KR101810333B1 - Month Periodic change observation teaching aid - Google Patents

Abstract

According to another aspect of the present invention, there is provided a lunar phase change learning apparatus comprising a first gear fixedly coupled to one side of a base plate, a first shaft penetratingly coupled to the first gear, a second gear meshed with the first gear, A first gear portion including a third shaft axially coupled to the second gear, a third gear meshed with the second gear, and a fourth shaft axially coupled to the third gear; A fourth gear that is axially coupled to the first shaft so as to be positioned above the first gear, a fifth gear that is gear-engaged with the fourth gear, And a sixth gear meshed with the fifth gear and axially coupled to the third shaft to be positioned above the second gear; And a lower mount coupled to the first, second, third, and fourth shafts so as to be positioned between an upper portion of the first, second, and third gears and a lower portion of the fourth, fifth, and sixth gears; A planetary model coupled to an upper end of the first axis; And a satellite model coupled to the upper end of the fourth axis and coupled to be movable upward and downward, wherein the solar model (light) used in the conventional parish is omitted and the satellite model is shaded to form a separate illumination and darkroom , It is possible to observe the phase of the Moon to simplify the structure of the diocese. By applying the gear ratio for realizing the movement of the celestial body, It can be understood that the learning effect can be improved.

Description

{Month Periodic change observation teaching aid}

The present invention relates to a teaching paradigm for correlating sun-earth-moon, and specifically relates to a parish enabling effective learning of the movement of the earth and the movement of the moon over time and the shape of the moon observed accordingly.

The commonly known triplet consists of a solar model with a sun symbol or a light bulb inserted to study the correlation of the sun, earth, and moon, and a moon model that revolves around the earth and around the earth rotating around the sun .

The light emitted from the solar model in this triangular structure illuminates the model of the earth and the moon to explain the principle of the day and night of the earth, and it shows the appearance of the moon rising and falling.

However, in order to observe the shadow movements of the earth and the moon in order to know the principles of the solar eclipses and lunar eclipses, the earth or satellite model itself revolves around the solar model, There was an inconvenience to observe the movement of the shadows by attaching paper to each shadow of the moving earth and satellite model.

In addition, when the sun model is made up of a light bulb and illuminates all directions to the top, bottom, left, and right, there is a problem of eye fatigue as the observation time becomes longer, In order to prevent the problem, when the light of the solar model is weakened, it is usually impossible to distinguish the light reflected by the earth and satellite models because the time for classroom teaching is usually daytime It is difficult to expect the educational effect because it is difficult to observe the distinction between the earth and the night and the appearance of the moon rising and tilting.

KR 10-0953860 B1 KR 10-1131839 B1 KR 10-1450473 B1 US 005967791 A

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above problems of the prior art.

Specifically, the object of the present invention is to omit the solar model (light) used in the conventional diocese and to observe the lunar phase without a separate illumination and darkroom configuration through the shading of the satellite model, By applying the gear ratio to realize the movement of the celestial body that revolves one time during the rotation, the movement of the actual celestial body is reduced.

According to an aspect of the present invention, there is provided a lunar phase change teaching implement including a first gear fixedly coupled to one side of a base plate, a first shaft penetratingly coupled to the first gear, A first gear portion including a second gear, a third shaft axially coupled to the second gear, a third gear meshed with the second gear, and a fourth shaft axially coupled to the third gear; A fourth gear that is axially coupled to the first shaft so as to be positioned above the first gear, a fifth gear that is gear-engaged with the fourth gear, And a sixth gear meshed with the fifth gear and axially coupled to the third shaft to be positioned above the second gear; And a lower mount coupled to the first, second, third, and fourth shafts so as to be positioned between an upper portion of the first, second, and third gears and a lower portion of the fourth, fifth, and sixth gears; A planetary model coupled to an upper end of the first axis; And a satellite model coupled to the upper end of the fourth axis so as to be movable up and down, wherein the satellite model revolves in the same direction as the rotation direction of the planetary model when the planetary model rotates, And rotates in a direction opposite to the revolving direction, but rotates in the same number of revolutions as the number of revolutions.

