KR101890171B1 - Imaging apparatus for manufacturing 3d figure and method thereof - Google Patents

Abstract

According to the present invention, an imaging device for 3D figure production comprises a camera mounting member (120) spaced from a figure original (Fi), and a camera mounting member And the camera installation member 120 is moved to form a closed path with respect to the figure original Fi and the camera installation member is moved to a closed path The camera 110 capturing the figure original Fi on the basis of the figure original Fi is closed with respect to the figure original Fi as shown in Fig. And a plurality of image images are acquired by capturing while moving along the path, and an imaging method for producing a 3D figure according to the present invention is characterized in that a figure original The camera 110 for picking up the image Fi captures a moving image so as to form a closed path with respect to the figure original Fi so as to obtain a plurality of image images. According to this, the number of cameras Can be greatly reduced.

Description

TECHNICAL FIELD [0001] The present invention relates to an imaging device for 3D figure production,

In particular, the present invention relates to a method of manufacturing a 3D figure by photographing a pre-existing figure with a camera, and more particularly, to a method of manufacturing a 3D figure by photographing a figure, The present invention relates to an imaging device for producing a 3D figure suitable for the following.

Typically, a figure is a 3D (3 Dimension) model that reproduces objects (buildings, vehicles, food, etc.), plants, animals, characters, celebrities, characters of animations and movies, And has exhibit value, can feel the feeling of three-dimensional feeling, and because of realistic depiction, it has excellent emotional input and delivery ability, and its use is expanding recently.

Among these figures are the so-called camera shooting method in which figures are created by taking pictures of figure objects (such as figures (family, friends, lovers), pets, symbol objects (vehicles, sports equipment, etc.) Is known.

A method of producing a figure using a camera in the above-described custom manufacturing method will be briefly described with reference to Fig.

FIG. 19 shows a flowchart of a method of photographing a typical camera to produce a figure.

As shown in FIG. 19, in a method of photographing a figure with a camera, the figure is photographed by a plurality of cameras provided in a fixed frame of a net shape in the room (S0).

Then, a video image (two-dimensional video data as video data) captured by a plurality of cameras (not shown) is transmitted to a caption computer (not shown), and the caption computer stores the received video image (S2).

The caption computer transmits the stored image to a 3D modeling processor computer (not shown), and the 3D modeling processor computer receives the 3D modeling data and generates 3D modeling data (S4).

Finally, a 3D printer (not shown) outputs the 3D figure based on the 3D modeling data and completes (S6).

Here, an apparatus and a method for photographing a figure material according to the prior art are as follows.

A plurality of cameras (for example, 85 to 95) are installed in the fixed frame of the mesh type, and a plurality of cameras are installed at the same time The figures were photographed.

The video images captured by the plurality of cameras (for example, 85 to 95) are transmitted to the caption computer as described above.

However, the apparatus and method for photographing the figure of the prior art have the following problems.

Conventionally, in order to acquire a video image for 3D modeling work, all the cameras need to be installed in a mesh-type fixed frame surrounding the figure figure, so that a large number of cameras are required so that the number of installed cameras is 85 to 95 . As such a large number of cameras were required, there was a problem of excessive expenditure in purchasing the camera.

In order to enclose a figure-shaped fixed frame for enclosing 85 to 95 cameras, the fixed frame of a net-like shape must first be made. In this case, A horizontal frame and a vertical frame are both required. Therefore, there is a problem that a manufacturing cost of a fixed frame in the form of a net for installing a camera is increased.

In addition, as described above, there is a problem that workability for installing approximately 85 to 95 cameras in a fixed frame of a mesh type is poor.

That is, in order to install the camera on the fixed frame of the mesh type, mounting brackets for installing the respective cameras were installed on the mesh fixing frame and the cameras were fixed to the mounting brackets.

In addition, in the case of the conventional camera imaging system, since shading has occurred, there has been a problem in that a correction operation after shooting has to be essentially performed.

