KR200387117Y1 - 3d optical instrument stand - Google Patents

Abstract

The present invention relates to a cradle, in particular, the guide rail, guide rods and coupling means are provided on the frame, and the rotation means are provided on the cradle, so that the installation position and angle can be freely moved and rotated while fixing optical devices such as scanners. The present invention relates to a three-dimensional optical device holder that can be conveniently operated without changing the position of a subject to be photographed.

The present invention is a lower horizontal frame protruding in parallel to a pair of guide rails along the longitudinal direction on the upper surface; A vertical frame having a pair of grooves slidingly coupled to the guide rails on a lower surface thereof, the guide rods being vertically fixed along the longitudinal direction; An upper horizontal frame coupled to the guide rod at one side thereof and having a coupling means for sliding and rotating; And rotation means coupled to the other end of the upper horizontal frame to be rotatable, and is made of a cradle on which an optical device is mounted.

Description

3-D Optical Instrument Cradle {3D OPTICAL INSTRUMENT STAND}

The present invention relates to a cradle, and more particularly, to a cradle of a three-dimensional optical device that can conveniently adjust the position and angle in the state where the optical device is installed to perform three-dimensional shooting without moving the subject conveniently will be.

Optical devices use reflection, absorption, refraction, interference, and diffraction, which are the characteristics of light radiated from the sun or electric light, to form images of objects in space or to analyze the radiation emitted from an object to analyze its properties. Say the device to study.

Among them, the recording of images generated by the lens and the purpose of reproducing them (cameras, video cameras, scanners, projectors, etc.) allow the photographer to work while holding the optics and move directly, or instead move the subject. do.

However, when a photographer is working directly with an optical device when a still subject is to be photographed at various angles, there is a problem that it is difficult to obtain an accurate photographing image in a state where the optical device is completely stopped.

Therefore, in general, the optical device is photographed in a state where a tripod, such as a tripod, the tripod is provided with three legs of a certain angle on the body and a sunter leg in the center, each leg is to be able to adjust the angle.

In addition, each of the legs is installed so that a plurality of cylinders of different diameters sliding each other is configured to adjust the height of the entire tripod by the sliding action.

However, such a tripod does not have a separate means for adjusting the angle of the installed optics itself, and it is difficult to adjust the three legs at an exact angle, and the joint between the legs and the body becomes loose after long use. The adjustment becomes more difficult.

In addition, due to the limitation of optics that can only shoot angles within a certain range of the front, when a tripod is installed, only the movement of the subject in a certain space in front can be recognized, and in order to shoot another part of the subject, the tripod must be completely reinstalled. there is a problem.

Of course, there is already a system that can remotely control the video equipment to shoot the movement of the subject while changing the location, but it is not available to the general public because expensive equipment is required to remotely control the camera. .

The present invention has been devised to solve the problems of the prior art as described above, the manufacturing cost is low due to the simple structure, and the position and angle of the imaging device can be conveniently used without moving the subject while the imaging device is installed. Its purpose is to provide a three-dimensional optical device holder that can be freely adjusted to make accurate three-dimensional imaging.

The three-dimensional optical device holder of the present invention for achieving the above object is a lower horizontal frame protruding parallel to the guide rail along the longitudinal direction on the upper surface;

A vertical frame having a pair of grooves slidingly coupled to the guide rails on a lower surface thereof, the guide rods being vertically fixed along the longitudinal direction;

An upper horizontal frame coupled to the guide rod at one side thereof and having a coupling means for sliding and rotating; And

Rotating means is rotatably coupled to the other end of the upper horizontal frame, characterized in that made of a cradle to which the optical device is mounted.

In addition, the rotation means of the cradle is characterized in that the ratchet member consisting of a wheel with a rack gear formed on the outer circumferential surface and a locking pin to adjust the angle of the wheel to be caught by the rack gear of the wheel.

In addition, the latch pin of the ratchet member is selectively caught on the upper or lower portion of the rack gear is characterized in that the rotational direction of the wheel can be selected.

Alternatively, the rotating means of the cradle is characterized in that the ball joint consisting of a ball nipple having a ball formed on one side and a ball receptor coupled to the ball of the ball nipple.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a front view showing a three-dimensional optical device holder according to the present invention, Figure 2 is a plan view showing a three-dimensional optical device holder according to the present invention, Figure 3 is a left (3) a), right (b) side view, Figure 4 is a plan view showing an embodiment of the three-dimensional optical device holder according to the present invention.

As shown, the three-dimensional optical device holder of the present invention is composed of a lower horizontal frame 10, a vertical frame 20, the upper horizontal frame 30 and the holder 40.

The lower horizontal frame 10 is a horizontal thin rectangular plate installed horizontally and a pair of guide rails 11 protruding in a narrow width along the longitudinal direction on the upper surface is formed in a pair, the lower surface firmly secures the entire cradle A plurality of pedestals 12 are coupled along the edge to support them.

The vertical frame 20 is a long rectangular plate body installed vertically, and a pair of grooves 21 are coupled to the guide rails 11 of the lower horizontal frame 10 and slide on the lower surface thereof, and the guide rods 22 are formed. ) Is fixedly installed vertically along the longitudinal direction.

The upper horizontal frame 30 is coupled to the guide rod 22 of the vertical frame 20 at one side thereof is provided with a tubular coupling means 31 for sliding up and down as well as rotating left and right.

The cradle 40 is 'b' shaped as the optical device (S) is mounted, the rotating means is coupled to one side rotatably to the other end of the upper horizontal frame (30).

In one embodiment of the present invention, as shown in Figure 2 the rotation means of the cradle 40 may be composed of a conventional ratchet member 50, the ratchet member 50 is a wheel 51 and the engaging pin Consists of 52.

