removal device equipped with a heat collection film and heat supply piping that allows heat at a certain temperature to be continuously ejected and supplied through holes machined in the piping hose, allowing snow to be immediately removed without snow falling on the heat collection film. is to provide.

Another object of the present invention is that the heat supply piping hose installed along the entire edge along the anchor line of the lower surface is connected to the heat supply piping hose that enters the heat collection film on the upper surface of the air dome, so that the heat supply piping hose is supplied to all located heat supply piping hoses. The aim is to provide a snow removal device for an air dome equipped with a heat collection membrane and a heat supply pipe that can remove snow falling on the upper surface of the air dome and snow accumulating on the lower surface by circulating heat and continuously supplying heated heat.

Another object of the present invention is that since snow removal water and calcium chloride are not used, there is no corrosion of the air dome load distribution cable and foundation anchor, as well as no contamination of the surrounding area, and the continuous supply of snow removal water without fear of freezing or interruption in any cold wave or heavy snowfall. The aim is to provide a snow removal device for an air dome equipped with a heat capture membrane and heat supply piping capable of sufficient snow removal.

Another object of the present invention is that compared to the sprinkler device, the equipment and operating method of the electric heat blower are simple and simple, so there is no burden on maintenance, and it is easy to control automatic operation and stop in relation to the operating time and temperature of the supplied heat, so that the facility can be installed even during heavy snowfall. The goal is to provide a snow removal device for air domes equipped with a heat capture membrane and heat supply piping that reduces labor and facility costs and has low operating costs because managers do not have to wait all night.

In order to achieve the above object, a snow removal device for an air dome equipped with a heat collection membrane and a heat supply pipe according to a preferred embodiment of the present invention lifts the air dome membrane by pressurizing and blowing external air into the indoor space inside the sealed air dome membrane. an air dome that forms a large indoor space without pillars; It is installed in the air dome air conditioning room located at the part where the bottom of one side of the air dome touches the ground. It has the function of adjusting the appropriate pressure inside the air dome according to changes in wind speed, and automatically detects and controls snowfall to automatically turn off electricity in the event of snowfall. An automatic control system that operates a heat blower, blows out heated heat through a heat supply pipe hose, removes snow, and has a function that automatically stops the electric heat blower when snowfall stops; A heat collection membrane covering the heat supply piping hose spaced apart from the air dome membrane forming the air dome to the expected snow area of the upper surface of the air dome, and having fixing band holes machined on all edges; It is inserted between the heat collection membrane and the air dome membrane material, and is located on the lower surface and the upper surface of the air dome exterior along the air dome basic anchor line. Heat exhaust holes are processed at regular intervals, and it is heated to a certain temperature and continuously pressurized and blown. A heat supply piping hose that has a function of removing snow by allowing part of the supplied heat to be ejected through the heat outlet and stagnating at a certain temperature inside the heat collection membrane; A hose fitting pipe connected to the same type of heat supply piping hose that goes up to the outer upper surface of the air dome; an air dome cable with an elastic rubber band installed in the fixing band hole of the heat collection film and connected to and fixed to the outer surface of the air dome; a cable-to-collection membrane connection band connecting the air dome cable and the heat collection membrane; A heat sealing skirt attached to the inside of the band hole machined on all edges of the heat collection film and having a function of minimizing heat loss from heat emitted through the heat outlet of the heat supply piping hose to the outside of the heat collection film; It is characterized by including.

In the present invention, the automatic control system sets the basic value for air dome snow removal, detects snowfall in the snowfall detection unit, and then snowfall data is input to the input/output unit and output to the instrument panel and control panel, and then supplies heat through a heat blower. It is characterized by including being driven in this form.

In the present invention, the electric heat blower is operated by being connected to an automatic emergency self-generator in preparation for incoming electricity and power outages, and heat generated by a combination of a hot air motor, a hot air fan, and a heater is supplied through a heat outlet through a heat supply piping hose. It is integrated with the control panel of the automatic control system and is capable of controlling the operating time and temperature of supplied heat, and is characterized by automatically controlling, operating and stopping according to the adjusted time and temperature.

