KR20130054021A - Altitude adjusting apparatus of equatorial mount for astronomical telescope - Google Patents

Abstract

PURPOSE: An altitude controlling apparatus of an equatorial telescope for an astronomical telescope is provided to perform altitude controlling for fitting a polar axis quickly and accurately. CONSTITUTION: An altitude controlling apparatus of an equatorial telescope(200) includes a base(110), a polar axis housing(120) installed on the base, and a declination axis housing(130) combined to meet an upper end of the polar axis housing at right angle. The altitude controlling apparatus of an equatorial telescope(200) comprises the followings: a fixed bracket(210) fixed on the base; a pivot bracket(220) in which a lower end is combined to the fixed bracket to be rotatable and the polar axis housing is combined to be rotatable in an upper end; a coarse controlling unit(230) which is prepared on the upper end of the pivot bracket and the polar axis housing, and enables the pivot bracket to rotate the polar axis housing within a fist angle range; a tremor controlling unit(240) which is prepared in the lower end of the pivot bracket and the fixed bracket, and enables the fixed bracket to rotate the pivot bracket within a second angle range which is narrower than the first angle range.

Description

Altitude adjusting apparatus of equatorial mount for astronomical telescope

The present invention relates to the equator of the astronomical telescope, and more particularly to an altitude control device for matching the polar axis of the celestial equator.

The equatorial mount is a type of mount that supports an astronomical telescope on the earth's surface for observing objects such as stars, the sun, and the moon.

In the celestial sphere, the circumferential movement of the celestial body is caused by the rotation of the earth. When the astronomical telescope makes one rotation around the axis parallel to the rotation axis of the earth every 24 hours, it can follow the circumferential movement of the celestial body for long periods of observation and photography. have. To this end, the equator is configured to rotate around an axis that can move in two directions, equatorial coordinates and declination by the equator coordinates.

1 is a diagram showing the configuration of a general astronomical telescope and the equator.

Referring to FIG. 1, a general equator 10 is mounted on a pedestal 30 so as to support and rotate the astronomical telescope 20. Specifically, the equator 10 includes a base 11 mounted on the pedestal 30, a polar housing 13 rotatably coupled to the bracket 12 installed on the base 11, and a polar housing ( A declination shaft housing 14 coupled to be orthogonal to the upper end of 13). The astronomical telescope 20 is mounted on the upper end of the declination shaft housing 14, and the balance weight 15 for balancing is installed at the lower end. Since the center line of the polar axis housing 13 is aligned in parallel with the rotation axis of the earth, it is called the polar axis Ca or the right ascension axis, and the center line of the declination axis housing 14 is called the declination axis Cd orthogonal to the right ascension axis. The polar axis housing 13 is provided with a rotation driving means (not shown) for rotating the declination shaft housing 14 with the polar axis Ca as the rotation center, and the declination shaft 14 has a rotation center of the declination shaft Cd. Rotation drive means (not shown) for rotating the astronomical telescope 20 is provided.

In order to use the astronomical telescope 20, the center line of the polar axis housing 13 of the equator 10, ie, the polar axis Ca, must be aligned in parallel with the rotation axis of the earth. The altitude control device for adjusting the altitude of the polar axis (Ca) is provided.

2 is a view schematically showing an example of the altitude control device provided in the conventional equator.

Referring to FIG. 2, one example of the conventional altitude adjusting device 40 is to fasten a bolt 42 having a knob 43 to a nut 41 installed on a bracket 12, and the bolt 42 is It is a way to adjust the altitude by pushing the polar housing (13) directly up.

However, in this method, at least three bolts 42 having different lengths should be prepared according to the altitude adjustment range, and the whole adjustment process is made only with fine adjustment so that the altitude can be precisely adjusted to exactly match the polar axis Ca. There was a disadvantage of slow altitude adjustment.

3 is a view schematically showing another example of the altitude control device provided in the conventional equator.

Referring to FIG. 3, another example of the conventional altitude adjusting device 50 includes a protrusion 51 installed at a lower portion of the polar housing 13 and a bolt fastened to the bracket 12. 52), the polar housing (13) is rotated while the altitude is controlled.

However, this method also has to prepare three or more bolts 51 having different lengths according to the altitude adjustment range, the whole process is made only fine adjustment so that the altitude can be precisely adjusted to exactly match the polar axis (Ca) There was a disadvantage of slow adjustment.

As described above, the altitude adjusting devices 40 and 50 provided in the conventional equator 10 should prepare a plurality of altitude adjusting bolts 42 and 52, and the whole adjustment process is made only of fine adjustment. There was a problem that the altitude adjustment is not made quickly.

