KR20170003811A - Binary rankine cycle system - Google Patents

Abstract

The present invention relates to a binary Rankine cycle system, which comprises: a geothermal borehole formed by excavating the ground; a pipe module arranged by being spaced from an inner surface of the geothermal borehole in the geothermal borehole; a pump module injecting a heat transmission medium to the inside of the geothermal borehole through a space between the geothermal borehole and the pipe module, and collecting the heat transmission medium to the ground through the inside of the pipe module; and a heat exchange module provided in a rear end of a binary Rankine cycle turbine to condense a working fluid by heat exchanging the heat transmission medium collected in the pump module and the working fluid of the binary Rankine cycle.

Description

[0002] BINARY RANKINE CYCLE SYSTEM [0003]

The present invention relates to a binary Rankine cycle system, and more particularly, to a binary Rankine cycle system that can cool and condense the working fluid of a Rankine cycle using deep geothermal heat.

The binary Rankine cycle is a heat engine cycle using a low boiling point material, typically an organic Rankine cycle (ORC) and a Rankine cycle using geothermal and solar heat.

These binary Rankine cycles are mainly used for power generation systems that utilize alternative energy as environmental pollution problems arise.

Geothermal heat, which is one of these alternative energies, is the heat retained in the ground, which is caused by the convection of the mantle inside the earth or the collapse of radioactive materials in the crust, or the heat by the magma in the volcanic area.

In order to utilize such geothermal energy as an energy source, various methods such as development of a hot spring have been applied. Among them, a geothermal passageway is drilled in the ground, and a pipe is inserted into the geothermal field so that a heat transfer medium flows Is widely used.

That is, by inserting one or more pipes into the passageway, the space inside the passageway is partitioned, and the heat transfer medium is injected into the passageway through a part of the partitioned space to receive the geothermal heat and recovered to the ground through another partitioned space And the heat energy is utilized.

Geothermal heat is divided into deep-seated and deep-seated geothermal heat, depending on the depth of reclamation, among which the heat from the surface to the relatively low depth is maintained at a relatively low temperature of about 12 to 25 degrees, regardless of the season, Deep geothermal can recover relatively high temperatures of about 40 to 150 degrees at relatively deep depths.

Generally, in the case of a binary Rankine cycle using geothermal heat, it is mainly applied to a method of heating a working fluid of a Rankine cycle by using deep geothermal heat and cooling a working fluid by installing a separate cooling tower or the like.

However, it is difficult to expect a stable performance of the cooling tower depending on the region and the weather depending on the region and the weather. In such a case, it is necessary to use a separate cooling device, which lowers the efficiency and productivity of the overall Rankine cycle system.

The technical problem of the present invention is to solve the problem mentioned in the background, and to provide a binary Rankine cycle system which can cool and condense a working fluid of a Rankine cycle by using geothermal geothermal heat.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not intended to limit the invention to the precise form disclosed. There will be.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects, features and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings in which: FIG. A pump module for injecting a heat transfer medium into the geothermal column via a space between the pipe modules and a pump module for collecting the heat transfer medium through the interior of the pipe module and a binary Rankine cycle turbine, And a heat exchange module for heat-exchanging the recovered heat transfer medium and the working fluid of the binary Rankine cycle to condense the working fluid.

Here, the tilt angle can be formed to a depth less than 300 meters.

Further, the pipe module may include a heat insulating portion for lowering heat exchange efficiency between the outside and the inside of the pipe module.

The binary Rankine cycle can utilize geothermal heat recovered through the geothermal heat generated by the depth for the deep geothermal heat recovery as a heat source.

Meanwhile, the binary Rankine cycle system according to the present invention includes a geothermal heat pipe formed by excavating a ground and a pipe module disposed inside the geothermal heat pipe at a distance from the inner surface of the geothermal heat pipe, The working fluid can be recovered to the ground through the inside of the pipe module through the lower portion of the geotechnical passage through the gap between the geotechnical tunnel and the pipe module.

Here, the tilt angle can be formed to a depth less than 300 meters.

Further, the pipe module may include a heat insulating portion for lowering heat exchange efficiency between the outside and the inside of the pipe module.

The working fluid is extended to the lower portion of the geotechnical column along the space between the geotechnical column and the pipe modules and is bent into the inside of the pipe module at a lower portion of the geotechnical column, As shown in Fig.

At this time, the flow path may be divided into a plurality of flow paths inserted into the space between the tipping pass and the pipe modules.

In addition, the flow path may have a relatively high thermal conductivity as compared to other portions of the portion provided at the lower portion of the retainer.

