KR101270215B1 - Celestial body observatory with auto sliding roof - Google Patents

Abstract

The present invention is equipped with an automatic sliding loop for easy observation of the celestial body by easily and fully open the sliding loop when observing the celestial body while safely storing expensive astronomical observation equipment such as astronomical telescope in the station. To an astronomical observatory.
The present invention implements the automatic opening and closing of a pair of sliding loops installed in the upper part of the astronomical station by automatically closing the sliding loops in order to protect various astronomical observation equipments safely, and simultaneously opening the sliding loops to both sides during celestial observation. It is a characteristic gist of the invention to facilitate observing the celestial body.

Description

Celestial body observatory with auto sliding roof

The present invention relates to a technique for easily observing a celestial body by fully opening the sliding loop completely and automatically when observing celestial objects while safely storing expensive astronomical observation equipment such as astronomical telescopes in the station.

The celestial body is becoming an area of interest to more people than in the past, and its number is gradually increasing to professionals who study the field as well as club members who meet regularly with special interest. At the same time, the movement of people to disseminate and popularize it is increasing.

However, most of them are using astronomical observations to obtain data from a few astronomical observatories or to help them. Many people find it difficult to use these facilities at the time and place they need.

In addition, in order to observe the celestial bodies, astronomical observation equipment such as expensive astronomical telescopes is required. It takes a lot of time to locate the astronomical observation equipment in a place where it can be easily observed. It takes a lot of time.

Therefore, when observing the celestial body while being able to keep it safe at all times while preventing theft without the hassle of installing or removing the astronomical observation equipment, an observatory of a small structure that can open and close the upper roof is urgently required.

As a prior art related to such an astronomical observatory, "Korean Utility Model Registration No. 207980, a special vehicle having a dome-shaped structure for observing a celestial object rotated by name / electricity" has been proposed.

The above-mentioned prior art provides a special type of container separated into an observation room and a control room, an astronomical telescope is mounted inside the observation room, and a hemispherical dome rotatable protruding outward is formed on the upper part of the observation room. To make astronomical observation convenient

The ability to approach and show the public directly to the public that requires viewing has the effect of heightening interest in the celestial body.

However, the above-mentioned prior art has a small opening area of the dome even when the door formed in a part of the hemispherical dome is completely open and closed, so it is impossible to observe in various directions during astronomical observation. It is inconvenient, and in particular, as the rotating structure of the hemispherical dome is further configured, the structure becomes complicated and the manufacturing cost increases.

In addition, in the prior art it is vaguely mentioned that the opening and closing of the door may be configured in various forms such as a sliding method and a sliding method, it is a situation that the technical configuration that can actually implement this is not clearly shown.

The present invention is to actively solve all the problems of the prior art, the automatic opening and closing of a pair of sliding loops installed on the top of the astronomical observation station by closing the sliding loops in ordinary times, various astronomical observation equipment In order to protect the safety, and to observe the celestial object to open the sliding loop to both sides at the same time to facilitate the observing the object of the invention.

The present invention rotatably installs a driven pinion in the center of the roof guide rail attached to the front and rear wall of the observation room as a means for solving the above problems, respectively, on one side upper and the other lower portion of the roof guide rail A plurality of upper and lower guide rollers are rotatably installed, and a pair of sliding loops are installed to face the upper part of the observation chamber, and the upper rack is fixed to the bottom of the loop slider installed at the front and rear inner surfaces of the one sliding loop. The roof slider is installed to engage the driven pinion and the upper rack while being guided by the lower guide roller, and fixedly installs the lower rack on the upper surface of the loop slider installed at the front and rear inner surfaces of the other sliding loop. The slider engages the driven pinion and the lower rack while being guided by the lower guide roller. On the other hand, one side of the station is installed on the inner side of the station through the front and rear wall of the power shaft selectively rotates according to the operation of the loop open and close the motor, the drive pinion coupled to the both ends of the power shaft is the technology to install the upper rack and engagement Take a look.

According to the present invention, by closing the sliding loop installed on the top of the usual astronomical observation station, it is possible to safely keep astronomical observation equipment at all times regardless of weather conditions as well as to prevent theft, without the hassle of installing or removing astronomical observation equipment every time It provides the effect of observing celestial bodies quickly and easily.

