JP2014081099A - Snow melting device using geothermal ventilation system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a snow melting device using a geothermal ventilation system capable of concurrently using heat of air in a building and earth thermal for melting snow.SOLUTION: A snow melting device includes: a ventilation device 15 which suctions air and blows the air; a supply air channel (a supply air duct 21 and air guide pipes 102a and 102b) which communicates with the ventilation device 15 and supplies outer air of the exterior of a building 1 to the interior of the builing 1; an exhaust air channel (an exhaust air duct 27 and a snow melting pipe 28) which communicates with the ventilation device 15 and exhausts the air in the building 1 to the exterior of the building 1; and a heat exchanger (an air duct 102) which is buried in ground and is provided at a mid part of one of the supply air channel and the exhaust air channel. An exhaust port 28a of the exhaust air channel is provided so as to exhaust the air toward a snow accumulation part at the exterior of the building 1.

Description

  The present invention relates to a snow melting device using a ventilation system using ground heat of a building.

  Conventionally, a snow melting pipe is buried near the ground surface in the ground around the building, a ground heat exchanger consisting of heat exchange pipes is buried in the ground, and the snow melting pipe and the ground heat exchanger are circulated pumps There is known a snow melting / cooling device provided with an air cooler that allows the air in the building to be cooled by the underground heat from the underground heat exchanger while the liquid is circulated through the ground (for example, , See Patent Document 1).

JP-A-2005-214581

  However, in this snow melting / cooling device, the air cooler simply cools the indoor air in the summer, so the heat of the air in the building and the underground heat cannot be used simultaneously for melting snow. there were.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a snow melting device using a ground heat utilization ventilation system that can simultaneously use the heat of the air in the building and the underground heat for melting snow.

  In order to achieve this object, a snow melting device using a ground heat utilization ventilation system according to the present invention includes a ventilation device that sucks and blows air, and supplies outside air to the building in communication with the ventilation device. An air supply air passage, an exhaust air passage communicating with the ventilation device and exhausting the air inside the building to the outside of the building, and embedded in the ground and provided in the middle of one of the air supply air passage and the exhaust air passage And an exhaust port of the exhaust air passage is provided so as to be able to be discharged toward a snow accumulation part outside the building.

  According to this configuration, the heat of the air in the building and the underground heat can be used simultaneously for melting snow.

It is explanatory drawing of a building provided with the snow-melting apparatus using the ventilation system of the underground heat utilization which concerns on this invention. (A) is a perspective view of the air blower of the ventilator shown in FIG. 1, (b) is sectional drawing which follows the A1-A1 line of (a). FIG. 2 is an operation explanatory diagram in winter of the snow melting device shown in FIG. 1. FIG. 2 is an operation explanatory diagram in the summer of the snow melting device shown in FIG. 1. It is explanatory drawing which shows the other example of a building provided with the snow melting apparatus using the ventilation system using the underground heat which concerns on this invention. FIG. 2 is an operation explanatory diagram in winter of the snow melting device shown in FIG. 1. It is explanatory drawing which shows the other example of the air blower in the ventilation apparatus shown in FIG. It is explanatory drawing which shows the further another example of the air blower in the ventilation apparatus shown in FIG. It is explanatory drawing which shows the further another example of the building provided with the snow melting apparatus using the ventilation system using the ground heat which concerns on this invention. It is explanatory drawing which shows the further another example of the building provided with the snow melting apparatus using the ventilation system using geothermal heat shown in FIG.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
Example 1
Hereinafter, a building ventilation system according to Embodiment 1 of the present invention will be described with reference to the drawings.
[Constitution]
1 is provided with a solid foundation 101 having a basic heat insulation structure on the ground surface 100a. In the underground 100b below the ground surface 100a, a ground heat is used by being positioned directly below the solid foundation 101. An air duct (heat exchanging device) 102 that is a heat exchanging pipe is embedded. The air duct 102 is horizontally embedded in the underground 100b along the solid foundation 101. In addition, one end of air guide pipes 102a and 102b protruding from the ground surface 100a to the ground is connected to both ends of the air duct 102. In addition, the air path inside the air guide pipes 102a and 102b is used as an air supply air path.