In addition, the heat transfer medium may be filled in the space between the tile pass and the pipe modules.

On the other hand, the binary Rankine cycle can utilize the geothermal heat recovered through the geothermal heat formed as the depth for the deep geothermal heat recovery as a heat source.

According to the binary Rankine cycle system of the present invention, the following effects can be obtained.

First, the Rankine cycle working fluid can be reliably condensed regardless of local and weather effects.

Secondly, it is possible to reduce the cost of manufacturing and operating the binary Rankine cycle system.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description of the claims.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a diagram showing the configuration of a first embodiment of a binary Rankine cycle system according to the present invention. Fig.
FIG. 2 is a view showing a configuration of a first embodiment of a binary Rankine cycle system according to the present invention using a deep geothermal heat as a heat source using a geothermal heat.
3 is a diagram showing a configuration of a second embodiment of the binary Rankine cycle system according to the present invention.
4 is a view showing a configuration of a flow path in which the working fluid of the second embodiment of the present invention is connected to the exhaust port.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, the well-known functions or constructions are not described in order to simplify the gist of the present invention.

Moreover, in describing the present invention, terms indicating a direction such as forward / rearward or upward / downward are described in order that a person skilled in the art can clearly understand the present invention, and the directions indicate relative directions, It is not limited.

<First Example >

First, the configuration and effects of the first embodiment of the binary Rankine cycle system according to the present invention will be described in detail with reference to FIGS. 1 and 2. FIG.

FIG. 1 is a view showing the construction of a first embodiment of a binary Rankine cycle system according to the present invention. FIG. 2 is a diagram showing a binary Rankine cycle system according to a first embodiment of the present invention, which uses a deep geothermal heat as a heat source, Fig.

1, the binary Rankine cycle system according to the present invention may include a geothermal column 100, a pipe module 200, a pump module 300, and a heat exchange module 400.

The binary Rankine cycle system according to the present invention is operated in the same manner as the ordinary Rankine cycle by the operation of the pump P to cause the working fluid to flow along the system and heat the heat of the heat source H through the evaporator E The fluid can be heated.

The heated working fluid is vaporized and supplied to the turbine T at the rear end to rotate the turbine T and the rotational force of the turbine T can be used for power generation using the generator.

The working fluid discharged from the turbine T is condensed again. The binary Rankine cycle system according to the present invention can condense the working fluid by using the geothermal heat pump 100.

First, a geothermal column 100 is formed by excavating a ground to a depth at which a geothermal heat of a desired temperature is generated.

In this embodiment, since the geothermal column 100 is intended to condense the working fluid of the binary Rankine cycle system according to the present invention by using the geothermal heat of relatively low temperature, the geothermal heat of about 12 to 30 degrees is recovered It may be advantageous to be formed at a depth D1 that can be formed.

In addition, it is advantageous that the geothermal column 100 is formed to have a width capable of flowing a sufficient amount of heat transfer medium to recover geothermal heat.

The pipe module 200 is configured to divide the inner space of the geotechnical device 100 and extends from the ground to a lower portion of the geotechnical device 100 and has a passageway 100 The inner circumferential surface and the inner circumferential surface.

In addition, it may be advantageous that the pipe modules 200 are disposed apart from each other at a predetermined interval without contacting the inner bottom surface of the geotechnical column 100.

That is, the structure of the pipe module 200 divides a space inside the geothermal tube 100 into an outer space and an inner space of the pipe module 200, and a heat transfer medium for recovering the geothermal heat includes a geothermal column 100 and a pipe module 200, and is heated by the geothermal heat, flows into the interior of the pipe module 200 from the lower part of the geothermal column 100, and is recovered to the ground through the pipe module 200.

The construction of such a pipe module 200 may advantageously be formed with sufficient strength to withstand the pressure in the ground and the pressure of the flowing heat transfer medium.

The pipe module 200 may include a heat insulating portion 210 for lowering heat exchange efficiency between the inside and the outside of the pipe module 200.

Since the temperature of the heat transfer medium injected into the geothermal column 100 and the temperature of the heat transfer medium collected by receiving the geothermal heat from the bottom of the geothermal column 100 differ greatly from the upper part of the geothermal column 100, 200 can not recover the geothermal heat completely, so that the efficiency of geothermal utilization can be lowered.

Accordingly, the heat insulating portion 210 can be formed by providing at least one heat insulating material along the surface of the pipe module 200, and the outer and inner pipes of the pipe module 200, It may be advantageous to be provided in the space.