In addition, when observing the celestial body, not only can the sliding loop be fully opened automatically and completely, but also a wide open area can be conveniently observed in various directions without any hassle, and the overall structure of the astronomical station is very simple. By reducing the cost, the astronomical observatories can be widely distributed to the general public, thereby contributing to the popularization of astronomical observations.

1 is a front view of an astronomical observatory to which the present invention is applied.
2 is a side cross-sectional view of an astronomical station to which the present invention is applied.
Figure 3 is a front view of a state in which the sliding loop of the present invention is open at the same time
Figure 4 is a side cross-sectional view of the loop opening and closing motor, the power shaft, the drive pinion and the upper rack of the present invention.
5 is an enlarged view of a portion A of the present invention Figure 2
6 is an operational front view of the driven pinion, the upper rack and the lower rack of the present invention.
Figure 7 is a side cross-sectional view of the installation state of the upper rack, loop slider and sliding loop of the present invention
Figure 8 is a side cross-sectional view of the installation state of the lower rack, loop slider and sliding loop of the present invention
9 is a cross-sectional view of the installation state of the close detection device and the proximity sensor of the present invention
10 is a cross-sectional view of the installation state of the open sensing rail and limit switch of the present invention.
Figure 11 is an enlarged cross-sectional view of the installation state of the leak-proof frame, waterproof cover and rainwater drainage of the present invention

Preferred embodiments of the present invention will now be described in more detail with reference to the accompanying drawings.

First of all, according to the accompanying drawings, the overall technical configuration according to a preferred embodiment of the present invention is briefly observed. An observation in which a pair of loop guide rails 13 are integrally installed on the upper and rear walls 11 and 12 is integrated. Thread 10; A driven pinion (20) rotatably installed in the center of the loop guide rail (13); A plurality of upper and lower guide rollers 30 and 30a rotatably installed in the upper and lower guide grooves 13a of the roof guide rail 13, respectively; A pair of sliding loops (40) (40a) installed on the upper side of the observation chamber (10) to selectively open and close the upper portion of the observation chamber (10); A loop slider (50) (50a) connected to the front and rear inner surfaces of the sliding loop (40) (40a) and slidingly moving on the upper and lower guide rollers (30) (30a); An upper rack (60) integrally attached to a bottom surface of the loop slider (50) and installed in engagement with the driven pinion (20); A lower rack (70) integrally attached to an upper surface of the loop slider (50a) and engaged with the driven pinion (20); A power shaft 80 installed through the front and rear walls 11 and 12 so as to be selectively reversely rotated according to the operation of the loop opening / closing motor 83 on one side of the observation chamber 10; It can be seen that it is integrally coupled to both ends of the power shaft 80, and made of an organic coupling configuration of the drive pinion 90 is meshed with the upper rack (60).

Hereinafter, the present invention having the above-described schematic configuration will be described in more detail for facilitating the implementation.

First of all, the observation room 10 of the present invention is not only to securely store expensive observing equipment at all times but also to prevent theft. The upper part is opened to observe the celestial body when the sliding loops 40 and 40a are opened. It is configured in the form of a rectangular body, a pair of loop guide rails 13 are integrally installed on the outer surfaces of the front and rear walls (11, 12), respectively, and the front wall (11) for entering and exiting the observer The door 14 is installed.

Here, the roof guide rail 13 has an outer center in the longitudinal direction thereof, and guide grooves 13a are recessed in the upper and lower portions thereof.

The pinion mounting plate 21 is installed in the center of the loop guide rail 13 to be connected up and down, and the pinion mounting plate 21 is rotatably installed, and the driven pinion 20 is The upper and lower pair of loop sliders 50 and 50a serve as mediators to move to both sides or to the center while simultaneously interlocking with each other.

In addition, a plurality of upper and lower guide rollers for guiding the left and right movement of the loop sliders 50 and 50a in the guide groove 13a and the lower guide groove 13a of the upper side of the roof guide rail 13, respectively. 30 and 30a are provided at a distance.

A pair of sliding loops 40 and 40a are disposed to face each other at an upper portion of the upper open observation chamber 10, and the sliding loops 40 and 40a are open while moving to both sides at the same time or simultaneously. By closing while moving to the center serves to selectively open and close the upper portion of the observation chamber (10).