Embodiments of the present invention provide an apparatus for adjusting the equatorial altitude for an astronomical telescope configured to quickly and accurately perform altitude adjustment for the polar axis.

In order to achieve the above technical problem, according to an aspect of the present invention, the equatorial telescope of the astronomical telescope comprising a base, a polar housing installed on the base and the declination shaft housing coupled to be orthogonal to the upper end of the polar housing. In the altitude control device,

A fixed bracket fixed to the base; A lower end rotatably coupled to the fixed bracket and an upper end rotatable bracket coupled to the polar housing; A coarse adjustment unit provided at an upper end portion of the pivot bracket and the polar housing to rotate the polar housing within a first angle range with respect to the pivot bracket; And a fine adjustment unit which is provided at a lower end of the pivot bracket and the fixed bracket and pivots the pivot bracket with respect to the fixed bracket within a second angle range narrower than the first angle range. An equatorial altitude control device for astronomical telescopes is provided.

The fixing bracket includes two side plates arranged side by side at a distance from each other, and a connecting plate connecting one end portion of each of the two side plates, and the rotation bracket has an outer side of each of the two side plates of the fixing bracket. Can be coupled to.

In addition, the coarse adjustment unit may include a first slot formed in an arc shape on the upper end of the rotation bracket, and a first bolt inserted into the first slot and fastened to the polar housing.

In addition, the fine adjustment unit may include a rotation means for rotating the rotation bracket, and a guide means for guiding the rotation of the rotation bracket and limiting the rotation angle range.

In addition, the rotating means may include a fixed bar fixed to the lower end of the rotating bracket, a coupling member coupled to the fixing bar, and a fine screw connected to the coupling member to reciprocally move the coupling member.

The guide means may include a second slot formed in an arc shape at a lower end of the pivot bracket, and a second bolt inserted into the second slot and fastened to the fixing bracket.

In addition, the fine screw is inserted into the fixing bracket to be horizontally penetrated, the front end is fastened to the coupling member, the rear end may be provided with a knob.

According to the embodiment of the present invention, since the altitude control device is composed of a coarse adjustment unit and a fine control unit, at first, the altitude is adjusted quickly using the coarse adjustment unit, and finally, the altitude is precisely controlled using the fine adjustment unit. Can be precisely adjusted. Therefore, there is an advantage that the altitude adjustment can be made accurately and easily and quickly.

1 is a view schematically showing the configuration of a general astronomical telescope and the equator.
2 is a view schematically showing an example of the altitude control device provided in the conventional equator.
3 is a view schematically showing another example of the altitude control device provided in the conventional equator.
Figure 4 is a perspective view showing the equator of the astronomical telescope equipped with an altitude control device according to an embodiment of the present invention.
Figure 5 is a partial perspective view showing in detail the fine adjustment of the altitude control apparatus shown in FIG.
6a to 6c are views for explaining the operation of the altitude control apparatus according to the embodiment of the present invention shown in Figs.

Hereinafter, with reference to the accompanying drawings will be described with respect to the celestial telescope height adjustment apparatus according to an embodiment of the present invention. In the drawings, the same reference numerals denote the same elements.

Figure 4 is a perspective view showing the equator of the astronomical telescope with an altitude adjusting device according to an embodiment of the present invention, Figure 5 is a partial perspective view showing in detail the fine adjustment of the altitude adjusting device shown in FIG.

4 and 5 together, the equator 100 is a type of mount that supports the astronomical telescope 20 for observing a celestial body such as a star, the sun, and the moon on the surface of the earth. It is configured to support and rotate the astronomical telescope 20 so as to enable long-term observation and photography.

The equator 100 includes a base 110, a polar housing 120 installed on the base 110, and an declination shaft housing 130 coupled to be orthogonal to an upper end of the polar housing 120. .

The base 110 supports the entire structure of the equator 100 and may have a circular plate shape. The base 110 is installed on a pedestal 30 such as a tripod.

The polar housing 120 has a cylindrical shape and is installed to be rotatable on the base 110 to adjust the inclination. This will be described in detail below. The center line of the polar housing 120 is called the polar axis Ca or the right ascension axis, and is aligned in parallel with the rotation axis of the earth.

The declination axis housing 130 also has a cylindrical shape and is coupled to be orthogonal to the upper end of the polar axis housing 120, and its center line is called the declination axis Cd, and is perpendicular to the polar axis Ca of the polar axis housing 120. The astronomical telescope 20 is mounted on the top of the declination shaft housing 130, the balance weight 140 for balancing can be installed at the bottom.

