KR20200113955A - Cooling and Heating Smart Waiting Station Using Geothemal Energy - Google Patents

Abstract

The present invention relates to a cooling and heating smart waiting station using geothermal heat that provides efficient improvement of a user′s waiting environment in cold or hot weather by using geothermal heat existing underground in a waiting area such as a platform or a crosswalk. The smart waiting station includes: a waiting station body that secures a waiting space inside by having an upper panel and a side panel; a geothermal heat exchange means installed vertically underground in the waiting space of the waiting station body and circulating air above ground to circulate and supply the air exchanged with geothermal heat to the waiting space. The geothermal heat exchange means includes: a heat exchange tank that is installed to be buried by drilling the ground and is filled with water; a heat exchange pipe extended vertically in the heat exchange tank and bent in a coil shape; and an air supply means that is installed in the waiting space of the waiting station body and communicates with the heat exchange pipe to circulate ground air and supply the air to the waiting space.

Description

Cooling and Heating Smart Waiting Station Using Geothemal Energy}

The present invention relates to a smart air-conditioning station for cooling and heating using geothermal heat, and more particularly, geothermal heat capable of efficiently improving a user's atmospheric environment during cold or hot weather by using geothermal heat existing underground at waiting places such as platforms or crosswalks. It relates to a cooling and heating smart waiting area using.

In general, at the platform where vehicles such as buses or taxis stop, the rear left and right sides are closed and the front is open in the form of a booth.The waiting area is to avoid sunlight or take a short break before the bus or taxi arrives. Is used to help you take it.

Recently, at a crosswalk prepared to cross a road, a red light status signal is waiting for the green light that can cross the road to light up, but a waiting area, a facility that allows pedestrians to avoid sunlight or rain while exposed to the outside, has been installed. It is a situation that continues to be required.

As a prior art disclosed in connection with the platform among the above waiting areas, Korean Utility Model Registration No. 392279 (2005.08.01.) discloses that in a normal bus platform, one side of the platform is made of a semicircular side membrane and a semicircular side is made. A front barrier was installed to be connected to the membrane, and the other side barrier was formed somewhat wider than the width of the semicircular side membrane, so that a bus platform with a windbreak membrane on the front surface to avoid the wind and rain that rushes to the front of the platform is known.

In addition, Registration Utility Model Publication No. 411843 (2006.03.13) states that in a normal bus platform, a window is made on one side of the platform, a transparent barrier is fixed on both sides of the front side, and a handle is provided so that the central part can be opened and closed on both sides. There are known bus platforms that have windbreak barriers on the front that can avoid the wind and rain that rushes to the front of the platform as the attached left and right barrier doors are integrated.

In addition, as a prior art disclosed in connection with a waiting area applied to a crosswalk, Registered Utility Model Publication No. 310066 (2003.03.27.) includes posts installed on both road sides of the crosswalk and horizontally installed on the top of the posts. Including a horizontal support and an awning that is supported by the horizontal support and blocks sunlight, snow, rain, etc., when a pedestrian is waiting for a signal to cross a crosswalk, it is configured to protect pedestrians from sunlight, snow, rain, etc. There are known waiting places for crosswalks that can provide the safety and convenience of pedestrians.

However, all of the above-described conventional techniques do not have great difficulty in temporarily avoiding the sun or rain at the time of waiting for boarding or crossing, but there is a disadvantage in that they are not very helpful in resolving the intense heat of the cold or hot weather. In particular, in the case of Registered Utility Model Publication No. 310066, since the front and rear sides are open and exposed unprotected to rain and wind, the effectiveness of the facility is poor and there is a problem.

In addition, in the case of Registered Utility Model Publications Nos. 392279 and Nos. 411843, the front of the shelter is simply partially or completely blocked, so the feeling of openness is usually reduced and it is frustrating and causes inconvenience in use due to the nature that many people use it. There was a problem that caused the bad news that ventilation was not smooth.

KR Registered Utility Model Publication No. 20-0392279 (2005.08.01.) KR Utility Model Publication No. 20-0411843 (2006.03.13.) KR Registered Utility Model Publication No. 20-310066 (2003.03.27.)

The present invention is to solve the above problems, and the temperature change according to the weather on the ground is configured to be corrected to an appropriate temperature in the atmosphere by using geothermal heat existing underground. The purpose of this is to provide a smart atmosphere for cooling and heating using geothermal heat that can improve the convenience and ventilation of use while maintaining openness or airtightness, and fundamentally relieve the cold of cold or intense heat in the hottest season and promote an excellent atmospheric environment. .

