KR101229742B1 - Solar energy boiler - Google Patents

Abstract

The present invention is to obtain a heat-collecting solar boiler that can collect the sunlight to the heat collecting plate to concentrate heat and quickly obtain hot water of high temperature by using a heat exchanger,
A support fixed to the floor;
A position tracking device installed on the support and formed to rotate up, down, left and right according to the position of the sun; Cradles installed on both sides of the position tracking device; A plurality of heat collecting plates installed in front of the two side holders and formed concave; A plurality of heat exchangers installed in front of each heat collecting plate and configured to heat and discharge water supplied to the inside by receiving solar heat; And a tank configured to circulate water to each of the heat exchangers by using a pump, and to store hot water circulated from each heat exchanger to supply water.

Description

Collective solar boiler {Solar energy boiler}

The present invention relates to a heat-collecting solar boiler that collects sunlight into a heat collecting plate to concentrate heat and to quickly obtain hot water of high temperature by using a heat exchanger.

In general, the solar boiler is fixed on the roof or roof as a flat plate with a vacuum tube installed.

Such solar boilers are forced to utilize low temperature heat due to their structural characteristics, and thermal efficiency is further reduced due to limitations of heat exchangers, storage tanks, fruits, and the like, and thus, they do not help much in real life.

The present invention is to solve the conventional problem that it is difficult to heat the hot water obtained by using a conventional solar boiler to an appropriate temperature, and delayed a lot of time to obtain hot water.

Heat-collecting solar boiler of the present invention is a support fixed to the bottom; A position tracking device installed on the support and formed to rotate up, down, left and right according to the position of the sun; Cradles installed on both sides of the position tracking device; A plurality of heat collecting plates installed in front of the two side holders and formed concave; A plurality of heat exchangers installed in front of each heat collecting plate and configured to heat and discharge water supplied to the inside by receiving solar heat; And a tank configured to circulate water to each of the heat exchangers by using a pump, and to store hot water circulated from each heat exchanger and supply the water to the water.

The location tracking device is coupled to the upper end of the motor box is installed to rotate left and right; A frame coupled to both sides of the upper portion of the motor box to rotate back and forth; A cylinder connected between the motor box and the frame and installed to rotate the frame back and forth; And a sensor installed at an upper portion of the frame to sense the position of the sun and to control the operation of the motor box and the cylinder.

The heat exchange device includes a housing having a dual structure in which a vacuum space is formed between inner and outer surfaces; A partition plate installed inside the housing and partitioning an internal space forward and backward while blocking a circulation of water forward; A heating element coupled through the partition plate and heated by receiving solar heat reflected by the heat collecting plate in front of the partition plate; And a circulation pipe connected to the rear of the housing to supply and discharge water.

And a heat dissipation fin coupled to an outer surface of the heating element located behind the partition plate and configured to discharge heat into the circulating water.

And a position correction device for adjusting an installation angle and a distance between the heat collecting plate and the heat exchanger.

The position correction device includes a lever installed to engage the heat exchanger in front of the heat collecting plate through the center of the heat collecting plate from the rear of the cradle; A case located behind the cradle and formed such that the lever is fitted therethrough; A shock absorber installed between the holder and the case; Distance adjustment bolt is installed so that the end is in close contact with the outer surface of the lever in the state fastened through the outer surface of the case; And an angle adjusting bolt installed to adjust the up, down, left, and right angles of the lever by compressing the shock absorber in a state of being penetrated through the holder and the case.

A wind power generator installed at an upper end of the holder and generating power while rotating by wind; And a power supply device configured to charge electricity obtained by the wind power generator and to use the power of the position tracking device.

According to the heat-collecting type solar boiler of the present invention, it is possible to obtain hot water at a high temperature through the heat collecting plate and the heat exchanger, and thus it is possible to supply hot water at a high temperature smoothly, which is useful in real life.

According to the heat collecting solar boiler of the present invention, the position tracking device is formed to rotate along the movement path of the sun, so that the optimal heat collecting is always achieved through the heat collecting plate.

According to the heat-collecting type solar boiler of the present invention, by adjusting the angle and the distance between the heat exchanger and the heat collecting plate by using the position correction device, the effect of easily correcting the error occurring between the heat exchanger and the heat collecting plate is effective. have.

According to the heat-collecting solar boiler of the present invention by charging the electricity using a wind power generator at night and by supplying the power required to drive the position tracking device through a power supply, it is possible to solve the power itself have.

1 is a front perspective view showing a heat collecting solar boiler to which the present invention is applied.
Figure 2 is a rear perspective view showing a heat collecting solar boiler to which the present invention is applied.
Figure 3 is a side cross-sectional view showing an operating state of the position tracking device to which the present invention is applied.
Figure 4 is a partially cutaway exploded perspective view showing a heat exchanger device to which the present invention is applied.
Figure 5 is a plan sectional view showing a heat exchanger device to which the present invention is applied.
Figure 6 is an exploded perspective view showing a position correction device to which the present invention is applied.
Figure 7 and Figure 8 is a side cross-sectional view showing an operating state of the position correction device to which the present invention is applied.
9 and 10 are perspective views showing another embodiment of a heat collecting solar boiler to which the present invention is applied.

Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings.

According to the heat collecting solar boiler of the present invention, as shown in FIGS. 1 to 9, the support 100 is fixedly installed on the floor, the location tracking device 200 installed on the support top, and both sides of the location tracking device. It includes a cradle 300 to be installed, a heat collecting plate 400 installed in front of the both sides of the holder, a heat exchanger 500 installed in front of each heat collecting plate and a tank 600 for circulating water to each of the heat exchangers do.

The support 100 is to be fixed to the floor, as shown in Figure 1 and 2, a flange is formed on the bottom edge, it can be fixed to the floor or a separate fixture with an anchor bolt.

In case of using the separate fixture, it can be easily installed and used in a camping ground or an event venue.

The position tracking device 200 is installed on the support, and is formed to rotate up, down, left and right according to the position of the sun.

As an embodiment of the position tracking device 200 as shown in Figure 3 motor box 210 to rotate left and right, the frame 220 to rotate up and down and the cylinder 230 and the motor box 210 and It may be configured as a sensor 240 for controlling the operation of the cylinder 230.

The motor box 210 is coupled to the upper end of the support 100 to be installed to rotate left and right, and thus a detailed description and drawings will be omitted since it is a conventional technology composed of a motor and a gear.

The frame 220 is to be coupled to both sides of the upper side of the motor box 210 is installed to rotate back and forth, so that the cradle 300 is coupled to both sides.

The cylinder 230 is connected between the motor box 210 and the frame 220 is installed to rotate the frame 220 back and forth through the front and rear operation.

The sensor 240 is installed on the frame 220 to sense the position of the sun, and is formed to control the operation of the motor box 210 and the cylinder 230.

The cradle 300 is installed on both sides of the location tracking device 200, for example, is coupled to the frame 220 of the location tracking device 200 as shown in FIG. For example, the holder 300 is configured to include a circular frame formed to install the heat collecting plate 400 together with the cross bars and vertical bars installed on both sides as shown in FIGS. 1 to 3.

The heat collecting plate 400 is installed in front of the both sides of the holder 300, it is formed concave, as shown in Figures 1 to 3 are provided with a plurality. The heat collecting plate 400 is formed in the form of an umbrella or parabola, for example, in order to concentrate a lot of heat at one point ahead. The surface of the heat collecting plate 400 may be coated with silver to increase the efficiency of heat collection.

The heat exchanger 500 is installed in front of each of the heat collecting plates 400, and is formed to heat and discharge water supplied to the inside by receiving solar heat, and a plurality of heat exchangers 500 are provided as illustrated in FIGS. 1 to 3.

As an example of the heat exchanger 500, as illustrated in FIGS. 4 and 5, a housing 510 having a dual structure, a partition plate 520 partitioning the interior of the housing forward and backward, and a heating element coupled to the partition plate. 530 and a circulation pipe 540 for circulating water behind the housing.

The housing 510 is formed in a double structure in which a vacuum space is formed between inner and outer surfaces so that the heat reflected from the heat collecting plate 400 can be stored in the vacuum space to heat the inside at a higher temperature. The housing 510 may be formed of a transparent material.

The partition plate 520 is installed inside the housing 510 and is formed to block the circulation of water forward while partitioning an inner space forward and backward. That is, in front of the heat is reflected through the air to be better transmitted to the heating element 530.

The heating element 530 is coupled to penetrate through the partition plate 520 and is heated by receiving solar heat reflected by the heat collecting plate 400 from the front of the partition plate 520. That is, it is heated by receiving solar heat from the front, and the heated temperature is transmitted to the rear to warm the circulating water. The heating element 530 is a gas or liquid fruit is stored in a sealed tube made of copper material, when the heat is heated on the surface of the copper material, the inside of the fruit becomes hot and dissipates heat to the surroundings because it is a conventional technology Description and drawings are omitted.

The circulation tube 540 is connected to the rear of the housing 510 to supply and discharge water. The circulation pipe 540 is connected to the tank 600 and the pump 610 described above.

On the other hand, a plurality of heat dissipation fins 550 are coupled to an outer surface of the heating element 530 positioned behind the partition plate 520. The heat dissipation fin 550 allows the heat generated from the heat generating element 530 to more smoothly discharge heat to the surrounding water.

The tank 600 is formed to circulate water to each of the heat exchangers 500 by using the pump 610, and to store hot water circulated from each heat exchanger 500 to supply water.

As illustrated in FIG. 3, the tank 600 circulates cold water supplied from the tap water to each of the heat exchangers 500 using a pump 610, and is discharged from the heat exchangers 500. Water is stored so that it can be used as water.

As described above, the present invention includes a position correction device 700 for adjusting an installation angle and a distance between the heat collecting plate 400 and the heat exchanger 500.

