JP4528029B2 - Underground snow melting tank with hollow tube embedded by rotary press-in method and snow melting equipment equipped with it - Google Patents

Description

The present invention relates to underground snow melting tank used to comb the snow road surface or the like and snow melting equipment having the same.

  Conventionally, as a means for melting snow, a concrete snow melting tank is used, or a heat radiating pipe is provided directly under the road surface to melt snow, and a stable temperature of the earth as a snow melting heat source is used as a heat source via a heat exchanger or a heat pump. The supplied hot heat is used (for example, refer patent documents 1-4).

  By the way, at the Kyoto Conference for the Prevention of Global Warming (COP3), Japan has set a goal of reducing greenhouse gas emissions such as CO2 by 6%. In the meantime, the problem is also directed to snow melting energy.

  Moreover, Japan's snow-covered area accounts for 60% of Japan, and in cities located there, snow is subject to processing with great expense and energy. Similarly, individual detached houses are subject to processing at high costs.

  For example, since snow transportation costs and snow storage costs account for a considerable portion of the snow processing costs, snow melting tanks are installed in urban buildings and parks in heavy snow cities such as Sapporo, There has been a case where a facility for melting snow by waste heat from waste disposal is created to reduce the cost of snow treatment.

In addition, facilities that save energy by considering snow as a resource and using snow stored underground for summer cooling are gradually being realized.
Japanese Patent Laid-Open No. 2002-173905 JP-A-2001-107307 Japanese Patent Laid-Open No. 2002-310524 Japanese Patent Laid-Open No. 2003-307354

  However, (A) conventional snow melting tanks and snow storage tanks require a large amount of space, and when installed in the basement, a large amount of construction costs are required. In addition, (B) it is difficult to provide a snow melting tank suitable for individual detached houses with a small site area.

  The present invention has been made to eliminate the above-mentioned problems of the prior art, and its purpose can advantageously solve the above-mentioned problems (A) and (B), and is very useful for embedding and installing an underground snow melting tank. An object of the present invention is to provide an underground snow melting tank that can be carried out with a small number of processes and does not require waste soil treatment, and a snow melting facility equipped with the snow melting tank.

Another object of the present invention is to provide an underground snow melting tank and a snow melting tank capable of ensuring excellent penetration and excavation efficiency when excavating a hole, and significantly reducing the construction cost for installing the underground snow melting tank. It is to provide a snow melting facility equipped.
Another object of the present invention aims at providing a high underground snow melting tank freedom of melting snow scale and snow melting equipment having the snow melting tank.

