KR101582987B1 - Desalination apparatus of sea water having solar panel - Google Patents

Abstract

The purpose of the present invention is to provide a desalination apparatus having a structure capable of improving fresh water production efficiency of a desalination apparatus using solar heat, and more effectively producing fresh water even in bad weather conditions. According to the present invention, a desalination apparatus including a photovoltaic power generating plate comprises: a fresh water producing part including a water tank including a transparent window and accommodating sea water inside, and collecting fresh water condensed by evaporating the sea water by solar heat entering through the transparent window; a heating part for heating the water tank of the fresh water producing part; and a photovoltaic power generating part installed in a back side of the fresh water producing part, and generating power by solar heat and supplying power for heating to the heating part as the photovoltaic power generating plate is slid and then protruding in a lateral direction of the fresh water producing part. The photovoltaic power generating part includes: a fixing frame fixed to a back side of the fresh water producing part; a sliding frame installed at an incline as the photovoltaic power generating plate is lifted upwards by hinge-combining the upper end of the photovoltaic power generating plate with a hinge shaft installed in an upper part, and accommodated in the fixing frame and appearing and disappearing in a lateral direction of the fresh water producing part from the fixing frame by sliding; and a gas spring whose both ends are combined with a back side of the photovoltaic power generating plate and a lower part of the sliding frame, respectively, for buffering movement that the photovoltaic power generating plate turns around the hinge shaft, and limiting an inclined range of the photovoltaic power generating plate around the hinge shaft.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a desalination apparatus having a solar-

The present invention relates to a desalination apparatus having a solar photovoltaic panel, and more particularly, to a desalination apparatus for producing fresh water by evaporating seawater by solar heat, further comprising a solar photovoltaic panel, The present invention relates to a desalination apparatus capable of easily installing and storing a photovoltaic panel.

In areas where desalination is insufficient, such as dry areas, remote islands, and maritime bases, seawater is desalinated and used as a water source by constructing separate desalination facilities.

The seawater desalination system using solar energy is attracting attention as an environmentally friendly device using natural energy by obtaining seawater by heating sea water using solar energy.

1 and 2 show a desalination apparatus using solar heating as disclosed in Korean Patent Publication No. 10-1134421.

1 and 2, a conventional desalination apparatus includes a transparent cover 1 inclined downward to one side, a seawater storage tank 2 having a fresh water storage oil passage 3 formed on one side thereof, a seawater storage tank 2, 2, 3, and 4-stage fresh water sections (4,5,6) provided vertically at one side of the first water column 4b, the wick 4a, the seawater supply section 4c and the condensate water pod 4d, , 7).

When the seawater is evaporated by the solar heat in the seawater storage tank 2, steam is condensed on the bottom surface of the cover 1 and on the entire surface of the steel plate 4b of the first end fresh water portion 4, The water droplets condensed on the steel plate 4b flow down to the lower end due to the vertically installed steel plates, and are stored in the condensate water pockets 4d and collected. The wick 4a of each of the first, second, third and fourth stages of fresh water portions 4, 5, 6, and 7 absorbs the seawater of the seawater supply portion 4c with surface tension, .

The steam generated in the seawater storage tank 2 using the solar heat is condensed on the entire surface of the steel plate 4b of the first stage fresh water portion 4. The latent heat of condensation generated at this time is transferred to the steel plate 4b to evaporate water by heating seawater flowing in the wick 4a of the first stage fresh water section 4 so as to condense on the entire surface of the steel plate 4b of the adjacent second stage fresh water section 5 And the water droplets condensed on the entire surface of the steel plate 4b of the second stage fresh water section 5 can be recovered from the lower condensate pod 4d. Such an operation is sequentially repeated in the first, second, third, and fourth stage fresh water portions (4, 5, 6, 7) so that the condensation heat can be sequentially recovered.

However, although the above-described desalination apparatus using solar heat recovers the condensation heat to improve the production efficiency of fresh water, the solar heat is limited in proportion to the area, and there is a limit to the quantity of water that can vaporize the seawater. Therefore, in order to produce a larger amount of fresh water, the size of the entire facility, such as the cover (1) and the seawater reservoir (2), must be increased.

In addition, there is a problem that fresh water is hardly generated in a weather condition.

It is an object of the present invention to provide a desalination apparatus having a structure capable of improving fresh water production performance of a desalination apparatus using solar heat and effectively producing fresh water even in a bad weather condition .

