KR101104694B1 - Working fluid circulation structure of tower solar power system - Google Patents

Abstract

The present invention is configured to circulate between the absorber and the steam generator or the heat storage tank, the working fluid is to operate the tower-type pneumatic solar power system to increase the thermal efficiency by allowing the working fluid to be reheated in the recycled state without being discharged to the atmosphere It relates to a fluid circulation structure.

The working fluid supply structure of the tower-type solar power generation system of the present invention includes a reflector reflecting sunlight, an absorber for heating the working fluid using solar heat reflected / condensed by the reflector, and steam by the heat of the working fluid heated by the absorber. In the working fluid supply structure of the tower-type solar power system comprising a steam generator for generating a, the working fluid passing through the absorber by connecting the inlet, the outlet of the working fluid from the absorber to the inlet, the outlet of the steam generator, the outlet Is circulated between the steam generator and the absorber without being discharged to the outside.

Solar power, absorber, ceramic, recirculation, heat exchanger, tower

Description

Air receiver and working fluid circulation system for solar thermal power tower

The present invention relates to a working fluid supply structure of a tower solar power system, and in particular, the working fluid can be circulated between an absorber and a steam generator or a heat storage tank so that the working fluid can be reheated without being discharged to the outside air. The present invention relates to a working fluid circulation structure of a tower type solar power system with improved thermal efficiency.

Due to the depletion of fossil fuels, many power generators using natural forces are being developed, and one of the means for generating power is solar heat.

Among solar power generators, there is a solar power generation system, and among these solar power generation systems, there is a tower solar power generation system.

The tower solar power system has several Heliostats that track, reflect, and collect the sun, and collect them in one place. It includes a steam generator for generating steam by the heat of the fluid, and a steam turbine for generating electricity by using the steam generated in the steam generator.

The tower solar power system thus constructed heats the working fluid passing through the absorber with the heat collected by the reflector, and the working fluid, which is raised up to about 1000 degrees from the absorber, is sent to the steam generator to generate saturated or superheated steam. It is sent to the turbine to generate power.

In this power generation system, the air used in the steam generator is supplied to the absorber through the fan again, and heat energy can be stored and used in the heat storage tank in case of a phenomenon such as a decrease in the radiant energy of the sun as an energy source. . That is, the tower solar power generation is composed of a reflector, a tower, an absorber, a storage tank, a turbine, a generator, a condenser, a deaerator, and the like.

The tower-type pneumatic absorber configured as described above is configured by installing a plurality of absorption modules 110 having a plurality of flow paths as shown in FIG. 1, and the outside air is introduced by the internal suction fan. The sunlight reflected by the reflector is focused and the temperature is very high, and the introduced external air passes through the flow path of the high temperature absorber module 110 and the temperature is increased.

That is, the absorber 100 constituting the tower solar power system uses air as a working fluid, and the air is sucked from the outside and passed through the absorber 100 to be heated as shown in FIG. 2. It is configured to transfer heat to the generator 300 or the heat storage tank 500 to be discharged to the outside or introduced to the absorber again, and in the case of such a conventional absorber by using external air at room temperature, a predetermined temperature (1000) at the outlet of the absorber It was difficult to raise above.

In particular, in the case of winter, the low-temperature air is sucked in and passed through the absorption module 100 to be heated, and thus the heat efficiency is lowered when the low-temperature air is absorbed and heated.

The present invention has been developed to solve the problems of the prior art as described above, the heat efficiency by passing through the absorber module and the heated air to be supplied back to the absorber module without being discharged to the outside to be heated by solar heat The purpose of the present invention is to provide a working fluid circulation structure of a tower type solar power generation system.

That is, the working fluid supply structure of the tower-type solar power generation system with high thermal efficiency by circulating between the absorber and the steam generator or the heat storage tank without allowing the working fluid to be discharged to the outside, thereby allowing the high-temperature working fluid, which is not completely cooled, to be heated by the absorber again. The purpose is to provide.

The working fluid circulation structure of the tower solar thermal power generation system of the present invention generates a vapor by the heat of the working fluid heated by the absorber and the absorber for heating the working fluid using the reflector reflecting sunlight, the solar heat reflected by the reflector. In the working fluid supply structure of the tower-type solar thermal power generation system comprising a steam generator to make, the working fluid passing through the absorber is connected to the inlet, the outlet of the working fluid from the absorber to the inlet, the outlet of the steam generator through the absorber It is characterized in that it is configured to circulate between the steam generator and the absorber without being discharged to.

The present invention has the effect of increasing the thermal efficiency by allowing the working fluid to be circulated without being discharged to the outside to heat the working fluid remaining heat even after transferring heat to the steam generator.

That is, the working fluid having residual heat is supplied to the absorber again and heated by solar heat of the absorber, so that the working fluid heated to a higher temperature can be supplied to the steam generator, thereby increasing power generation efficiency.

Hereinafter, a working fluid supply structure of a tower solar power system according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a configuration diagram showing a working fluid circulation structure of the tower solar power system according to the present invention, Figure 4 is an exploded perspective view showing an example of the absorber constituting the tower solar power system according to the present invention, Figure 5 4 is a cross-sectional view of the absorber shown in FIG. 4, and FIG. 6 is an exploded perspective view showing another example of the absorber according to the present invention.

