KR102453311B1 - Electricity generation system using solar energy - Google Patents

Abstract

The present invention relates to a solar heat power generation system. More specifically, according to the present invention, since a sunlight is accurately reflected by a heat collecting unit, light collecting efficiency may be increased. A heat of a thermal oil turns a Stirling engine. After a hydraulic pressure is formed at a low rotational speed of the Stirling engine, a generator is operated at a high rotational speed using the formed hydraulic pressure. Therefore, an electric power can be produced even at the low rotational speed of the Stirling engine. The solar heat power generation system of the present invention comprises: a light collecting dish; the heat collecting unit; a first heat exchange pipe; a thermal oil tank; a second heat exchange pipe; the Stirling engine; a hydraulic pump; the generator; and an energy storage system (ESS).

Description

Solar power generation system {Electricity generation system using solar energy}

The present invention relates to a solar thermal power generation system, and more particularly, it is possible to increase the light collection efficiency by accurately reflecting sunlight to a heat collecting part, and to rotate a Stirling engine with heat of hot oil, and to form hydraulic pressure at a low rotation speed of the Stirling engine. Then, it relates to a solar power generation system capable of producing electric power even at a low rotational speed of a Stirling engine by operating a generator at a high rotational speed using the formed hydraulic pressure.

Solar thermal power generation technology is a technology that absorbs radiation from the sun, converts it into thermal energy, and then utilizes it for heating and cooling, industrial process heat, and thermal power generation.

Solar power generation systems are divided into passive systems and active systems depending on the presence or absence of a driving device for the heating medium. On the other hand, the active system is a system that collects solar heat by using a heat medium driving device such as a pump by installing a separate collector and collecting solar heat, and this active system is often called a solar power generation system.

The most important component of a solar power generation system is a collector that can collect sunlight. These collectors include a flat plate collector, a vacuum tube collector, a Parabolic Trough Concentrator (PTC) type collector, a CPC (Compound Parabolic Concentrator) type collector, It is divided into dish-type collectors, etc.

On the other hand, the dish-type collector, also called a parabolic collector, is a concave dish-shaped collector dish that reflects sunlight to the focal position and circulates the heating medium to the focal position to heat the heating medium. It is used to generate electricity or for heating and cooling.

However, the conventional dish-type collector has a problem of low efficiency because it cannot reflect sunlight at an accurate focal length.
As a prior art having such a problem, Korean Patent Publication No. 10-1017723 discloses 'a light-collecting reflector having a formula surface, a method for manufacturing the same, and a light-collecting device using the same'. In the above technique, it is practically difficult to reflect sunlight at an accurate focal length because the reflector installed on the condenser has a so-called dish shape having a formula surface.

The present invention has been devised to solve the above-described problems, and an object of the present invention is to provide a solar thermal power generation system capable of greatly improving light collection efficiency by reflecting sunlight at an accurate focal length.

Another object of the present invention is to provide a solar thermal power generation system capable of generating electricity even at a low rotational speed of the Stirling engine by operating a Stirling engine with collected heat.

In addition, another object of the present invention is to provide a solar thermal power generation system that can prevent the explosion of the thermal oil tank.

In order to achieve the above object, the present invention is a condensing plate for condensing at a focal position by reflecting sunlight; a heat collecting unit positioned at a focal position of the condensing plate and heated by the condensed sunlight; a first heat exchange pipe having one end connected to the heat collecting unit and the other end connected to the thermal oil tank below, and transferring the heat of the heat collecting unit to the thermal oil inside the thermal oil tank below by circulating the thermal medium filled therein; a thermal oil tank filled with thermal oil therein, the other end of the first heat exchange pipe is connected, and receives heat from a thermal medium circulating in the first heat exchange pipe to heat the filled thermal oil; a second heat exchange pipe having one end connected to the thermal oil tank and the other end connected to the Stirling engine below, and circulating the heating medium filled therein to the Stirling engine below to operate the Stirling engine below; a Stirling engine for generating rotational force by the heat transferred from the second heat exchange pipe; a hydraulic pump for generating hydraulic pressure by the rotational force of the Stirling engine; a generator generating electric power while rotating by the hydraulic pressure of the hydraulic pump; and an energy storage system (ESS) that stores the power produced by the generator and supplies the stored power to a load, wherein the revolutions per minute (RPM) of the generator is higher than the revolutions per minute of the Stirling engine. It provides a solar thermal power generation system, characterized in that large.

