KR20000018236A - Tracking Solor Heater - Google Patents

Abstract

PURPOSE: A hot water supplier tracing solar heat is provided to reduce the cost for fuel by producing hot water using solar heat. CONSTITUTION: A motor rotates in the adjustment focus for 7-8 seconds if sunlight is irradiated into a 12th lens, a concave lens rotates in the direction of 1, and the focus is sent out of the adjustment focus. And the motor is in the middle while rotating for 7-8 seconds in the adjustment focus. The motor moves to the center while rotating for 7-8 seconds if the sunlight is shed the right adjustment focus after 10 minutes suspension in the center. So the motor is in the middle all the time and the distance of focusing is 24.5cm. And the time for the movement by 1cm of the focus is about 10 minutes. Therefore, the concave lens traces the sunlight left, right, up and down by making the concave lens move by each 1cm within 7-8 seconds by using a left and right rotation low speed motor. Otherwise, the concave lens traces the sunlight every 5 minutes if the distance of focusing is shortened by 5mm.

Description

Solar Tracking Water Heater {Tracking Solor Heater}

As shown in [Fig. 9], when the sun shines with the convex lens, the focus is made at a distance of 24.5 cm, and the focus light takes about 10 minutes to move. As the picture shows, when the sun rises from the center of the sun, the light comes into focus, the bimetal moves, the electricity comes in, the motor moves up, and the light goes out, which takes about 7-8 seconds. In addition, the light that comes out of the center within 90 degrees is sent out of the organizing focus, so it is sent from the organizing focus to the center so that the sun is always in the center.

In FIG. 10, when light enters the lens within 180 degrees on the left side, for example, when the light enters the lens side 12, the motor rotates for 7 to 8 seconds at the theorem while focusing out of the theorem. In addition, if you have 10 minutes from the center, on the contrary, if you focus on the right theorem, you will go to the center by turning for 7-8 seconds and you will always be at the center. Sunlight is always moving to the right. 9cm convex lens is a square and the focusing distance is 24.5cm, and the focusing time is 1cm. The moving time is about 10 minutes. I run right, up, down.

Also, with 5mm, you can narrow the focus and focus distance to follow the sun every 5 minutes.

If you follow the sun exactly as shown in Fig. 1 and install a radiator that has a 50cm width of the circle in the focus of the concave lens, the hot air does not go out, and follows the sun exactly all day and produces hot water more than 80 degrees a day. If only 1000 liters of water is produced, it can be used for heating boilers for general households, and for various kinds of bathing waters and for various insulations in farming and fishing villages, especially for reducing oil prices and fuel costs.

I went to the Office of Patent Office to find hot water by following the sun every 5 to 10 minutes and heating the radiator with that heat. Gangnam Sola has good sunlight and can produce hot water at noon and produces hot water at night by using electricity at night. Compared to the present invention, the hot water can be produced more than five times.

The present invention always moves to the place where the sun is visible only when the sun is visible and looks exactly at the sun with a concave lens of 4 cm in diameter, and when the sun moves up, down, left and right, it immediately follows the sun and focuses on the concave lens. A radiator with a diameter of 50 cm can be installed, and the focal temperature can be used to produce more than 1000 liters of water of 80 degrees or more per day if the sun is needed. But how exactly do you follow the sun? To solve the technical problem and to make the invention.

1 is a side view of the overall model of the solar tracker of 4m diameter

2 is a front view of a solar tracker of 4m in diameter

Figure 3 shows a 9cm circular convex lens with a 7cm square convex lens to determine the focal length is 24.5cm, the left, right, up and down focus and the focal length is 7cm, the position where the focus moves After finding the exact position of the straight line with an error of about 0.5cm, and then finding a spot where two or more focal points come in. Also, the focal point is located and the focal point is arranged. [See Fig. 6] Here, the focus comes first and the first This is where the correct focus comes later. You can also control the focus in and out by 90 degrees up and down and 180 degrees left and right.

Figure 4 A is the width position of the top and bottom when bimetal 9cm.

Fig. 4B is a diagram in which a 9 cm convex lens is 4 cm 7 cm

[Fig 5] is a bimetal attached to the iron plate that does not stretch to the heat bent to one side when the heat is applied to the length of 0.8mm thick bimetal under the width of 3mm to lengthen the focal point to hold the focus, and also to lengthen the bimetal, When I put them in the position of the focus, I straighten them so that the upper part is like the top and the lower part is like the bottom, and there are 97 bimetals with a width of 3mm.

FIG. 6 is a bimetal bonded to the welding position as shown in FIG. 5 and assembled in the shape as shown in FIG. 4, and the position of the focal point is also drawn. There is graphite at the lower end and at the upper end, and the graphite is cut into 2cm in the straight part of the straight line in the straight part, and the reason for using graphite is that the lead is in contact with graphite because the bimetal end is made of lead. When it is sparked, electricity will pass through, but it will not pour into graphite even if lead melts. If lead and graphite have the shape as shown in the 5mm figure, two or more focal points within 180 degrees left and right and 90 degrees above and below will heat the bimetal to the focal temperature, causing the bimetal to bend and contact the graphite.

[Fig. 7], as shown in [Fig. 3], when the focus comes in, the error is about 5mm and finds the position of the straight line in the focusing point, and it can be seen that two or more focal points come in the shape of the straight line.

There is a theorem focusing, when the sunlight comes in from the sixth convex lens side, the sunlight comes in from the five convex lens side and two focal points act as bimetals as shown in [Fig. 8]. If you turn it toward, the first focus will focus on the theorem, and the motor will turn on in the theorem, so the focus goes out and there is no focus in the bimetal.

So when the focal point is in the bimetal, it goes out through the final clearance focus, and the time taken for the final clearance focus point to drop is 0.6-7 seconds.

FIG. 8 is easily expanded to FIG. 7.

9 is an explanatory diagram of a vertical solar tracker.

The sun is supposed to be at the center line. When the sun's light rises 1cm above the convex lens, the confocal lens comes into focus. As the lens focus goes up, the motor stops and the sun is at the centerline. Several bimetals act as a point when the sun shines. For example, when the motor rotates and the focal point passes, for example, when the focal point enters the lower 6, the motor rotates downward and the focal point from the convex lens 1 reflects the focus. You're on the centerline, going below the focus, so you're only on the top and bottom centerlines.

Figure 10 is a principle diagram that can move to the center of the center where the sun was right where the sun was left or right.

[Fig. 11] The picture made [Fig. 7]

Pictures that have made [Figure 9]

[Fig. 12] The picture made [Fig. 6]

Pictures that have been made [Figure 10]

If the present invention can mass produce hot water with solar heat, there is now Gangnam Solar. The heat set device is a fixed flat plate and can produce 400ℓ of water about 60 degrees a day, and can produce water over 80 degrees with 1000 liters of solar heat. If there is a concave lens, the focal temperature is on fire. If you make a large concave lens and follow the sun all day and produce hot water, it will produce more than 80 degrees and 1000 liters. How do you follow the sun exactly? After much thought, I invented this device.

If the production of the present invention to produce hot water of more than 80 degrees 1000 liters per day, the boiler will be replaced by this water without fuel in all households, I think it will be used a lot in farms.

This will result in fuel savings in our homes as well as fuel savings unimaginable nationwide.

Claims (1)

[Fig. 9] Move to the top and bottom center (See Fig. 11) [Fig. 10] Follow the sunlight in the left and right 360 degrees at intervals of 5 to 10 minutes, using the concave lens focal temperature as shown in [Fig. 1], solar tracking water heater (see [Fig. 12] photo)