(1) In the first invention, the hollow tube body in which a rotating blade made of a spiral blade is attached to the lower end portion is applied with a rotational force to rotate and penetrate into the ground. The hollow tube constructed and buried using the internal space as a snow melting chamber is a steel pipe, and the buried hollow tube is provided with a snow inlet at the upper end or upper part thereof, and further buried. The hollow tube is installed in a stable underground temperature region throughout the season, and the snow in the snow melting chamber can be melted directly by underground heat obtained from the wall surface of the hollow tube. It is an underground snow melting tank.
(2) In the second aspect of the invention, the hollow tube having a rotary blade attached to the lower end thereof is rotationally press-fitted into the ground by applying a rotational force and a downward force, and the inside of the hollow tube embedded The hollow tube body that is constructed and embedded using the space as a snow melting chamber is a steel pipe, and the embedded hollow tube body is provided with a snow inlet at an upper end portion or an upper portion thereof, and further embedded in the hollow tube body. The hollow tube is installed in a stable underground temperature region throughout the season, and the snow in the snow melting chamber can be melted directly by underground heat obtained from the wall surface of the hollow tube. It is an underground snow melting tank.
(3) The third invention is the underground snow melting tank of the first invention or the second invention, wherein the hollow tube body is formed of a steel pipe, and the hollow tube body is a rotary press-fit as a foundation pile for supporting a building. It is also used as a steel pipe pile.
(4) The fourth invention is the underground snow melting tank of any one of the first to third inventions, wherein the rotating blade is a spiral blade, and the opening angle between the starting end surface and the terminating end surface of the rotating blade is It is characterized by being set to 10 degrees to 90 degrees.
(5) According to a fifth aspect of the present invention, in the underground snow melting tank according to any one of the first to fourth aspects, an open end hole set to a diameter equal to or smaller than the inner diameter of the hollow tubular body is provided at a central portion of the rotary blade. It is characterized by.
(6) The sixth invention is the underground snow melting tank according to any one of the first to fifth inventions, wherein a bottom cover is provided at the lower end or the middle of the hollow tube so that the inside of the hollow tube is It is hermetically sealed.
(7) A seventh invention is characterized in that the first invention Te either underground snow melting tank odor of the sixth aspect of the present invention, a hollow tube body bottom cover is secured to the interior are embedded in a rotary press fit And
(8) An eighth aspect of the underground snow melting tank of the seventh aspect of the present invention, that the pressure relief holes are opened in a hollow tube side wall portion of the lower side of the bottom cover or bottom cover that is attach to the inside It is characterized by.
(9) The ninth aspect of the present invention is the underground snow melting tank of the first to sixth aspects of the present invention, wherein the rotational force and the downward direction are eliminated while removing the earth and sand that enters the hollow tubular body having the rotating blades attached to the lower end portion. It is characterized in that it is constructed by applying force and rotating and pressing it into the ground, providing a bottom cover at the bottom and sealing it, and utilizing the embedded internal space of the hollow tube as a snow melting chamber.
(10) The tenth aspect of the invention is the underground snowmelt tank of the first to sixth aspects of the present invention, while removing the earth and sand that penetrates the hollow tube body with the excavating teeth attached to the lower end thereof, and the rotational force and the downward direction. It is characterized in that it is constructed by applying force and rotating and pressing it into the ground, providing a bottom cover at the bottom and sealing it, and utilizing the embedded internal space of the hollow tube as a snow melting chamber.
(11) An eleventh invention, in any one of the underground snow melting tank of the first to sixth aspects of the invention, hollow tube body collision caused was the bottom cover forming position of the inner circumference is attached is embedded in a rotary press fit the drop-lid inscribed in the hollow tube embedded and installation was dropped before Symbol hollow tube body portion, an inner periphery and the drop lid and is secured to and bottom lid of the hollow tube body is formed It is characterized by that.
(12) A twelfth invention, in any one of the underground snow melting tank of the first to sixth aspects of the invention, hollow tube body collision caused was the bottom cover forming position of the inner circumference is attached is embedded in a rotary press fit The bottom lid is formed by filling a time-hardening material into the bottom lid forming position in the hollow tube body that is embedded and installed .
(13) a thirteenth invention, in any one of the underground snow melting tank of the first to sixth aspects of the invention, hollow tube body collision caused was the bottom cover forming position of the inner circumference is attached is embedded in a rotary press fit , that the drop lid inscribed in the hollow tube embedded and installation was dropped before Symbol hollow tube body portion, comprising the bottom cover is filled with time curing material is formed on the upper side of the drop lid Features.
(14) The fourteenth invention is characterized in that, in the underground snow melting tank of any one of the first to thirteenth inventions, at least one of the inner surface and the outer surface of the hollow tubular body is coated with anticorrosion.
(15) The fifteenth invention is characterized in that in the underground snow melting tank of any one of the first invention to the fourteenth invention, a fin for promoting heat exchange is attached to the outer surface of the hollow tubular body.
( 16 ) The sixteenth invention is the underground snow melting tank of any of the first to fifteenth inventions, wherein either or both of a water supply pipe and a return water pipe are installed inside a steel pipe, etc. It is possible to melt the snow in the snow melting chamber by circulating the heat medium.
( 17 ) A seventeenth aspect of the present invention is to connect a heat exchanger such as an underground heat exchanger and a heat pump through a pipe line, and connect the heat pump and the underground snow melting tank of any of the first to fifteenth aspects of the present invention. It is a snow melting facility equipped with an underground snow melting tank, characterized in that it is possible to use the heat produced by a heat pump connected through a road as a heat source for snow melting.
( 18 ) In an eighteenth aspect of the present invention, the underground heat exchanger and the underground snow melting tank of any one of the first to sixteenth aspects of the present invention are connected via a pipe line, and the geothermal water in the underground heat exchanger is It is a snow melting facility equipped with an underground snow melting tank, characterized in that it can be directly used as a heat source for melting snow by supplying water to the underground snow melting tank with a circulation pump.
( 19 ) A nineteenth aspect of the invention is a snow melting facility comprising the underground snow melting tank of any one of the first to sixteenth inventions or the underground snow melting tank of the seventeenth or eighteenth invention, wherein ground water, river water, sea water, etc. This is a snow melting facility equipped with an underground snow melting tank characterized in that the heat produced by a heat pump using natural heat source energy can be used as a heat source for snow melting.
( 20 ) A twentieth aspect of the present invention is the snow melting facility comprising the underground snow melting tank of any of the first to sixteenth inventions or the underground snow melting tank of any of the seventeenth to nineteenth aspects of the invention. A snow melting facility equipped with an underground snow melting tank, characterized in that it can be used as a heat source.
( 21 ) A twenty-first aspect of the present invention is the snow melting facility comprising the underground snow melting tank of any one of the first to sixteenth inventions or the underground snow melting tank of any of the seventeenth to twentieth inventions, It is a snow melting facility equipped with an underground snow melting tank, characterized in that the heat produced by a heat source device using electric power can be used as a heat source for melting snow.
( 22 ) A twenty-second aspect of the present invention is the snow melting facility comprising the underground snow melting tank of any of the first to sixteenth inventions or the underground snow melting tank of any of the seventeenth to twenty-first aspects of the invention, solar heat, sewer water heat Waste heat, subway exhaust, high-pressure underground transmission line exhaust heat, substation exhaust heat, cogeneration exhaust heat or fuel cell exhaust heat can be used as a heat source for melting snow. This is a snow melting facility equipped with an underground snow melting tank.
(23) The twenty-third invention is a hollow buried in a snow-melting facility provided with the underground snow-melting tank of any one of the first to sixteenth inventions or the underground snow-melting tank of any of the seventeenth to twenty-second inventions. A snow melting facility provided with an underground snow melting tank is provided with a flowing water tank provided with a drainage pit around the upper end of the tube.
(24) A twenty-fourth aspect of the present invention is a hollow snow buried in a snow melting facility comprising the underground snow melting tank of any one of the first to sixteenth inventions or the underground snow melting tank of any of the seventeenth to twenty-second inventions. A snow melting facility provided with an underground snow melting tank, characterized in that an overflow horizontal pipe connected to a drain pit is provided at the upper part of the pipe body.

  The underground snow melting tank of the present invention can be installed at a low cost in a significantly shorter process than a concrete underground snow melting tank constructed on site. Also, no muddy water or waste soil treatment is required, and the unique rotary blade shape is excellent in the penetration of the hollow tube, so that the construction cost for installing the underground snow melting tank can be greatly suppressed. In particular, in the present invention, since it is a vertical underground snow melting tank using a hollow tube body, it can be easily installed deep in the ground, avoiding unstable underground areas with shallow temperatures, and stable underground throughout the season. Since it can be installed in the temperature range, it is effective in melting snow, and even when using a ground heat exchanger or other heat source, the thermal energy can be effectively used for melting snow.