Document 1: Published Patent Application No. 10-2006-0021767 (Publication Date: Mar. 08, 2006) Document 2: Published Patent Application No. 10-2015-0103898 (Published on September 14, 2015)

The object of the present invention is to provide an imaging device for 3D figure production according to the present invention,

First, a camera is installed in a camera mounting member such as a pole, which can move while forming a closed path to a figure original, instead of fixing the camera to a fixed frame in the form of a net, which is installed so as to surround the figure raw material, , The camera mounting member is rotated with respect to the figure original and the camera is imaged a plurality of times while the camera mounting member is rotated so that the number of cameras for photographing the figure original can be drastically reduced,

Secondly, since the number of cameras for photographing the figure object can be drastically reduced, the cost of producing a figure can be remarkably reduced,

Third, since only a camera mounting member such as a pole that can install the camera in the vertical direction can be provided without adopting a net-shaped fixed frame installed to surround the figure, the camera installation workability can be improved and the camera installation cost can be reduced And,

Fourth, since the camera mounting member is mounted on the moving means and the camera is rotated, the rotation of the camera can be smoothly and conveniently performed,

Fifth, by mounting the camera mounting member on the rotating body and rotating the camera, the rotation of the camera can be made more smooth and convenient,

Sixth, by configuring the moving means as a prime mover, the camera can be automatically and conveniently rotated,

Seventh, by adopting a rail and rotating the camera mounting member or the moving means along the rail, the rotation of the camera can be performed stably and conveniently,

Eighth, it is possible to make the portable and mobile installation work convenient by varying the pole for installing the camera,

Ninthly, the camera mounting members are provided in pairs so as to be spaced apart from each other, and the pair of camera mounting members are provided at the same horizontal height in correspondence with the cameras so that the camera can be stereoscopically imaged without a square angle at a horizontal angle Thereby eliminating the need to correct post-horizontal angles,

By arranging the camera on the camera mounting member as the tenth and specific photographing angle of the present invention, it is possible to make a stereoscopic image without a square at a vertical angle, thereby eliminating the need for a post-vertical angle correction operation,

Eleventh, the image storage and transmission means are installed at the upper part of the camera installation member so that the storage and transmission of the image image captured by the camera can be made convenient,

The twelfth, the configuration of one input means and the signal distributor makes it possible to simultaneously execute an image pickup command for all the cameras by one input means,

The controller is configured to automatically capture an image at a predetermined time period for a thirteenth time, so that the camera can be automatically picked up at regular intervals while being rotated, so that a necessary image can be automatically acquired while rotating 360 degrees,

And an image pickup device for producing a 3D figure which is suitable for allowing the camera to detect an imaging angle at the time of setting by providing the display means on one side of the camera mounting member.

According to an aspect of the present invention, there is provided an imaging device for producing a 3D figure, A figure production system for photographing a figure original as a camera, modeling the captured image as 3D data, and outputting a figure as a 3D printer based on the 3D modeling data, comprising: a camera installation member And a plurality of cameras provided along the height direction on the camera mounting member, wherein the camera mounting member is moved to form a closed contour with respect to the figure raw material apart from the figure raw material, And the camera images the figure raw material a plurality of times while the camera mounting member is moved in the closed path.

The image pickup apparatus for 3D figure production according to the present invention is characterized in that the camera setting member is rotated at 360 degrees with respect to the figure original by being spaced from the figure original and the camera rotates the image of the figure .

In the imaging device for 3D figure production according to the present invention, the camera installation member is constituted by a pole, and the cameras are provided in plural in the height direction along the pole.

The imaging device for 3D figure production according to the present invention is further comprised of a moving means for moving a figure original to form a closed path around the figure original, and the camera mounting member is mounted on the moving means and rotates.

In the imaging device for 3D figure production according to the present invention, the moving means is a castor member, and the camera mounting member is mounted on the castor member and rotates and moves.

