KR20160073946A - Constellation device using star pointer - Google Patents

Abstract

The present invention relates to an astronomical observation device, and more specifically, to an astronomical observation device, which is configured to locate target constellation to be observed on a point reflected through a reflecting mirror located on the center in a celestial spherical main body when light of a star pointer is incident into a point of a celestial spherical surface on which the target constellation to be observed is displayed, and facilitates observing location of the target constellation to be observed and location of deep sky, which is hard to observe with naked eyes. To this end, the astronomical observation device (100) comprises: a celestial spherical main body (200) including a constellation part (220) on a celestial spherical surface (210); and a supporter (400) for supporting the celestial spherical main body (200). In the celestial spherical main body (200), a horizontal hemisphere (300) formed with a reflecting mirror (320) on the center of a cut surface (310) moves along the celestial spherical surface (210) inside the celestial spherical main body (200). In addition, the astronomical observation device further comprises a pair of magnets (330) having an attractive force between the lowest end point of the horizontal hemisphere (300) and one point of the supporter (400) which is located on a straight line with respect to the lowest end point such that the reflecting mirror (320) maintains horizontal balance with a horizontal plane even when the celestial spherical main body (200) is rotated.

Description

[0002] Constellation device using star pointer [

More particularly, the present invention relates to a celestial object observing apparatus, and more particularly, to a celestial object observing apparatus capable of placing an object to be observed at a point reflected through a reflector located in the center of a celestial body, , And an object of the present invention is to provide an astronomical observation instrument which can more easily find a position of a celestial object to be observed or a deep sky position that is difficult to visually recognize.

It is a fact that it is not easy to observe stars with stars in the night sky due to the influence of air pollution and lighting. In particular, it is even more difficult to grasp the position of deep sky such as nebulae or clusters with low apparent magnitudes located outside the solar system.

Because of this situation, the indirect astronomical position using the constellation learning tool is estimated.

The constellation plate, which is currently being used as a constellation learning tool, is a mechanism that allows the constellation arrangement to be recognized easily when the date and time scale of the observation are matched. In the inner celestial plate, an object such as an equatorial plane, an ecliptic plane, and a star is drawn , And a scale indicating the date is engraved on the edge. The horizon is considered on the outside of the rotating plate considering the latitude of the observation area and the time from 0:00 to 24:00 is displayed on the edge. If the two plates are properly overlapped, the night sky It is easy to see how it changes. In the inside of the spiral plate, an elliptical transparent window is shown, which shows the appearance of the sky seen at a specific day. The center of the transparent window is the ceiling (top of the observer's head) and the edge is the horizon. The four orientations of the north and azimuth angles are indicated. (Related Prior Art: Korean Patent Registration No. 1353680, Korean Patent Laid-Open Publication No. 2011-0025943, etc.) With such constellation plates, constellations , But it is impossible to determine the position of the entire celestial body floating in the sky.

Another constellation learning device, CELESTIAL GLOBE, is a device that displays the constellation position, equator, and ecliptic on the celestial sphere on the assumption that the observer is in the center of the celestial sphere. (Korean Patent Registration No. 0704702, Korean Laid-Open Patent Publication No. 2010-0095501, etc.) Such a celestial object can learn a constellation position and the like which can be seen on an observation date in three dimensions. However, It also has the problem that it can not accurately grasp the position of the object in the sky.

SUMMARY OF THE INVENTION The object of the present invention is to provide an object observing mechanism that can more easily grasp the position of a celestial object in the sky in order to solve the above problems.

To this end,

A celestial body inner mechanism including a body of a celestial sphere including a constellation part on the celestial plane and a pedestal supporting the body of the celestial body, wherein a horizontal hemisphere having a reflector formed at the center of the cut surface is movable along the inner celestial surface of the celestial body And a pair of magnet portions having a mutually attraction relationship at a lowermost point of the horizontal hemisphere and at a point on a pedestal that is in line with the lowermost point so that the reflector remains horizontal with the horizontal plane even if the body of the celestial body rotates The object of the present invention is to provide an astronomical observing mechanism.

The celestial body may include a rotation shaft protruding outward at the south pole, and the support may include a guide portion having a groove formed in a vertical direction so that the rotation shaft can be inserted and moved up and down.

The pedestal may further include a lighting unit at a predetermined point so that the constellation formed on the celestial surface can be easily recognized,

The horizontal hemisphere may further include a bearing portion on the hemispherical surface for reducing friction with the inner meditative surface of the cen- tral portion.

The celestial object observing apparatus may further include an attachment period including a contact surface portion having a curvature corresponding to the celestial surface so that the light source is vertically incident on the celestial surface.