  Moreover, in this invention, it became possible to utilize internal space with high water-tightness as a snow melting room by the formation method of a rotary blade or a bottom cover.

  In addition, a concrete underground snow melting tank or a snow melting facility equipped with this is an excellent facility as a centralized snow melting facility, but the current situation is that its widespread use is hindered by very high construction costs. Therefore, it can be expected that the spread of the present invention is promoted by the above effect.

<First Embodiment>
Hereinafter, the underground snow melting tank of 1st Embodiment of this invention is demonstrated, referring drawings. As shown in FIG. 1, the underground snow melting tank 26 according to the first embodiment embeds a hollow tube body 1 having a rotary blade 2 attached to the lower end portion thereof by rotary press-fitting, and a bottom cover 3 of the hollow tube body 1. It is constructed by installing the water supply pipe 4 and the return water pipe 5 in the internal space above.

  More specifically, in this embodiment, after the hollow tube body 1 is rotationally press-fitted, an on-site construction or precast concrete running water tank 23 is provided so as to surround the periphery of the hollow tube body 1. A drainage pit 24 is provided to stop the water in contact with the water tank 23 and to connect to the flowing water tank 23 that receives overflow from the upper end of the hollow tube 1. In the figure, reference numeral 51 denotes the ground surface.

  In the present invention, the inside of the hollow tube 1 is used as a snow melting chamber 25, and the water feeding pipe 4 and the return water pipe 5 are installed in the snow melting chamber 25 inside the hollow tube 1, and the underground snow melting tank 26 of the first embodiment. Is completed. Snowmelt water 27 guided to the drainage pit 24 is pumped by a pump 28 and discharged to a sewer or the like as indicated by an arrow A through a pipe 29. In the upper part of the flowing water tank 23 directly above the hollow tube body 1, a charging hole 30 and a lid 31 such as a closed lid or a porous lid are provided. If necessary, the lid 31 can be removed to drop snow into the snow melting chamber 25. To be. The outlet of the water pipe 4 is located slightly below the overflow level so that the dropped snow is effectively melted with a heat medium such as hot water having a high thermal energy.

  FIG. 2 shows a hollow tube 1 used in the first embodiment. When the hollow tube 1 is a single tube and does not reach the required snow melting chamber length, the necessary snow melting chamber length is secured by adding steel pipes by circumferential welding or the like at the site. The material of the hollow tube 1 is not limited to a steel pipe, and the hollow tube 1 may be formed of a resin-based material such as plastic. Further, the outer surface of the hollow tube 1 may be coated with polyethylene, urethane or the like, and the inner surface may be coated with hard vinyl chloride or epoxy, etc. Good.

  As shown in FIG. 2A, the lower end of the hollow tube 1 is notched in a spiral shape, and the start end and the end end of the spiral notch are connected via a stepped portion. A rotating blade 2 is concentrically fixed to the hollow tube 1 along the lower end surface of the hollow tube 1 cut out in a spiral shape.

  As shown in FIG. 3, the rotary blade 2 is formed by partially cutting a disk-shaped (ring-shaped) steel plate in the radial direction, and an excavation blade 7 is fixed to the starting end cutting surface 6 of the rotary blade 2 by welding. ing. The rotary blade 2 is formed so as to gradually spiral from the starting end cut surface 6 while being gradually separated from the lower end portion of the hollow tubular body 1 and to circulate about one turn to the terminal cut surface 8.

  The opening angle 9 between the starting end cutting surface 6 and the terminal cutting surface 8 of the rotary blade 2 is about 45 degrees in the example of FIG. 3, but can be set in the range of 10 degrees to 90 degrees. In addition, when the rotary blade 2 is extended and the opening angle 9 is set to a position of 0 degrees, the virtual end cut surface 8a and the start end cut surface 6 indicated by broken lines are parallel to each other.

  An open end hole 10 is opened at the center of the rotary blade 2. 2 and 3, the diameter D of the open end hole 10 is set to about 0.6 times the inner diameter of the hollow tube 1, but the diameter of the open end hole 10 of the present invention is that of the hollow tube 1. Any diameter may be used as long as it is equal to or smaller than the inner diameter, and the open end hole 10 may not be provided in the rotary blade 2.

  The rotary blade 2 having the opening angle 9 and the open end hole 10 as described above ensures excellent penetration of the hollow tube 1 and contributes to cost reduction by improving construction efficiency. Further, the rotary blade 2 having the above-described shape can adjust the invasion of soil into the tube between about 1.5 times the tube diameter and about half the tube length. Effective use of space becomes possible.

  Further, a bottom cover 3 is installed inside the hollow tube 1. The bottom cover 3 includes a lower portion of the hollow tube 1 into which soil 11 enters and an upper portion of the hollow tube 1 used for an underground snow melting tank. It is divided by. This bottom lid 3 may be formed in advance in the hollow tube body 1 before rotational press-fitting, or may be formed in the hollow tube body 1 after rotational press-fitting.

  FIG. 4 shows an example of how the bottom lid 3 is attached. In this example, a ring-shaped angle 12 is welded in advance as a projection at the bottom cover forming position on the inner periphery of the hollow tubular body 1, and the bottom cover 3 is formed by dropping and fixing the cover 21 from above the ring-shaped angle 12. . In addition, you may attach a reinforcement stiffener to the ring-shaped angle 12 as needed.