The polar axis housing 120 is provided with a rotation driving means (not shown) for rotating the declination shaft housing 130 at the center of rotation of the polar axis Ca, and the declination shaft Cd within the declination shaft housing 130. Rotation driving means (not shown) for rotating the astronomical telescope 20 to the center of rotation is provided.

In order to use the astronomical telescope 20, the center line of the polar housing 120 of the equator 100, ie, the polar axis Ca, must be aligned in parallel with the rotation axis of the earth, and the equator 100 has a polar housing ( An altitude adjusting device 200 for adjusting the altitude of the 120 to adjust the polar axis Ca is provided.

Altitude adjustment apparatus 200 according to an embodiment of the present invention, the fixed bracket 210 is fixedly installed on the base 110, the rotating bracket 220 is coupled to the fixed bracket 210 to be rotatable, It includes a coarse adjustment unit 230 provided on the upper end and the polar housing 120 of the rotating bracket 220, and the fine adjustment unit 240 provided on the lower end and the fixing bracket 210 of the rotating bracket 220.

Specifically, the fixing bracket 210 is to be fixed to the upper surface of the base 110, the two side plates 211 are arranged side by side and spaced apart by a predetermined interval, connecting one end of each of the two side plates 211 Including the connecting plate 212, which has a total "C" shape.

The lower end of the pivot bracket 220 is coupled to the fixed bracket 210 to be rotated by a predetermined angle. This will be described in detail later with the fine adjustment 240. The rotating bracket 220 is coupled to the outside of each of the two side plates 211 of the fixing bracket 210 is made of two. The upper end of the rotating bracket 220 is coupled to the polar housing 120 to be rotatable, for this purpose, the upper end of the rotating bracket 220 is provided with a rotating pin 232 coupled to the polar housing (120).

The coarse adjustment unit 230 is provided on the upper end of the rotating bracket 220 and the polar housing 120, by rotating the polar housing 120 with respect to the rotating bracket 220 within a predetermined angle range, the polar housing ( It is to act to quickly adjust the altitude of 120).

The coarse adjustment unit 230, the first slot 234 formed on the upper end of the rotation bracket 220, the first bolt inserted into the first slot 234 is fastened to the side of the polar housing 120 236 may include. The first slot 234 is formed in an arc shape centering on the pivot pin 232, and the angle range in which the polar housing 120 can be rotated depends on its length. A detailed operation of the coarse adjustment unit 230 will be described later.

The fine adjustment unit 240 is provided on the lower end of the rotating bracket 220 and the fixing bracket 210, by rotating the rotating bracket 220 with respect to the fixed bracket 210 within a predetermined angle range, the rotating bracket ( It is to act to finely adjust the altitude of the polar housing 120 coupled to the upper end of the 220.

The fine adjustment unit 240 includes a rotation means for rotating the rotation bracket 220, and a guide means for guiding the rotation of the rotation bracket 220 and limiting the rotation angle range. The rotation means, the fixed bar 241 is fixed to the lower end of the rotation bracket 220, the coupling member 242 coupled to the fixed bar 241, and the coupling member 242 is connected to the coupling member It may include a fine screw 244 for reciprocating the movement (242), the guide means, the second slot 247 formed in an arc shape on the lower end of the rotation bracket 220, and the second slot 247 It may include a second bolt 236 is inserted into and fastened to the side of the fixing bracket 210.

Specifically, the fixing bar 241 connects two pivot brackets 220 and both ends are fixedly installed on the inner side surfaces of the two pivot brackets 220. As will be described later, the fixing bar 241 is moved by the rotation of the fine screw 244, in this case, in order to avoid the fixing bar 241 interfere with the fixing bracket 210, the fixing bracket 210 Each of the two side plates 211 of the fixing bar moving groove 213 is formed.

The coupling member 242 may have, for example, a substantially rectangular parallelepiped shape, and a fixing bar insertion groove 243 into which the fixing bar 241 is inserted is formed at an upper surface thereof.

The fine screw 244 is inserted into the connecting plate 212 of the fixing bracket 210 horizontally, the front end is fastened to the coupling member 242. A knob 245 is provided at a rear end of the fine screw 244 so as to easily turn the fine screw 244.

When the fine screw 244 is rotated, the coupling member 242 is reciprocated horizontally moving in accordance with the rotation direction, and the fixing bar 241 coupled to the coupling member 242 is also moved, the fixed bar The rotating bracket 220 connected to the 241 is rotated. This will be described later.