In the imaging device for 3D figure production according to the present invention, the moving means is a rotating body rotating around the figure original, and the camera mounting member is mounted on the rotating body and rotates and moves.

The imaging device for 3D figure production according to the present invention is characterized in that the rotating body includes a rotating shaft which is rotatably installed on the floor and a rotating plate that rotates and rotates on the rotating shaft, and the camera mounting member is mounted on the rotating plate, .

The imaging device for 3D figure production according to the present invention is a prime mover in which the moving means rotates to form a closed path around the figure original, and the camera mounting member is mounted on the prime mover and rotates.

The imaging device for 3D figure production according to the present invention is further configured to include a rail formed to surround the figure raw material to form a closed circuit with respect to the figure original, .

The imaging device for 3D figure production according to the present invention is constituted by further comprising a rail formed to surround the figure stock Fi and forming a closed circuit with respect to the figure object, .

In the imaging device for 3D figure production according to the present invention, the height of the pole is variable.

The imaging device for 3D figure production according to the present invention is characterized in that the pole is composed of a plurality of elements coaxially and folded or unfolded in multi-stages, and the height is variable.

The imaging device for 3D figure production according to the present invention is characterized in that the camera mounting members are provided in pairs in mutually spaced relation and the camera is provided to correspond to the same horizontal height in the pair of camera mounting members .

In the imaging device for 3D figure production according to the present invention, a plurality of cameras provided on the camera installation member are divided into an upper end camera, a center camera, and a camera installed in three areas of the lower end camera, The center camera is installed to face the front, and the lower camera is installed to face upward.

The imaging device for 3D figure production according to the present invention is provided with an image storing and transmitting means for storing an image captured by the camera on one side of the camera mounting member and transmitting the stored image to a remote modeling computer .

The imaging device for 3D figure production according to the present invention is characterized in that it further comprises an input means for inputting an imaging operation command of the camera and a signal distributor for distributing the imaging operation command inputted from the input means to each camera .

The imaging device for 3D figure production according to the present invention is further characterized in that it is further comprised of a controller connected to the input means and configured to automatically perform imaging at a set time period.

The imaging device for 3D figure production according to the present invention is further provided with display means provided on one side of the camera installation member and for confirming the camera angle at which the camera picks up the image.

According to an aspect of the present invention, there is provided an imaging method for manufacturing a 3D figure, comprising: capturing a figure as an object to be produced by a camera as a camera, 3D modeling the sensed image, In the figure production method, a camera for picking up a figure figure is centered on a figure figure, and a plurality of images are acquired by picking up a figure while moving so as to form a closed path with respect to the figure figure.

The imaging method for 3D figure production according to the present invention is characterized in that the camera acquires a plurality of image images by imaging the figure's figure while rotating 360 ° around the figure's original.

An imaging method for manufacturing a 3D figure according to the present invention is characterized in that it is provided in a camera mounting member moving so as to form a closed path with respect to a figure figure, thereby picking up the figure figure.

The imaging method for 3D figure production according to the present invention is characterized in that the camera is provided on a rotating body rotating around the figure original to pick up a figure original.

The imaging apparatus for 3D figure production according to the present invention having the above-described configuration has the following effects.

First, a camera is installed in a camera mounting member such as a pole, which can move while forming a closed path to a figure original, instead of fixing the camera to a fixed frame in the form of a net, which is installed so as to surround the figure raw material, , The camera mounting member is rotated with respect to the figure original, and the method of picking up the figure original several times by the camera while the camera mounting member is rotated is adopted, whereby the number of cameras for photographing the figure original is drastically reduced There is an effect that can be.

Secondly, the number of cameras for photographing a figure object can be drastically reduced, and the cost of producing a figure can be remarkably reduced.

Third, since only a camera mounting member such as a pole that can mount the camera in the vertical direction can be provided without adopting a net-shaped fixed frame installed to surround the figure, the camera installation workability can be improved and the camera installation time can be reduced There is an effect that can be.