According to an aspect of the present invention, there is provided a desalination apparatus including a solar power generation plate having a transparent window and having a water tank for receiving seawater therein, the solar water being introduced through a transparent window, A fresh water producing unit for collecting the condensed fresh water by evaporation; A heating unit for heating the water tank of the fresh water producing unit; And a photovoltaic power generation unit installed on the rear side of the fresh water production unit and generating solar power by supplying sunlight to the heating unit by sliding the solar power generation plate in the lateral direction of the fresh water production unit The photovoltaic power generation unit includes a fixed frame fixed to a rear surface of the fresh water producing unit, and a hinge shaft provided on the hinge shaft. The upper end of the photovoltaic power generation plate is hinged to be inclined upward A sliding frame accommodated in the stationary frame and protruding and retracting from the stationary frame in the lateral direction of the fresh water producing section by the sliding, both ends of the sliding frame being coupled to the lower surface of the solar- The photovoltaic panel cushioning the movement of the photovoltaic panel about the hinge axis, And a gas spring for limiting a range of inclination of the solar cell plate.

Further, in the present invention, the sliding frame may have a rectangular shape comprising a top horizontal frame, a bottom horizontal frame parallel to the top horizontal frame, and a side support frame connecting the top horizontal frame and the bottom horizontal frame from both sides, The lower horizontal frame is provided with an inclination angle adjusting screw extending in the longitudinal direction of the lower horizontal frame and an inclination angle adjusting motor for rotating the inclination adjusting screw. Wherein the gas spring is provided with two transfer blocks each of which is connected to both sides of the center of the inclined angle adjusting screw so that one end of the gas spring is coupled to the lower part of the sliding frame, Blocks, respectively, so that one end of the gas spring is rotated by the rotation of the inclination adjusting screw, The inclined angle of the photovoltaic power generation plate is changed by changing the position where the riding frame is coupled to the lower portion of the riding frame.

The present invention may further comprise a production power meter for measuring the power produced by the solar power generation plate and a controller for receiving the measured value of the production power meter and controlling the operation of the tilt angle adjustment motor, The inclination angle adjusting motor is operated so that the production electric power meter searches the inclination angle of the solar power generation plate having the highest measured value every set time so that the inclination angle of the solar power generation plate is changed according to the result As shown in FIG.

Further, the present invention is characterized in that the fixed frame is provided with a plurality of rollers for supporting the upper horizontal frame and the lower horizontal frame to slide the sliding frame, wherein the rollers support the upper horizontal frame, And is disposed further outward in the lateral direction of the fresh water producing section than the roller that supports the fresh water producing section.

The desalination apparatus equipped with the solar photovoltaic panel of the present invention as described above is equipped with a solar photovoltaic panel in which solar power can be generated in a conventional desalination apparatus for desalinating seawater by using solar heat, As a result, the production of fresh water can be significantly improved. In addition, since it is possible to supply the developed power to the seawater supply pump necessary for the seawater desalination apparatus, it is possible to construct a solar water seawater desalination plant capable of energy independence.

In addition, since the present invention can generate steam of seawater by using generated power generated even in a bad weather condition, production of fresh water can be more effectively performed, and fresh water can be produced at a power charged at night .

Further, the present invention provides a gas spring which is installed on a slide frame so as to be able to tilt the solar power generation plate and limits a range of inclination of the solar power generation plate, slides in a state in which the solar power generation plate is folded, It is very convenient to install and store the solar photovoltaic panel, and the inclined operation and installation of the solar photovoltaic panel can be stably performed by the gas spring.

The present invention further includes a production power meter and a controller for controlling the operation of the inclination angle adjusting motor upon receipt of the measured value so that the inclination angle of the solar power generator capable of producing the highest electric power can be detected and adjusted at each set time Bar and photovoltaic power generation can be performed with high efficiency, thereby improving the production efficiency of fresh water.