According to the present invention, when the main body of the celestial sphere is adjusted according to the observer position and the observation date, and the starry period is placed at the position of the object to be observed with reference to the constellation indicated on the celestial plane, Because it becomes the object to be observed, it has the effect that the beginner can easily find the position of the actual celestial body, and it is easier to understand the movement of the star according to the azimuth angle and the altitude from the perspective of the observer viewing the celestial object from the outside using the three- It is advantageous to be able to be utilized also as a.

1 is an exploded perspective view of an astronomical observation instrument according to an embodiment of the present invention;
2 is a perspective view showing a coupling relationship between a main body of a crown, a horizontal hemisphere, and a pedestal according to an embodiment of the present invention.
FIG. 3 is a perspective view of an attachment period according to an embodiment of the present invention; FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. For the sake of reference, the same components are denoted by the same reference numerals as possible, and a detailed description of known configurations may be omitted if it is determined that the gist of the present invention may be blurred.

1 is a perspective view of an astronomical observation instrument 100 according to an embodiment of the present invention.

The celestial object observing apparatus 100 includes a celestial body 200 and a pedestal 400 for supporting the celestial body 200.

First, the celestial body 200 is a transparent sphere shaped like a celestial sphere. The celestial surface 210 includes constellation portions 220 that can be observed by the time, and includes a zodiacal image, an enemy meridian, an azimuthal line, , A frog point, a ground point, and the like may be displayed. The constellation part 220 displays a celestial body that can be observed by time on the celestial body surface 210. When the main body 200 of the celestial sphere is adjusted according to the latitude and the observation date of the observation point, it is possible to identify an object including a main constellation that can be seen in the night sky.

More specifically, an observer shoots a starry starter 500 toward a star of a star floating in the night sky by adjusting the crown body 200 to the observation point and observation date, Can be interpreted as being reflected through the center reflector 320 by launching the starboard period 500 at any point on the corresponding celestial surface 210 at the center. When the observer does not know the position of the object to be searched, the constellation to be searched is placed in the main body (200) of the celestial object (200) with the north and the south of the celestial body (200) (210) and reflects it by shooting a separate period (500) at the corresponding point, the spot pointed to by the starlight in the night sky becomes the position of the object to be searched.

For this purpose, the reflector 320 at the center of the main body 200 of the celestial body should always be kept horizontal with the horizon, even if the main body 200 of the celestial body is rotated in accordance with the latitude and longitude to match the observation point and the date.

In order to satisfy such a situation, a horizontal hemisphere 300 exists inside the cen- tral body 200, and a reflector 320 is formed at the center of the cut-off surface 310 of the hemisphere 300. The hemispherical surface 311 of the horizontal hemisphere 300 is formed to be substantially similar to the curved surface of the celestial surface 210 so that the horizontal hemisphere 300 can move along the inner celestial surface 210 of the cen- tral body 200 .

Since the horizontal hemisphere 300 having the reflector 320 is required to be kept horizontal with respect to the horizon plane so that a mutual attraction relationship is maintained at a lowermost point of the horizontal hemisphere 300 and a point on a pedestal straight on from the lowermost point A pair of magnet portions 330 are attached. 2, since the horizontal hemispherical magnet portion 331 is attached to the lowermost point of the horizontal hemisphere 300 and the pedestal magnet portion 332 is attached to one of the bases on the straight line from the lowermost point, The hemispherical magnet unit 330 and the pedestal magnet unit 332 are in a mutual attraction relationship so that even when the main body 200 of the celestial body rotates and moves, the cut surface 310 of the horizontal hemisphere 300, . In order to stably maintain the horizontal level, it is preferable that both of the pair of magnet portions 331 and 332 are magnets. Also, for stronger attraction, the magnet is preferably neodymium.

However, if the attracting force of the pair of magnet portions 331 and 332 is too strong, the horizontal hemisphere 300 and the celestial body 200 may be too close to each other, which may make it difficult to rotate the celestial body 200. The bearing portion 340 may be formed on the hemispherical surface 311 of the horizontal hemisphere 300 in order to reduce the friction caused by the close contact between the horizontal hemisphere 300 and the main body 200 of the cistern.

A rotation axis 250 protruding outward may be formed at the south pole 230 of the celestial body 200. The rotation axis may be perpendicular to the vertical plane of the celestial plane 210 on the straight line connecting the south pole 230 and the north pole 240, As shown in Fig. The rotation axis 250 is formed to reflect the motion of the celestial body on the celestial body due to the rotation of the celestial sphere according to the rotation of the earth.

Next, the pedestal 400 plays a role of supporting the main body 200 of the celestial body adjusted in accordance with the observation date and the observation point so that it does not move. The embodiment of the present invention is configured to receive and support a part of the celestial body 200 A ring-shaped pedestal 400 is applied. However, if it is possible to support the celestial body 200 in various ways, it corresponds to the pedestal 400 of the present invention.