Wheel 51 has a rack gear (51a) is formed on the outer circumferential surface, the engaging pin 52 is the wheel 51 so that the end thereof is caught in the rack gear of the wheel 51 in order to adjust the angle of the wheel 51 Fixed installation close to.

In particular, when the locking pin 52 of the ratchet member 50 is fixedly installed to be rotatable based on a point spaced apart from the wheel 51 by a fixed distance, the rack gear may be rotated and fixed by the locking pin 52. The rotation direction of the wheel 51 can be selected by being selectively caught on the upper or lower portion of the 51a).

In another embodiment of the present invention, as shown in Figure 4, the rotation means of the cradle 40 may be composed of a ball joint 60, the ball joint 60 is the ball nipple 61 and the ball receptor It consists of 62.

The ball nipple 61 has a ball 61a protrudingly formed at one side thereof, and the ball receiver 62 stably accommodates the ball 61a formed at the ball nipple 61 from the outside so that the ball 61a is not detached. Allow it to rotate in it.

As described above, when the rotating means of the holder 40 is configured by the ball joint 60, it can be rotated three-dimensionally, so that the angle of the optical device can be adjusted more broadly than when the ratchet member 50 is configured.

In addition to the above embodiment, the rotating means of the lower horizontal frame 10, the vertical frame 20, the upper horizontal frame 30 and the cradle 40 is equipped with a drive motor or the like or by using various actuators of the movement or rotation It will be apparent to those skilled in the art that fine tuning or remote control can be configured.

The three-dimensional optical device holder of the present invention configured as described above acts as follows.

First, the guide rail 11 of the lower horizontal frame 10 and the groove 21 of the vertical frame 20 are used in accordance with the position of the subject to be photographed while the optical device S is mounted on the holder 40. By sliding the vertical frame 20 horizontally to adjust its position.

Then, using the guide rod 22 of the vertical frame 20 and the coupling means 31 of the upper horizontal frame 30, the upper horizontal frame 30 is slid up and down, and at the same time rotated to the left and right to adjust its position. do.

As such, when the positions of the vertical frame 20 and the upper horizontal frame 30 are properly adjusted, fine adjustment is made for photographing by using the rotating means of the holder 40 on which the optical apparatus S is mounted.

That is, in one embodiment of the present invention, when the rotation means of the holder 40 is configured as a ratchet member 50 as shown in Figure 2 by finely adjusting the angle of the holder 40 by rotating the wheel 51 After that, the locking pins 52 are fixed to the rack gears 51a of the wheels 51 by walking.

At this time, when the locking pin 52 is fixedly installed to be rotatable based on a point spaced apart from the wheel 51 by a fixed distance, the locking pin 52 is rotated to selectively walk on the upper or lower portion of the rack gear 51a. The direction of rotation of the 51 can be limited in one direction.

On the other hand, in another embodiment of the present invention, as shown in Figure 4, when the rotation means of the holder 40 is composed of a ball joint 60, the ball 61a of the ball nipple 61 and the ball receiving it By freely rotating the ball nipple 61 using the receptor 62, a wide three-dimensional angle adjustment of the holder 40 is possible.

Other lower horizontal frame 10, the vertical frame 20, the upper horizontal frame 30 and the use of a separate drive motor or various actuators in the rotation means of the cradle 40 due to the configuration that is added in part to each frame 10 The movement of the 20 and 30 or the rotation of the holder 40 becomes more fine and remote control may be possible.

Since the three-dimensional optical device holder of the present invention configured as described above has a simple structure, the manufacturing cost is low, and the installation position and angle can be freely adjusted three-dimensionally by moving and rotating the optical device such as a scanner in a fixed state. It is useful for accurate and convenient work without moving the position of the subject to be photographed.

Although the present invention has been described in detail only with respect to the described embodiments, it will be apparent to those skilled in the art that various changes or modifications can be made within the spirit and scope of the present invention. It shall fall within the scope of the attached utility model registration request.

1 is a front view showing a three-dimensional optical device holder according to the present invention,

2 is a plan view showing a three-dimensional optical device holder according to the present invention,

3 is a side view showing a three-dimensional optical device holder according to the present invention,

Figure 4 is a plan view showing an embodiment of a three-dimensional optical device holder according to the present invention.

<Explanation of symbols for the main parts of the drawings>

10: lower horizontal frame 11: guide rail

12: base 20: vertical frame

21: groove 22: guide rod

30: upper horizontal frame 31: coupling means

40: holder 50: ratchet member

51: wheel 51a: rack gear

52: locking pin 60: ball joint

61: ball nipple 61a: ball

62: ball receptor S: optical instrument

P: Subject Mount

Claims (4)

A lower horizontal frame on which a pair of guide rails protrude in parallel along the longitudinal direction; A vertical frame having a pair of grooves slidingly coupled to the guide rails on a lower surface thereof, the guide rods being vertically fixed along the longitudinal direction; An upper horizontal frame coupled to the guide rod at one side thereof and having a coupling means for sliding and rotating; And A three-dimensional optical device holder, characterized in that the rotating means is coupled to the other end of the upper horizontal frame rotatably, and made of a cradle to which the optical device is mounted. The method of claim 1, Rotating means of the cradle is a three-dimensional optical device cradle, characterized in that the rack gear is formed on the outer circumferential surface and the ratchet member consisting of a locking pin to adjust the angle of the wheel to be caught by the rack gear of the wheel. The method of claim 2, The latch pin of the ratchet member is selectively hung on the upper or lower portion of the rack gear, characterized in that the three-dimensional optical device cradle that can select the rotation direction. The method of claim 1, Rotating means of the holder is a three-dimensional optical device holder, characterized in that the ball joint consisting of a ball nipple and a ball receptor coupled to the ball of the ball nipple is formed on one side.