1 is a cross-sectional view of a conventional solar thermal desalination apparatus
Fig. 2 is a cross-sectional view showing the structure of the first stage fresh water portion of Fig. 1
3 is a perspective view showing the structure of a desalination apparatus having a solar photovoltaic panel according to an embodiment of the present invention.
4 is an explanatory view for explaining the operation of a desalination apparatus having a solar photovoltaic panel according to an embodiment of the present invention;
5 is a side sectional view showing a configuration of a desalination apparatus having a solar photovoltaic panel according to an embodiment of the present invention.
6 is a structural explanatory view showing a rear structure of a desalination apparatus having a solar photovoltaic panel according to an embodiment of the present invention
7 is a rear perspective view showing a state in which a solar photovoltaic panel is installed in a desalination apparatus having a solar photovoltaic panel according to an embodiment of the present invention.
8 is a rear perspective view showing a configuration of a desalination apparatus having a solar photovoltaic panel according to another embodiment of the present invention and a state in which a solar photovoltaic panel is installed.
9 is a rear perspective view showing an operating state of a desalination apparatus having a solar photovoltaic plate according to another embodiment of the present invention.
10 is a block diagram illustrating a control operation of a desalination apparatus having a solar photovoltaic plate according to another embodiment of the present invention
11 is a block flow diagram illustrating a control procedure of a desalination apparatus having a solar photovoltaic panel according to another embodiment of the present invention.
12 is a structural explanatory view for explaining the constructions of the fixed frame and the sliding frame in the desalination apparatus having the photovoltaic panel according to another embodiment of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described in detail with reference to the drawings.

3 to 6, a desalination apparatus having a solar photovoltaic panel according to an embodiment of the present invention includes a water tank 12 having a transparent window 11 and containing seawater therein, A fresh water producing unit 10 for collecting the condensed fresh water by evaporating seawater by solar heat flowing through the window 11, a heating unit 20 for heating the water tank 12 of the fresh water producing unit 10, The solar power generation plate 31 is slid and protruded in the lateral direction of the fresh water producing unit 10 so as to generate electric power by the sunlight and generate electric power for heating And a solar power generating unit 30 for supplying the solar power.

The freshwater producing unit 10 has a water tank 12 installed on the bottom surface of the freshwater producing unit 10 to receive seawater and a sloping transparent window 11 is installed on the front surface of the freshwater producing unit 10 so that solar heat is transferred to the inside.

The steam generated by the heating of the seawater by the solar heat is condensed on the inner surface of the transparent window 11 and condensed on the condensate pocketing 14 by flowing down along the inner surface thereof. .

The seawater of the water tank 12 is constantly supplied from the outside, thereby compensating for the amount lost by evaporation.

The heating unit 20 is a part for heating the water tank 12 of the fresh water producing unit 10 and includes a heat exchange pipe 21 installed in the water tank 12 and a heat transfer pin 23 And a heating device 27 provided outside the heating pipe 27 for supplying a heated fluid to the heat exchange pipe 21.

The heat exchange pipe 21 is installed in the water tank 12 so as to heat seawater of the water tank 12 independently of the solar heat transmitted through the transparent window 11.

The heat exchange pipe (21) heats seawater in the water tank (12) while fluid heated by electric power in the external heating device (27) flows inside. A heat transfer fin 23 is installed so that heat transfer from the heat exchange pipe 21 to the seawater can be more efficiently generated.

The heating pipe 27 and the heat exchange pipe 21 may be replaced by a heating pipe which is directly heated by electric power supplied from a solar power generating unit 30 to be described later.

The fresh water producing unit 10 is installed on a wheeled base plate 60.

On the other hand, the solar power generation unit 30 generates electric power by sunlight and supplies electric power for heating to the heating unit 20.

The photovoltaic power generation unit 30 includes a fixed frame 35 fixed to a rear surface of the fresh water producing unit 10 and a hinge shaft 31a provided at an upper portion thereof, A sliding frame (not shown) installed so that the photovoltaic plate 31 is lifted upward and inclined and is housed in the fixed frame 35 and protrudes and retracts from the fixed frame 35 in the lateral direction of the fresh water producing unit 10 by sliding Both ends of which are coupled to the rear surface of the solar photovoltaic plate 31 and the lower portion of the sliding frame 33 to buffer the movement of the solar photovoltaic plate 31 about the hinge axis 31a And a gas spring 36 for limiting the inclined range of the solar power generation plate 31 around the hinge axis 31a.

7, the stationary frame 35 is fixed to the rear surface of the fresh water producing unit 10 to house the solar power generation plate 31 and the sliding frame 33 on the rear surface of the fresh water producing unit 10.

The fixed frame 35 includes an upper guide bar 35a horizontally installed at the upper end of the rear surface of the fresh water producing unit 10 and a lower guide bar 35b horizontally installed at the lower end of the rear surface of the fresh water producing unit 10 .

A plurality of rollers 352 are provided on the inner side of the upper guide bar 35a and the lower guide bar 35b so that the sliding frame 33 is in rolling contact with the sliding frame 33 have.