  The solid foundation 101 has a bottom plate 101a and a foundation 101b that rises from the bottom plate 101a. Moreover, a base heat insulating member 103 is provided along the periphery of the solid base 101. The basic heat insulating member 103 includes a side surface portion 103a formed along the inner peripheral surface of the foundation 101b and a bottom surface portion 103b formed on the upper surface portion of the bottom plate 101a. For this basic heat insulating member 103, glass wool, urethane foam, polystyrene foam or the like is used.

  In FIG. 1, 1 is a building provided on a solid foundation 101, 2 is a room on the first floor of building 1, 3 is a room on the second floor of building 1, and 4 is a floor member (floor board) of room 1 on the first floor. It is. A plurality of living rooms 2 and 3 are provided. 2A is a partition between the living rooms 2 and 2, and 3A is a partition between the living rooms 3 and 3. The partitions 2A, 3A and the like are provided with a ventilation passage such as a louver (not shown).

  Reference numeral 5 denotes a space in which a hall or a corridor or a staircase (not shown) connected to the first floor and the second floor is provided, and 6 is a floor member (floor board) of the space 5. Floor members 4 and 6 A floor space 7 is formed below the floor members 4 and 6, that is, between the floor members 4 and 6 and the solid foundation 101.

  8 is a partition wall that partitions the living rooms 2 and 3 and the space 5, 9 is an outer wall of the space 5, and 10 is an upper space between the ceiling 2 a of the living room 2 and the floor 3 a of the living room 3. The partition wall 8 is also provided with an air passage (not shown) such as a louver that allows the rooms 2 and 3 to communicate with the space.

  Furthermore, the floor member 4 is formed with an opening 11 for communicating the living room 2 and the underfloor space 7, and the opening 12 for communicating the space 5 and the underfloor space 7 is formed in the portion of the floor member 6 on the partition wall 8 side. ing. A louver 13 is detachably attached to the living room 2 side in the opening 11, and a louver 14 is detachably attached to the opening 5 in the space 5 side.

  The underfloor space 7 has a ventilation device 15 disposed on the solid foundation 101. The ventilation device 15 is provided with a filter box 16 fixed on the solid foundation 101, a blower device (ventilation device main body) 17, and a branch box 18. As shown in FIG. 2A, the blower device 17 includes a case 19 whose interior is divided into a blower passage 19a and an exhaust passage 19b, and a blower fan 20 disposed in the blower passage 19a. As shown in FIG. 2B, the blower fan 20 includes a drive motor 20a and a fan 20b rotated by the drive motor 20a.

  The blower (ventilator main body) 17 has an outside air inlet 17a for sucking outside air into the air passage 19a of FIG. 2B and an outside air outlet 17b for blowing out the outside air sucked into the air passage 19a. Further, the blower (ventilator main body) 17 includes an indoor air suction port 17c that sucks indoor air in the building 1 into the exhaust passage 19b of FIG. 2A and indoor air that discharges the indoor air of the blower passage 19b to the outside. An exhaust port 17d is provided.

  As shown in FIG. 2B, an air supply duct (inside the air supply air passage) 21 is connected to the inflow side of the filter box 16 with one end communicating with the atmosphere and disposed in the outer wall 9. . The outflow side of the filter box 16 is connected to the outside air inlet 17a of the air passage 19a via the duct 22.

  Further, the other end portion of the air guide pipe 102 b whose one end is connected to the air duct 102 is connected to the outside air inlet 21 a of the air supply duct 21. Note that the end of the air guide pipe 102a connected to the air duct 102 is provided at a height where snow on the ground surface 100a does not block the opening end S1. The blower fan 20 rotates the fan 20b with the drive motor 20a, so that the outside air from the duct 22 side is sucked into the blower passage 19a and blown to the duct 23 side as indicated by the arrow A3. ing.

  A branch box 18 is connected to the outside air outlet 17b of the air passage 19a through a duct 23. An air conditioning device (not shown) for temperature adjustment (heating and cooling) is disposed in the branch box 18.

  As shown in FIG. 1, the branch box 18 is provided with air outlets (aeration ports) 18a and 18b of the ventilator 15, and the air outlet 18a is heated by an air conditioner (not shown). An air blowing duct 24 for blowing the adjusted air to the underfloor space 7 is connected. One end of an air supply duct 25 disposed in the partition wall 8 is connected to the air outlet 18 b of the branch box 18. As a result, air whose temperature has been adjusted by an air conditioner (not shown) in the branch box 18 is supplied to the air supply duct 25. The air supply duct 25 has a plurality of branch duct portions 25a disposed in the upper space 10, and each branch duct portion 25a is connected to the living room 3 on the second floor.