In a preferred embodiment, an auxiliary thermal oil tank filled with thermal oil therein and receiving heat from a thermal medium circulating through the first heat exchange pipe to heat the internal thermal oil; a third heat exchange pipe having one end connected to the auxiliary heat oil tank and the other end connected to the following steam turbine, and circulating the heat medium filled therein to the following steam engine to operate the following steam turbine; a steam turbine generating rotational force by heat transferred from the third heat exchange pipe; an auxiliary generator for generating electric power while rotating by the rotational force of the steam turbine; and an auxiliary energy storage device for storing the electric power produced by the auxiliary generator and supplying the stored electric power to a load, wherein the other end of the first heat exchange pipe is connected in parallel to the heat oil tank and the auxiliary heat oil tank, , When the heat medium temperature of the heat medium tank is equal to or greater than the set temperature, the heat medium of the first heat exchange pipe circulates in the following auxiliary heat medium tank.

In a preferred embodiment, the auxiliary energy storage device supplies power to the load when the energy storage device is discharged, and after discharging the energy storage device until the power of the auxiliary energy storage device is supplied to the load An uninterruptible power supply (UPS) that supplies power for a period of time includes an uninterruptible power supply (UPS).

In a preferred embodiment, the collecting plate includes: a plurality of square tubes bent in a circular annular shape and having different diameters; a flat iron for support in the form of a ring that is welded and erected along the center of the upper surface of each tube; and a support for attaching a mirror to which a lower end is inserted and fixed together with the flat convex for support, and a mirror for reflecting sunlight is attached to the upper end, and a plurality of mirrors are attached so as not to overlap each other in the longitudinal direction; A plurality of mirror attachment supports are installed adjacent to each other in a circle along the flat iron for support to form a plate shape.

In a preferred embodiment, the upper surface of the mirror attachment support is provided with a plurality of mirror attachment plates, the lower surface of which is attached to the upper surface of the mirror attachment support so that an angle can be adjusted, and one mirror is attached to the upper surface, and the mirror attachment support The upper surface of the is made of a stepped surface so that the mirror attachment plates can be attached in a stepwise manner, and one mirror attachment plate is fastened to one stepped surface.

In a preferred embodiment, the upper edge portion of the mirror attachment plate is fastened to the upper surface of the mirror attachment support through a first bolt, and the lower edge portion is fastened to the upper surface of the mirror attachment supporter via a second bolt, and the mirror Between the lower surface of the attachment plate and the upper surface of the mirror attachment support, it is inserted into the outer surface of the second bolt to space the lower surface of the mirror attachment plate and the upper surface of the mirror attachment support from each other so that the angle of the mirror attachment plate can be adjusted. A spring is provided.

In a preferred embodiment, the first heat exchange pipe is manufactured by joining a plurality of pipes by welding, and is welded from the outside of the heat oil tank so that there is no welded portion at the position of the first heat exchange pipe passing through the inside of the heat oil tank. this is done

The present invention has the following excellent effects.

First, according to the solar power generation system of the present invention, it is possible to install the mirrors of the condensing plate in a stepwise manner, and by adjusting the angle of each mirror, the sunlight can be reflected at the correct focus position, so that the light collecting efficiency can be greatly improved. .

In addition, according to the solar power generation system of the present invention, the Stirling engine is operated with the heat of the heat oil tank to generate electric power, but first, the hydraulic pump is rotated with the low-speed rotational force of the Stirling engine to form the hydraulic pressure, and then, the generator with the formed hydraulic pressure Since it generates power by rotating the engine at high speed, it has the advantage of being able to produce power even with a low-speed Stirling engine.

In addition, according to the solar power generation system of the present invention, the welding part of the heat exchange pipe is not located inside the heat-heat oil tank, so that even if the heat medium leaks from the heat-exchange pipe, it does not come into contact with the water inside the heat-heat oil tank to prevent explosion. There are advantages.