The sliding frame 33 supports and supports the photovoltaic power generation plate 31 and slides along the fixed frame 35 so as to protrude and retreat in the lateral direction of the freshwater producing portion 10 from the rear surface of the freshwater producing portion 10.

The sliding frame 33 includes an upper horizontal frame 33a, a lower horizontal frame 33c parallel to the upper horizontal frame 33a, and upper and lower horizontal frames 33a and 33c on both sides And a side support frame 33b for connection.

The upper horizontal frame 33a and the lower horizontal frame 33c are received in the upper guide bar 35a and the lower guide bar 35b of the fixed frame 35 and are in rolling contact with the rollers 352 have.

The photovoltaic power generation plate 31 is a solar cell in which a plurality of conventional solar cells are arranged on a flat plate and generates electric power by sunlight and stores the electric power in an external storage battery 57, 20).

The upper part of the sliding frame 33 is hinged to an upper end of the hinge shaft 31a of the upper horizontal frame 33a so that the upper part of the sliding frame 33 can be inclined upward .

The hinge shaft 31a is a shaft extending in a direction in which the sliding frame 33 slides and in which the sliding frame 33 slides sideways of the fresh water producing portion 10 and projects therefrom, The photovoltaic plate 31 can be inclined by turning.

The gas spring 36 is a mechanical part that acts as a spring by acting as a repulsive load to change the pressure of the internal nitrogen gas in accordance with the stroke (compression displacement) of the rod 361.

Both ends are coupled to the rear surface of the solar photovoltaic plate 31 and the lower portion of the sliding frame 33 to buffer the photovoltaic power generation plate 31 at the time of turning around the hinge axis 31a Thereby alleviating the speed of the turning movement.

The inclination of the solar cell plate 31 is allowed to be the maximum length of the rod 361 of the gas spring 36 so that the inclination of the solar cell plate 31 with respect to the hinge axis 31a The range is limited. Therefore, the maximum inclination angle of the solar cell plate 31 is determined according to the elongation length of the gas spring 36.

The desalination apparatus having the solar photovoltaic plate 31 constructed as described above can be installed toward the south and desalinate seawater in the fresh water producing unit 10 using solar heat.

In order to increase the desalination efficiency by using the solar photovoltaic plate 31, the photovoltaic panel 31 and the sliding frame 33 are slid from the stationary frame 35 to the side of the fresh water production section 10 And the solar cell plate 31 is exposed.

When the lower end of the solar photovoltaic plate 31 is lifted as shown in Fig. 7 in a state in which the sliding frame 33 has escaped from the stationary frame 35, the gas spring 36 is extended and the solar photovoltaic power generation plate 31 The gas spring 36 can be rotated until the gas spring 36 is fully elongated by turning slowly around the hinge shaft 31a.

As shown in FIG. 7, the photovoltaic power generation plate 31 in which the gas spring 36 is fully extended generates sunlight in an inclined state, and the generated power is stored in the storage battery 57, Or directly supplied to the heating device 27 without passing through the storage battery 57. In the heating device 27,

The solar cell plate 31 is rotated about the upper hinge axis 31a to shrink the gas spring 36 and the solar cell plate 31 is slid When the frame 33 is pushed into the stationary frame 35, the state in which the photovoltaic panel 31 is slid on the rear surface of the fresh water producing unit 10 in a state in which the gas spring 36 is contracted as shown in Fig. 6 .

Meanwhile, a desalination apparatus having a solar photovoltaic plate 31 according to another embodiment of the present invention will be described.

Referring to FIG. 8, in the desalination apparatus of this embodiment, the inclined angle of the solar power generation plate 31 is adjusted by changing the position where the lower end of the gas spring 36 is engaged with the sliding frame 33. The inclination angle of such a solar power generation plate 31 needs to be changed according to the latitude of the installation area and the sun altitude according to the timing.

An inclination angle adjusting screw 37 extending in the longitudinal direction of the lower horizontal frame 33c and an inclination angle adjusting motor 38 for rotating the inclination angle adjusting screw 37 are installed in the lower horizontal frame 33c in this embodiment do.

The inclination angle adjusting screw 37 is formed with a spiral for conveying the conveying block 371 by its rotation, and the spiral direction of both sides is reversed with respect to the center portion thereof.

An inclination angle adjusting motor 38 is provided at the lower end horizontal frame 33c of the sliding frame 33 at the center of the inclination angle adjusting screw 37 to rotate the inclination angle adjusting screw 37, Two transfer blocks 371 are provided on both sides of the transfer block 371, respectively.

