KR200413487Y1 - A water leakage measurement device for a heat exchanging system of underground energy - Google Patents

Abstract

The present invention relates to a leak measuring device of a groundwater heat exchange system, comprising: a water storage tank that maintains a constant water level in a heat exchange system that obtains geothermal energy from groundwater through a bore hole; A water supply pipe connected to an upper portion of the water storage tank to supply external water; Water supply adjusting means for adjusting the water supplied from the water supply pipe; A supplementary pipe connected to a lower end of the water storage tank to replenish the amount of groundwater leaked into the bore hole; It is composed of measuring means connected to the supplementary pipe or the water supply pipe to measure the amount of water supplied into the borehole, and easily measures the amount of groundwater leaked into the specific borehole into the ground to exchange heat using the borehole. It can help you determine if you can install the system.

Groundwater, heat exchange system, leak, measuring device

Description

A water leakage measurement device for a heat exchanging system of underground energy}

1 is a perspective view showing a leak measuring device of the groundwater heat exchange system according to the present invention.

2 and 3 is a cross-sectional view showing the operating state of the leak measuring device of the present invention.

Figure 4 is an enlarged view showing the structure of the water supply control valve of the present invention.

Figure 5 is a sectional view showing another position where the leak measuring device of the present invention is installed.

<Explanation of protection for main parts of drawing>

 1: borehole 10: water reservoir tank

20: water supply pipe 24: water supply control valve

30: supplemental pipe 40: water meter

The present invention relates to a leak measuring device of a groundwater heat exchange system, and more particularly, to a leak measuring apparatus of a groundwater heat exchange system capable of measuring the amount of groundwater leaking into a borehole bored to obtain geothermal energy. It is about.

Generally, fossil fuels such as coal, petroleum, natural gas, or nuclear fuel are used as energy sources used to obtain heating and cooling hot water.

However, fossil fuels pollute the environment due to various pollutants generated during the combustion process, and nuclear fuel generates harmful substances such as water pollution and radioactivity, and these energy sources have a limited amount of reserves. Therefore, in recent years, the development of alternative energy to replace this has been actively progressed.

Among these alternative energy, natural energy such as wind, solar, geothermal, etc. has been studied for a long time, and air-conditioning and heating system using it have been installed and used. These natural energy are infinite energy with little influence on environmental pollution and climate change. On the other hand, due to the drawback of very low energy density, increasing the density and converting it into a usable form has become a core task of natural energy technology development.

Among these natural energy technologies, a heat exchange system is known, which uses geothermal heat as a heat source for cooling and heating. This is a heat pump installed with a heat exchanger to recover heat from the ground at a temperature of 10 to 20 ° C or to discharge heat into the ground. It is a technology used as a heat source.

As such, heat exchange systems using underground heat sources are known to have the highest energy efficiency among all cooling and heating technologies.

In order to install a heat exchange system using ground water among these heat exchange systems, it is necessary to first drill a bore hole using an excavator, and then check whether the water can be used as a heat exchange system by investigating the quantity and leakage rate of the ground water remaining in the bore hole.

However, in the prior art, since there was no separate measuring device for checking the groundwater leakage level in the borehole, it was inevitable to rely only on the experience, and most of them were designed and constructed only by the pumping quantity checking procedure after sufficient groundwater was secured.

Therefore, since the heat exchange system is installed and used without sufficiently grasping the leak rate of groundwater leak in the borehole, there is no provision for the change in the quantity of groundwater. As a result of moving and using a new borehole, there was a problem that the development against the environmental preservation was not only made, but also the economic time loss caused by the reconstruction.

The present invention was devised to solve this problem, and a water storage tank for supplying water as much as the amount of groundwater in the borehole drilled using an excavator leaks to the ground and a measuring means for measuring the amount of water supplied into the borehole. The purpose of the present invention is to provide a leak measurement window that can calculate the amount of groundwater leaks and the leak rate by checking the amount of water supplied from the water storage tank into the borehole.

In order to achieve the above object, the present invention provides a heat exchange system that obtains geothermal energy from groundwater by drilling a borehole, the water storage tank maintaining a constant water level therein; A water supply pipe connected to an upper portion of the water storage tank to supply external water; Water supply adjusting means for adjusting the water supplied from the water supply pipe; A supplementary pipe connected to a lower end of the water storage tank to replenish the amount of groundwater leaked into the bore hole; It is connected to the supplemental pipe or the water supply pipe is characterized in that the measuring means for measuring the amount of water supplied into the bore hole.

In particular, the supplementary pipe has a predetermined length from the upper portion of the bore hole, and usually one end is immersed in the surface of the bore hole, and water leaks in the bore hole, causing the surface of the bore hole to be lowered. When the addition is dropped from the water surface inside the borehole is characterized in that the water is replenished from the water storage tank.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail.

First, the present invention is basically, as shown in Figure 1, the water storage tank 10 to maintain a constant water level therein, the water supply pipe 20 is connected to the upper portion of the water storage tank and supplies water to the outside, A water supply control means 24 for controlling water supplied from the water supply pipe, a supplemental pipe 30 connected to the lower end of the water storage tank to replenish the amount of groundwater leaked into the bore hole 1, and It can be carried out by configuring the measuring means 40 is connected to the supplementary pipe to measure the amount of water supplied into the borehole (1).

Here, the supplementary pipe 30 has a predetermined length from the upper portion of the bore hole 1 as shown in FIG. 2, and the one end 30 is submerged in the surface of the bore hole 1. As the water leaks in the bore hole 1, the water surface inside the bore hole is lowered, and when one end portion 30 falls from the water surface inside the bore hole 1, water is discharged from the water storage tank 10. It is the core technical idea of the present invention to use the supplementary principle.