The second slot 247 is formed in an arc shape at the lower end of the rotation bracket 220. A second bolt 246 fastened to an outer surface of the side plate 211 of the fixing bracket 210 is inserted into the second slot 247. The second slot 247 and the second bolt 246 guide the rotation of the rotation bracket 220 with respect to the fixed bracket 210, and also the rotation angle range of the rotation bracket 220 with respect to the fixed bracket 210. It will act to limit. Two second slots 247 and two bolts 246 may be provided, and the second slots 247 and the second bolts 246 may be spaced apart by a predetermined interval along the rotation direction of the rotation bracket 220.

Hereinafter, the operation of the altitude control device 200 of the equator 100 having the above configuration will be described.

6a to 6c are views for explaining the operation of the altitude control apparatus according to the embodiment of the present invention shown in Figs.

First, referring to FIG. 6A, the range of the rotation angle α of the polar housing 120 with respect to the rotation bracket 220 may be set to, for example, 30 ° (30 ° to 60 °), and the fixing bracket 210 may be used. The rotation angle β range of the rotation bracket 220 relative to may be set to, for example, 10 ° (-5 ° to + 5 °). The pivot center of the polar housing 120 becomes the pivot pin 232, but the pivot center 232 of the polar housing 120 and the pivot center P of the pivot bracket 220 need not coincide with each other. Therefore, the rotation center P of the rotation bracket 220 may be located at any position to allow the rotation bracket 220 to rotate stably.

For example, to adjust the altitude of the polar axis Ca with respect to the horizontal plane H at 25 °, first, loosen the first bolt 236 of the coarse adjustment unit 230, and the rear end of the polar housing 120 is loosened. The first bolt 236 is lifted until it is at the top of the first slot 234. Then, the polar housing 120 is rotated to the maximum in the clockwise direction, if the first bolt 236 is firmly tightened in this state, the polar housing 120 is fixed to the rotation bracket 220.

Next, loosely loosen the second bolt 246 of the fine movement adjusting unit 240, by turning the fine screw 244 to move the coupling member 242 and the fixing bar 241 in the direction of arrow A. Then, the rotation bracket 220 is rotated in the clockwise direction until the second bolt 246 comes to the right end of the second slot 247, and in this state, if the second bolt 246 is firmly tightened, the rotation bracket The bracket 220 is fixed to the fixing bracket 210. Accordingly, as shown in FIG. 6A, the altitude of the polar axis Ca is adjusted to 25 ° and then fixed.

On the other hand, in order to adjust the altitude of the polar axis Ca to 30 °, loosen the second bolt 246 of the fine motion control unit 240 in the above state, and turn the fine screw 244 to rotate the second bolt ( The coupling member 242 and the fixing bar 241 are moved in the opposite direction of the arrow A until 246 is in the middle of the second slot 247. Then, the rotating bracket 220 is rotated 5 ° counterclockwise, the altitude of the polar axis Ca is adjusted to 30 °.

If you want to adjust the altitude of the polar axis Ca to 35 °, loosen the second bolt 246 of the fine control unit 240 in the above state, and turn the fine screw 244 to rotate the second bolt ( The coupling member 242 and the fixing bar 241 are moved in the opposite direction of the arrow A until 246 is at the left end of the second slot 247. Then, the rotation bracket 220 is rotated again by 5 ° counterclockwise, the altitude of the polar axis Ca is adjusted to 35 °.

Next, referring to FIG. 6B, when the altitude of the polar axis Ca with respect to the horizontal plane H is set to 45 °, first, the first bolt 236 of the coarse adjustment unit 230 is loosened and the polar housing ( The rear end of 120 is lowered until the first bolt 236 is in the middle of the first slot 234. Then, the polar housing 120 is rotated about 15 degrees counterclockwise, and in this state, if the first bolt 236 is tightened firmly, the polar housing 120 is fixed to the rotation bracket 220.

Next, loosen the second bolt 246 of the fine movement control unit 240, by turning the fine screw 244 to move the coupling member 242 and the fixing bar 241 in the direction of the arrow B. Then, the rotating bracket 220 is rotated 5 ° counterclockwise until the second bolt 246 comes to the middle portion of the second slot 247, in this state to firmly tighten the second bolt 246 Clamping, the rotation bracket 220 is fixed to the fixing bracket (210). Accordingly, as shown in FIG. 6B, the altitude of the polar axis Ca is adjusted to 45 ° and then fixed.

On the other hand, by operating the fine screw 244 of the fine control unit 240 in the above state can adjust the altitude of the polar axis (Ca) within the range of 40 ° ~ 50 °.