In the present invention, a T-shaped iron pipe pipe is connected to the heat discharge port of the electric heat blower and is exposed to extend outside the air conditioning room, and flexible heat supply pipe hoses for high temperature and high pressure are installed on both sides of the exposed T-shaped iron pipe pipe. It is characterized by being connected in a direction and positioned in a form surrounding the entire lower surface edge along the air dome basic anchor line.

In the present invention, the hose fitting is characterized in that it includes a three-way elbow shape and a four-way elbow shape.

In the present invention, the method further includes monitoring the degree of snowfall and the operating state of the electric heat blower automatically detected in a management room where a manager resides, and manually controlling the operation of the electric heat blower.

In the present invention, the high-temperature, high-pressure heat supply piping hose located on the lower surface along the air dome basic anchor line is connected to the same type of heat supply piping hose rising to the outer upper surface of the air dome at a certain point on each side through a joint pipe. , It is evenly distributed so that heat can be supplied to the expected snow cover area of the upper surface of the air dome, and the heat supplied by heating and pressurizing through all heat supply piping hoses is evenly supplied.

In the present invention, in addition to fixing the entire heat collection membrane with a rubber band to the edge band hole of the heat collection membrane to prevent injury and damage to the heat collection membrane due to the heat emitted from the heat supply piping hose and the wind during bad weather and to adhere closely, the entire heat collection membrane is additionally installed. It is characterized by fixing it to the air dome cable by pressing it with a rope made of highly elastic rubber at regular intervals.

As described above, the snow removal device for an air dome equipped with a heat collection membrane and heat supply pipe has the following effects.

First, the present invention operates an electric heat blower with electricity supplied to the air dome air conditioning room and a self-emergency generator in preparation for a power outage, and a heat supply piping hose connected to the basic anchor line on the lower surface of the air dome and the snow section at the top of the outer surface of the air dome. By continuously supplying heat at a constant temperature, there is no need to worry about securing and continuously supplying water for snow removal since it does not use water by using an electric heat blower, and it is also necessary to secure an area for additional facilities for water storage tanks. There is no, and sufficient snow removal can be done in the air dome for a long time.

Second, the present invention allows the operation time of the electric heat blower for snow removal during heavy snowfall and the temperature of the supplied heat to be adjusted at any time according to the situation, so the installation cost as well as the operation cost are much cheaper than the sprinkler method, so there is no burden on the operation of the snow removal device. It is possible to prevent snow removal from being stopped in the middle due to interruption of the supply of snow removal water or blockage due to freezing of the nozzle.

Third, the present invention continuously supplies heat through the heat supply piping hose installed on the lower and upper surfaces of the air dome in the form of displacement due to the irregular flow of the air dome, so that the air is always flexible due to heat at a certain temperature. In addition to the fact that there is no risk to the dome membrane material, sufficient snow removal is possible without freezing and preventing operation even during low temperatures and cold waves in the winter.

Fourth, the present invention is manufactured according to the size of the expected snow area based on structural shape analysis of the air dome, and a heat supply piping hose is introduced into the heat collection membrane installed in the form of a cover film on the upper surface of the air dome, and the introduced heat supply piping By allowing heat at a certain temperature to be continuously ejected and supplied through holes machined in the hose, snow falling on the heat collection film can be removed immediately without forming a layer of snow.

Fifth, in the present invention, the heat supply piping hose installed along the entire edge along the lower surface anchor line is connected to the heat supply piping hose entering the heat collection membrane on the upper surface of the air dome, thereby reducing the heat supplied to all located heat supply piping hoses. This continuous supply of circulated and heated heat can remove snow that falls on the upper surface of the air dome and snow that accumulates on the lower surface.

Sixth, since the present invention does not use snow removal water or calcium chloride, there is no corrosion of the air dome load distribution cable and foundation anchor, as well as surrounding contamination, and it is continuously maintained without the fear of freezing or stopping the supply of snow removal water even in any cold wave or heavy snowfall. Sufficient snow removal is possible.