The heat insulating portion 210 is formed of a foamed insulating material such as foamed urethane or foamed rubber filled with various heat insulating materials such as air, styrofoam, and glass fiber. can do.

The pump module 300 injects the heat transfer medium into the interior of the geotechnical station 100 through the space between the geotechnical station 100 and the pipe module 200, In a configuration in which the medium is recovered to the ground, a generally used pump configuration can be applied.

Here, the heat transfer medium may be various without limitation as long as it is a fluid having a high thermal conductivity, such as the same fluid or a different fluid, irrespective of the working fluid of the binary Rankine cycle system according to the present invention.

It may also be advantageous that the heat transfer medium is applied as a fluid that is not vaporized while heat exchanging with the working fluid of the binary Rankine cycle system.

In the process of the heat transfer medium flowing through the inside of the geotechnical column 100 by the pump module 300, a separate channel is not formed and the heat transfer medium is inserted into the space between the geotechnical column 100 and the pipe module 200 The pump module 300 sucks the inside of the pipe module 200 from the upper part of the pipe module 200 and discharges the heat transfer medium under the geo heat pump 100 And the like.

In this case, a separate flow path is not provided in the inside of the support tube 100, and a flow path for circulation of the heat transfer medium can be provided only on the ground.

Through the above-described configuration, the heat transfer medium can be cooled down to the ground by receiving geothermal heat at a relatively low temperature from the ground inside the geothermal heat pipe 100.

In addition, a heat storage unit may be further provided in the space between the inner surface of the geothermal tube 100 and the outer surface of the pipe module 200.

The heat storage unit may include a heat storage material, and may be formed to allow the heat transfer medium injected into the heat storage unit 100 to pass therethrough.

The heat storage material composed of the heat storage portion may be a material having a large heat capacity such as gravel, sand or concrete. In addition, if the heat storage medium is provided to transmit heat to the heat transfer medium surrounding the geothermal heat, have.

In this configuration, as the heat transfer medium flows to the lower portion of the geothermal column 100, the flow rate of the heat transfer medium is increased to form a turbulent flow, and such turbulence can promote heat transfer from the geothermal column 100 to the production column .

Also, since the heat transfer medium receives the geothermal heat through the inner circumferential surface of the geothermal heat pipe 100 and can receive the heat of the heat storage portion heated by the geothermal heat, have.

Therefore, the total amount of heat transferred to the heat transfer medium is greatly increased, so that more geothermal heat can be recovered and the efficiency of the heat recovery can be improved.

The heat exchange module 400 is disposed at the rear end of the turbine T of the binary Rankine cycle system according to the present invention and is connected to the working fluid of the binary Rankine cycle system discharged from the turbine T and the pump module 300 The heat transfer medium recovered inside the support tube 100 can be heat-exchanged with each other.

At this time, the working fluid passing through the turbine T is vaporized in a relatively high temperature state, and the heat transfer medium recovered in the geothermal column 100 is cooled to a relatively low temperature, Cooled, liquefied and condensed.

That is, the binary Rankine cycle system according to the present invention may be configured to include one additional cycle for recovering the geothermal heat of the ground in order to condense the working fluid.

Because the underground geothermal heat in the basement maintains a constant temperature without being influenced by the surrounding conditions such as the weather, the binary Rankine cycle system according to the present invention, through this configuration, can stably supply Rankine cycle The working fluid can be condensed.

In addition, since it is not necessary to separately provide a large-scale cooling tower or an additional cooling device, it is possible to reduce the cost of manufacturing and operating the binary Rankine cycle system and increase the efficiency of the entire binary Rankine cycle system.

Meanwhile, as shown in FIG. 2, the binary Rankine cycle system according to the present invention can use the geothermal heat recovered through the geothermal heat pump 500 formed at the depth D2 for the deep geothermal heat recovery as a heat source.

The present geothermal heat pump 500 is basically the same as the above-mentioned geothermal geothermal power pump 100, but has a depth D2 capable of recovering deep geothermal heat at a relatively high temperature, As shown in FIG.

For this purpose, the base paper passive 500 also includes a pipe module 600, and the pipe module 600 may include a heat insulating portion 610 for lowering heat exchange efficiency between the inside and the outside of the pipe module 600 have.

The construction of the pipe module 600 and the heat insulating portion 610 is the same as that of the ceiling geothermal pipe module 200 and the heat insulating portion 210 described above but extends to a deeper depth .

With this configuration, it is possible to obtain the effect of recovering the deep geothermal heat of a relatively high temperature and improving the geothermal heat recovery efficiency.