The pedestal 400 may further include a guide portion 410 having a groove 411 formed in a vertical direction and the rotation axis 250 of the body 200 of the celestial body is inserted into the groove 411 of the guide portion 410. So that the celestial body 200 can be rotated up and down without swaying left and right. The reason why such a rotational movement is necessary is to adjust the body 200 of the celestial sphere to match the latitude of the observer. For fine adjustment of latitude, the guide part 410 may be displayed with an angle scale.

In addition, the pedestal 400 may further include an illumination unit 420 at a predetermined point to facilitate identification of the constellation 220 displayed on the ceiling surface 210. The illumination unit 420 may be formed of an LED or the like and the light emitted from the illumination unit 420 is projected into the main body 200 of the celestial body so that the constellation part 220 can be recognized even in the dark night.

The celestial object observing apparatus 100 according to the present invention may include a separate sheet period 500 for transmitting the forward light toward the reflector 330 as shown in FIG. And a contact surface portion 520 having a curvature corresponding to the celestial surface 210 so as to vertically enter the light source. If the reflector 330 is located at an ideal point at the center of the cut surface 310 of the horizontal hemisphere 300, all of the marginal rays may be incident perpendicular to the celestial surface 210, but since the reflector 330 has a certain area , It is preferable that a separate light source 500 is vertically incident on the celestial surface 210 for more accurate constellation confirmation. The contact surface portion 520 formed around the light source portion 510 of the separate sheet period 500 has a curvature corresponding to the celestial surface 210 so that the separate sheet period 500 is maintained perpendicular to the celestial surface 210 .

Hereinafter, a method of using the celestial object observing mechanism of the present invention will be briefly described.

First, the center of the guide unit 410 at the south pole 230 of the main body 200 of the celestial body 200 is aligned with the S-pole direction of the compass using a compass to align the celestial body 200 in the north-south direction, The point of the observation date is aligned with the center of the guide part 410. [ For the sake of reference, 'date circle' means that the circumferential length of the main body 200 of the celestial body is equally divided into 365 so that the celestial body that is culminating at a specific time is positioned on the opposite side of the celestial body, and is displayed on the equator of the celestial plane 210.

Next, the rotating shaft 250 is moved upward and downward along the groove 411 of the guide part 410 to adjust the latitude of the observation point to the latitude of the observation point.

In this state, the celestial object viewed above the celestial plane 210 is set in the opposite direction to the celestial object at the actual observation point.

Next, when a spot of the sky 500 corresponding to the object to be searched is selected, and a starlight 500 is emitted from the spot toward the reflector 320 located at the center of the horizontal hemisphere 300, The point in the night sky is the location of the celestial object you are looking for. For example, in order to find a deep sky such as a nebula which is hardly visible to the naked eye, a corresponding point is selected on the celestial plane 210 with reference to a deep sky position indicated by a relative position with the guide stars, (500), the reflection point becomes the position of the corresponding deep sky.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined in the appended claims. It will be appreciated by those of ordinary skill in the art that this is possible.

100: astronomical observation instrument 200: main body of the sky
210: Moonface 220:
230: South Pole 240: North Pole
250: rotating shaft 300: horizontal hemisphere
310: cut plane 311: hemisphere plane
320: Reflector 330: Magnet portion
340: bearing part 400: pedestal
410: guide portion 411: groove
420: illuminating part 500:
510: light source 520:

Claims (5)

A celestial body 200 including a constellation part 220 on a celestial plane 210 and a pedestal 400 for supporting the celestial body 200,
A horizontal hemisphere 300 having a reflector 320 formed at the center of the cut surface 310 is positioned to be movable along the inner celestial surface 210 of the celestial body 200,
A mutual attraction relationship is established between a lowermost point of the horizontal hemisphere 300 and a point on a pedestal that is in line with the lowermost point so that the reflector 320 is kept horizontal with the horizontal plane even if the cen- tral body 200 rotates And a pair of magnet portions (330) having a plurality of magnet portions (330). The method according to claim 1,
The celestial body 200 includes a rotation shaft 250 projecting outwardly to the south pole 230,
Wherein the pedestal (400) includes a guide part (410) having a groove (411) formed in a vertical direction so that the rotation shaft (250) can be inserted and moved up and down. The method according to claim 1,
Wherein the pedestal (400) includes an illumination unit (420) at a predetermined point so that the constellation part (220) formed on the celestial surface (210) can be easily checked. The method according to claim 1,
Wherein the horizontal hemisphere 300 includes a bearing portion 340 on the hemispherical surface 311 for reducing friction with the inner celestial surface 220 of the cen- tral body 200. [ 5. The method according to any one of claims 1 to 4,
The celestial object observing apparatus 100 includes a separate period 500 for transmitting the forward light toward the reflector 330,
Wherein the separate period of time (500) comprises a contact surface portion (520) having a curvature corresponding to the celestial surface (210) for vertically entering the light source at the celestial surface (210).

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