KR20100123493A - A heating and cooling system using the tunnel constant temperature zone - Google Patents

Abstract

PURPOSE: A cooling and heating system using the tunnel the geothermal exchanger is established in formed in the tunnel construction. It smooths and the cool air for the warmth is supplied easily to the tunnel management office without the heat loss. CONSTITUTION: A cooling and heating system(100) using the tunnel comprise the geothermal exchanger(120), the circulating pump, the heater pump(130), interior heating and cooling instrument. The geothermal exchanger has the heat transfer fluid absorbing the warmth or the cool air of the geothermic.

Description

Heating and cooling system using the tunnel constant temperature zone

The present invention relates to a cooling and heating system, and in particular, by providing a geothermal heat exchanger in the constant temperature layer inside the tunnel so that the geothermal energy is continuously circulated, the excavation cost for the installation of the geothermal heat exchanger and the need for additional support and structure of the tunnel The present invention relates to a cooling and heating system using a tunnel constant temperature layer that does not lower the stability of the system.

In general, an air conditioning system for cooling and heating a building uses fossil fuels such as coal, oil, and natural gas as energy sources, or mainly uses power energy produced using fossil fuels or nuclear power as described above.

In addition, recently, many air-conditioning and heating systems using geothermal energy, which is an infinite energy source, have been developed in addition to the fossil fuel and power energy.

Looking at an example of a conventional air-conditioning system using geothermal energy of the air-conditioning system, a geothermal heat exchanger having a heat transfer fluid that absorbs the warmth or cold air of geothermal heat, and geothermal energy heat exchanged by the heat transfer fluid of the geothermal heat exchanger A circulating pump for conveying, an evaporator for absorbing a heat source to receive heat from the geothermal energy transferred by the circulating pump, performing heat exchange at an appropriate temperature for cooling and heating, and supplying the heat-exchanged geothermal energy to a place of use, and compressing heat converted into gas. A heater pump including a compressor for converting to a high temperature, a condenser for releasing the compressed high temperature and high pressure gas to transfer heat to water in a water line, and an expansion valve for reducing the refrigerant liquefied while passing through the condenser; Cooled or supplied with warm or cold air energy generated by the heater pump It consists of indoor air-conditioning equipment etc. which heats.

However, in the conventional heating and cooling system using the above-mentioned geothermal energy, in order to install the geothermal heat exchanger, in most cases, the ground must be secured and the perforation is performed in the ground in a substantially vertical direction. There is a problem that can not be applied where it takes a lot of room to secure a lot of land.

In addition, after the geothermal heat exchanger is inserted into the perforations, the construction is uncomfortable and structural instability and defects are caused by filling the perforations with soil from the ground surface to a predetermined depth and grouting the remaining ground surfaces. have.

In addition, the air-conditioning system of the tunnel management office located near the tunnel is scattered in a cold area such as a mountain, there is a problem that the auxiliary heater must be used when the heating efficiency is low.

Accordingly, the present invention has been made to solve the above problems, an object of the present invention by installing an underground heat exchanger with a rock bolt (Rock Bolt) in the constant temperature layer formed during tunnel construction, excavation work for installing a geothermal heat exchanger, etc. It is to provide a cooling and heating system using a tunnel constant temperature layer to achieve smooth and easy cooling and heating without heat loss to the tunnel management office mainly scattered in cold regions such as mountainous areas.

Another object of the present invention is to provide a cooling and heating system using a tunnel constant temperature layer that can support the excavation surface more firmly so that the heat exchange pipe of the geothermal heat exchanger supported by the rock bolt during the recovery of the constant temperature layer formed by the tunnel blasting serves as a reinforcing material To provide.

The present invention for achieving the above object is a geothermal heat exchanger having a heat transfer fluid absorbing the hot or cold air of the geothermal heat, a circulation pump for transferring geothermal energy heat exchanged by the heat transfer fluid of the geothermal heat exchanger, and the circulation pump A heat pump that receives the geothermal energy transferred by the heat exchanger and heats it to an appropriate temperature for cooling and heating, and supplies the heat exchanged geothermal energy to a place of use, and an indoor air conditioner that receives air or cold air generated by the heater pump and cools or heats the air. In the air-conditioning system using geothermal energy including a group, the geothermal heat exchanger is characterized in that it is installed in a constant temperature layer formed when the tunnel blasting.