Also, the configuration of the heat storage unit described above can also be applied to the present paper passive heat 500.

In this case, the effect of improving the efficiency of recovering the geothermal heat supplied to the Rankine cycle system as a heat source can be obtained.

<2nd Example >

Next, with reference to FIG. 3 and FIG. 4, the construction and effect of the second embodiment of the binary Rankine cycle system according to the present invention will be described in detail.

FIG. 3 is a view showing a configuration of a second embodiment of a binary Rankine cycle system according to the present invention, and FIG. 4 is a diagram illustrating a configuration of a flow path in which a working fluid of a second embodiment of a binary Rankine cycle system according to the present invention is connected to a non- Fig.

3, the binary Rankine cycle system according to the present invention may include a geothermal heat pump 500 and a pipe module 600. [

The configuration of the geothermal control unit 500 and the pipe module 600 is the same as the configuration of the geothermal control unit 100 and the pipe module 200 in the first embodiment of the present invention, .

The configuration of the pump P, the evaporator E and the turbine T may be the same as the configuration of the first embodiment.

However, in the binary Rankine cycle system according to the present embodiment, the heat transfer medium and the working fluid are not heat-exchanged with each other, and the working fluid of the binary Rankine cycle system is directly injected into the inside of the geothermal column 500 And may be configured to be cooled.

That is, the working fluid of the binary Rankine cycle system according to the present invention passes through the space between the geothermal control unit 500 and the pipe module 600, passes through the lower part of the geothermal control unit 500, And can be fed back to the binary Rankine cycle system.

At this time, since the working fluid is recovered in a state of being cooled in the lower part of the geothermal column 500 and condensed, the structure itself including the geothermal control unit 500 and the pipe module 600 may be a condenser.

The working fluid may be injected and recovered in the same manner as the heat transfer medium of the first embodiment described above. However, in order to prevent the working fluid of the binary Rankine cycle system from being contaminated during the flow of the fluid inside the geothermal column 500, It may be advantageous for the working fluid to flow through a separate flow path 700 as in this embodiment.

The flow path 710 extends to the lower portion of the geothermal column 500 along the space between the geothermal column 500 and the pipe module 600 and the lower end portion 730 of the flow path extends from the lower portion of the geothermal column 500 to the pipe module 600, and the flow path 720 may be formed to extend upwardly through the inside of the pipe module 600.

That is, a flow path can be formed along the direction in which the heat transfer medium of the first embodiment and the working fluid of the second embodiment flow in the inside of the geothermal heat pipe 500. [

Inside the geothermal tube 500, the working fluid receives geothermal heat through the inner surface of the geothermal tube 500.

Therefore, it is advantageous that the flow path 710 is disposed as close as possible to the inner circumferential surface of the geothermal column 500.

In addition, it may be advantageous to fill the space between the geothermal tube 500 and the pipe module 600 with a separate heat transfer medium 800.

Since the geothermal heat generated from the inner circumferential surface of the geothermal control unit 500 is transmitted to the heat transfer medium 800 by the heat transfer medium 800 being filled in contact with the inner circumferential surface of the geothermal control unit 500 and surrounding the flow paths 710 and 730, It is possible to obtain the effect of being delivered to the flow paths 710 and 730 with high efficiency.

Therefore, it is possible to obtain an effect of preventing the contamination of the working fluid and improving the efficiency of the recovery of the geothermal heat.

Also in this embodiment, the configuration of the heat storage portion of the above-described first embodiment can be applied.

In this case, the heat transfer medium in the geothermal heat pipe 500 of the present embodiment receives geothermal heat through the inner circumferential surface of the geothermal heat pipe 500 and can receive the heat of the heat storage portion heated by the geothermal heat, The coefficient can be improved and the geothermal heat can be absorbed more effectively.

Therefore, the total amount of heat transferred to the heat transfer medium is greatly increased, so that more geothermal heat can be recovered and the efficiency of the heat recovery can be improved.

The space between the passageway 500 and the pipe module 600 in which the working fluid is injected into the inside of the geothermal column 500 is formed in the shape of a ring on a plane, It may be advantageous that the working fluid is dispersed and heat-exchanged inside the geothermal column 500.

Therefore, as shown in FIGS. 3 and 4, the flow path 710 inserted into the space between the geothermal column 500 and the pipe module 600 may be branched into a plurality of channels.

The branched flow path 710 may be bent into the pipe module 600 at a lower portion of the geothermal column 500 and then combined into one flow path 720 again.