The sliding loops 40 and 40a are installed at the front and rear inner surfaces of the angle bar 41 by penetrating through the pieces 42, and the loop sliders 50 and 50a are disposed at the inner end of the angle bar 41. Each is integrally connected and installed, the loop sliders 50 and 50a are coupled to slide left and right by upper and lower guide rollers 30 and 30a.

At this time, the upper rack 60 is integrally attached to the bottom surface of the one-side loop slider 50, the upper rack 60 is meshed with the upper side of the driven pinion 20, while the other side of the loop slider 50a The lower rack 70 is integrally attached to the upper surface, and the lower rack 70 is engaged with the lower side of the driven pinion 20.

Therefore, when the upper rack 60 moves to the left in the drawing as shown in FIG. 6, the driven pinion 20 coupled with the upper rack 60 transmits rotational power to the lower rack 70 while rotating counterclockwise. The lower rack 70 is moved to the right in the drawing, so that the pair of loop sliders 50 and 50a interlock and move to both sides or to the center at the same time, so that the sliding loops 40 and 40a are automatically moved. It opens and closes smoothly, especially by simultaneously opening on both sides, opening the entire upper part of the observation room 10 to secure a wider open area, thus providing a special effect that can conveniently observe the object from various directions without any hassle. do.

On the other hand, a plurality of support brackets 81 are attached to one side of the inner surface of the observation chamber 10, and the power shaft 80 is rotatably installed through the bearing unit 82 installed in the support bracket 81. The power shaft 80 is installed to penetrate the front and rear walls 11 and 12 to be exposed to the outside.

In addition, a loop open / close motor 83 is fixedly installed on the support bracket 81 attached to the inner surface of the observation chamber 10, and a main gear 84 coupled to the motor shaft 83a of the loop open / close motor 83. Is engaged with the driven gear 85 installed in the power shaft 80, the both ends of the power shaft 80 is coupled to the drive pinion 90 for transmitting the rotational power to the upper rack 60, this drive The pinion 90 is engaged with the upper rack 60, while the loop opening / closing motor 83 and the power shaft 80 are installed to surround the protective cover 87 so as not to be exposed to the outside.

Therefore, the rotational power according to the operation of the loop open / close motor 83 is transmitted to the power shaft 80 through the combination of the main gear 84 and the driven gear 85, the drive coupled to the power shaft 80 The rotational power of the pinion 90 is transmitted to the upper rack 60 to selectively move the upper rack 60 to the left and right according to the forward and reverse rotation direction of the power shaft 80, and is engaged with the upper rack 60 As the driven pinion 20 rotates, the lower rack 70 is moved left and right.

At this time, the upper rack 60 and the lower rack 70 is moved to both sides at the same time or to the center as shown in Figure 6 by sliding the sliding loop 40, 40a while moving to both sides at the same time or at the same time moving to the center It can be closed.

On the other hand, such a sliding loop 40, 40a is to be additionally grafted technology that automatically stops the closing operation when completely closed, the inner surface of the one side of the sliding loop 40 as shown in FIG. 100 is attached and the close detection port 100 is stopped by the loop opening and closing motor 83 automatically at the moment of detecting the proximity sensor 101 installed on the rear wall 12 of the observation room 10 above the It provides the effect of stopping the closing operation of the sliding loop 40 (40a).

In addition, the sliding loop 40, 40a is to be further grafted to the technology that automatically stops the opening operation when fully open, the open detection rail 120 is integrally integrated into the inner surface of the sliding loop 40a. The sliding loop 40a is completely opened while the open sensing rail 120 is in contact with the limit switch 121 installed on the rear wall 12 of the observation chamber 10. 121 stops the opening and closing of the sliding loop 40 (40a) by automatically stopping the loop opening and closing motor 83 at the time of non-contact.

In the present invention, the sliding loops 40 and 40a face each other so that rainwater may be introduced into the observation chamber 10 through contact portions between the sliding loops 40 and 40a in a closed state. The leak prevention frame 130 is additionally attached to the front end and the upper surface, respectively, and the upper part of the leak prevention frame 130 of the one side sliding loop 40a in the state of overlapping the other side of the leak prevention frame 130. The waterproof cover 131 is additionally installed to effectively prevent rainwater from flowing into the observation chamber 10.