1 is a view showing the overall configuration of a solar power generation system according to an embodiment of the present invention;
2 is a view showing in detail a light collecting plate of a solar power generation system according to an embodiment of the present invention;
3 is a view showing in detail the configuration of a support for attaching a mirror of a light collecting dish of a solar power generation system according to an embodiment of the present invention.

As for the terms used in the present invention, general terms that are currently widely used are selected as possible, but in certain cases, there are also terms arbitrarily selected by the applicant. So the meaning must be understood.

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

However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Like reference numerals refer to like elements throughout.

1 is a view showing the overall configuration of a solar thermal power generation system according to an embodiment of the present invention.

Referring to FIG. 1 , a solar power generation system 100 according to an embodiment of the present invention is a system that heats a heating medium with solar heat and generates electricity using the heat of the heated heating medium, and heating is possible using hot water. .

The solar power generation system 100 includes a light collecting plate 110 , a heat collecting unit 120 , a first heat exchange pipe 130 , a heat oil tank 140 , a second heat exchange pipe 150 , a Stirling engine 160 , and hydraulic pressure. It comprises a pump 170 , a generator 180 and an energy storage device 190 .

The condensing plate 110 reflects sunlight and condenses it at a predetermined focal point, and is manufactured in the form of a plate.

In addition, although not shown, a driving unit for driving the collecting dish 110 to track the sun is provided under the light collecting dish 110 , and the driving unit changes the angle of the light collecting dish 110 or changes the sun. It includes a hydraulic pump that can be rotated to face and a controller for controlling the hydraulic pump.

In addition, the hydraulic pump may drive the light collecting dish 110 up and down through a hydraulic cylinder and rotate the light collecting dish 110 through a hydraulic ring gear.

However, the hydraulic pump may be replaced by an electric motor.

Also, FIG. 2 is a view showing the light collecting dish 110 in detail, and FIG. 3 is a view showing in detail the coupling relationship between the mirror attachment support 113 and the mirror 114 of the light collecting dish 110 .

2 and 3 together, the light collecting dish 110 is bent in a circular annular shape and includes a plurality of square tubes 111 having different diameters.

In addition, in the center of the upper surface of each tube (111a, 111b, 111c) is erected by welding the flat iron 112 for support in the form of a ring.

Although the drawings show that the square tubes 111a, 111b, and 111c are composed of three, there is no particular restriction on the number.

Also, among the square tubes 111a, 111b, and 111c, it is positioned higher from the ground as it goes from the square tube 111a having the smallest diameter to the square tube 111c having the largest diameter.

In addition, the lower end of the mirror attachment support 113 is inserted and fixed to each of the support flat irons 112a, 112b, and 112c erected on the respective pipes 111a, 111b, and 111c, and the mirror attachment support 113 is the A plurality of flat irons for support (112a, 112b, 112c) are installed adjacent to each other in a circle to form a plate shape.

In addition, in the support 113 for attaching the mirror, a cut-out groove (a) for fastening the flat iron for support into which the flat iron for support can be inserted and fixed is formed.

That is, the lower end of one mirror attachment support 113 is inserted and fixed together in the plurality of support flat irons 112a, 112b, and 112c.

In addition, the mirror attachment support 113 includes one side support 113a and the other side support 113b spaced apart from the one side support 113a.

However, the support 113 for attaching the mirror can be manufactured integrally in which the one side support 113a and the other side support 113b are connected to each other.

In addition, the upper surface of the mirror attachment support 113 is formed of a stepped surface 113c, and the stepped surface 113c decreases in height from the outer to the center of the plate.

In addition, a mirror attachment plate 115 is fastened to each of the stepped surfaces 113a, and a mirror 114 capable of reflecting sunlight is attached to the upper surface of the mirror attachment plate 115 .

In addition, the mirror 114 may be adhered to the upper surface of the mirror attachment plate 115 using an adhesive such as silicone.

In addition, in the mirror attachment plate 115 , the upper edge facing the outside of the plate is fastened with the first bolt 116 , and the lower edge facing the center of the plate is fastened with the second bolt 117 .