  In the example of FIG. 4, when the penetration resistance is not large due to soft ground or the like, the propulsion of the spiral rotating blade 2 is performed in a state where the bottom cover 3 is previously welded to the annular angle 12 and the attachment of the bottom cover 3 is completed. It is also possible to perform rotary penetration or rotary press-fitting of the hollow tube body 1 by force. In this case, as shown in FIG. 5, the soil 11 appropriately enters the lower part of the hollow tube 1 below the bottom cover 3, and the air spring effect is exerted by the compression of the air remaining in the lower part of the hollow tube 1. Thus, when the hard stratum is reached, the soil 11 further penetrates into the pipe and the penetration into the hard soil may be improved.

  On the other hand, when the penetration resistance of the ground is large and it is difficult to seal the lower part of the hollow tube body 1 by attaching the bottom lid 3 in advance, only the ring-shaped projections formed of the ring-shaped angle 12 are hollowed in the state where the ring-shaped projections are pre-attached The bottom lid 3 may be welded to the annular angle 12 after the tube body 1 is rotationally press-fitted.

  In the example of FIG. 6, the bottom cover 3 is attached to the inner periphery of the hollow tube 1 in advance, and a pressure relief hole 14 is provided in the lower portion of the hollow tube 1 so that the soil 11 can easily enter the lower portion of the hollow tube 1. In this mode, the penetration resistance is reduced and rotational press-fitting is performed. 6A and 6B, the pressure relief hole 14 is provided in the bottom lid 3, and the formation of the bottom lid 3 is completed by closing the pressure relief hole 14 with the plate 15 after the rotary press-fitting of the hollow tube 1. It is an example. FIG. 6C shows an example in which the pressure relief hole 14 is opened in the side wall of the hollow tubular body 1 immediately below the bottom cover 3. In this case, it is not necessary to close the pressure relief hole 14 after the rotational press-fitting. In this case, a rotary force and a downward force are added to the bottom of the hollow tube body 1 with excavating teeth attached to the lower end portion, and rotational force and downward force are applied to the bottom portion. A bottom lid 3 may be provided and sealed.

  Further, when it is desired to avoid the use of fire in the hollow tube 1 after the rotary press-fitting, the bottom cover 3 can be formed later by the following various methods.

  FIG. 7 is an example of a mode in which the bottom lid 3 is formed after the rotary press-fitting when the soil 11 enters the hollow tube 1 to some extent. In the example of FIG. 7, a ring-shaped reinforcing bar 16 for concrete fixing is previously welded to the upper part of the soil intrusion position (bottom cover forming position) on the inner periphery of the hollow tube 1. Next, concrete 17 is poured after the hollow tube body is rotationally pressed, and cinder concrete 18 having a waterproof joint at the joint with the hollow tube body is placed. Then, after sealing the joint 19, the waterproof coating 20 is applied to form the bottom cover 3. Even when the groundwater level is shallower than the bottom lid formation position, the bottom lid 3 can be formed by placing underwater concrete.

  Moreover, FIG. 8 is an example of an aspect in which the bottom cover 3 is formed after rotary press-fitting when the soil 11 does not penetrate so much into the hollow tube body. In the example of FIG. 8, a ring-shaped angle 12 (projection) is previously welded to the upper part of the soil intrusion position (bottom lid formation position) on the inner periphery of the hollow tube 1. Next, after the hollow tube 1 is rotationally press-fitted, the cinder concrete 18 is placed after dropping the drop lid 21 inscribed in the hollow tube 1. Thereafter, the bottom cover 3 is formed in the same process as the above example of FIG.

  Also in these examples, as shown in FIG. 1, after the hollow tube 1 is rotationally press-fitted, a flowing water tank 23 for receiving overflow and a drain pit 24 connected thereto are provided, and the inside of the hollow tube 1 The water supply pipe 4 and the return water pipe 5 are installed in the snow melting chamber 25 to complete the underground snow melting tank 26. Snowmelt water led to the drainage pit 24 is pumped up by a pump and discharged into a sewer. The basic structure of the underground snow melting tank 26 of the present invention is that the hollow tube body 1 having the rotating blade 2 attached to the lower end portion is buried in the ground, and the inside of the hollow tube body 1 is used as a snow melting chamber 25. is there.

  Further, in this embodiment, the water supply pipe 4 and the return water pipe 5 are connected to a ground heat exchanger (details will be described later) 32 as shown in FIG. The hot water (hot water) is supplied from the water supply pipe 4 by the water supply pump 4 through the ground heat exchanger 32 without passing through the water, and the cold water whose temperature has decreased due to snow melting is returned by the return water pipe 5 and the water absorption pump. It can be circulated back to the heat source. The snow melting chamber 25 is filled with water 33 for melting snow such as water.

  The underground snow-melting tank 26 of the first embodiment is configured to use the internal space of the hollow tube 1 as a snow-melting chamber 25 and to directly use it as a circulation passage for the heat medium. The ground heat can be collected from the surrounding soil or can be dissipated.

  FIG. 9 is an arrangement example of the water supply pipe 4 and the return water pipe 5 in the underground snow melting tank of the first embodiment. Since the diameter of the hollow tube body 1 is relatively large, a double tube system in which one of the water supply pipe 4 and the return water pipe 5 is inserted as shown in FIG. The water pipe 5 is inserted, and as shown in FIG. 9B, a steel pipe well system in which both the water supply pipe 4 and the return water pipe 5 are inserted may be adopted.

  In the underground snow melting tank 26 of the first embodiment, after the hollow tube body 1 is rotationally press-fitted, the water supply tank 23, the drain pit 24, and the water supply pipe 4 and the return water pipe 5 are simply installed inside the hollow tube body 1. Since the construction is completed in this way, the process can be shortened remarkably compared with the conventional underground construction snow melting tank of the on-site construction method, and drastic cost reduction becomes possible.