The mount portion may include an upper mount coupled to the first, second, third, and fourth shafts so as to be positioned above the fourth, fifth, and sixth gears, and a mount fixing portion And further comprising:

The solar module further includes a solar module detachably attached to one side of the base plate and having a solar module mounted thereon. The solar module and the planetary module are separated from each other by separation or combination of the solar module and the baseplate. .

In addition, the solar model may be illuminated to illuminate the planet model and the satellite model.

In addition, the planetary model is characterized in that an observer doll capable of indicating a bearing on the footrest is detachably attached.

Further, the first gear is characterized in that the time is displayed on the upper part.

In addition, the satellite model is characterized in that half is composed of a shaded portion.

As described above, according to the present invention, the configuration of the parish is simplified by omitting the sun model (light) used in the conventional parish and observing the lunar phase without the separate illumination and darkroom configuration through the shadow processing of the satellite model It can be intuitively understood by applying the gear ratio to realize the motion of the celestial body which once revolves when the earth rotates several times such as 30 times or 29.33 ... times. And has an effect of improving the learning effect.

1 is a perspective view of a lunar phase change teaching apparatus according to an embodiment of the present invention.
Fig. 2 is a perspective view showing the operating state of Fig. 1. Fig.
3 is a detailed side view of a lunar phase change teaching apparatus according to an embodiment of the present invention.
4 is a conceptual diagram showing only the schematic state of FIG.
5 is a plan view of a first gear according to an embodiment of the present invention;
6 is a perspective view of a base plate and a solar panel according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings, but the present invention is not limited by the scope of the present invention.

1 to 5, the moon phase change teaching implement according to the present invention includes a first gear portion 100, a second gear portion 200, and a mount portion M. As shown in FIG.

The first gear portion 100 includes a first gear 130 fixedly coupled to one side of the bottom plate 10, a first shaft 310 axially coupled to the first gear 130, A third shaft 330 axially coupled to the second gear 120 and a third gear 110 meshed with the second gear 120 to be meshed with the second gear 120, And a fourth shaft 340 axially coupled to the third gear 110.

The second gear portion 200 includes a fourth gear 230 that is axially coupled to the first shaft 310 so as to be positioned above the first gear 130 and a fourth gear 230 that is engaged with the fourth gear 230, A second shaft 320 coupled to the fifth gear 220 in a shaft or coupled manner and a second shaft 320 coupled to the fifth gear 220 in a gear- And a sixth gear (210) axially coupled to the third shaft (330) so as to be positioned.

The mount portion M is inserted into the first, second, third, and fourth shafts 310, 320, 330, and 340 so as to be positioned between the upper portions of the first, second, and third gears 110, 120, In order to prevent the first and second gear portions 100 and 200 from being detached from the existing position in addition to the lower mount M2 to be coupled with the first and second gear portions 100 and 200, An upper mount M1 which is inserted through the four axes 310, 320, 330 and 340 and a mount fixing table M 'which fixedly engages the upper mount M1 and the lower mount M2.

And a satellite model 30 coupled to the upper end of the fourth axis 340 and a satellite model 30 when rotating the planetary model 20, ) Revolves in the same direction as the direction of rotation of the planetary model (20), during which the satellite model (30) rotates in a direction opposite to the revolving direction while revolving, rotating at the same number of revolutions.

For example, when the planetary model 20 rotates 30 times, the satellite model 30 revolves once in the same direction as the direction of rotation of the planetary model 20, and the satellite model 30 rotates once during the revolution And rotates once in a direction opposite to the revolution direction.

Specifically, the satellite model 30 is configured with a half of a shaded portion so that the phase of the moon can be expressed without any additional illumination, and the up and down movement of the moon 30 can be performed, thereby facilitating implementation and explanation of the solar eclipse and lunar eclipsing phenomenon.

Between the satellite model 30 and the planetary model 20, a transparent cover in which the surface of the satellite is expressed is fixedly disposed on the upper side of the upper mount M1 at a position close to the satellite model 30, ), It is possible to implement and explain that when observing the moon on Earth, the same part of the moon is always identified in a form that only the shade changes.