Fourth, there is an effect that the rotation of the camera can be smoothly and conveniently performed by mounting the camera mounting member on the moving means and rotating the camera.

Fifth, by rotating the camera with the camera mounting member mounted on the rotating body, the rotation of the camera can be smoothly and conveniently performed.

Sixth, there is an effect that the camera can be automatically and conveniently rotated by constituting the moving means with a prime mover.

Seventh, there is an effect that the rotation of the camera can be performed stably and conveniently by adopting the rails and rotating the camera mounting member or the moving means along the rails.

Eighth, a camera installation member such as a pole for installing a camera is variably implemented, so that the portable and mobile installation work can be made convenient.

Ninthly, the camera installation members are provided in a pair at mutual intervals d1 and the cameras are installed at the same horizontal height on the pair of camera installation members so as to correspond to each other by a couple so that there is no square angle at a horizontal angle, And as a result, there is no need to correct the post-horizontal angle.

By arranging the camera on the camera mounting member as the tenth and specific photographing angle of the present invention, it is possible to perform stereoscopic imaging without a square at a vertical angle, and as a result, there is an effect that correction work of a post vertical angle is unnecessary.

Eleventh, the image storage and transmission means are installed at the upper end of the camera installation member, so that it is possible to conveniently store and transmit the image image captured by the camera.

The twelfth, one input means and a signal divider have the effect of simultaneously executing an image pickup command for all the cameras with one input means.

The controller is configured to automatically capture an image at a predetermined time period for the thirteenth time, so that the camera can be automatically picked up at regular intervals while being rotated, and the necessary image can be automatically acquired while rotating 360 degrees.

By providing the display means on one side of the camera mounting member, it is possible to confirm the imaging angle of the camera at the time of setting.

FIG. 1 is a conceptual diagram of a method in which a camera 110 rotates to form a closed path C1 with respect to a figure original Fi in an imaging method for 3D figure production according to an embodiment of the present invention.
2 is a schematic plan view of FIG.
3 is a configuration diagram and an example of a use state of an imaging device for 3D figure production according to an embodiment of the present invention.
Fig. 4 is a plan view of Fig. 3. Fig.
5 is a configuration diagram and an example of a use state of a camera-mounting member 120 in which a casters member 130 as a moving means is provided in an imaging device for 3D figure production according to an embodiment of the present invention.
Fig. 6 is a plan view of Fig. 5. Fig.
7 is a configuration diagram and an example of a use state of the imaging device for 3D figure production according to an embodiment of the present invention when the rotating body 140, which is a moving means, is provided on the camera mounting member 120. FIG.
8 is a plan view of Fig.
9 is a configuration diagram and an example of a use state of the imaging device for 3D figure production according to an embodiment of the present invention, in which the prime mover 150, which is a moving means, is provided on the camera mounting member 120. FIG.
10 is a power transmission block configuration diagram of the prime mover 150 shown in FIG.
FIG. 11 is a plan view of the imaging apparatus for 3D figure production according to the embodiment of the present invention, in which a rail 160 for rotating the moving means is provided on the floor B. FIG.
12 is a conceptual diagram of an operation in which the prime mover 150 rotates on the rail 160 in the imaging device for 3D figure production according to an embodiment of the present invention disclosed in Fig.
13A and 13B are diagrams showing a modified example of the camera mounting member 120 in the imaging device for 3D figure production according to the embodiment of the present invention. 13 (b) is a conceptual diagram of a state in which the camera mounting member 120 is folded.
FIG. 14 is a view for explaining an image pickup apparatus for producing a 3D figure according to an embodiment of the present invention. In FIG. 14, camera setting members 120 are spaced apart from each other by a distance d1 for horizontal correction, And the cameras 110 are paired at the same position in the horizontal direction on the display unit 120. Fig.
Fig. 15 is a configuration diagram of the camera mounting member 120 provided with a pair of cameras in Fig.
16 is a diagram showing the configuration in the case where the display means 182 is provided on the camera mounting member 120 in the imaging device for 3D figure production according to the embodiment of the present invention.
17 is an enlarged view of an essential part and an example of a case where the camera 110 is mounted on the camera mounting member 120 by a mount bracket bk.
18 is a block diagram of a control block of an imaging device for 3D figure production according to an embodiment of the present invention.
19 is a flowchart of a method of photographing a typical camera to produce a figure.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A preferred embodiment of an imaging device for 3D figure production according to the present invention will be described in detail below with reference to the accompanying drawings.