  Further, the opening 12 in FIG. 1 is connected to the indoor air suction port 17c of the exhaust passage 19b via the exhaust duct 26, and the indoor air exhaust port 17d of the exhaust passage 19b is an exhaust duct disposed in the outer wall 9. The inside is communicated with the atmosphere via an exhaust air passage 27. The exhaust duct 26, the exhaust path 19b, and the exhaust duct 27 constitute a series of exhaust air paths.

A snow melting pipe (the internal air passage is an exhaust air passage) 28 is connected to the air exhaust port 27 a of the exhaust duct 27. The snow outlet pipe 28 has an exhaust port (air outlet) 28a that is disposed so as to exhaust in the horizontal direction toward a portion of the snow accumulation portion on the ground surface 100a where snow melting is desired.
[Action]
Next, the operation of the ventilation system for a building having such a configuration will be described.
(i). Ventilation in Winter (Winter) When the blower fan 20 is operated, outside air is sucked into the air guide pipe 102a, and the sucked outside air is sucked into the air supply duct 21 through the air duct 102. At this time, the air duct 102 exchanges heat between the outside air flowing inside and the underground heat in the underground 100b. When the temperature of the outside air is lower than the temperature of the underground heat of the underground 100b, the outside air flowing in the air duct 102 is warmed by the underground heat, that is, the outside air flowing in the air duct 102 is heated in the underground 100b. It is heated by the underground heat. The warmed outside air is sucked into the filter box 16 through the air guide pipe 102a and the air supply duct 21. The sucked air dust is removed by a filter (not shown) in the filter box 16.

  The outside air from which the dust has been removed is sucked into the air blowing path 19a via the duct 22 in FIG. 1 and then supplied into the branch box 18 via the duct 23 by the blower fan 20.

  A part of the outside air supplied into the branch box 18 is supplied to the plurality of rooms 3 on the second floor through the air supply duct 25 as indicated by the arrow SA2. Further, the remainder of the outside air supplied into the branch box 18 is blown into the underfloor space 7 through the air blowing duct 24 and then into the plurality of rooms 2 on the first floor through the gallery 13 with an arrow SA1. Vented as shown.

  By supplying such warmed outside air into the rooms 2 and 3, the air in the rooms 2 and 3 is warmed, and the temperature in the rooms 2 and 3 can be raised.

  On the other hand, the air in the living rooms 2 and 3 is discharged into the space 5 by supplying outside air to the living rooms 2 and 3 through the louver (not shown) of the partitions 2A and 3A, the louver (not shown) of the partition wall 8, and the like. The

The air discharged into the space 5 flows into the exhaust passage 19b through the louver 14 and the exhaust duct 26 as indicated by the arrow RA. The air flowing into the exhaust passage 19b is exhausted to the atmosphere as shown by an arrow B (snow melting) in FIG. 3 through the exhaust duct 27 and the snow melting pipe 28 in FIG. At this time, when snow is piled up on the ground surface 100 a to form the snow accumulation portion 29, the snow accumulation portion 29 is melted by the heat of the air exhausted from the snow melting pipe 28. FIG. 3 schematically shows the relationship between the air blower 17 as the ventilation device of FIG. 1 and the air duct 102, and the other components are not shown.
(ii). Ventilation in Summer (Summer) When the blower fan 20 is operated, outside air is sucked into the air guide pipe 102 a and the sucked outside air is sucked into the air supply duct 21 through the air duct 102. At this time, the air duct 102 exchanges heat between the outside air flowing inside and the underground heat in the underground 100b. Since the temperature of the outside air is high in the summer, the outside air flowing in the air duct 102 is cooled by the underground heat in the summer, that is, the outside air flowing in the air duct 102 is absorbed into the underground 100b and cooled. The cooled outside air is sucked into the filter box 16 through the air guide pipe 102a and the air supply duct 21. The sucked air dust is removed by a filter (not shown) in the filter box 16.

  The outside air from which the dust has been removed is sucked into the air blowing path 19a via the duct 22 in FIG. 1 and then supplied into the branch box 18 via the duct 23 by the blower fan 20.