Accordingly, when the inclination angle adjusting motor 38 rotates the inclination angle adjusting screw 37, the conveying blocks 371 on both sides are conveyed in the direction in which the conveying blocks 371 are assembled to each other or are moved away from each other.

One end of the gas spring 36 coupled to the lower part of the sliding frame 33 is coupled to the two transport blocks 371 and the other end of the gas spring 36 is connected to the other end And is coupled to the rear surface of the solar cell plate 31. The two gas springs 36 are installed symmetrically with respect to the center of the inclination angle adjusting screw 37.

According to the above-described configuration, when the inclination angle adjusting screw 37 rotates, the position where one end of the gas spring 36 coupled to the transport block 371 is engaged with the lower portion of the sliding frame 33 is changed, The inclined angle of the solar power generation plate 31 is changed because the solar power generation plate 31 is pulled or pushed as the engagement position of the gas spring 36 having a constant length moves.

9 shows a state in which the inclination angle adjusting motor 38 rotates the inclination angle adjusting screw 37 to transfer the conveying block 371 to the central portion to lower the inclined angle by lowering the solar power generation plate 31. [

9, both ends of the gas spring 36 are installed via two hinge shafts 361b, 361c, 362b, and 362c, which are orthogonal to each other, so that the gas spring 36 can be tilted freely. The two hinge shafts 361b, 361c (362b, 362c) orthogonal to each other freely tilt the joining portions at both ends of the gas spring (36).

In this embodiment, the production power meter 52 for measuring the power produced by the solar power generation plate 31, the operation of the tilt angle adjustment motor 38 by receiving the measurement value of the production power meter 52, And a controller (50) for controlling the controller (50).

The production power meter 52 is connected to a transmission line of the solar power generation plate 31 as a normal power system to measure the power produced by the solar power generation plate 31.

Referring to FIGS. 10 and 11, the controller 50 receives the measured value of the production power meter 52 and controls the operation of the tilt angle adjusting motor 38. More specifically, the inclination angle adjusting motor 38 is operated so that the production power meter 52 searches the inclination angle of the solar power generation plate 31 having the highest measured value every set time, And controls the operation of the tilt angle adjusting motor 38 so that the tilt angle of the tilt angle adjusting motor 31 is changed.

Referring to FIG. 11, the controller 50 searches every one hour to adjust the inclination angle of the solar power generation plate 31 to adjust the inclination angle.

First, the controller 50 changes the set amount of the inclination angle of the solar photovoltaic plate 31 (Step S20) when one hour has elapsed from the start time (Step S10). Is the magnitude of the inclination angle that is changed when the rotation amount is 5 revolutions.

After the inclination angle of the solar power generation plate 31 is changed, the production power measuring instrument 52 measures the electric power and transmits it to the controller 50 (Step S30). The controller 50 controls the operation of the solar power generation plate 31 It is determined whether the measured number of times of electric power measurement by the production electric power meter 52 is counted, for example, six times, while changing the inclination angle (step S40)

The angle of inclination of the solar cell plate 31 is changed by changing the inclination angle adjusting screw 37 to the set amount (the inclination angle adjusting screw is rotated 5 times), and the production power is measured. Such a process is repeated until the number of power measurement times is six, which is the set number of times.

After the power measurement is performed six times, which is the set number of times, the controller 50 changes the photovoltaic power generation plate 31 at the tilt angle at which the maximum production power is measured among the six times of the power measurement (Step S50)

The above-described operation is repeated every one hour, so that the state in which the inclination angle of the solar cell plate 31 is automatically adjusted with the elapse of time and the electric power is maximized can be maintained until the sunset. That is, since the altitude of the sun changes with time, the solar power generation plate 31 is changed according to the altitude of the sun.

12 shows another embodiment of the structure of the fixed frame 35 and the sliding frame 33. The fixed frame 35 includes an upper horizontal frame 33a and a lower horizontal frame 33c, And a roller 352 for supporting the lower horizontal frame 33c is disposed on the downstream side of the roller 352 supporting the upper horizontal frame 33a, (Reference numerals 352a and 352b) in the lateral direction of the main body 10.

In such a configuration, since the fixed frame 35 is difficult to support the sliding frame 33 due to the load of the solar power generation plate 31 and the sliding frame 33, the lower guide bar 35b So that the sliding frame 33 can be supported by the rollers 352 from the lower side.