In this case, the surface area of the flow paths 710 and 730, to which the working fluid can receive the geothermal heat, is increased, thereby improving the efficiency of cooling the working fluid by the geothermal heat.

In addition, it may be advantageous that the portion of the flow path 700 provided below the geothermal tube 500 is relatively higher in thermal conductivity than the other portions.

The temperature at which the working fluid is cooled in the passage 700 is the temperature of the lower portion of the trough 500 so that the material of the passage 730 provided at the lower portion of the trough 500 is made of a material having a high thermal conductivity So that the working fluid is cooled by the geothermal heat intensively at a lower portion of the geothermal column 500.

Further, a separate heat exchanger for more efficient heat exchange between the working fluid and the geothermal heat of the binary Rankine cycle system according to the present invention may be installed at the lower end of the geothermal column 500, or a gas-liquid separator for filtering the non- Further configurations may be applied.

By virtue of all of the above-described constructions, the binary Rankine cycle system according to the present invention can reliably condense the Rankine cycle working fluid irrespective of local and weather effects.

In addition, since it is not necessary to separately provide a large-scale cooling tower or an additional cooling device, it is possible to reduce the cost of manufacturing and operating the binary Rankine cycle system and increase the efficiency of the entire binary Rankine cycle system.

In this embodiment, too, the geothermal heat recovered through the geothermal heat generated at the depth for the deep geothermal heat recovery can be used as the heat source, as in the first embodiment.

Such a configuration is the same as the configuration of the first embodiment described above, and thus a detailed description thereof will be omitted.

With this configuration, the present embodiment also achieves the effect of recovering the deep geothermal heat of a relatively high temperature and improving the geothermal heat recovery efficiency.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is self-evident to those of ordinary skill in the art. Accordingly, it should be understood that such modifications or alterations should not be understood individually from the technical spirit and viewpoint of the present invention, and that modified embodiments fall within the scope of the claims of the present invention.

100: Passion
200: Pipe module
300: Pump module
400: Heat exchange module
500: Passion
600: Pipe module
700: Euros
800: Heat transfer medium

Claims (12)

Geo - Jeong - jung formed by excavating the ground;
A pipe module disposed inside the retainer so as to be spaced apart from the inner surface of the retainer;
A pump module for injecting a heat transfer medium into the geothermal tube through the geothermal heat pipe and the space between the pipe modules and recovering the heat transfer medium to the ground through the interior of the pipe module; And
A heat exchange module provided at a rear end of the Binary Rankine cycle turbine to heat exchange the heat transfer medium recovered from the pump module and the working fluid of the Binary Rankine cycle to condense the working fluid;
/ RTI &gt; The method according to claim 1,
The above-
A binary Rankine cycle system formed with depths for deep geothermal reclamation. The method according to claim 1,
The pipe module includes:
And a heat insulating portion for lowering the heat exchange efficiency between the outside and the inside of the pipe module. The method according to claim 1,
Wherein the binary Rankine cycle comprises:
A binary Rankine cycle system that uses geothermal heat recovered through geothermal enthusiasm as a depth for deep water recovery. Geo - Jeong - jung formed by excavating the ground; And
A pipe module disposed inside the retainer so as to be spaced apart from the inner surface of the retainer;
/ RTI &gt;
Wherein the working fluid discharged from the turbine of the binary Rankine cycle is recovered to the ground through the interior of the pipe module through the bottom of the geothermal tube through the space between the geothermal tube and the pipe module. 6. The method of claim 5,
The above-
A binary Rankine cycle system formed with depths for deep geothermal reclamation. 6. The method of claim 5,
The pipe module includes:
And a heat insulating portion for lowering the heat exchange efficiency between the outside and the inside of the pipe module. 6. The method of claim 5,
The working fluid,
A duct extending along a space between the tilting column and the pipe modules to a lower portion of the tilting column and bent into the inside of the pipe module at a lower portion of the tile; Flowing Binary Rankine Cycle System. 9. The method of claim 8,
The flow path includes:
And the flow path inserted into the space between the tilting pass and the pipe modules is branched into a plurality of channels. 9. The method of claim 8,
The flow path includes:
Wherein a portion of the lower portion of the retainer is formed with a relatively higher thermal conductivity than the other portion. 9. The method of claim 8,
Wherein the heat transfer medium is filled in the space between the heat retaining pipe and the pipe modules. 6. The method of claim 5,
Wherein the binary Rankine cycle comprises:
A binary Rankine cycle system that uses geothermal heat recovered through geothermal enthusiasm as a depth for deep water recovery.

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