In addition, between the mirror mounting plate 115 and the stepped face (c) is fitted on the outer surface of the second bolt 117 to space the mirror mounting plate 115 and the step face (c) from each other, A spring 118 capable of adjusting the angle of the mirror attachment plate 115 according to the fastening degree of the second bolt 117 is provided.

That is, the operator fastens the first bolt 116 to fix the upper edge of the mirror attachment plate 115 , adjusts the fastening degree of the second bolt 117 , and the mirror attachment plate 115 . angle can be easily adjusted.

Therefore, according to the present invention, since the angles of all the mirrors 114 can be adjusted, there is an advantage in that sunlight can be condensed at an accurate focal position.

In addition, the angles of all of the stepped surfaces 113c with respect to the ground may not be the same, and the angle formed with the ground may decrease from the highest surface to the lowest surface.

For example, when the stepped surface 113c consists of seven surfaces, the highest first surface is 27.7° with the ground v, the second surface that is the next surface is 25.5° with the ground, and the third surface that is the next surface is 22.9° to the ground, the fourth side after it is 21.6° to the ground, the fifth side after it is 18.3 to the ground, the sixth side is 16.3° to the ground, and the lowest 7th side is 12.9° to the ground The angle can be adjusted to achieve .

The heat collecting unit 120 is positioned at a focal position of the light collecting plate 110 and heated by the concentrated sunlight.

In addition, the heat collecting part 120 is preferably made of stainless steel rather than copper to withstand a high temperature of about 800° C. or higher, and one end of the first heat exchange pipe 130 to be described below is connected.

In addition, a cover is attached to the heat collecting part to prevent loss of generated heat, and the cover transfers radiant heat to the first heat exchange pipe 130 to increase thermal efficiency.

In addition, one end of the first heat exchange pipe 130 passing through the heat collecting unit 120 may have a meander shape, and the area of the first heat exchange pipe 130 passing through the heat collecting unit 120 may be maximized. It is desirable to increase the amount of heat absorption by making it possible.

On the other hand, one end of the first heat exchange pipe 130 does not pass directly to the heat collecting part 120 , but the heat collecting part 120 is manufactured in the form of a disk in which a heat medium circulation line through which the heat medium can circulate is formed. By connecting the first heat exchange pipe 130 to the inlet and outlet of the circulation line, the heating medium may be heated.

In addition, a solar tracking sensor may be provided in the center of the upper surface of the heat collecting unit 120 , and the solar tracking sensor transmits solar tracking information to the controller, and the controller controls the hydraulic pump to collect the light. The plate 110 faces the sun.

The first heat exchange pipe 130 has one end connected to the heat collecting unit 120 and the other end connected to a thermal oil tank 140 to be described below, and the heat collecting unit 120 by circulation of a heating medium filled therein. ) to transfer the heat to the thermal oil tank 140 .

In addition, the heating medium is generally refined mineral oil, synthetic paraffin, diaryl alkane, polyphenyl derivatives, aryl ether, dimethyl siloxane polymer, etc. of high temperature thermal oil can be used.

The thermal oil tank 140 is filled with thermal oil therein, the other end of the first heat exchange pipe 130 is connected, and the heat of the heating medium circulating inside the first heat exchange pipe 130 is supplied to the filled heating medium. Heats oil to store heat.

In addition, as the thermal oil, general water may be used.

On the other hand, the other end of the first heat exchange pipe 130 is located inside the heat oil tank 140 in the form of direct connection by welding a plurality of pipes to increase the contact area inside the heat oil tank 140 . is located only on the outside of the thermal oil tank 140, and the welding part is not located inside.

The reason is that when the heating medium, which is hot oil circulating in the first heat exchange pipe 130, leaks from the welding part inside the thermal oil tank 140, it meets with water and an explosion occurs, so even if the heating medium leaks from the welding part, the thermal oil tank ( 140) to prevent explosion by avoiding contact with water.

The second heat exchange pipe 150 has one end connected to the thermal oil tank 140 and the other end connected to the Stirling engine 160 below, and circulates the internal thermal medium to heat the thermal oil tank 140 . is transmitted to the Stirling engine 160 .