<Second Embodiment>
FIG. 10 is a view showing the underground snow melting tank 26 of the second embodiment. In the following embodiments, the same components as those in the first embodiment are denoted by the same reference numerals, and redundant description is omitted.

  In the second embodiment, a rotary press-fit steel pipe pile 22 as a foundation pile supporting a building is rotary-pressed and buried in the ground, and a bottom cover 3 is formed near or at the middle of the rotary press-fit steel pipe pile 22 and sealed. Then, a lid 31 is provided at the upper end of the steeply inclined snow throwing inclined pipe 34 connected to the vicinity of the upper part of the rotary press-fit steel pipe pile 22, and the underground constructed by using the internal space of the rotary press-fit steel pipe pile 22 as the snow melting chamber 25 This is a snow melting tank 26. Further, a drainage pit 24 is provided adjacent to the foundation, and an overflow horizontal pipe 35 connected to the drainage pit 24 is provided at the upper part of the hollow tube body 1. Since the underground snow melting tank 26 of the second embodiment also uses the foundation pile that is originally necessary for supporting the building as the snow melting tank, the cost of burying and installing the snow melting tank alone becomes unnecessary, and further cost reduction is possible. . In addition, as shown in FIG. 10, as a method of taking out the water supply pipe 4 and the return water pipe 5, as usual, it is assumed that the top part of the rotary press-fit steel pipe pile 22 is covered with the footing 22a, and the water supply pipe 4 and the return water pipe 5 are taken out horizontally. It is conceivable to transmit a supporting force from the pile to the footing by attaching a protrusion to the outer periphery of the footing coupling portion at the top of the rotary press-fit steel pipe pile 22. Although not shown, in the form in which a hole is provided in the upper support lid 36 of the hollow tube body 1 and a snow throwing vertical pipe is provided to the upper end of the hole and the footing 22a, and snow is thrown from the snow throwing vertical pipe, The steeply inclined snow throwing inclined pipe 34 can be omitted.

<Third Embodiment>
FIG. 11 is a view showing an underground snow melting tank of the third embodiment. In the third embodiment, heat exchange promoting fins 1 a are attached to the outer periphery of the hollow tube 1. The shape of the fin 1a may be any shape as long as it does not hinder the rotary press-fitting of the hollow tubular body 1, and for example, a small-diameter spiral fin formed by extending a rotary blade for excavation upward is conceivable. In FIG. 11, the fins 1a are provided over almost the entire length excluding the upper end of the hollow tube 1, but the fins 1a are effective in promoting heat exchange when groundwater is present. What is necessary is just to provide the fin 1a so that the formation part in which groundwater exists, such as an aquifer, may be covered.

Next, an example of an underground heat exchanger for effectively melting snow by connecting to the water supply pipe 4 and the circulating water pipe 5 connected to the underground snow melting tank of each of the above embodiments via a pipe line will be briefly described. explain.
As shown in FIG. 12, the hollow tube body 37 in the underground heat exchanger 32 is different in diameter from the hollow tube body 1 of the underground snow melting tank 26 in the embodiment, but may have a similar structure. Other structures can also be used.

  Referring to the figure, a hollow tube body 37 having a rotary blade 38 attached to the lower end is rotationally press-fitted and embedded, and a water pipe 40 is inserted into the upper internal space from the bottom lid 39 of the hollow tube body 37. And the return water pipe 41 is constructed, and the water supply pipe 40 and the circulating water pipe 41 are connected to the water supply pipe in the underground snow melting tank 26 via a heat pump 42 and a pipe line 43 as shown in the schematic explanatory view of FIG. 4 and the ring water pipe 5.

  FIG. 13 shows a hollow tube 37 used in the underground heat exchanger 32. When the hollow tube body 37 is a single tube and does not satisfy the required heat exchange length, the required heat exchange length is secured by adding by circumferential welding or the like at the site. As in the case of the underground snow melting tank 26, the material of the hollow tube 37 is not limited to a steel pipe, and the hollow tube 37 may be formed of a resin material such as plastic. Furthermore, when the outer surface of the hollow tube 37 needs to be protected, the outer surface may be coated with polyethylene, urethane, or the like. When the inner surface needs to be protected, the inner surface may be coated with hard vinyl chloride, epoxy, or the like. Good.

  As shown in FIG. 13A, the lower end of the hollow tube body 37 is notched in a spiral shape, and the start end and the end end of the spiral notch are connected via a stepped portion. A rotating blade 38 is concentrically fixed to the hollow tube 37 along the lower end surface of the hollow tube 37 cut out in a spiral shape.

  As shown in FIG. 14, the rotary blade 38 is formed by partially cutting a disk-shaped (ring-shaped) steel plate in the radial direction, and the excavating blade 7 is fixed to the starting end cutting surface 6 of the rotary blade 38 by welding. ing. The rotary blades 38 are formed so as to gradually spiral from the starting end cut surface 6 while being gradually separated from the lower end portion of the hollow tubular body 37 and to circulate about one turn to the end cut surface 8.

  The opening angle 9 between the starting end cutting surface 6 and the terminal cutting surface 8 of the rotary blade 38 is about 45 degrees in the example of FIG. 14, but can be set in the range of 10 degrees to 90 degrees. When the rotary blade 38 is extended and the opening angle 9 is set to a position of 0 degree, the virtual end cut surface 8a and the start end cut surface 6 indicated by broken lines are parallel to each other.