  A part of the outside air supplied into the branch box 18 is supplied to the plurality of rooms 3 on the second floor through the air supply duct 25 as indicated by the arrow SA2. The remaining outside air supplied into the branch box 18 is discharged into the underfloor space 7 through the discharge duct 24 and then indicated by arrows SA1 in the plurality of rooms 2 on the first floor through the gallery 13. It is aired as if.

  By supplying such cooled outside air into the rooms 2 and 3, the air in the rooms 2 and 3 is cooled, and the temperature in the rooms 2 and 3 can be lowered.

  On the other hand, the air in the living rooms 2 and 3 is discharged into the space 5 by supplying outside air to the living rooms 2 and 3 through the louver (not shown) of the partitions 2A and 3A, the louver (not shown) of the partition wall 8, and the like. The

The air discharged into the space 5 flows into the exhaust passage 19b through the gallery 15 and the exhaust duct 26 as indicated by the arrow RA. The air flowing into the exhaust passage 19b is exhausted to the atmosphere as shown by an arrow B (exhaust) in FIG. 4 via the exhaust duct 27 and the snow melting pipe 28 in FIG. FIG. 4 schematically shows the relationship between the blower 17 as the ventilation device of FIG. 1 and the air duct 102, and the other components are not shown.
(Example 2)
In the embodiment described above, the air guide pipe 102b is connected to the air supply duct 21 and the snow melting pipe 28 is connected to the exhaust duct 27. However, the present invention is not necessarily limited to this structure.

  For example, as shown in FIG. 5, the air guide pipe 102a is connected to the exhaust duct 27, and the open end S1 of the air guide pipe 102a is horizontally directed toward the portion of the snow accumulation portion on the ground surface 100a where snow melting is desired. It is good also as a structure arrange | positioned so that it may exhaust.

  In this configuration, when the blower fan 20 is operated, outside air is sucked into the filter box 16 through the air supply duct 21. The sucked air dust is removed by a filter (not shown) in the filter box 16.

  The outside air from which the dust has been removed is sucked into the air blowing path 19a via the duct 22 of FIG. 5 and then supplied into the branch box 18 via the duct 23 by the blower fan 20.

  A part of the outside air supplied into the branch box 18 is supplied to the plurality of rooms 3 on the second floor through the air supply duct 25 as indicated by the arrow SA2. The remaining outside air supplied into the branch box 18 is discharged into the underfloor space 7 through the discharge duct 24 and then indicated by arrows SA1 in the plurality of rooms 2 on the first floor through the gallery 13. It is aired as if.

  On the other hand, the air in the living rooms 2 and 3 is discharged into the space 5 by supplying outside air to the living rooms 2 and 3 through the louver (not shown) of the partitions 2A and 3A, the louver (not shown) of the partition wall 8, and the like. The

The air discharged into the space 5 flows into the exhaust path 19b through the exhaust duct 26 as indicated by the arrow RA. The air flowing into the exhaust passage 19b is exhausted to the atmosphere as shown by an arrow C in FIG. 6 through the exhaust duct 27, the air guide pipe 102b, the air duct 102, and the air guide pipe 102a in FIG. Is done. At this time, when snow is piled up on the ground surface 100a to form the snow accumulation portion 29, the snow accumulation portion 29 is melted by the heat of the air exhausted from the air guide pipe 102b.
(Example 3)
The drive motor 20a of the blower fan 20 of the blower device 17 in the first and second embodiments is a DC motor, and the rotational drive direction of the drive motor 20a is controlled by the control unit (control means, blower switching means) 30 in FIG. A configuration in which switching control is possible is also possible.

In this case, by changing the rotation direction of the drive motor 20a, the air blowing direction is switched to one of the direction indicated by the arrow A3 and the direction indicated by the arrow A4 in FIG. The use conditions of the air duct 102 can be changed.
(Example 4)
In the third embodiment, the use condition of the air duct 102 embedded in the underground 100b during ventilation is changed as a configuration in which the rotational drive direction of the drive motor 20a can be switched and controlled by the control unit (control means) 30 in FIG. Although the example which did so was shown, it is not necessarily limited to this.