The Stirling engine 160 generates rotational force by receiving heat from the heat exchange pipe 150 .

In addition, the Stirling engine 160 is a type of heat engine and generates rotational force by applying heat to a working fluid and rotating the crank while repeatedly compressing and expanding the working fluid.

Meanwhile, since the rotational speed per minute (RPM) of the rotational force generated by the Stirling engine 160 is very low, there is a problem in that electricity cannot be produced by rotating the generator 180, which will be described below.

Accordingly, the present invention includes a hydraulic pump 170 that generates hydraulic pressure with the rotational force of the Stirling engine 160, and rotates the generator 180 with the hydraulic pressure of the hydraulic pump 170 to produce electricity.

That is, the revolutions per minute of the generator 180 is greater than the revolutions per minute of the Stirling engine 160 .

The generator 180 generates electric power by rotating a rotor through the hydraulic pressure of the hydraulic pump 170 .

The energy storage device (190, ESS: Energy Storage System) includes a plurality of batteries, receives and stores the power produced by the generator 180, and supplies power to a load.

On the other hand, the solar thermal power generation system 100 of the present invention auxiliary heat oil tank 141 for storing and generating power auxiliary when the heat is discarded because the heat oil tank 140 can no longer store heat, It may further include a third heat exchange pipe 151 , a steam turbine 161 , an auxiliary generator 181 , an auxiliary energy storage device 191 , and an uninterruptible power supply device 192 .

The auxiliary thermal oil tank 141 is filled with thermal oil therein, and receives the heat of the thermal medium circulating through the first heat exchange pipe 130 to heat the internal thermal oil.

In addition, a valve 131 is provided in the first heat exchange pipe 130 , and the valve 131 operates when the temperature of the thermal oil tank 140 is higher than or equal to a set value (for example, it may be 500° C.), A path is formed so that the heating medium circulates only to the auxiliary thermal oil tank 141 .

The third heat exchange pipe 151 has one end connected to the auxiliary heat oil tank 141 and the other end connected to the lower steam turbine 161, and heats the auxiliary heat oil tank 141 to the steam turbine. forward to (161).

The steam turbine 161 generates a rotational force by generating steam compressed by the heat of the auxiliary thermal oil tank 141 .

The auxiliary generator 181 receives rotational force from the steam turbine 161 to generate electric power.

In addition, the auxiliary generator 181 primarily stores the generated power in the energy storage device 190, and when the energy storage device 190 is fully charged, it supplies power to the auxiliary energy storage device 191. Save.

Also, the auxiliary energy storage device 191 supplies power to a load when the energy storage device 190 is discharged.

On the other hand, after the energy storage device 190 is discharged, when the power of the auxiliary energy storage device 191 is supplied to the load, a power non-supply state occurs for several seconds. For this purpose, power is supplied to the load through an uninterruptible power supply (192, UPS: Uninterruptible Power Supply).

In addition, the uninterruptible power supply 192 stores some of the power of the energy storage device 190 and the auxiliary energy storage device 191 and supplies power to the load, and the energy storage device 190 discharges the power. to prevent a power outage when

As described above, the present invention has been illustrated and described with reference to preferred embodiments, but it is not limited to the above-described embodiments, and those of ordinary skill in the art to which the present invention pertains within the scope not departing from the spirit of the present invention Various changes and modifications will be possible.

100: solar power system 110: condensing plate
111: square tube 112: flat iron for support
113: mirror attachment support 114: mirror
115: mirror mounting plate 116: first bolt
117: second bolt 120: heat collecting unit
130: first heat exchange pipe 131: valve
140: fruit oil tank 141: auxiliary heat oil tank
150: second heat exchange pipe 151: third heat exchange pipe
160: Stirling engine 161: Steam turbine
170: hydraulic pump 180: generator
181: auxiliary generator 190: energy storage device
191: auxiliary energy storage device 192: uninterruptible power supply

Claims (7)