  An open end hole 10 is opened at the center of the rotary blade 38. 13 and 14, the diameter D of the open end hole 10 is set to about 0.6 times the inner diameter of the hollow tube 37, but the diameter of the open end hole 10 is less than or equal to the inner diameter of the hollow tube 37. Any diameter may be used, and the open end hole 10 may not be provided in the rotary blade 38.

  The rotary blade 38 having the opening angle 9 and the open end hole 10 as described above ensures excellent penetration of the hollow tube body 37 and contributes to cost reduction by improving construction efficiency. In addition, the rotary blade 38 having the above-described shape can adjust the invasion of soil into the tube between about 1.5 times the tube diameter and about half the tube length. Effective use of space becomes possible.

  When the underground heat exchanger 32 including the hollow tube body 37 having the rotating blades 38 is used, the underground heat exchanger can be installed at a very low cost, and the underground heat is used by using the underground heat exchanger 32. By collecting heat, it is possible to supply heat for snow-melting with low energy and low cost, which is economical.

  FIG. 15 is an explanatory view showing an embodiment of a snow melting facility provided with an underground snow melting tank and a heat source such as an underground heat exchanger, which is suitable for vacant or parked commercial facilities suitable for providing a large number of underground snow melting tanks. When the present invention is applied to a car park or a park, and will be further described with reference to the same figure, a large number of underground snow-melting tanks 26 are provided in the ground at intervals, and the water pipes 4 in the respective underground snow-melting tanks 26 are connected to pipes. Connected to a control valve (not shown), a pump (not shown) and a heat source, and each water pipe 5 is connected to the heat source via a conduit, a control valve (not shown) and a suction pump (not shown). Connected. The planar arrangement form of each underground snow melting tank 26 is set in a zigzag pattern or a straight line pattern depending on the installation location.

  A large number of underground heat exchangers 32 are provided in the ground at intervals, and each of the underground heat exchangers 32 is connected to a pipeline via a heat pump 42 and a control valve 44.

  As shown in FIG. 15, the lid 31 at the top of the flowing water tank 23 is appropriately removed in the underground snow melting tank 26 in which the internal space of the hollow tube 1 is the snow melting chamber 25, or the snow removed and drained from the porous lid is introduced. Then, the snow melt 27 melted by the snow melting liquid such as water in the hollow tube 1 and overflowed from the upper portion of the hollow tube 1 is pumped up from the drain pit 24 by the pump 28 or the like to the sewer. Release.

  The underground snow-melting tank 26 is not only used as a snow-melting tank but also stores snow stored in the last snow-melting room in winter without melting, and can also be used as a cooling heat source for a cooling load during the air-conditioning cooling period. It is also possible to use the water in the tank in the tubular body 1 and the surrounding ground 45 as an equal heat storage tank that uses the heat storage body for heat storage during the season.

  In addition, the ground heat exchanger 32 circulates the low-temperature hot water collected from the soil to the underground snow-melting tank 26 to forcibly dissolve the snow in the snow-melting chamber. The temperature is raised by using a soil heat source heat pump (GSHP) 42 according to the ratio of the heat collection amount of the underground heat exchanger 32 and the necessary amount of snow melting. As in the case of FIG. 1, the melted snow water 27 is overflowed, led to the drain pit 24 through the flowing water tank 23, and discharged into the sewer using the pump 28.

  As the heat source, in addition to the above-mentioned soil heat source (geothermal heat), as shown in a frame, the generated heat simultaneous use form that simultaneously uses artificial or natural generated heat and the generated heat are stored in the season. The heat storage during the season can be roughly classified into the heat storage use form during the generation heat season in which the heat stored during the season is used as a heat source.

In addition, as a form of simultaneous use of generated heat, fossil fuels such as boilers or district heat supply are used, or natural energy that uses heat such as groundwater heat, river water heat, hot spring water using geothermal heat, etc. is used. , Solar heat (solar heat or its radiant heat), sewer water heat, waste treatment exhaust heat, subway exhaust heat, high-pressure underground transmission line exhaust heat, substation exhaust heat, cogeneration exhaust heat, fuel cell exhaust heat or air conditioning exhaust heat Various forms such as forms using warm exhaust heat such as solar heat, hot spring water heat, waste heat treatment wastewater, subway exhaust heat, high-pressure underground transmission line exhaust heat, substation, etc. are possible. At least one or more of the heat exhausted from the plant, cogeneration exhaust, fuel cell exhaust or air conditioning exhaust is stored in the underground snow melting tank 26 or the ground heat exchanger 32 in the water or surrounding ground for the season. Seasonal heat storage Operation mode of using the snow melting heat source in winter also possible, in this case, more energy saving and low running cost can be reduced.
In such cases, solar heat, hot spring water heat, waste treatment exhaust heat, subway exhaust heat, high-pressure underground transmission line exhaust heat, substation exhaust heat, cogeneration exhaust heat, fuel cell exhaust heat or At least one or more of the air conditioning exhaust heat can be circulated to at least one of (A) and (B) of (A) a ground heat exchanger and (B) an underground snow melting tank or a snow melting facility, Operate the facility so that the stored heat in the underground heat exchanger or underground snow melting tank and the surrounding ground heat is stored in the season.
The cogeneration exhaust heat is exhaust gas heat of the generator engine or cooling water.
The air conditioning exhaust heat is exhaust heat exhausted from the air conditioner or exhaust heat generated due to air conditioning.

  In addition, as an application example of the present invention, for a detached house, a snow melting facility with only at least one underground snow melting tank 26, or a snow melting facility with an underground heat exchanger 32 added thereto, A snow melting facility equipped with a heat pump or the like may be used, or a snow melting facility that can be circulated and connected to various heat sources as necessary. In this case, the final snow is not melted in the underground snow melting tank 26. If this is done, it will be possible to use snow-cooled cooling that uses snow heat from the ground heat exchanger for cooling in the summer, and energy can be saved.