In addition, the satellite model 30 may be detachable or may be provided with an extra satellite model 30 to provide a planetary model 20, such as a solar eclipse and a total solar eclipse, and a solar model 40, It is possible to easily explain the principle in which different phenomena appear depending on the position of the satellite model 30. [

At this time, the solar model 40 is illuminated inside or outside to facilitate understanding of the principle of astronomical motion by irradiating light in the direction of the planetary model 20 and the satellite model 30, As shown in FIG. 6, it is easy to understand that the distance between the actual sun and the sun is considerably large because the solar module 40 can be separated from the solar module 10_2 coupled to the sun module 40, It is possible to make it easy to explain the principle of the golden annulus and the partial eclipse.

In the planetary model 20, an observer doll 50 capable of indicating a bearing can be attached to the foot plate. Specifically, the observer doll 50 can be attached in the same manner as a magnetic force or a frictional force, It is possible to make it easy for the actual observer observing in the third person by holding the shape to prevent the situation in which the observer can not concentrate on the observer in order to misunderstand the direction as the earth rotates or understand the direction .

5, when the planetary model 20 is rotated, the planetary model 20 is rotated by the first gear 130 to display time on the upper part or to represent one time per tooth with 24 gear teeth, It is possible to easily grasp the time change on the screen.

4 to 5, the name of the lunar date or the moon according to the shape of the moon is written along the radius of rotation in which the satellite model 30 revolves, It is possible to easily grasp the phase change of the moon.

The lunar phase change training apparatus including the components can be represented by the following embodiment with reference to Figs.

In order to rotate the first axis 310 as a starting point for driving the lunar phase change educational instrument, a separate handle is formed on the upper end of the planetary pattern 20 coupled with the first axis 310 to manually rotate the motor, A separate power source such as a motor may be provided and rotated.

The first gear 130 is fixed separately from the rotation of the shaft, and the remaining gears except for the first gear 130 rotate in conjunction with the rotation of the shaft that is axially coupled through the center.

The fifth gear 220 meshes with the fourth gear 230 rotating in conjunction with the rotation of the first shaft 310 so that the rotational direction of the sixth gear 210 coincides with the fourth gear 230 The second gear 120 meshing with the first gear 130 is connected to the sixth gear 210 via the third shaft 330 and rotated in the same direction so that the direction of rotation of the planetary gear 20 (30) are made to be in the same direction.

The second gear 120 is engaged with the third gear 110 that is involved in the revolution and rotation of the satellite model 30 so that the satellite model 30 can rotate in the opposite direction to the idle direction while revolving the planetary model 20 . At this time, by attaching a miniature ball caster to the lower part of the second and third gears 110 and 120, friction with the bottom plate 10 can be prevented and the satellite model 30 can be revolved and rotated easily.

Specifically, when the planetary model 20 rotates 30 times, the satellite model 30 revolves once in the same direction as the direction of rotation of the planetary model 20, while the satellite model 30 rotates in the opposite direction The present invention has the following premise.

Since the satellite model 30 represents the contrast, when the satellite model 30 revolves once in the planetary model 20, it must rotate in the opposite direction one time so that the bright portion of the satellite model 30 always points in one direction do.

Therefore, in order to implement the rotation of the satellite model 30 once in the opposite direction when the satellite model 30 revolves once, the third gear 110 at the center should not be fixed and rotated and connected to the same axis as the satellite model 30 At least one spur gear, that is, a second gear 120, must be connected between the first gear 130 and the third gear 110 as well as the first gear 130.

In addition, two conditions are required for the satellite model 30 to revolve the planet model 20 once in the same direction when the planetary model 20 rotates several times.

First, the sixth gear 210 connected to the planetary gear 20 in the axial direction must rotate in the same rotational direction as the second gear 120. In order to realize this, the sixth gear 210 is connected to the second gear 120, The fifth gear 220 is required.

Secondly, the gear ratios of the planet model (20) and the satellite model (30) must be set.