  For example, in the ventilation device 15 of FIG. 5, the connection port (first connection port) to which the filter box 16 of the blower device 17 is connected is the outside air suction port 16a, and the exhaust duct (exhaust air passage) 27 of the blower device 17 is When the connection port (second connection port) to be connected is the indoor air exhaust port 17d as described above, the connection state to the air supply duct 21, the exhaust duct 27, the air duct 102, and the snow melting pipe 28 is shown in FIG. The air path switching valve (fan switching means) 40 may be used.

  According to this configuration, when the snow is piled up on the ground surface 100a to form the snow accumulation portion 29 as shown in FIG. 6 in the winter season, the air supply duct 21 is connected to the air duct 21 by the air passage switching valve (fan switching means) 40. In addition to being connected to the filter box 16, the exhaust duct 27 is connected to the indoor air exhaust port 17d. In this connected state, the indoor air exhausted from the air guide pipe 102b through the exhaust duct 27 is snowed from the opening S1 through the air duct (heat exchange device) 102 and the air guide pipe 102a as shown in FIG. It can blow out toward the part 29. At this time, if the indoor air is lower than the underground heat, the indoor air is warmed by the underground heat, and the warmed air is blown from the opening S1 of the air guide pipe 102a to the snow accumulating portion 29, and the snow accumulating portion 29 snow melts. When the indoor air is higher than the underground heat, this air is blown to the snow accumulating portion 29 from the opening S1 of the air guide pipe 102a, and the snow in the snow accumulating portion 29 is melted.

In such a configuration, the air supply duct 21 is switched and connected to the indoor air exhaust port (second connection port) 17d of the blower device 17 by the air path switching valve (air blowing switching means) 40 in the summer, and the exhaust gas is exhausted. By connecting the duct 27 to the outside air suction port (first connection port) 16a of the blower device 17, the air supply duct 21 can be used as an exhaust duct and the exhaust duct 27 can be used as an air supply duct. At this time, the outside air sucked through the exhaust duct 27 is cooled through the air duct (heat exchange device) 102 buried in the ground, and then sent to the blower device 17 through the air guide pipe 102b and the filter box 16. After being inhaled, it is used for ventilation in building 1. Thus, in the summer, the inside of the building 1 can be cooled by the outside air by ventilating the inside of the building 1 with the outside air cooled by the underground heat.
(Example 5)
Moreover, as shown in FIG. 9 corresponding to FIG. 4 of Example 1, in order to assist the ventilation apparatus 17 of a ventilation system, the auxiliary ventilation fan 50 is provided in the middle of the air supply duct 21 in the middle of a ventilation path. Or you may provide the auxiliary ventilation fan 60 in the suction part of the air guide pipe 102b in the middle of a ventilation path like a broken line.

Moreover, as shown in FIG. 10, it is good also as a structure which provided both the auxiliary | assistant ventilation fans 50 and 60. As shown in FIG.
<Supplementary explanation 1>
As described above, the snow melting device using the underground heat-utilizing ventilation system according to the embodiment of the present invention includes the ventilation device 15 that sucks and blows air, and the outside air that communicates with the ventilation device 15 and is outside the building 1. Air supply passage (air supply duct 21, air guide pipes 102 a and 102 b) for supplying air into the building 1 and exhaust air for communicating the ventilation device 15 and exhausting the air inside the building 1 to the outside of the building 1. A passage (exhaust duct 27, snow melting pipe 28), and an air supply passage (air supply duct 21, air guide pipes 102a, 102b) and an exhaust air passage (exhaust duct 27, snow melting pipe 28) buried in the ground. A heat exchange device (air duct 102) provided in the middle of one of the above. Moreover, the exhaust port 28a of the exhaust air passage (exhaust duct 27, snow melting pipe 28) is provided so as to be discharged toward the snow accumulation part outside the building 1.

According to this structure, the heat of the air in the building 1 and the underground heat can be used simultaneously for melting snow.
<Supplementary explanation 2>
In the snow melting apparatus using the underground heat-utilizing ventilation system according to the embodiment of the present invention, air blowing switching means (the control unit 30 and the air path switching valve 40) for switching the air blowing direction of the ventilation apparatus 15 is provided.

According to this configuration, by switching the air blowing direction, the heat of the air in the building and the underground heat are simultaneously used for melting snow in the winter, or the underground heat is used for ventilation in the building in the summer. Or can be used for cooling
<Supplementary explanation 3>
In the snow melting apparatus using the underground heat utilization ventilation system according to the embodiment of the present invention, the air blowing switching means switches and controls the rotation direction of the drive motor 20a for driving the wind fan 20b in the ventilation apparatus 15. (Control unit 30).