Furthermore, the rainwater drainage 135 having both sides open to the upper inner surface of the one side sliding loop 40 is additionally installed, so even if rainwater flows through the fine gap between the leak prevention frames 130, the rainwater drainage 135 After rainwater is collected, the rainwater is drained out of the front and rear walls 11 and 12 of the observation chamber 10 through the openings on both sides to completely block the inflow of rainwater into the inside of the observation chamber 10. It can provide special effects.

10: Observation Room 11: Front Wall
12: rear wall 13: roof guide rail
14: Door 20: driven pinion
30: upper guide roller 30a: lower guide roller
40, 40a: sliding loop 41: angle bar
50, 50a: loop slider 60: upper rack
70: lower rack 80: power shaft
82: bearing unit 83: loop open / close motor
84: main gear 85: driven gear
90: drive pinion 100: close detection port
101: proximity sensor 120: open detection rail
121: limit switch 130: leak prevention frame
131: waterproof cover 135: rainwater drainage

Claims (8)

An observation chamber (10) in which a pair of loop guide rails (13) are integrally installed on an outer surface of the front and rear walls (11, 12);
A driven pinion (20) rotatably installed in the center of the loop guide rail (13);
A plurality of upper and lower guide rollers 30 and 30a rotatably installed in the upper and lower guide grooves 13a of the roof guide rail 13, respectively;
A pair of sliding loops 40a and 40a which are installed to face each other on the upper side of the observation chamber 10 and selectively open and close the upper portion of the observation chamber 10 while slidingly moving to both sides or the center at the same time;
A loop slider (50) (50a) connected to the front and rear inner surfaces of the sliding loop (40) (40a) and slidingly moving on the upper and lower guide rollers (30) (30a);
An upper rack (60) integrally attached to a bottom surface of the loop slider (50) and installed in engagement with the driven pinion (20);
A lower rack (70) integrally attached to an upper surface of the loop slider (50a) and engaged with the driven pinion (20);
A power shaft 80 installed through the front and rear walls 11 and 12 so as to be selectively reversely rotated according to the operation of the loop opening / closing motor 83 on one side of the observation chamber 10;
Astronomical observatory with an automatic sliding loop, which is integrally coupled to both ends of the power shaft (80) and made of a drive pinion (90) engaged with the upper rack (60).
The method of claim 1,
The observatory with an automatic sliding loop, characterized in that the front wall 11 of the observation room 10 is provided with a door 14 for entry and exit.
The method of claim 1,
A pair of guide grooves 13a are recessed in the roof guide rails 13, and the pinion mounting plate 21 is installed in the center of the loop guide rail 13 to be connected up and down. A observatory with an automatic sliding loop, characterized in that the driven pinion (20) is rotatably installed in (21).
The method of claim 1,
The power shaft 80 is rotatably installed through the bearing units 82 respectively installed on the support bracket 81 attached to the inner surface of the observation chamber 10, and the driven gear 85 installed on the power shaft 80. ) Is an automatic sliding loop characterized in that it is meshed with the main gear 84 coupled to the motor shaft (83a) of the loop opening and closing motor 83 is fixed to the support bracket 81 attached to the inner surface of the observation chamber (10). Astronomical Observatory equipped.
The method of claim 1,
A close detector 100 is attached to the inner end of the sliding loop 40, and the close detector 100 is detected by the proximity sensor 101 installed on the rear wall 12 of the observation room 10. Observatory with an automatic sliding loop, characterized in that the closing operation of the sliding loop 40 is automatically stopped.
The method of claim 1,
An open sensing rail 120 is attached to an inner surface of the sliding loop 40a, and the open sensing rail 120 is in contact with the limit switch 121 installed on the rear wall 12 of the observation room 10. Observatory with automatic sliding loop, characterized in that the opening operation of the sliding loop (40a) is automatically stopped.
The method of claim 1,
The leak prevention frame 130 is further attached to the front end and the upper surface of the sliding loop 40, 40a facing each other, and the other leakage preventing frame 130 is disposed on the leak prevention frame 130 of the one sliding loop 40a. The observatory with an automatic sliding loop, characterized in that the waterproof cover 131 is further installed to cover the upper portion of the 130 in an overlapping state.
8. The method of claim 7,
The observatory with an automatic sliding loop, characterized in that the upper side of the upper side of the sliding loop 40 is installed in both sides of the rainwater drainage 135 is open.

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