As shown, the working fluid supply structure of the tower solar power generation system of the present invention includes a reflector 200 reflecting sunlight, an absorber 100 for heating the working fluid using solar heat reflected by the reflector, and an absorber. In the working fluid supply structure of the tower-type solar power system comprising a steam generator 300 for generating steam by the heat of the working fluid heated by the, the inlet, outlet through which the working fluid enters and exits from the absorber 100 It is characterized in that the working fluid passing through the absorber by connecting to the inlet and outlet of the generator is circulated between the steam generator and the absorber without being discharged to the outside.

The working fluid circulation structure of the tower solar power generation system of the present invention configured as described above maintains a constant temperature even when cooled because the working fluid is circulated between the absorber 100 and the steam generator 300 without being discharged to the outside as described above. As a result, the heating time by the heat absorbed by the absorber 100 may be shortened.

That is, in the conventional case, the air used as the working fluid flows in from the outside to pass through the absorber 100 and is heated, and the air thus air is discharged to the outside after being transferred to the steam generator 300 or partly back to the absorber. It is configured to be introduced, so that the outside air is sucked again and heated in the absorber and supplied to the steam generator, so if the outside air temperature is low, cold air is introduced and the absorber 100 is heated using solar heat. There is a problem that the heating is not above a predetermined temperature, the present invention is the air passed through the steam generator 300 is not discharged to the outside is supplied back to the absorber 100 and the air thus supplied transfers heat to the steam generator 300 Since a certain temperature is maintained even after the absorption of heat in the absorber 100 can be heated to a higher temperature.

An example of the absorber 100 for allowing the working fluid to circulate between the absorber 100 and the steam generator 300 or the heat sink 500 may be configured as shown in FIGS. 4 to 6.

That is, the absorber 100 includes a main body 1 having a plurality of flow path grooves 11 in which a working fluid flows on one surface in a plate shape; A cover detachably installed on a surface on which the flow path groove 11 of the main body 1 is formed to block an open portion of the flow path groove so that a flow path is formed, and a cover having an oil and an entrance on the part facing the end of the flow path (2). It is configured to include).

That is, the absorber 100 connects the inlet 21 and the outlet 22 formed in the cover 2 constituting the same to the outlet and the inlet (not shown) of the steam generator 300 to discharge the working fluid to the outside. It is configured to be able to circulate without being.

The absorber 100 is made of ceramics (ceramics) with excellent heat transfer performance, and can be connected to each other to increase the collection area, thereby making it easy to adjust the size of the absorber according to the solar power generation capacity.

The flow path grooves 11 formed in the main body 1 constituting the absorber 100 are separated from each other by the flow path wall 12 as described above, and a plurality of flow path grooves are formed in parallel. It may vary depending on the type of working fluid passing through.

In the absorber 100 configured as described above, the surface of the main body 1 serves as a heat collecting plate for absorbing solar heat, and the collected heat is transferred to the flow path groove 11 through the flow path wall 12 to move along the flow path. Heat exchange with the fluid.

The absorber is mainly made of silicon carbide (SiC) among the ceramics, which has the advantage that the high melting point and thermal conductivity of silicon carbide can be used smoothly in an operating temperature of more than 1000 degrees and in a local heat intensive environment.

As described above, the absorber is provided with the cover 2 in the main body 1 in which the flow path grooves 11 are formed as described above, so that the open portion of the flow path grooves 11 is blocked by the cover 2, so that the flow path is closed. The flow path thus formed may form a flow path in a serpentine form between the inlet and the outlet as shown in FIG. 4, or may form a flow path spirally formed outward from the center inlet as shown in FIG. 6. The length of the flow path can be made as long as possible, so that the working fluid passing through can absorb a lot of heat.

This lengthening of the flow path allows the working fluid to exchange heat in large areas when the absorber is exposed to solar heat.

1 is a cross-sectional view showing an example of an absorber constituting a conventional tower solar power system,

2 is a configuration diagram showing a working fluid supply structure of a conventional tower solar power system,

3 is a block diagram showing a working fluid supply structure of the tower solar power system according to the present invention,

Figure 4 is an exploded perspective view showing an example of the absorber constituting the tower solar power system according to the present invention,

5 is a cross-sectional view of the absorber shown in FIG.

6 is an exploded perspective view showing another example of the absorber according to the present invention.

Description of the Related Art [0002]

DESCRIPTION OF SYMBOLS 1 Main body 11 Euro groove 12 Euro wall

2: cover

  21: inlet 22: outlet

Claims (3)

Reflector 200 for reflecting sunlight, absorber 100 for heating the working fluid using the solar heat reflected by the reflector, and the steam generator 300 for generating steam by the heat of the working fluid heated by the absorber In the working fluid circulation structure of the tower-type solar thermal power system comprising a, The working fluid passing through the absorber is connected to the inlet and outlet of the steam generator through the inlet and outlet of the working fluid from the absorber 100, and is configured to circulate between the steam generator and the absorber without being discharged to the outside. The absorber, A main body 1 having a plurality of flow path grooves 11 having a working fluid flowing on one surface thereof in a plate shape; A cover detachably installed on a surface on which the flow path groove 11 of the main body 1 is formed to block an open portion of the flow path groove so that a flow path is formed, and a cover having an oil and an entrance on the part facing the end of the flow path (2). The working fluid circulation structure of the tower-type solar power system, characterized in that it comprises a. delete The method of claim 1, The absorber is a working fluid circulation structure of the tower solar system, characterized in that consisting of ceramic (ceramics).

Images