As shown in FIGS. 1 to 3 and 6 to 8, as shown in FIGS. 1 to 3 and 6 to 8, the lever 710 is installed to couple the heat exchanger while being installed through the center of the heat collecting plate. Case 720 located behind the cradle, the shock absorber 730 is installed between the cradle and the housing, the distance adjusting bolt 740 is installed to secure the lever through the outer surface of the housing and the cradle and the housing It consists of an angle adjustment bolt 750 which is installed to adjust the angle of up, down, left and right through the lever.

The lever 710 is installed to pass through the center of the heat collecting plate 400 from the rear of the holder 300 to couple the heat exchanger 500 in front of the heat collecting plate 400. In addition, the lever 710 is formed in the form of a pipe, it can be protected from being melted by the heat passing through the circulation pipe 540 of the heat exchange device 500 therein.

The case 720 is formed at the rear of the cradle 300 so that the lever 710 is inserted therethrough. At this time, the case 720 is to be formed so that the lever 710 is installed to move freely in a certain angle range.

The shock absorber 730 is installed between the holder 300 and the case 720, and is formed in the form of a coil spring. In this case, the shock absorber 730 may be formed of a plurality of pieces installed along the edge of the case 720 or one having the same diameter as the case 720.

The end of the distance adjusting bolt 740 is fastened to be in close contact with the outer surface of the lever 710 in a fastened state through the outer surface of the case 720 is installed. Therefore, the distance adjusting bolt 740 should be composed of two or more.

The angle adjusting bolt 750 is installed to adjust the up, down, left and right angles of the lever 710 by compressing the shock absorber 730 in the state of being fastened between the cradle 300 and the case 720. The angle adjusting bolt 750 is free to adjust the angle should be installed in at least three directions along the edge of the case (720).

As another exemplary embodiment of the present invention, as shown in FIGS. 9 and 10, power is generated by itself to supply power for driving the position tracking device 200.

To this end, the top of the cradle 300 is installed on both sides or the center of the wind power generator 800 that is generated by rotating by the wind, by charging the electricity obtained by the wind power generator 800 by the position tracking device ( A power supply 900 formed for use with power of 200 should be installed. The power supply device 900 may be fixedly installed, for example, on the support 100.

According to the present invention having such a configuration it is possible to obtain a high temperature hot water through the heat collecting plate 400 and the heat exchanger 500, it is possible to smoothly supply high temperature hot water can be useful in real life.

In addition, by forming to rotate along the movement path of the sun by the position tracking device 200, it is possible to increase the thermal efficiency because the optimal heat collecting is always made through the heat collecting plate (400).

In addition, by adjusting the angle and the distance between the heat exchanger 500 and the heat collecting plate 400 using the position correction device 700, an error occurring between the heat exchanger 500 and the heat collecting plate 400. Can be easily corrected.

In addition, by charging the power through the wind power generator 800 and the power supply device 900 it is possible to supply the power required to drive the position tracking device 200 itself.

100: Support
200: location tracking device 210: motor box
220: frame 230: cylinder
240: sensor
300: stand
400: heat collecting plate
500: heat exchanger 510: housing
520: partition plate 530: heating element
540: circulation tube 550: heat radiation fin
600: tank 610: pump
700: position correction device 710: lever
720: case 730: shover
740: distance adjustment bolt 750: angle adjustment bolt
800: wind turbine
900: power supply

Claims (7)

A support fixed to the floor;
A position tracking device installed on the support and formed to rotate up, down, left and right according to the position of the sun;
Cradles installed on both sides of the position tracking device;
A plurality of heat collecting plates installed in front of the two side holders and formed concave;
It is installed in front of each of the heat collecting plate, is formed to heat and discharge the water supplied to the inside by receiving solar heat, and a double structure housing having a vacuum space formed between the inner and outer surfaces, and installed inside the housing, the inner space in front A partition plate which blocks the circulation of water forward while being partitioned to the rear and rear, a heating element which is coupled through the partition plate and heated by the solar heat reflected by the heat collection plate in front of the partition plate, and rearwards inside the housing. A heat exchanger device connected to the circulation pipe for supplying and discharging water; And
And a tank configured to circulate water to each of the heat exchangers by using a pump, and to store hot water circulated from each heat exchanger and supply the water to the heat exchangers.
delete delete The heat-collecting solar boiler according to claim 1, further comprising a heat dissipation fin coupled to an outer surface of the heating element located behind the partition plate and configured to discharge heat into the circulating water.
The heat collecting type solar boiler according to claim 1, wherein a position correcting device for adjusting an installation angle and a distance between the heat collecting plate and the heat exchanger is configured.
The method of claim 5, wherein the position correction device,
A lever installed to couple the heat exchanger in front of the heat collecting plate through the center of the heat collecting plate from the rear of the holder;
A case located behind the cradle and formed such that the lever is fitted therethrough;
A shock absorber installed between the holder and the case;
Distance adjustment bolt is installed so that the end is in close contact with the outer surface of the lever in the state fastened through the outer surface of the case; And
And an angle adjusting bolt installed to adjust the upper, lower, left, and right angles of the lever by compressing the shock absorber in the fastened state between the holder and the case.
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