The geothermal heat exchanger is characterized in that it is installed in the constant temperature layer except 50m before and after the tunnel which is affected by the outside air temperature.

The geothermal heat exchanger is supported by a lock bolt installed at the time of tunnel construction to prevent sag and at the same time to more firmly support the excavation surface during the reheating of the constant temperature layer.

The air conditioning system is characterized in that it is used for cooling and heating of the tunnel management offices scattered in the cold districts.

As described above, the present invention installs a geothermal heat exchanger at about the same time as the installation of the rock bolt in the constant temperature layer formed during the tunnel construction so that cold or warm air can be smoothly and easily supplied to the tunnel management office mainly located in a cold region. By doing so, there is no need to secure the earth and the excavation process for the installation of the geothermal heat exchanger, thereby reducing the cost.

In addition, the present invention has the effect that the excavation surface is more firmly supported by the geothermal heat exchanger is installed with the lock bolt during the constant temperature layer ventilating operation of the tunnel can solve the structural instability.

Hereinafter, a preferred embodiment of a cooling and heating system using a tunnel constant temperature layer according to the present invention will be described in more detail with reference to the accompanying drawings.

Here, in all the drawings below, the components having the same function are omitted by the same reference numerals, and the following terms are defined in consideration of functions in the present invention, which are inherently commonly used. It should be interpreted in a meaningful sense.

1 is a view schematically showing a cooling and heating system according to a preferred embodiment of the present invention, Figure 2 is a view showing a side state of Figure 1, Figure 3 is a geothermal heat exchanger according to a preferred embodiment of the present invention tunnel It is a figure which shows the state installed in the longitudinal direction of.

1 to 3, the air-conditioning system 100 of the present invention excavates the tunnel 110 using a conventional technique at a position to build a road.

At this time, the shotcrete layer 113 having a thickness is formed such that the inner wall flatness of the excavated tunnel 110 becomes constant to some extent.

Subsequently, after the non-woven fabric and the waterproof sheet (not shown) are installed in the shotcrete layer 113, holes (not shown) having a predetermined distance and depth in the longitudinal direction of the tunnel 110 are radially drilled. Inject the adhesive into the hole and firmly install the anchor bolt (anchor bolt) or rock bolt 114 to prevent the falling of the rock.

Subsequently, a geothermal heat exchanger 120 including a pipe filled with a heat transfer fluid for heat exchange therein is installed along the lock bolt 114. Here, the space in which the geothermal heat exchanger 120 is formed is formed of a constant temperature layer 112 that is disconnected from the outside during the construction of the concrete lining layer 111 later. Accordingly, the geothermal heat exchanger 120 made of a heat exchange pipe may be easily and easily installed in the constant temperature layer 112 during the construction of the tunnel 110.

In addition, since the geothermal energy present in the constant temperature layer 112 is lower than the atmospheric temperature in summer and higher than the atmospheric temperature in winter, the geothermal energy is not only suitable as a heat source of a heat pump type air-conditioning system using geothermal heat, but also maintains a tunnel. It can be used very effectively for the heating and cooling of all tunnel management offices installed for management.

The geothermal heat exchanger 120 is formed of a semi-permanent material having high thermal conductivity such as high-density polyethylene (HDPE) and no corrosion, and a heat transfer fluid therein for geothermal energy and heat exchange. It is filled.

Here, the heat transfer fluid is preferably used to prevent freezing by using a mixture of antifreeze and water.

In addition, the geothermal heat exchanger 120 may be formed in the longitudinal direction or the width direction of the tunnel 110, and may be formed in various forms that do not have a problem to effectively heat exchange the heat energy.