The smart air-conditioning station for cooling and heating using geothermal heat proposed by the present invention includes: a waiting station body having an upper panel and a side panel to secure an air space therein; And a geothermal heat exchange means for circulating air above the ground and circulating air that has been heat-exchanged with geothermal heat to the atmospheric space by circulating and supplying the air that has been heat exchanged with geothermal heat, and the geothermal heat exchange means perforates the ground. A heat exchange tank that is installed buried and filled with water, a heat exchange pipe extending vertically in the heat exchange tank and bent in a coil shape, and a heat exchange pipe installed in the atmospheric space of the atmosphere body and communicated with the heat exchange pipe to provide ground air. It comprises a supply means for supplying toward the waiting space after circulating.

The heat exchange tank includes a water exchange means for draining and supplying water to exchange water filled therein.

The air supply means includes an intake pipe connected on the heat exchange pipe to inject air from the outside, a supply pipe connected on the heat exchange pipe and moving heat exchanged air through the heat exchange pipe toward an external atmospheric space, The intake pipe and the air supply pipe are connected to each other and constitute a supply driving fan that drives air to be supplied to the atmosphere space of the atmosphere body.

The air supply means is provided with a filtering filter installed in the air supply fan and filtering fine dust in the air supplied through the air supply pipe.

In addition, the present invention may further include a smart control unit installed in the waiting station body and applying a control signal to the air supply means of the geothermal heat exchange means according to the environment setting of the waiting space and an external sensing signal.

The smart control unit controls to temporarily stop driving of the air supply means among the geothermal heat exchange means at a set time period at night after sensing day/night.

The smart control unit is configured with a temperature sensor that senses the ambient temperature in the atmosphere space of the atmosphere body, the smart control unit sets an appropriate temperature range in the atmosphere space of the atmosphere body, and a detection signal input from the temperature sensor is set. When the temperature is out of the range, a control signal for driving the air supply means among the geothermal heat exchange means is applied.

A human body detection sensor is configured to detect whether the waiting body enters the waiting space, and the smart control unit applies a control signal to control the driving of the air supply means among the geothermal heat exchange means when a detection signal is input from the human body detection sensor. To be organized.

According to the smart air-conditioning station for cooling and heating using geothermal heat according to the present invention, since it is configured to continuously circulate and supply the ground air in the air space in the air space with the geothermal heat existing underground, the temperature of the air space is always constant during cold or hot weather. It optimizes the air environment with the warm air temperature in the cold season and the cool air temperature in the hot weather, and corrects the atmospheric environment in the atmosphere, while maintaining the openness, half-openness, or airtightness according to the various types of facilities. The effectiveness of the waiting area, such as convenience and ventilation, can be significantly improved.

In addition, since the smart air-conditioning station for cooling and heating using geothermal heat according to the present invention is configured to purify the air when supplying the air exchanged with geothermal heat to the atmospheric space, it filters and adsorbs fine dust in the air to reduce the concentration of fine dust in the air space. There is an effect that can reduce a large amount.

In addition, since the cooling and heating smart waiting room using geothermal heat according to the present invention is automatically controlled to maintain an appropriate atmospheric environment according to the environment setting and detection signal of the atmospheric space, the atmospheric environment is more optimized and limited by the flexible control operation of the waiting room. There is an effect of minimizing the power consumption through the proper setting operation.

1 is a perspective view schematically showing an embodiment according to the present invention.
Figure 2 is a cross-sectional view schematically showing an embodiment according to the present invention.
Figure 3 is a cross-sectional view showing a geothermal heat exchange means in an embodiment according to the present invention.
4 is a block diagram schematically showing another embodiment according to the present invention.

The present invention comprises an upper panel and a side panel to secure a waiting space therein; And a geothermal heat exchange means for circulating air above the ground and circulating air that has been heat-exchanged with geothermal heat to the atmospheric space by circulating and supplying the air that has been heat exchanged with geothermal heat, and the geothermal heat exchange means perforates the ground. A heat exchange tank that is installed buried and filled with water, a heat exchange pipe extending vertically in the heat exchange tank and bent in a coil shape, and a heat exchange pipe installed in the atmospheric space of the atmosphere body and communicated with the heat exchange pipe to provide ground air. The technology configuration features a cooling and heating smart waiting station using geothermal heat that includes a supply means for supplying air to the waiting space after circulating.

Next, with reference to the drawings, a preferred embodiment of a cooling and heating smart waiting room using geothermal heat according to the present invention will be described in detail.

First, an embodiment of a cooling/heating smart waiting station using geothermal heat according to the present invention includes an atmosphere main body 100 and a geothermal heat exchange means 200 as shown in FIGS. 1 and 2.

