KR200446862Y1 - Solar altimeter - Google Patents

Abstract

The present invention relates to a solar altimeter, and more particularly, to a solar altimeter that allows students to easily grasp the change in the position of the sun over the season and time by measuring the altitude and direction of the sun.

According to the present invention, students can actually experience the change of the position of the sun according to the change of season or time while measuring the altitude of the sun directly, and the sunlight coming in through the entrance hole using an open-sided cylindrical tube with one side open By adjusting it to reach the center of the opposite side, it is easy to match the direction of the barrel and sunlight.

Compass, solar, altitude, bearing, solar cell

Description

Solar altimeter {SOLAR ALTIMETER}

1 is an exemplary view showing a method of measuring the altitude of the conventional sun.

Figure 2 is a perspective view showing the structure of the solar altimeter according to an embodiment of the present invention.

Figure 3 is an exploded perspective view showing the structure of the barrel.

4 is an exemplary view showing a state of measuring the azimuth angle of the sun.

5 is an exemplary view showing a state of measuring the altitude of the sun.

** Description of Signs for Main Parts of Drawings **

100: solar altimeter 102: table 104: support

106: compass 108: solar cell 110: bearing plate

112: direction indicator 114: altitude plate 116: goniometer

118: barrel

The present invention relates to a solar altimeter, and more particularly, to a solar altimeter that allows students to easily grasp the change in the position of the sun according to season and time by measuring the altitude and direction of the sun.

The 7th elementary school curriculum aims to `` acquire basic science concepts and basic science concepts, and develop proper scientific attitudes. '' To do this, it is important for students to understand the basic concepts of science and to develop scientific inquiry skills. In particular, elementary school science learning aims to have an interest and curiosity in natural phenomena and objects through observation and experience of nature, to understand basic concepts of science, and to learn to explore and to have a correct view of nature. It is explicit.

In other words, science learning should prioritize natural phenomena and objects, rather than understanding concepts, and study instruction should be made to understand basic concepts and to have a correct view of nature through inquiry.

However, in the school field, there is a lack of materials and textbook-oriented classes that students can directly manipulate and explore.

Usually, there are many kinds of scientific instruments installed in elementary school, which students use for observation and observation. Among them, a solar altitude meter is installed, and a student often finds a mistake in solar altitude measurement. The most common thing is that you have to look at the sun with your lens attached to it and try to observe it upside down, and the altitude measurement of the sun is wrong. Second, it's hard to see the sun through a small hole.

Figure 1 is an exemplary view showing a conventional method for measuring the altitude of the sun, the contents described in the actual science textbook 4th semester 2 semester. This is difficult to map because there are many inconveniences and problems in measuring the altitude of the sun based on the conceptual understanding of light and shadow when changing seasons.

Typically, students measure the sun's altitude by aligning the protractor's center with the thread and the shadow's end, with the end of the bar and the shadow end threaded together.

However, when measuring the altitude of the sun using this method, an error occurs due to the margin at the bottom of the protractor, and it becomes difficult to read the altitude (angle) because the protractor is placed on the floor. It is also difficult to match the end of the thread to the baseline of the protractor.

The altitude of the sun is the angle formed by the sun and the horizon, which can lead to the misconception of the angle between shadows and threads because of the use of shadows.

Applicant took the hint here and supplemented the existing textbook materials and teaching aids, and felt the necessity of producing materials that can measure the altitude and solar energy of the sun and understand the concepts accordingly.

The present invention has been made to solve the above problems, an object of the present invention is to provide a solar altimeter that can easily measure the altitude and orientation of the sun using a rotating barrel attached to the bearing plate, protractor, protractor. .

The present invention devised to solve the above problems is a table placed in parallel with the ground; An azimuth plate attached to an upper surface of the table and having an azimuth angle drawn about a center hole thereof; A rod-shaped direction guide which is rotatably installed in the hole formed in the center of the bearing plate; A quadrant-shaped altitude plate attached to an upper surface of the direction indicator in a state perpendicular to the ground and integrally rotating with the direction indicator, and having a 90 degree range angle sensor attached to one side thereof; It consists of a rectangular parallelepiped barrel which is rotatably installed at the origin of the goniometer, wherein the barrel has a rectangular parallelepiped shape in which one surface is open from six surfaces, the incident hole is formed in the center of one side of the solar light incident The center of the opposite side of the one side is characterized in that the target point is provided.