The imaging device for 3D figure production described in the entire specification of the present invention strictly means an imaging device for a figure original, and the imaging method for 3D figure production strictly means a method of imaging a figure original.

As shown in the figure, an imaging device for 3D figure production according to an embodiment of the present invention picks up a figure original Fi as a production model (that is, a production target) of a figure as a camera 110, , A modeling system for modeling the sensed image image as 3D data and outputting a figure as a 3D printer based on the 3D modeling data, the system comprising: a camera mounting member (120) spaced from a figure original (Fi) , And a plurality of cameras (110) provided along the height direction on the camera mounting member.

At this time, the camera mounting member 120 is moved away from the figure stock Fi to form a closed contour C1 with respect to the figure stock Fi, and the camera mounting member 120 is moved And the camera 110 picks up the figure stock Fi multiple times while being moved to the closed path C1.

Specifically, the camera mounting member 120 rotates 360 degrees with respect to the figure stock Fi from the figure original Fi and rotates the camera 110 while the camera mounting member 120 rotates, Is adapted to pick up the figure stock Fi multiple times.

The closed path C1 is not a physical configuration but means a moving trajectory of the camera 110 or the camera mounting member 120. [

The closed path C1 is not necessarily limited to the garden, and the closed path C1 formed by the rotation is not necessarily limited to the garden.

According to the above configuration, since the camera 110 rotates while forming the closed path with respect to the figure, the number of cameras 110 is not required as in the prior art, and only a few (for example, about 4 to 9) Since it is possible to acquire image data for 3D modeling, the number of cameras 110 can be significantly reduced, which is advantageous in dramatically reducing the cost of 3D figure production.

The camera 110 photographs the figure original Fi a plurality of times while the camera mounting member 120 rotates 360 degrees and the figure original Fi is imaged a plurality of times so that the imaging regions overlap each other do.

Accordingly, there is an advantage that a video image for 3D modeling can be perfectly provided.

The image captured by the camera 110 is transmitted to the image storage and transmission unit 181.

In one embodiment of the present invention, the camera mounting member 120 may be formed of a bar-shaped pole as shown in FIG.

17, the camera 110 may be mounted on the camera mounting member 120 by, for example, a mounting bracket bk, and the mounting bracket bk itself is a known structure before the application.

Meanwhile, in one embodiment of the present invention, the camera mounting member 120 is formed of a rod-like pole, but the present invention is not limited thereto. The camera mounting member 120 may be a rectangular frame, The present invention is not limited to the above-described embodiments.

As shown in FIGS. 3 to 6, only one camera mounting member 120 is required, but the present invention is not limited thereto.

As shown in FIG. 7, the camera mounting members 120 are provided so as to be opposed to each other at intervals of 180 degrees.

According to this, there is an advantage in that the image pickup data of the figure source can be obtained even if the image is rotated by only 180 degrees, which is advantageous in that the image pickup operation time is quickened.

In addition, three camera installation members 120 are installed at intervals of 120 degrees.

According to this, there is an advantage that the image pickup data of the figure source can be obtained even if the image is rotated by only 120 degrees, which is advantageous in that the imaging operation time is further accelerated.

In addition, four camera mounting members 120 are provided at 90 intervals.

According to this, there is an advantage in that the image pickup data of the figure source can be obtained even if the image is rotated by only 90 degrees, which is advantageous in that the image pickup operation time is further accelerated.