Finally, referring to FIG. 6C, when the altitude of the polar axis Ca with respect to the horizontal plane H is set to 65 °, first, the first bolt 236 of the coarse adjustment unit 230 is loosened and the polar housing ( The rear end of 120 is lowered until the first bolt 236 is at the lower end of the first slot 234. Then, the polar housing 120 is rotated to the maximum in the counterclockwise direction, if the first bolt 236 is firmly tightened in this state, the polar housing 120 is fixed to the rotation bracket 220.

Next, loosen the second bolt 246 of the fine movement control unit 240, by turning the fine screw 244 to move the coupling member 242 and the fixing bar 241 in the direction of the arrow B. Then, the rotating bracket 220 is rotated in the counterclockwise direction until the second bolt 246 comes to the left end of the second slot 247, and in this state to tighten the second bolt 246 firmly, The rotating bracket 220 is fixed to the fixing bracket 210. Accordingly, as shown in FIG. 6C, the altitude of the polar axis Ca is adjusted to 65 ° and then fixed.

On the other hand, by operating the fine screw 244 of the fine control unit 240 in the above state can adjust the altitude of the polar axis (Ca) within the range of 55 ° ~ 65 °.

As described above, according to the altitude control apparatus 200 of the equator 100 according to the embodiment of the present invention, the altitude of the polar axis Ca can be quickly adjusted by using the coarse adjustment unit 230 at first. Subsequently, the fine movement adjusting unit 240 may adjust the altitude of the polar axis Ca precisely and finely to a desired altitude. Therefore, there is an advantage that the altitude adjustment can be made accurately and easily and quickly.

And, the altitude control of a wide range is performed by the coarse adjustment unit 230, and the altitude control by the fine adjustment unit 240 can be set in the range of approximately 10 °, without having to replace the fine screw 244 Only one fine screw 244 has the advantage of controlling the altitude of the polar axis (Ca) in a wide range.

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 scope of the present invention. Accordingly, the true scope of protection of the present invention should be defined by the appended claims.

20 telescopes 30
100 ... equatorial 110 ... bass
120 ... Axial Housing 130 ... Axial Housing
140 ... balance 200 ... adjustment
210 ... Fixing bracket 211 Side plate
Connection plate 213
220 ... Rotating Bracket 230 ... Coarse Control
232 ... Rotating pin 234 ... Slot 1
236.No.1 bolt 240 ... Sliding adjustment part
241 fixing bar 242 coupling member
243.Fit bar insertion groove 244 Fine thread
245 Knob 246 Second bolt
247 ... slot 2

Claims (6)

In the equatorial altitude control device for astronomical telescope comprising a base, a polar housing installed on the base and a declination shaft housing coupled to be orthogonal to the upper end of the polar housing,
A fixed bracket fixed to the base;
A lower end rotatably coupled to the fixed bracket, and an upper end rotatable bracket coupled to the polar housing;
A coarse adjustment unit provided at an upper end portion of the pivot bracket and the polar housing to rotate the polar housing within a first angle range with respect to the pivot bracket; And
It is provided on the lower end of the rotation bracket and the fixed bracket, and the fine adjustment unit for rotating the rotation bracket with respect to the fixed bracket within a second angle range narrower than the first angle range; Equatorial altitude control device for astronomical telescopes. The method of claim 1,
The fixing bracket includes two side plates arranged side by side at a distance from each other, and a connecting plate connecting one end of each of the two side plates, and the rotation bracket is coupled to the outside of each of the two side plates of the fixing bracket. Equatorial altitude control device for astronomical telescope, characterized in that the. The method of claim 1,
The coarse adjustment unit, the height adjustment of the equator for the astronomical telescope, characterized in that it comprises a first slot formed in an arc shape on the upper end of the rotation bracket, and a first bolt inserted into the first slot and fastened to the polar housing. Device. 4. The method according to any one of claims 1 to 3,
The fine adjustment unit, the equatorial altitude control device for astronomical telescopes, characterized in that it comprises a rotation means for rotating the rotation bracket, and a guide means for guiding the rotation of the rotation bracket and limiting the rotation angle range. 5. The method of claim 4,
The rotating means includes a fixed bar fixed to the lower end of the rotating bracket, a coupling member coupled to the fixed bar, and a fine screw connected to the coupling member to reciprocally move the coupling member.
The guide means, the height adjustment of the equator for the astronomical telescope, characterized in that it comprises a second slot formed in an arc shape in the lower end of the rotation bracket, and a second bolt inserted into the second slot and fastened to the fixing bracket. Device. 6. The method of claim 5,
The fine screw is inserted into the fixing bracket to horizontally penetrate, the front end is fastened to the coupling member, the rear end of the celestial telescope height adjustment device, characterized in that the knob is provided.

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