One side of the upper surface of the table is characterized in that the compass is installed parallel to the ground.

One side of the upper surface of the table is characterized in that the solar cell is installed parallel to the ground.

An altitude confirmation window is formed at the center of one side of the opposite side of the open surface of the barrel, and the surface on which the altitude confirmation window is formed is rotated while contacting the altitude plate printed with the goniometer.

The lower portion of the table is characterized in that the support for height adjustment is attached.

Hereinafter, a solar altimeter according to an embodiment of the present invention with reference to the drawings.

Figure 2 is a perspective view showing the structure of the solar altimeter according to an embodiment of the present invention, Figure 3 is an exploded perspective view showing the structure of the barrel.

Referring to Figures 2 and 3, the solar altimeter 100 of the present invention is installed on a square table 102.

The support table 104 is installed below the table 102, and the support table 104 has a shape similar to a tripod used in a camera, and it is preferable to allow height adjustment. Since the support 104 is provided at a constant height, students can measure the sun altitude in a comfortable position when practicing outdoors.

One side of the upper surface of the table 102 is provided with a compass 106 and a solar cell 108.

The compass 106 facilitates the reference direction when the solar altimeter 100 is placed on the ground.

The solar cell 108 is a device that converts light energy into electrical energy, and generates a current in proportion to the intensity of incident sunlight. The intensity of sunlight incident on the solar cell depends on the brightness and the angle of incidence. The greater the angle of incidence (the lower the altitude of the sun), the smaller the amount of light energy incident on the unit area, resulting in a lower magnitude of current. Therefore, students can experience the change in solar altitude while measuring the magnitude of the current generated from the solar cell 108.

Devices capable of measuring the magnitude of current generated in the solar cell 108 are conventional techniques disclosed in the art, and thus, detailed descriptions thereof will be omitted.

In the center of the upper surface of the table 102, a circular bearing plate 110 is fixedly installed. The bearing plate 110 has a central hole, and the north, south, west, and north directions are shown around the center hole, and the azimuth angle at which the sun is located can be measured.

At the center of the bearing plate 110, a long rod-shaped direction indicator 112 is rotatably installed. An arrow 112a is drawn at the end of the direction indicator 112. The azimuth angle of the sun is measured by rotating the arrow 112a in the direction in which the sun is located.

The screw fastening hole 112b is formed in the inner center of the direction indicator 112, and the direction indicator 112 is fixed to the hole in the center of the bearing plate 110 by a screw or bolt.

The altitude plate 114 is installed on the upper surface of the direction indicator 112, the altitude plate 114 is maintained in a vertical state with respect to the ground. Since the altitude plate 114 is fixed to the direction indicator 112, it is possible to rotate with the direction indicator 112. The elevation plate 114 is manufactured in the shape of a quadrant.

One side of the elevation plate 114 is shown a goniometer 116. The goniometer 116 has a quadrant shape like the altitude plate 114, and can measure angles from 0 ° to 90 °.

The barrel 118 is rotatably installed on the goniometer 116. The barrel 118 has a rectangular parallelepiped shape of which one side is open, and is a device that reads the altitude of the sun by adjusting it to coincide with the angle at which sunlight is incident.

As shown in FIG. 3, the barrel 118 has a rectangular parallelepiped shape without one side of the long side, and an incident hole 118a through which sunlight enters the center of the left side is formed, and the incident sunlight is formed in the center of the right side. A target point 118e is shown to confirm that the directions of the barrel 118 coincide with each other.

The target point 118e may be displayed by placing a dot on the inner center of the right side, but may be displayed through a screw or a bolt.