As shown in Figs. 1 and 2, the waiting area main body 100 secures a space in which a user can wait for various purposes such as getting on and off a vehicle such as a bus or a taxi, crossing a road at a crosswalk, and resting in a park. As a structure constructed in the form of a booth, an upper panel 110 and a plurality of side panels 120 are provided to secure a waiting space (S) therein.

The upper panel 110 is configured by installing a photovoltaic panel (not shown in the drawing) to provide power to various control facilities installed in the waiting station body 100 including the geothermal heat exchange means 200 It is also possible.

In the drawings (Figs. 1 to 2), the most common type of waiting area for the waiting area body 100, that is, a semi-open type waiting area structure in which the side panels 120 are provided on both the left and right sides and rear sides based on the upper panel 110. Although shown, depending on the application purpose and purpose of the waiting area, the side panel 120 is configured as an open waiting area structure applied only to the left and right sides or rear side based on the upper panel 110, or the upper panel 110 is used as a reference. / It is possible to configure the airtight atmosphere structure with the rear or left and right sides sealed so that it can be opened and closed.

As shown in FIG. 2, the geothermal heat exchange means 200 is buried and installed vertically underground in the atmospheric space (S) of the atmosphere main body 100, but some of the upper components are disposed in an exposed state in the atmosphere to supply air. Build a structure that can be done.

As shown in Figs. 2 and 3, the geothermal heat exchange means 200 circulates air in the atmospheric space S above the ground, but circulates and supplies the air exchanged with geothermal heat to the atmospheric space S. (210) and a heat exchange pipe (220), it is configured to be provided with a supply means (230).

The heat exchange tank 210 is installed to be buried by drilling the ground in the atmosphere space S of the atmosphere body 100. That is, the ground is drilled to a depth proportional to the length of the heat exchange tank 210, but the ground is drilled to a depth of 1 m or more, that is, 7 m below the ground, so that the heat exchange tank 210 is buried and installed. There is no anger, and it is possible to achieve smooth heat exchange.

The heat exchange tank 210 is constructed of a metal material to facilitate heat exchange due to excellent durability and thermal conductivity to withstand external forces.

The heat exchange tank 210 is filled with water as a heat medium therein, and has an upper cover 215 at its upper end to keep the inner space sealed.

The upper cover 215 forms a connection end 216 so that the heat exchange pipe 220 and the air supply unit 230 can be coupled to each other.

In addition, in the heat exchange tank 210, as shown in FIG. 3, it is possible to configure a water exchange means 240 so as to exchange water filled therein.

The water exchange means 240 is configured to drain and supply water filled in the heat exchange tank 210. That is, the water exchange means 240 is connected to the upper cover 215 of the heat exchange tank 210 to form a path through which water can be supplied from an external water supply source (not shown in the drawing), and a water supply pipe 241, A drain pipe 243 which is a path through which water filled in the heat exchange tank 210 can be drained is provided.

The water exchange means 240 constitutes a pump 245 so that the water filled in the heat exchange tank 210 can be drained through the drain pipe 243.

In the drawing (FIG. 3), the pump 245 is shown by applying a submersible pump installed so as to be submerged in water in the heat exchange tank 210, but the pump 245 is outside the heat exchange tank 210. It is also possible to configure by applying a general pump connected to the drain pipe (243).

The water filled in the heat exchange tank 210 is configured to be filled by supplying water of different temperatures depending on the season. For example, in a cold season, hot water in the heat exchange tank 210 is filled with the water exchange means 240 to form a medium-temperature thermal tank, and in a hot season, the water exchange means 240 allows the heat exchange tank (210) It is configured to form a cold and hot tank with cold water filled in.

When the water exchange means 240 is configured as described above, it is possible to improve the environment by cooling or heating in the atmosphere body 100 so that more efficient heat exchange for each season can be achieved.

The heat exchange pipe 220 is fixedly installed on the upper cover 215 of the heat exchange tank 210 and extends vertically in the heat exchange tank 210 in the vertical direction.

The heat exchange pipe 220 is in contact with water in the heat exchange tank 210 so as to exchange heat, but is bent in a coil shape to maximize the contact area, and forms a path through which air can flow inside.

The heat exchange pipe 220 is made of a copper tube having excellent thermal conductivity and antibacterial action.

The air supply unit 230 performs a function of circulating the air in the atmosphere space S of the atmosphere body 100 to exchange heat and supply it.

The air supply means 230 is installed in an exposed state in the atmosphere space S of the atmosphere body 100.