According to this configuration, the air flow direction can be switched with a simple configuration, and the heat of the air in the building and the underground heat can be used for snow melting at the same time in the winter, or the ground heat can be used for ventilation in the building in the summer. Can be used to cool the air in the building.
<Supplementary explanation 4>
In the snow melting apparatus using the underground heat utilization ventilation system according to the embodiment of the present invention, the ventilation apparatus 15 is connected to the supply air passage (the supply duct 21 and the air guide pipes 102a and 102b). A second connection port to which the other of the connection port and the exhaust air channel is connected, and the air blowing switching means is configured to supply the air supply air channel (air supply duct 21, air guide pipes 102a and 102b) and the exhaust air channel (exhaust gas). An air path switching valve (40) for switching the connection of the first connection port and the second connection port to the duct 27 and the snow melting pipe 28).

According to this configuration, the air flow direction can be switched with a simple configuration, and the heat of the air in the building and the underground heat can be used for snow melting at the same time in the winter, or the ground heat can be used for ventilation in the building in the summer. Can be used to cool the air in the building.
<Supplementary explanation 5>
In the snow melting device using the ground heat-use ventilation system according to the embodiment of the present invention, the heat exchange device (air duct 102) is in the middle of the air supply air passage (air supply duct 21, air guide pipes 102a, 102b). Is provided.

According to this configuration, the air flow direction can be switched with a simple configuration, and the heat of the air in the building and the underground heat can be used for snow melting at the same time in the winter, or the ground heat can be used for ventilation in the building in the summer. Can be used to cool the air in the building.
<Supplementary explanation 6>
In the snow melting apparatus using the underground heat utilization ventilation system of the embodiment of the present invention, the heat exchange device (air duct 102) is provided in the middle of the exhaust air passage (exhaust duct 27, snow melting pipe 28). ing.

  According to this configuration, the air flow direction can be switched with a simple configuration, and the heat of the air in the building and the underground heat can be used for snow melting at the same time in the winter, or the ground heat can be used for ventilation in the building in the summer. Can be used to cool the air in the building.

1 Building 15 Ventilator 20a Drive Motor 20b Fan 21 Air Supply Duct (Air Supply Airway)
27 Exhaust duct (exhaust air passage)
28 Snow melting pipe (exhaust air passage)
28a Exhaust port 30 Control unit 40 Air path switching valve 102 Air duct (heat exchange pipe, heat exchange device)
102a, 102b Air guide pipe (supply air passage)

Claims (6)

A ventilator that inhales and blows air;
An air supply passage that communicates with the ventilator and supplies outside air outside the building into the building;
An exhaust air passage communicating with the ventilator and exhausting the air in the building to the outside of the building;
A heat exchanging device embedded in the ground and provided in the middle of one of the supply air passage and the exhaust air passage,
A snow melting device using a ventilation system using geothermal heat, wherein an exhaust port of the exhaust air passage is provided so as to be discharged toward a snow accumulation part outside the building.   The snow melting apparatus using the underground heat utilization ventilation system according to claim 1, further comprising a ventilation switching means for switching a ventilation direction of the ventilation apparatus. apparatus.   The snow melting apparatus using the underground heat utilization ventilation system according to claim 2, wherein the air blowing switching means is a control means for switching and controlling a rotation direction of a drive motor for driving a blower fan in the ventilation apparatus. A snow melting device that uses a geothermal heat ventilation system.   The snow melting apparatus using the ground heat utilization ventilation system according to claim 2, wherein the ventilation apparatus has a first connection port to which the supply air path is connected and a second connection to which the exhaust air path is connected. The air flow switching means is an air path switching valve that switches and connects the connection of the first connection port and the second connection port to the supply air path and the exhaust air path. Snow melting equipment using a ground heat ventilation system.   The snow melting apparatus using the ground heat utilization ventilation system according to claim 1, wherein the heat exchange device is provided in the middle of the air supply air passage. Snow melting device.   The snow melting apparatus using the underground heat utilization ventilation system according to claim 1, wherein the heat exchange device is provided in the middle of the exhaust air passage. Snow melting device.