An altitude confirmation window 118b is formed on the opposite side of the open portion of the barrel 118. The altitude confirmation window 118b corresponds to the portion where the number is printed on the goniometer 116, and the number shown through the altitude confirmation window 118b is rotated when the barrel 118 is rotated to match the sunlight. And the angle of the earth, which is the height of the sun.

A reference line 118d is shown in the longitudinal direction at the center of the surface on which the altitude confirmation window 118b is formed so that it can easily match the direction of sunlight.

A through hole 118c is formed at one side of the inner surface of the barrel 118, and the barrel 118 and the altitude plate 114 are rotatably fixed through the through hole 118c. The through hole 118c of the barrel 118 is installed to correspond to the origin of the goniometer 116. Therefore, the barrel 118 can rotate with the rotation axis as the center of the goniometer 116.

Using the solar altimeter 100 having such a configuration will be described how to measure the orientation and altitude of the sun.

4 is an exemplary view showing a state of measuring the azimuth angle of the sun, Figure 5 is an exemplary view showing a state of measuring the altitude of the sun.

As shown in FIG. 4, the bearing plate 110 is placed in the correct position with reference to the compass 106.

Then, the direction indicator 112 is rotated to coincide with the direction in which the sun is located, and the direction of the sun is read by measuring the direction of the arrow 112a.

After measuring the orientation of the sun, as shown in FIG. 5, the barrel 118 is rotated on the goniometer 116 so as to lie parallel to the direction of sunlight.

The target point 118e is used to match the direction of incidence of sunlight with the direction of the barrel 118. That is, when the barrel 118 is properly rotated, the light comes in near the opposite target point 118e while the sunlight enters through the incident hole 118a. And while rotating the barrel 118 in detail, if the sunlight is precisely adjusted to the target point 118e, the direction of the barrel 118 and the direction of the sunlight is to match.

In the state where the barrel 118 and the direction of sunlight coincide with each other, the altitude of the sun is obtained by finding a position coinciding with the reference line 118c on the scale of the goniometer 116 through the altitude check window 118b.

In this way, students can easily measure the altitude of the sun while they are in class or practicing.

Table 102, altitude plate 114, barrel 118 and the like used in the present invention may be made of a material such as cardboard, wood rock, wood or plastic.

Although the preferred embodiments of the present invention have been described above with reference to the accompanying drawings, the technical configuration of the present invention described above may be modified by the person skilled in the art to which the present invention belongs without changing the technical spirit or essential features of the present invention. It will be appreciated that the present invention may be practiced as. Therefore, the above-described embodiments are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the utility model registration claims to be described later rather than the detailed description, and the scope of the utility model registration claims. All changes or modifications derived from the meaning and scope and equivalent concepts shall be construed as being included in the scope of the present invention.

According to the present invention, students can actually experience the change in the position of the sun according to the change of season or time while measuring the altitude of the sun.

In addition, according to the present invention, it is possible to easily match the direction of the barrel and the solar light by adjusting the solar light input through the incident hole to reach the center of the opposite side by using an open rectangular parallelepiped barrel.

Claims (5)

A table placed in parallel with the ground; A compass installed on one side of the upper surface of the table in parallel with the ground; A solar cell installed parallel to the ground on one side of the upper surface of the table; An azimuth plate attached to an upper surface of the table and having an azimuth angle drawn about a center hole thereof; A rod-shaped direction guide which is rotatably installed in the hole formed in the center of the bearing plate; A quadrant-shaped altitude plate attached to an upper surface of the direction indicator in a state perpendicular to the ground and integrally rotating with the direction indicator, and having a 90 degree range angle sensor attached to one side thereof; A barrel having a rectangular parallelepiped shape rotatably installed at the origin of the goniometer; The support is attached to the lower portion of the table to be adjustable in height; The barrel has a rectangular parallelepiped shape in which one surface is open among six surfaces, and an incident hole into which sunlight is incident is formed at the center of one side, and a target point is provided at the center of the opposite side of the one side. The altitude confirmation window is formed at the center of one side of the opposite side of the open surface of the barrel, And a surface on which the altitude confirmation window is formed rotates while the goniometer is in contact with the printed altitude plate. delete delete delete delete

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