In the above, the air supply unit 230 can be fixedly installed on the side panel 120 frame of the waiting station body 100, and has a separate dedicated support frame (not shown in the drawing) in the waiting station body 100 It is also possible to configure a fixed installation.

As shown in FIG. 3, the air supply means 230 communicates with the heat exchange pipe 220 to circulate ground air for heat exchange with geothermal heat, and then supply the air to the atmospheric space (S). 231), an air supply pipe 233, and a supply driving fan 235 are configured.

The intake pipe 231 and the supply pipe 233 are connected in communication with the heat exchange pipe 220 and are connected and coupled to a connection end 216 provided on the upper cover 215 of the heat exchange tank 210 And fix it.

The intake pipe 231 forms a path through which air can be injected from the outside toward the heat exchange pipe 220, and the supply pipe 233 transfers heat exchanged air through the heat exchange pipe 220 to an external atmosphere space. It forms a path that moves toward (S).

The air supply fan 235 is installed in the air supply housing 235a in which the suction hole 235b and the air supply hole 235c are formed.

In the drawing, the configuration of the air supply housing 235a and the air supply driving fan 235 is shown as a structure applied solely within the standby main body 100, but supply air in the direction of various angles at various positions within the air supply body 100 It is also possible to configure by applying a plurality of air supply housings (235a) and air supply drive fan 235 to be made.

The air supply fan 235 is driven so that the air intake pipe 231 and the air supply pipe 233 are connected to each other and supply air toward the air space S of the atmosphere body 100. That is, the air supply means 230 is driven by the air supply fan 235 to apply a suction force to the air intake pipe 231 by moving air for supplying air to the supply pipe 233.

The air supply means 230 constitutes a filter filter 237 installed corresponding to the air supply driving fan 235 and filtering fine dust in the air supplied through the supply pipe 233.

When the filtration filter 237 is configured in the air supply unit 230 as described above, the air is purified when the air exchanged with geothermal heat is supplied to the atmosphere space S, so that fine dust in the air is filtered and adsorbed. It is possible to mass decrease the concentration of fine dust in the air space (S).

That is, according to the cooling/heating smart standby station using geothermal heat according to the present invention configured as described above, since it is configured to continuously circulate and supply the ground air in the atmosphere space of the waiting area with geothermal heat existing underground, It optimizes the air environment with warm air temperature in cold weather and cool air temperature in hot weather while always maintaining the temperature of the air space, and maintains the convenience of use and ventilation by maintaining the open feeling while correcting the air environment in the atmosphere. It is possible to significantly improve the effectiveness of the waiting area.

And another embodiment of the cooling and heating smart waiting station using geothermal heat according to the present invention is installed in the waiting station body 100, as shown in Figure 4, the geothermal heat exchange means according to the environment setting and external sensing signal of the waiting space (S). It is made by further comprising a smart control unit 300 for applying a control signal to the air supply means 230 of (200).

Although not shown in the drawing, it is also possible to configure a controller that can be operated and set in the smart control unit 300 so that an administrator can externally input various environment settings.

In the above, the controller configures a wireless communication module to communicate wirelessly with the plurality of smart controllers 300, and configures the administrator to collectively set the plurality of smart controllers 300 from one controller. It is possible.

It is also possible to set the smart control unit 300 to automatically control the operation of the geothermal heat exchange means 200 by dividing day and night by time zone. That is, the smart control unit 300 detects whether it is day or night, and then the air supply unit 230 of the geothermal heat exchange unit 200 at a set time period at night (for example, at night at night) when there is no flow of the user. Since the operation is controlled to stop temporarily, it is possible to minimize the amount of power consumption for maintenance of the smart standby station.

The smart control unit 300 is configured with a temperature sensor 310 that senses and measures the ambient temperature in the atmosphere space S of the atmosphere body 100.

The smart control unit 300 sets an appropriate temperature range in the waiting space S of the atmosphere body 100, and when the detection signal input from the temperature sensor 310 is out of the set temperature range, the geothermal heat exchange means ( 200) is configured to apply a control signal for driving the air supply means 230.

For example, if the smart control unit 300 sets the temperature of the waiting space S of the waiting body 100 in a range of 15 to 30°C, the waiting space measured by the temperature sensor 310 ( When the temperature of S) is less than 15° C., the smart control unit 300 controls the air supply unit 230 of the geothermal heat exchange unit 200 to be automatically driven, and the atmosphere measured by the temperature sensor 310 in hot weather When the temperature of the space S exceeds 30° C., the smart control unit 300 controls the air supply unit 230 of the geothermal heat exchange unit 200 to be automatically driven.