At this time, the geothermal heat exchanger 120 is preferably installed in the constant temperature layer 112 of the portion except 50m before and after the tunnel which is affected by the outside air temperature. That is, in order to use the thermal energy existing in the constant temperature layer 112 formed in the tunnel 110 as a heat source, the inlet and outlet sides of the tunnel 110 are approximately 40 m from the outside to be affected by the outside temperature so that the efficiency of the heat source In order to maximize the temperature, it should be formed into a part which is not affected by the ambient temperature.

As described above, after the geothermal heat exchanger 120 is installed in the constant temperature layer 112 of the tunnel 110, the concrete is poured to form a concrete lining layer 111 having a predetermined thickness.

At this time, the geothermal heat exchanger 120 is supported by the lock bolt 114 is installed during the construction of the tunnel 110 to prevent sag and at the same time both ends are connected to the other member outside the constant temperature layer 112 of the tunnel 110. It is formed to protrude. Therefore, there is no need to secure the earth and the excavation process for the installation of the geothermal heat exchanger 120 installed in the ground, thereby reducing the cost.

In addition, according to the present invention, the excavation surface is more firmly supported by the geothermal heat exchanger 120 installed together with the lock bolt 114 at the time of ventilating the constant temperature layer 112 of the tunnel 110 to solve structural instability. .

Subsequently, one end of the geothermal heat exchanger 120 is an inlet pipe (not shown) of the heat pump 130 that heat-exchanges geothermal energy heat-exchanged by heat transfer fluid through a head pipe (not shown) to an appropriate place for cooling and heating. The other end is connected to the outlet pipe (not shown) of the heater pump 130 through the head pipe.

Here, one side of the geothermal heat exchanger 120 is formed with a circulation pump 121a for transferring geothermal energy heat exchanged by the heat exchange fluid.

Subsequently, the other side of the heater pump 130 is connected to a connection pipe of an indoor air conditioner (not shown) that receives the warm or cold air generated by the heater pump 130 and cools or heats it. Heating is performed.

Therefore, by continuously repeating the above-described operation, the tunnel management in which the geothermal heat of the tunnel constant temperature layer 112 lower than the atmospheric temperature is supplied in summer, and the geothermal heat of the tunnel constant temperature layer 112 higher than the atmospheric temperature in winter, is scattered in the cold region and the like. It can be provided to the office smoothly and easily.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. And will be apparent to those skilled in the art to which the invention pertains.

1 is a view schematically showing a cooling and heating system according to a preferred embodiment of the present invention from the front.

2 is a view showing a side state of FIG.

3 is a view showing a state in which the geothermal heat exchanger is installed in the longitudinal direction of the tunnel according to an embodiment of the present invention.

[Description of Reference Numerals]

110 tunnel 111 concrete lining layer

112: constant temperature layer 113: shotcrete layer

114: Rock Bolt 120: Geothermal Heat Exchanger

121a: circulation pump 130: heater pump

100: air conditioning system

Claims (4)

Geothermal heat exchanger having a heat transfer fluid that absorbs the hot or cold air of the geothermal heat, a circulation pump for transferring the geothermal energy heat exchanged by the heat transfer fluid of the geothermal heat exchanger, and the geothermal energy transferred by the circulation pump is supplied to the cooling and heating In a cooling and heating system using geothermal energy, including a heater pump that performs heat exchange at an appropriate temperature and supplies heat-exchanged geothermal energy to a place of use, and an indoor air-conditioning device that receives and cools or heats hot or cold air generated by the heater pump. , The geothermal heat exchanger is a heating and cooling system using a tunnel constant temperature layer, characterized in that installed in the constant temperature layer formed when the tunnel blasting. The air conditioning system according to claim 1, wherein the geothermal heat exchanger is installed in a constant temperature layer except for 50m before and after the tunnel which is affected by outside temperature. The geothermal heat exchanger of claim 1 or 2, wherein the geothermal heat exchanger is supported by a lock bolt installed at the time of tunnel construction to prevent sag and to support the excavation surface of the constant temperature layer more firmly. Heating and cooling system. The air conditioning system according to claim 1, 2 or 3, wherein the air conditioning system is used for cooling and heating a tunnel management office scattered in a cold region.

Images