Seventh, in the present invention, compared to the sprinkler device, the equipment and operating method of the electric heat blower are simple and simple, so there is no burden on maintenance, and it is easy to control automatic operation and stop in relation to the operating time and temperature of the supplied heat, allowing facility managers to easily control the operation and stop even during heavy snowfall. Since there is no need to wait all night, labor and facility costs are reduced and operating costs are low.

Figure 1 is a view showing the snow distribution on the upper part of the air dome according to an embodiment of the present invention.
Figure 2 is a view showing the installation location of the heat supply piping hose for air dome snow removal according to an embodiment of the present invention.
Figure 3 is a diagram showing the connection relationship between an electric heat blower and a heat supply piping hose in an air conditioning room according to an embodiment of the present invention.
Figure 4 is a plan view showing the heat supply piping hose for snow removal in the air dome and the heat collection membrane installed on the upper surface of the air dome according to an embodiment of the present invention.
Figure 5 is a view showing the internal heat supply pipe hose projected onto the installation plane of the heat supply pipe hose for snow removal in the air dome according to an embodiment of the present invention.
FIG. 6 is a detailed view showing the section “A” of the heat supply pipe hose for snow removal in the air dome of FIG. 5.
FIG. 7 is a detailed view showing the section “B” of the heat supply pipe hose for snow removal in the air dome of FIG. 5.
FIG. 8 is a detailed view showing the heat supply piping hose and heat collection membrane “C” area for snow removal in the air dome of FIG. 5.
Figure 9 is a diagram showing the driving flow of the manual control system for air dome snow removal according to an embodiment of the present invention.

The following is a look at preferred embodiments of the present invention along with the accompanying drawings. In explaining the present invention, if it is judged that a detailed description of related known technology or configuration may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. Description will be omitted, and the terms described below are terms defined in consideration of the functions in the present invention, and may vary depending on the intention or custom of the user or operator, etc., so the definitions are defined by the heat collection membrane and heat supply piping of the present invention. This decision should be made based on the content throughout this specification explaining the snow removal device for the air dome.

As shown in Figures 1 to 8, the snow removal device for an air dome equipped with a heat collection membrane and a heat supply pipe according to an embodiment of the present invention includes an air dome (10), an air dome membrane material (11), and an air conditioning chamber (20). ), electric heat blower (21), hot air motor (21-1), hot air fan (21-2), heater (21-3), automatic control system (22), control panel (23), heat outlet (24) , iron pipe pipe (25), heat supply piping hose (30), heat outlet (31), heat collection film (40), fixing band hole (41), rubber band (42), hose fitting (50), air It consists of a dome cable (60), a cable-capture connection band (70), and a heat sealing skirt (80).

Figure 1 is a view showing the distribution of snow on the upper part of the air dome according to an embodiment of the present invention, and Figure 2 is a view showing the installation location of the heat supply piping hose for snow removal in the air dome according to an embodiment of the present invention. 3 is a diagram illustrating the connection relationship between an electric heat blower and a heat supply piping hose in an air conditioning room according to an embodiment of the present invention, and Figure 4 is a diagram illustrating a heat supply for air dome snow removal according to an embodiment of the present invention. It is a drawing showing the plane where the heat collection membrane is installed on the supply piping hose and the upper surface of the air dome, and Figure 5 is a perspective view of the internal heat supply piping hose on the installation plane of the thermal supply piping hose for snow removal in the air dome according to an embodiment of the present invention. Figure 6 is a diagram showing in detail the section of the heat supply piping hose “A” for snow removal in the air dome of Fig. 5, and Fig. 7 is a diagram showing the heat supply piping hose “B” for snow removal in the air dome of Fig. 5. It is a drawing showing the zone in detail, and FIG. 8 is a drawing showing in detail the heat supply piping hose and heat collection membrane “C” zone for air dome snow removal of FIG. 5, and FIG. 9 is a drawing showing the air dome snow removal area “C” in detail, and FIG. This is a diagram to explain the driving flow of the manual control system for dome snow removal.