Condensing plate for condensing the focus position by reflecting sunlight;
a heat collecting unit positioned at a focal position of the condensing plate and heated by the condensed sunlight;
a first heat exchange pipe having one end connected to the heat collecting unit and the other end connected to the thermal oil tank below, and transferring the heat of the heat collecting unit to the thermal oil inside the thermal oil tank below by circulating the thermal medium filled therein;
a thermal oil tank filled with thermal oil therein, the other end of the first heat exchange pipe is connected, and receives heat from a thermal medium circulating in the first heat exchange pipe to heat the filled thermal oil;
a second heat exchange pipe having one end connected to the thermal oil tank and the other end connected to the Stirling engine below, and circulating the heating medium filled therein to the Stirling engine below to operate the Stirling engine below;
a Stirling engine for generating rotational force by the heat transferred from the second heat exchange pipe;
a hydraulic pump for generating hydraulic pressure by the rotational force of the Stirling engine;
a generator generating electric power while rotating by the hydraulic pressure of the hydraulic pump; and
and an energy storage system (ESS: Energy Storage System) that stores the power generated by the generator and supplies the stored power to a load;
The revolutions per minute (RPM) of the generator is greater than the revolutions per minute of the Stirling engine,
an auxiliary thermal oil tank filled with thermal oil and receiving heat from a thermal medium circulating through the first heat exchange pipe to heat the internal thermal oil;
a third heat exchange pipe having one end connected to the auxiliary thermal oil tank and the other end connected to the following steam turbine, and circulating the heating medium filled therein to the following steam engine to operate the following steam turbine;
a steam turbine generating rotational force by heat transferred from the third heat exchange pipe;
an auxiliary generator generating electric power while rotating by the rotational force of the steam turbine; and
Including; and an auxiliary energy storage device for storing the power generated by the auxiliary generator and supplying the stored power to the load;
The other end of the first heat exchange pipe is connected in parallel to the heat medium oil tank and the auxiliary heat oil tank below, and when the heat medium temperature of the heat medium tank is above a set temperature, the heat medium of the first heat exchange pipe is the auxiliary heat oil tank A solar power system, characterized in that it circulates.
delete The method of claim 1,
The auxiliary energy storage device supplies power to the load when the energy storage device is discharged,
After discharging the energy storage device, an uninterruptible power supply (UPS) for supplying power for a period of time until the power of the auxiliary energy storage device is supplied to the load. .
4. The method according to any one of claims 1 to 3,
The collecting plate is
A plurality of square tubes bent in the form of a circular ring and having different diameters;
a flat iron for support in the form of a ring that is welded and erected along the center of the upper surface of each tube; and
The lower end is fixed by being inserted into the flat convex for support, and a mirror for reflecting sunlight is attached to the upper end, and a mirror attachment support on which a plurality of mirrors are attached so as not to overlap each other in the longitudinal direction; is made including,
A solar power generation system, characterized in that a plurality of the mirror attachment supports are installed adjacent to each other in a circle along the flat iron for support to form a plate shape.
5. The method of claim 4,
A plurality of mirror attachment plates are provided on the upper surface of the support for attaching the mirror, the lower surface is attached to the upper surface of the support for attaching the mirror so that an angle can be adjusted, and a single mirror is attached to the upper surface,
The upper surface of the support for attaching the mirror is made of a stepped surface so that the mirror attachment plates can be attached in a stepwise manner,
A solar power generation system, characterized in that one mirror attachment plate is fastened to one stepped surface.
6. The method of claim 5,
The upper edge of the mirror attachment plate is fastened to the upper surface of the mirror attachment support through a first bolt, and the lower edge portion is fastened to the upper surface of the mirror attachment support by a second bolt,
The second bolt is inserted between the lower surface of the mirror attachment plate and the upper surface of the mirror attachment support to space the lower surface of the mirror attachment plate and the upper surface of the mirror attachment support from each other to adjust the angle of the mirror attachment plate. Solar power generation system, characterized in that provided with a spring that enables.
7. The method of claim 6,
The first heat exchange pipe is manufactured by joining a plurality of pipes by welding.
The solar thermal power generation system, characterized in that welding is performed outside the thermal oil tank so that there is no welded portion at the position of the first heat exchange pipe passing through the inside of the thermal oil tank.

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