로 설계하였을 경우, 위성모형(30)이 1회 공전하는 동안 행성모형(20)은 q+1회 자전하게 된다. 일반적인 기어 설계는 구동기어와 종동기어가 제자리회전을 하기 때문에 일반적인 기어비에 따라 회전이 결정된다.

The planetary model 20 rotates q + 1 times while the satellite model 30 revolves once. In a typical gear design, rotation is determined by the general gear ratio because the drive gear and the driven gear rotate in place.

In the present invention, since the sixth gear 210, which is a driving gear, not only rotates the first gear 130 as a follower, but also revolves around the driving gear, the driving gear must rotate one more time The gear is returned to its original position. Therefore, when the gear ratio is 1 / q, the general gear design requires the drive gear to rotate q times in order to rotate the driven gear once. However, in the present invention, the drive gear is rotated in the q + Should be.

에서 'q=29'가 되어야 하는 것이다. 도 1에서는 '1/30'의 회전비를 예시로 들었으나, 본 발명의 원리를 이용하면 '1/29' 뿐만 아니라 '1/33.333333...' 과 같은 회전비로서도 구성이 가능하다.For example, while the planetary model 20 rotates 30 times, the satellite model 30 rotates one time and at the same time rotates in the opposite direction of the revolution

Quot; q = 29 ". In FIG. 1, the rotation ratio of '1/30' is exemplified, but the rotation ratio of '1 / 33.333333...' As well as '1/29' can be constructed using the principle of the present invention.

1 to 5 illustrate examples corresponding to the above description, but the numerical values are not limited by the drawings, and all the configurations for forming the number of teeth in the same context as the prerequisite conditions are possible.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

10: Base plate 10_2: Solar plate
20: Planet Model 30: Satellite Model
40: The Sun Model 50: The Observer Doll
100: first gear portion 110: third gear
120: second gear 130: first gear
200: second gear portion 210: sixth gear
220: fifth gear 230: sixth gear
310: first axis 320: second axis
330: third axis 340: fourth axis
M: Mount portion M1: Upper mount
M2: Lower mount M ': Mounting bracket

Claims (7)

A first gear fixedly coupled to one side of the base plate, a first shaft penetratingly coupled to the first gear, a second gear meshed with the first gear, and a third shaft axially coupled to the second gear, A third gear meshed with the second gear, and a fourth shaft axially coupled to the third gear;
A fourth gear that is axially coupled to the first shaft so as to be positioned at an upper portion of the first gear, a fifth gear that is gear-engaged with the fourth gear, And a sixth gear meshed with the fifth gear and axially coupled to the third shaft to be positioned above the second gear;
And a lower mount coupled to the first, second, third, and fourth shafts so as to be positioned between an upper portion of the first, second, and third gears and a lower portion of the fourth, fifth, and sixth gears;
A planetary model coupled to an upper end of the first axis; And
And a satellite model coupled to an upper end of the fourth axis so as to be movable up and down,
Wherein when the planetary model rotates, the satellite model revolves in the same direction as the rotational direction of the planetary model,
Wherein the satellite model rotates in a direction opposite to the idle direction while revolving, and rotates the same number of times as the idle time. The method according to claim 1,
The mounting portion includes:
Second, third, and fourth axes so as to be positioned above the first, second, third, fourth, and fifth gears, and a mount bracket for fixedly coupling the upper mount and the lower mount Moon phase change educational institution. The method according to claim 1,
And a sun plate which is detachably attached to one side of the base plate and is provided with a solar model on the upper side, wherein the distance between the sun model and the planetary model is adjusted by separation or combination of the sun plate and the base plate Features a Moon phase change educational instrument. The method of claim 3,
Wherein the sun model is illuminated to illuminate the planet model and the satellite model direction. The method according to claim 1,
Wherein the planetary model is characterized in that an observer doll capable of indicating a bearing on the footrest is detachably attached thereto. The method according to claim 1,
And the first gear indicates a time at an upper portion thereof. The method according to claim 1,
Wherein the satellite model comprises a shade portion.

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