As shown in FIGS. 1 to 9, the snow removal device for an air dome equipped with a heat collection membrane and a heat supply pipe pressurizes and blows external air into the indoor space inside the sealed air dome membrane material (11) to form the air dome membrane material (11). ) an air dome (10) that floats to form a large indoor space without pillars; It is installed in the air dome air conditioning room (20) located at the part where the bottom of one side of the air dome (10) comes into contact with the ground, and has the function of adjusting the appropriate pressure inside the air dome according to changes in wind speed and automatically detecting and controlling snowfall. Therefore, when it snows, the electric heat blower (21) automatically operates and blows heated heat through the heat supply pipe hose (30) to remove snow. When snowfall stops, the electric heat blower (21) automatically stops operating. an automatic control system (22) having a function to enable; The heat supply piping hose 30, which is spaced apart from the air dome membrane 11 forming the air dome 10, is covered according to the expected snow area on the outer upper surface of the air dome 10, and fixing band holes ( a heat collection film 40 on which 41) is processed; It is introduced between the heat collection film 40 and the air dome membrane material 11, and is located on the lower surface and the outer upper surface of the air dome 10 along the basic anchor line of the air dome 10, and heat exhaust ports 31 at regular intervals. ) is processed, and some of the heat that is heated to a certain temperature and continuously pressurized and supplied is blown out through the heat outlet (31) and stagnates at a certain temperature inside the heat collection film (40), thereby removing snow. (30) and; A hose fitting pipe (50) connected to the same type of heat supply piping hose (30) that goes up to the outer upper surface of the air dome (10); an air dome cable (60) with an elastic rubber band (42) installed in the fixing band hole (41) of the heat collection film (40) and connected to and fixed to the outer surface of the air dome (10); a cable-to-collection membrane connection band (70) connecting the air dome cable (60) and the heat collection membrane (40); It is attached to the inside of the band hole 41 machined on all edges of the heat collection film 40, and heat emitted through the heat outlet 31 of the heat supply piping hose 30 is transmitted to the outside of the heat collection film 40. A heat-sealing skirt (80) that has the function of minimizing heat loss escaping; Equipped with

The functions of the main technical means of the snow removal device for the air dome equipped with the heat collection membrane and heat supply pipe are as follows.

The air dome 10 pressurizes and blows external air into the indoor space inside the sealed air dome membrane material 11 to levitate the air dome membrane material 11 to form an indoor large space without pillars.

The automatic control system 22 is installed in the air dome air conditioning room 20 located at the bottom of one side of the air dome 10 and the ground, and has the function of adjusting the appropriate pressure inside the air dome according to changes in wind speed. , Snowfall is automatically detected and controlled, and when snowfall occurs, the electric heat blower (21) automatically operates, blowing heated heat through the heat supply pipe hose (30) to remove snow, and when snowfall stops, the electric heat blower (21) is automatically operated. 21) also has a function to automatically stop operation.

Here, as shown in FIG. 9, the automatic control system 22 sets the basic value for air dome snow removal, detects snowfall in the snowfall detection unit, and then snowfall data is input to the input/output unit and output to the instrument panel and control panel. It is then driven in such a way that heat is supplied through a heat blower.

In addition, as shown in FIG. 3, the electric heat blower 21 is connected and operated with an automatic emergency self-generator in preparation for incoming electricity and power outages, and includes a hot air motor 21-1 and a hot air fan 21-2. ) and the heater (21-3) are transmitted to the heat supply piping hose (30) through the heat outlet (24), and are integrated with the control panel (23) of the automatic control system (22) to monitor operation time and It is possible to control the temperature of the supplied heat, and it is automatically controlled, started, and stopped according to the adjusted time and temperature.

In addition, a T-shaped iron pipe 25 is connected to the heat discharge port 24 of the electric heat blower 21 and is exposed to extend outside the air conditioning room 20, and high temperature is generated in the exposed T-shaped iron pipe 25. , the high-pressure flexible heat supply piping hose 30 is connected in both directions and is positioned to surround the entire lower surface edge along the basic anchor line of the air dome 10.