  In addition, when applied to a sidewalk or a roadside belt portion, the underground snow melting tank shown in FIGS. 1 to 15 is provided on the sidewalk or the roadside belt portion, and an upper cover (not shown) provided on the porous lid 31 of the flowing water tank on the upper side is provided. What is necessary is just to combine the underground heat exchanger and heat pump of the form which utilizes ground heat directly so that snow can be thrown from the removal porous lid | cover 31 and it connects to the said underground snow melting tank.

  As described above, in the present invention, various things such as natural energy and warm exhaust heat can be used, and not only the exhaust heat etc. are generated simultaneously with the generation of snow during the snow melting period, but also an underground snow melting tank and underground heat exchange. It is also possible to use the soil through the vessel as a heat storage body, and to store the exhaust heat generated out of season for the season and use it during the snow melting season, thus saving energy and reducing running costs.

  FIG. 16 shows an example of a heat pump 42 disposed between the heat source side pipe line 43 (43a, 43b) connected to the underground snow melting tank 26 side and the underground heat exchanger 32. In the figure, 45 is a compressor, 46 is a condenser, 47 is an expansion valve, 48 is an evaporator, 49 is a refrigerant pipe, 50 is a four-way valve, and the compressor is changed to a condenser by switching the four-way valve 50 or the like. The

In addition, at least one of the inner surface and the outer surface of the hollow tubes 1 and 37 may be coated with anticorrosion. Moreover, when implementing this invention, you may make it circulate heat media other than the water with warm heat. Moreover, you may use heat exchangers other than an underground heat exchanger.

  As described above, an underground snow melting tank constructed by burying a hollow tube with rotating blades in the ground can be constructed at a low cost even with a relatively small underground snow melting tank. Site snow treatment (snowfall snow treatment) facilities can be constructed, and medium- and small-scale waste heat can be used effectively as a heat source.

It is the figure which showed the underground snow melting tank of 1st Embodiment. It is a figure which shows the hollow tube used for 1st Embodiment. It is a figure which shows the rotary blade used for 1st Embodiment. It is the figure which showed an example of the attachment aspect of a bottom cover. It is a figure explaining the air spring effect at the time of forming a bottom cover beforehand in a hollow tube. It is the figure which showed the example of installation of the pressure relief hole of a hollow tube. It is the figure which showed an example of the aspect which forms a bottom cover after rotary pressing. It is the figure which showed an example of the aspect which forms a bottom cover after rotary pressing. It is the figure which showed the example of arrangement | positioning of the water pipe in the underground snowmelt tank of 1st Embodiment, and a return water pipe. It is the figure which showed the underground snow melting tank of 2nd Embodiment. It is the figure which showed the underground snow melting tank of 3rd Embodiment. It is the figure which showed the underground heat exchanger. It is a figure which shows the hollow tube used for an underground heat exchanger. It is a figure which shows the rotary blade used for an underground heat exchanger. It is explanatory drawing of the snow melting facility provided with the underground snow melting tank. It is a schematic explanatory drawing which shows an example of a heat pump.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Hollow tube 1a Fin 2 Rotary blade 3 Bottom cover 4 Water supply pipe 5 Return water pipe 6 Start end cut surface 7 Excavation blade 8 End cut surface 8a Virtual end cut surface 9 Opening angle 10 Open end hole 11 Soil 12 Ring-shaped angle 13 Welding part 14 Pressure relief hole 15 Plate 16 Ring-shaped rebar 17 Concrete 18 Cinder concrete 19 Seal 20 Coating waterproof 21 Drop lid 22 Rotary press-fit steel pipe pile 22a Footing 23 Flowing water tank 24 Drain pit 25 Snow melting chamber 26 Underground snow melting tank 27 Snow melting water 28 Pump 29 Pipe line 30 Filling hole 31 Lid 32 Ground heat exchanger 33 Water 34 Snow throwing inclined pipe 35 Overflow horizontal pipe 36 Lid 37 Hollow tube body 38 Rotary blade 39 Bottom plate 40 Water feed pipe 41 Circulating water pipe 42 Heat pump 43 Pipe 44 Control valve 45 Compression 46 Condenser 47 Expansion valve 48 Evaporator 49 Refrigerant piping 50 Four-way valve 51 Ground surface

Claims (24)