In addition, a human body detection sensor 320 for detecting the entry of the waiting person in the waiting space S is configured in the waiting area body 100, and a detection signal indicating whether a human body is detected is transmitted to the smart control unit 300. Make up.

When a detection signal is input from the human body detection sensor 320, the smart control unit 300 applies a control signal to control the operation of the air supply unit 230 of the geothermal heat exchange unit 200.

For example, in a state in which there is no waiter in the waiting space (S) of the waiting station body 100, the driving of the geothermal heat exchange means 200 in the smart control unit 300 is maintained in a stopped state or the smart control unit 300 ) To maintain the driving of the geothermal heat exchange means 200 in a driving state for each set period, and a waiting person in the waiting space (S) of the waiting station body 100 enters and a detection signal from the human body detection sensor 320 is received. When inputted, the air supply unit 230 of the geothermal heat exchange unit 200 is controlled to be driven while initializing all the settings of the smart control unit 300.

That is, if the present invention is configured as in the other embodiments described above, the atmosphere environment is more optimized through flexible control operation of the atmosphere because it is controlled to automatically maintain an appropriate atmosphere environment according to the environment setting and detection signal of the atmosphere space, It is possible to minimize power consumption with limited set operation.

In the above, a preferred embodiment of a cooling and heating smart atmosphere using geothermal heat according to the present invention has been described, but the present invention is not limited thereto, and various modifications are made within the scope of the claims, the specification of the invention, and the accompanying drawings. It is possible, and this also falls within the scope of the present invention.

100: waiting area body 110: upper panel 120: side panel
200: geothermal heat exchange means 210: heat exchange tank 215: upper cover
216: connection end 220: heat exchange pipe 230: air supply means
231: intake pipe 233: supply pipe 235: supply drive fan
235a: air supply housing 235b: suction hole 235c: air supply hole
237: filtration filter 240: water exchange means 241: water supply pipe
243: drain pipe 245: pump 300: smart control unit
310: temperature sensor 320: human body detection sensor

Claims (8)

A waiting body having an upper panel and a side panel to secure a waiting space therein;
Including; geothermal heat exchange means for circulating and supplying air exchanged with geothermal heat to the atmospheric space while circulating ground air and circulating air above the ground while being buried in the atmospheric space of the atmospheric body.
The geothermal heat exchange means includes a heat exchange tank which is installed to be buried by drilling the ground and filled with water, a heat exchange pipe extending vertically in the heat exchange tank and bent in a coil shape, and an atmospheric space of the atmosphere body. It is installed and communicates with the heat exchange pipe to circulate ground air, and then a cooling and heating smart waiting station using geothermal heat comprising a supply means for supplying to the atmosphere space.
The method according to claim 1,
The heat exchange tank includes a water exchange means for draining and supplying water to exchange water filled therein.
The method according to claim 1,
The air supply means includes an intake pipe connected on the heat exchange pipe to inject air from the outside, a supply pipe connected on the heat exchange pipe and moving heat exchanged air through the heat exchange pipe toward an external atmospheric space, A cooling and heating smart waiting room using geothermal heat comprising a supply drive fan connected to the intake pipe and the air supply pipe and driving to supply air toward the atmosphere space of the atmosphere body.
The method of claim 3,
The air supply means is a cooling and heating smart atmosphere using geothermal heat comprising a filter filter installed in the air supply fan and filtering fine dust in the air supplied through the supply pipe.
The method according to any one of claims 1 to 4,
A cooling and heating smart waiting station using geothermal heat, which is installed in the waiting station body and further comprises a smart controller configured to apply a control signal to the air supply means of the geothermal heat exchange means according to an environment setting of the waiting space and an external sensing signal.
The method of claim 5,
The smart control unit detects day/night and then controls to temporarily stop driving of the air supply means among the geothermal heat exchange means at a set time period at night.
The method of claim 5,
In the smart control unit, a temperature sensor for sensing the ambient temperature in the atmosphere space of the atmosphere body is configured,
The smart control unit sets an appropriate temperature range in the atmosphere space of the atmosphere body, and applies a control signal for driving the air supply means among the geothermal heat exchange means when the detection signal input from the temperature sensor exceeds the set temperature range. Smart waiting area for cooling and heating using geothermal heat.
The method of claim 5,
Construct a human body detection sensor that detects whether the waiting body enters the waiting space,
In the smart control unit, when a detection signal is input from the human body detection sensor, a cooling and heating smart waiting station using geothermal heat applies a control signal to control the driving of the air supply means among the geothermal heat exchange means.

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