The heat collection membrane 40 is configured to fit the heat supply piping hose 30, which is spaced apart from the air dome membrane material 11 forming the air dome 10, to the expected snow cover area on the outer upper surface of the air dome 10, as shown in FIG. As shown, it is covered and fixing band holes 41 are machined on all edges.

As shown in Figures 5 and 7, the heat supply piping hose 30 is inserted between the heat collection film 40 and the air dome membrane material 11, and is attached to the lower surface along the basic anchor line of the air dome 10. It is located on the outer upper surface of the air dome (10), and heat outlets (31) are processed at regular intervals. Part of the heat that is heated to a certain temperature and continuously pressurized and supplied is ejected into the heat outlet (31) and forms a heat collection film. (40) It has the function of removing snow by allowing it to stagnate at a certain temperature inside.

Here, as shown in FIGS. 6 and 7, the high-temperature, high-pressure heat supply piping hose 30 located on the lower surface along the basic anchor line of the air dome 10 is connected to the air dome 10 at a certain point on each side. It is connected to the same type of heat supply piping hose (30) and joint pipe (50) that goes up to the external upper surface, and is evenly distributed to supply heat to the expected snow area of the external upper surface of the air dome (10), and all heat supply piping The heat supplied by heating and pressurizing through the hose 30 is supplied evenly.

In addition, as shown in FIG. 8, a band hole at the edge of the heat collection film 40 is provided to prevent the heat emitted from the heat supply piping hose 30 and the heat collection film 40 from being floated, damaged, or adhered to by wind during bad weather. In addition to fixing it to (41) with a rubber band (42), the entire heat collection film (40) is additionally fixed to the air dome cable (60) by pressing it with a rope made of highly elastic rubber at regular intervals.

The hose fitting 50 is connected to the same type of heat supply piping hose 30 that goes up to the outer upper surface of the air dome 10.

Here, the hose fitting 50 is equipped in the form of a three-way elbow and a four-way elbow.

As shown in FIG. 8, the air dome cable 60 is connected to the outer surface of the air dome 10 by attaching an elastic rubber band 42 to the fixing band hole 41 of the heat collection film 40. It is connected and fixed.

The connection band 70 between the cable and the heat collection film connects the air dome cable 60 and the heat collection film 40, as shown in FIGS. 6 and 8.

As shown in FIGS. 6 and 8, the heat sealing skirt 80 is attached to the inside of the band hole 41 machined on all edges of the heat collection film 40, and is connected to the heat supply piping hose 30. ) has the function of minimizing heat loss from the heat emitted through the heat outlet 31 to the outside of the heat collection film 40.

The present invention described above monitors the degree of snowfall and the operating status of the electric heat blower automatically detected in the management room where the manager resides, and also makes it possible to manually control the operation of the electric heat blower.

Therefore, as described above, various substitutions, modifications and changes can be made by those skilled in the art without departing from the technical spirit of the present invention, and the above-described embodiments and the accompanying drawings It is not limited to.

The snow removal device for an air dome equipped with a heat collection membrane and a heat supply pipe as described above can be applied to the snow removal field of an air dome.

10: air dome 11: air dome membrane material
20: Air conditioning room 21: Electric heat blower
21-1: hot air motor 21-2: hot air fan
21-3: Heater 22: Automatic control system
23: control panel 24: heat outlet
25: iron pipe 30: heat supply piping hose
31: heat outlet 40: heat collection film
41: fixing band hole 42: rubber band
50: hose fitting 60: air dome cable
70: Connection band between cable and capture membrane 80: Skirt for heat sealing

Claims (8)