It is preferable that at least two rollers 352a and 352b support the sliding frame 33 in the lower guide bar 35b in a state where the sliding frame 33 is maximally slid to the outside, It is preferable that the support roller 355 pushes the sliding frame 33 upward from the upper guide bar 35a in a state where the support frame 352a and 352b support the sliding frame 33. [ This is for the purpose of stably supporting the load of the sliding frame 33 by the fixed frame 35.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limited to the particular embodiments set forth herein. It goes without saying that other modified embodiments are possible.

10; Fresh water production section 11; Transparent window
12; Aquarium 20; Heating section
21; A heat exchange pipe 23; Heat transfer pin
27; A heating device 30; Solar power generation department
31; A solar power generation plate 31a; Hinge axis
33; A sliding frame 33a; Upper horizontal frame
33c; A lower horizontal frame 33b; Side support frame
35; Fixed frame 35a; Upper guide bar
35b; A lower guide bar 352; roller
36; A gas spring 37; Angle adjustment screw
38; An inclination angle adjusting motor 371; Transfer block
50; A controller 52; Production power meter
57; Battery 60; Base plate

Claims (4)

A fresh water producing unit 10 having a transparent window 11 and a water tank 12 for receiving seawater therein and collecting the condensed fresh water by evaporating the seawater by solar heat introduced through the transparent window 11, ;
A heating unit 20 for heating the water tank 12 of the fresh water producing unit 10; And
The solar power generation plate 31 is slid in the lateral direction of the fresh water producing unit 10 and protrudes so as to generate electric power by the sunlight and to be supplied to the heating unit 20 And a photovoltaic power generation unit (30) for supplying power for heat generation,
The solar power generation unit 30
A fixed frame 35 fixed to a rear surface of the fresh water producing unit 10,
The upper end of the photovoltaic power generation plate 31 is hinged to the hinge axis 31a provided at the upper part so that the photovoltaic generation plate 31 can be inclined upwardly, A sliding frame (33) accommodated and protruded from the fixed frame (35) in the lateral direction of the fresh water producing part (10) by the sliding,
Both ends of the solar power generation plate 31 are coupled to the rear surface of the solar power generation plate 31 and the lower portion of the sliding frame 33 to buffer movement of the solar power generation plate 31 about the hinge axis 31a, And a gas spring (36) for restricting the inclined range of the solar power generation plate (31) around the hinge axis (31a)
The sliding frame 33 includes an upper horizontal frame 33a, a lower horizontal frame 33c parallel to the upper horizontal frame 33a, and upper and lower horizontal frames 33a and 33c, And a side support frame 33b connected to the side support frame 33b.
In the lower horizontal frame 33c,
An inclination angle adjusting screw 37 extending in the longitudinal direction of the lower horizontal frame 33c,
An inclination angle adjusting motor 38 for rotating the inclination angle adjusting screw 37,
The inclination angle adjusting screw 37 has opposite spiral directions with respect to the center portion thereof,
The inclination angle adjusting screw 37 is provided with two conveying blocks 371 which are coupled to both sides of the inclination angle adjusting screw 37,
One end of the gas spring 36 coupled to the lower portion of the sliding frame 33 is coupled to the transport block 371,
The inclination angle of the solar power generation plate 31 is changed by changing the position where one end of the gas spring 36 is coupled to the lower portion of the sliding frame 33 by the rotation of the inclination angle adjusting screw 37 A desalination apparatus having a solar photovoltaic panel The method according to claim 1,
A production power meter 52 for measuring the power produced by the solar power generation plate 31,
Further comprising a controller (50) that receives the measurement value of the production power meter (52) and controls the operation of the tilt angle adjusting motor (38)
The controller (50)
The inclination angle adjusting motor 38 is operated so that the production power meter 52 searches the inclination angle of the solar power generation plate 31 having the highest measured value every set time, 31) is controlled by controlling the operation of the inclination angle adjusting motor (38) so that the inclination angle of the inclined angle adjusting motor 3. The method according to claim 1 or 2,
The fixed frame 35 is provided with a plurality of rollers 352 for supporting the upper horizontal frame 33a and the lower horizontal frame 33c to slide the sliding frame 33,
The rollers 352 are arranged such that the rollers 352 supporting the lower horizontal frame 33c are disposed further outward in the lateral direction of the fresh water producing portion 10 than the rollers 352 supporting the upper horizontal frame 33a A desalination apparatus having a solar photovoltaic panel delete

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