The water supply control means 24 may be a water supply control valve connected to an end of the water supply pipe 20 in the water storage tank 10 and opened and closed according to the water level inside the water storage tank. .

At this time, the water supply control valve is provided with a ball tab 25 so as to be opened and closed by the end hinge 28 of the water supply pipe 20, as shown in FIG. It is preferable to make a knitting valve fastened and fixed by the supporting rod 27 by a simple structure.

In addition, the measuring means 40 for measuring the quantity of water supplied into the borehole 1 may be attached to the water supply pipe 20 as shown in FIG. 5. This is because the water is supplied from the water supply pipe 20 by the water supply control valve 24 of the water storage tank 10 by the amount of water replenished with the replenishment pipe 30.

In addition, the quantity measuring means is a known water meter, it is particularly preferable to display the quantity supplied per hour.

Since the technology related to the water meter is well known to those skilled in the art, a detailed description thereof will be omitted.

Next, with reference to the accompanying drawings will be briefly described the use and operation of the leakage measuring device of the groundwater heat exchange system according to the present invention.

When the borehole 1 is drilled using an excavator, groundwater is accumulated inside the borehole 1. When the groundwater accumulated in the borehole 1 is passed for a certain time, the groundwater penetrates into the underground according to the underground environment such as the lack of groundwater in the underground, and the quantity of groundwater is lowered. Thus, the present invention is used to measure the leakage of groundwater accumulated in the borehole.

Furthermore, the borehole 1 is drilled in a hard rock layer with no underground water vein layer, and water is supplied from the outside to the heat exchange system to obtain geothermal heat. In particular, the borehole formed in the hard rock layer as described above may also be used to check whether there is economical use in the heat exchange system because the leak occurs due to cracks and the like.

In the operation of the water leakage measuring device of the groundwater heat exchange system according to the present invention, as shown in FIG. 2, one end of the supplemental pipe 30 is immersed in the surface of the borehole 1, and as shown in FIG. 3. If water leaks in the bore hole 1 and the water level inside the bore hole is lowered, and one end of the supplementary pipe 30 falls from the water surface in the bore hole 1, the water leakage amount is increased from the water storage tank 10. When the water is replenished and the water level of the water storage tank 10 is lowered by replenishing the leakage amount, the water supply control valve 24 is opened to receive external water from the water supply pipe 20.

Meanwhile, replenishment of the leakage amount by the replenishment pipe 30 is stopped when one end of the replenishment pipe 30 is submerged in the surface of the bore hole 1 again, as shown in FIG. 2, and then the water supply pipe External water supply by (20) is also stopped by closing the water supply control valve 24 by the mouth 26 or the like.

At this time, the amount of water supplied by the water supply pipe 40 installed in the replenishment pipe 30 or the water supply pipe 20 is measured, and the leakage rate is automatically calculated and displayed.

As a result, according to the present invention, the water level of the bore hole 1 and the water storage tank 10 can be kept constant, and the leakage amount and leakage rate of the bore hole 1 can be easily calculated.

Although a preferred embodiment of the present invention has been described in detail above, those of ordinary skill in the art to which the present invention belongs, in various forms within the technical spirit of the present invention described in the appended claims Modifications or changes can be made and the description thereof is omitted.

The present invention can easily measure the amount of groundwater leaking underground in the borehole drilled using an excavator for the purpose of obtaining geothermal heat, thereby means to determine whether the borehole can be used as a heat exchange system Becomes

Furthermore, when the degree of leakage of the borehole is small, the present invention can supply the external water as much as the amount of leakage to maintain the groundwater at a certain level at all times, so that the heat exchange system can be installed even in a terrain having a slight leakage.

Claims (6)

In the heat exchange system that obtains geothermal energy from groundwater through a borehole, A water storage tank for maintaining a constant water level therein; A water supply pipe connected to an upper portion of the water storage tank to supply external water; Water supply adjusting means for adjusting the water supplied from the water supply pipe; A supplementary pipe connected to a lower end of the water storage tank to replenish the amount of groundwater leaked into the bore hole; Leakage measuring device of the groundwater heat exchange system, characterized in that the measuring means for measuring the amount of water supplied into the bore hole connected to the supplemental pipe or the water supply pipe. The method of claim 1, The replenishment pipe has a predetermined length from the top of the bore hole, and usually one end is immersed in the water surface inside the bore hole, and water leaks in the bore hole, and the water surface in the bore hole is lowered, so that the one end is the The water leakage measuring device of the groundwater heat exchange system, characterized in that the water is replenished from the water storage tank when dropped from the water surface inside the borehole. The method of claim 2, The water supply control means is a water leakage measuring device of the groundwater heat exchange system, characterized in that the water supply valve is connected to the end of the water supply pipe in the water storage tank is opened and closed in accordance with the water level in the water storage tank. The method of claim 3, wherein The water supply control valve is a water leakage measuring device of the groundwater heat exchange system, characterized in that the ball tab is provided to be opened and closed by the hinge of the end of the water supply pipe, the buoyancy buoyancy to the ball tab is fastened by a support rod. The method of claim 4, wherein Measuring means for measuring the amount of water supplied to the borehole is water leakage measuring device of the groundwater heat exchange system, characterized in that the water meter. The method of claim 5, wherein The water meter is a water leakage measuring device of the groundwater heat exchange system, characterized in that to display the hourly water supply to the borehole.

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