In the snow removal device for air dome equipped with a heat collection membrane and heat supply piping,
An air dome that blows outside air under pressure into the indoor space inside the sealed air dome membrane, levitating the air dome membrane material to form a large indoor space without pillars.
It is installed in the air dome air conditioning room located at the part where the bottom of one side of the air dome touches the ground. It has the function of adjusting the appropriate pressure inside the air dome according to changes in wind speed, and automatically detects and controls snowfall to automatically turn off electricity in the event of snowfall. An automatic control system that operates a heat blower, blows out heated heat through a heat supply pipe hose, removes snow, and has a function that automatically stops the electric heat blower when snowfall stops;
A heat collection membrane covering the heat supply piping hose spaced apart from the air dome membrane forming the air dome to the expected snow area of the upper surface of the air dome, and having fixing band holes machined on all edges;
It is inserted between the heat collection membrane and the air dome membrane material, and is located on the lower surface and the upper surface of the air dome exterior along the air dome basic anchor line. Heat exhaust holes are processed at regular intervals, and it is heated to a certain temperature and continuously pressurized and blown. A heat supply piping hose that has a function of removing snow by allowing part of the supplied heat to be ejected through the heat outlet and stagnating at a certain temperature inside the heat collection membrane;
A hose fitting pipe connected to the same type of heat supply piping hose that goes up to the outer upper surface of the fish dome;
an air dome cable with an elastic rubber band installed in the fixing band hole of the heat collection film and connected to and fixed to the outer surface of the air dome;
a cable-to-collection membrane connection band connecting the air dome cable and the heat collection membrane;
A heat sealing skirt attached to the inside of the band hole machined on all edges of the heat collection film and having a function of minimizing heat loss from heat emitted through the heat outlet of the heat supply piping hose to the outside of the heat collection film; A snow removal device for an air dome equipped with a heat collection membrane and heat supply piping, comprising a. According to clause 1,
The automatic control system sets the basic values for air dome snow removal, detects snowfall in the snowfall detection unit, and then snowfall data is input to the input/output unit, output to the instrument panel and control panel, and then heat is supplied through a heat blower. A snow removal device for an air dome equipped with a heat collection membrane and a heat supply pipe, comprising: According to clause 1,
The electric heat blower is operated by being connected to an automatic emergency self-generator to prepare for incoming electricity and power outages, and transfers the heat generated by the combination of the hot air motor, hot air fan, and heater to the heat supply piping hose through the heat discharge port, and automatically controls the heat blower. It is integrated with the control panel of the system, allowing control of operation time and temperature of supplied heat, and is equipped with a heat collection membrane and heat supply piping, which include automatic control, operation and stop according to the adjusted time and temperature. Snow removal device for air dome. According to clause 3,
A T-shaped iron pipe is connected to the heat discharge port of the electric heat blower and is exposed to extend outside the air conditioning room. Flexible heat supply piping hoses for high temperature and high pressure are connected to the exposed T-shaped iron pipe in both directions to create an air dome. A snow removal device for an air dome equipped with a heat collection membrane and heat supply piping, characterized in that it is located in a form surrounding the entire lower surface edge along the basic anchor line. According to clause 1,
The hose joint pipe is a snow removal device for an air dome equipped with a heat collection membrane and a heat supply pipe, characterized in that it is installed in the form of a three-way elbow and a four-way elbow. According to clause 1,
Equipped with a heat collection membrane and heat supply piping, further comprising monitoring the degree of snowfall and the operating status of the electric heat blower automatically detected in the management room where the manager resides, and manually controlling the operation of the electric heat blower. Snow removal device for air dome. According to clause 1,
The high-temperature and high-pressure heat supply piping hose located on the lower surface along the air dome's basic anchor line is connected to the same type of heat supply piping hose that goes up to the outer upper surface of the air dome at a certain point on each side through a joint pipe, and is connected to the outer upper surface of the air dome. For an air dome equipped with a heat collection membrane and heat supply piping, which is evenly positioned and distributed to supply heat to the expected snow cover area, and the heat supplied under heating and pressurization through all heat supply piping hoses is evenly supplied. Snow removal equipment. According to clause 1,
In order to prevent the heat emitted from the heat supply piping hose and the heat from being blown up by the wind during bad weather, and to prevent damage and adhere closely, in addition to fixing it with a rubber band to the edge band hole of the heat collecting membrane, the entire heat collecting membrane is made elastic at regular intervals. A snow removal device for an air dome equipped with a heat collection membrane and heat supply piping, which is secured to the air dome cable by pressing it with a rope made of good rubber.