Applying rotational force to the hollow tube body attached with a rotating blade consisting of spiral blades at the lower end, rotating and penetrating into the ground, and utilizing the internal space of the buried hollow tube as a snow melting chamber The hollow tube constructed and buried is a steel pipe and has a snow inlet at the upper end or upper part of the buried hollow tube, and the buried hollow tube is stable throughout the season. An underground snow melting tank , which is installed in an underground temperature region and is capable of melting snow in the snow melting chamber directly by underground heat obtained from the wall surface of the hollow tube . Constructed by applying rotational force and downward force to a hollow tube with rotating blades attached to the lower end and rotating and pressing it into the ground, and using the internal space of the buried hollow tube as a snow melting chamber The embedded hollow tube is a steel pipe and has a snow inlet at the upper end or upper part of the embedded hollow tube, and the embedded hollow tube is stable throughout the season. An underground snow melting tank which is installed in an underground temperature region and is capable of melting snow in the snow melting chamber directly by underground heat obtained from the wall surface of the hollow tube . The underground snow melting tank according to claim 1 or 2, wherein the hollow tubular body is formed of a steel pipe, and the hollow tubular body also serves as a rotary press-fit steel pipe pile as a foundation pile for supporting a building.   The rotary blade is a spiral blade, and the opening angle between the starting end cutting surface and the terminal cutting surface of the rotating blade is set to 10 degrees to 90 degrees. The underground snow melting tank according to item 1.   The underground snow melting tank according to any one of claims 1 to 4, wherein an open end hole set to have a diameter equal to or less than a tube inner diameter of the hollow tube body is provided in a central portion of the rotary blade. .   The basement according to any one of claims 1 to 5, wherein a bottom cover is provided at a lower end portion or an intermediate portion of the hollow tube body to seal the inside of the hollow tube body. Snow melting tank. The underground snow melting tank according to any one of claims 1 to 6, wherein a hollow tube body having a bottom lid fixed therein is embedded by rotary press-fitting. Underground snow melting tank according to claim 7, characterized in that the pressure relief holes are opened in a hollow tube side wall portion of the lower side of the bottom cover or bottom cover that is attach to the inside.   Rotating and pressing into the ground by adding rotational force and downward force while excluding earth and sand entering the inside of the hollow tube with a rotating blade attached to the lower end, sealing with a bottom lid at the bottom, The underground snow melting tank according to any one of claims 1 to 6, wherein the underground snow melting tank is constructed by utilizing an internal space of the hollow tube body as a snow melting chamber.   Rotating and pressing into the ground by adding rotational force and downward force while excluding earth and sand entering the hollow tube body with drilling teeth attached to the lower end, sealing with a bottom lid at the bottom, The underground snow melting tank according to any one of claims 1 to 6, wherein the underground snow melting tank is constructed by utilizing an internal space of the hollow tube body as a snow melting chamber. Hollow tube body collision caused material to the inner periphery of the bottom cover forming position is attached is buried at a rotational press fitting, dropping a drop-lid inscribed in the hollow tube embedded and installation was before Symbol hollow tube body portion The underground snow melting tank according to any one of claims 1 to 6, wherein a bottom lid is formed by fixing an inner periphery of the hollow tube body and the dropping lid. Hollow tube body collision caused material to the inner periphery of the bottom cover forming position is attached is embedded in a rotary press fit, is filled with time curing material in the bottom cover forming position of the buried and installation was said hollow tube body The underground snow melting tank according to any one of claims 1 to 6, wherein a bottom cover is formed. Hollow tube body collision caused material to the inner periphery of the bottom cover forming position is attached is embedded in a rotary press fit, a drop lid inscribed in the hollow tube embedded and installation was before Symbol hollow tube body portion The underground snow melting tank according to any one of claims 1 to 6, wherein a bottom cover is formed by dropping and filling an aging hardening material on an upper side of the drop cover.   The underground snow melting tank according to any one of claims 1 to 13, wherein at least one of the inner surface and the outer surface of the hollow tube body is coated with anticorrosion.   The underground snow melting tank according to any one of claims 1 to 14, wherein fins for promoting heat exchange are attached to an outer surface of the hollow tube body. A water pipe and / or a return water pipe are installed inside a steel pipe, etc., and the snow in the snow melting chamber can be melted by circulating hot water or other heat medium. Item 16. An underground snow melting tank according to any one of items 1 to 15 . A heat exchanger such as a ground heat exchanger and a heat pump are connected via a pipe line, and the heat pump and the underground snow melting tank of any one of claims 1 to 15 are connected via a pipe line, A snow melting facility equipped with an underground snow melting tank, characterized in that the heat produced in this way can be used as a heat source for melting snow. A ground heat exchanger and the underground snow melting tank of any one of claims 1 to 16 are connected via a pipe line, and the ground heat water in the underground heat exchanger is connected to the underground snow melting tank by a circulation pump. A snow melting facility equipped with an underground snow melting tank, which can be directly used as a heat source for melting snow by supplying water to the ground. A snow melting facility comprising the underground snow melting tank according to any one of claims 1 to 16 or the underground snow melting tank according to claim 17 or claim 18 , wherein natural heat source energy such as ground water, river water, and sea water is used. A snow melting facility equipped with an underground snow melting tank, wherein the heat produced by a heat pump can be used as a heat source for melting snow. In the snow melting facility comprising the underground snow melting tank according to any one of claims 1 to 16 or the underground snow melting tank according to any one of claims 17 to 19 , A snow melting facility equipped with an underground snow melting tank characterized by being usable as a heat source. The fossil fuel or electric power such as boiler in the snow melting facility comprising the underground snow melting tank according to any one of claims 1 to 16 or the underground snow melting tank according to any one of claims 17 to 20. A snow melting facility equipped with an underground snow melting tank, characterized in that the heat produced by the heat source device using the heat can be used as a heat source for melting snow. A snow melting facility comprising the underground snow melting tank according to any one of claims 1 to 16 or the underground snow melting tank according to any one of claims 17 to 21 , wherein solar heat, sewer water heat, Waste heat, subway exhaust, high-pressure underground transmission line exhaust heat, substation exhaust heat, cogeneration exhaust heat, or fuel cell exhaust heat can be used as a heat source for melting snow. A snow melting facility equipped with an underground snow melting tank.   An embedded hollow tube in a snow melting facility comprising the underground snow melting tank according to any one of claims 1 to 16 or the underground snow melting tank according to any one of claims 17 to 22. A snow melting facility equipped with an underground snow melting tank, characterized in that a flowing water tank with a drainage pit is provided around the upper end of the body.   An embedded hollow tube in a snow melting facility comprising the underground snow melting tank according to any one of claims 1 to 16 or the underground snow melting tank according to any one of claims 17 to 22. A snow melting facility equipped with an underground snow melting tank, characterized in that an overflow horizontal pipe connected to the drain pit is provided at the top of the body.

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