In one embodiment of the present invention, the apparatus further comprises moving means 130,140,150 for moving the figure stock Fi to a closed path, and the camera mounting member 120 comprises a moving means 130,140,150, And is rotated and moved.

The moving means is, for example, a castor member 130, and the camera mounting member 120 is mounted on the castor member 130 and rotates.

The casters 130 include a caster frame 131 connected to the camera installation member 120 and a caster 132 installed on the caster frame 131.

The moving means is a rotating body 140 rotating around the figure original Fi and the camera mounting member 120 is mounted on the rotating body 140 and rotates.

The rotating body 140 includes a rotating shaft 141 rotatably mounted on a floor B and a rotating plate 142 rotatably mounted on the rotating shaft 141, And is mounted on the rotary plate 142 and rotates.
The camera mounting member 120 composed of the poles is installed upright on the rotation plate 142.

The rotating body 140 further includes a first bearing br1 installed on the floor B and a second bearing br2 inserted into the upper end of the rotating shaft 141, And the stage S is shrouded in the bearing br2.

The first bearing br1 is configured to include a mounting plate 143 provided on the bottom B to facilitate installation of the first bearing br1, And is installed at the lower end of the rotary shaft 141. [

The moving means is a prime mover 150 that rotates to form a closed path around the figure stock Fi and the camera mounting member 120 is mounted on the prime mover 150 and rotates .

The prime mover 150 includes a casing 151, a wheel 154 rotatably installed at a lower portion of the casing 151, a motor 152 provided inside the casing 151, And a power transmitting means (153) for transmitting the rotation of the wheel (152) to the wheel (154).

In one embodiment of the present invention, a rail 160 (FIG. 1) is provided on the floor B to form a closed circuit (physical path) with respect to the figure stock Fi, ) Of the first and second electrodes.

At this time, the moving means moves along the rail (160).

For example, when the moving means is the prime mover 150, it is preferable that the casing 151 of the prime mover 150 is provided with a guide member gd1 for guiding the rotation along the rail 160. [

It is preferable that a guide member (not shown) for guiding the rotation along the rail 160 is formed on one side of the frame 131 of the casters member 130 even when the moving means is the castor member 130 .

In the embodiment in which the moving means is not adopted, the camera mounting member 120 is directly moved along the rail 160.

At this time, a guide member (not shown) for guiding the rotation along the rail 160 may be formed on the lower end of the camera installation member 120.

In an embodiment of the present invention, as shown in FIG. 13, when the camera mounting member 120 is formed of a pole, the height of the pole is variable. Thereby, there is an advantage that the movement and the portability of the pole are improved.

The camera mounting member 120 is composed of a plurality of elements 120a, 120b, and 120c that are coaxially and folded or unfolded in multi-stages, and the height is variable.

The poles are folded in a height direction in a so-called telescopic manner, and each of the elements 120a, 120b, and 120c is folded out into multiple stages or folded into multiple stages inside.

In an embodiment of the present invention, as shown in FIGS. 14 and 15, the camera mounting members 120 are provided at a pair of spacing d1, The camera mounting member 120 is provided with a pair of lenses corresponding to the same horizontal height.

According to this, since images are taken in pairs in the horizontal direction, there is no square angle at the horizontal angle, and three-dimensional imaging is possible, and as a result, there is an advantage that correction work of the post horizontal angle is not necessary.

In an embodiment of the present invention, a plurality of cameras (e.g., nine cameras) provided on the camera installation member 120 are connected to three upper end cameras 110, three middle camera 110, and three lower end cameras 110 The upper camera 110 is installed to be inclined downward and to be directed downward. The center camera 110 is installed to face the front side, And the lower end camera 110 is installed so as to be upwardly inclined upward.

This is to enable three-dimensional imaging without a square at a vertical angle as an installation reference.

7, when the nine cameras 110 are installed, the camera installed at the uppermost position is installed at a higher position than the figure original Fi and is set so as to face the face portion of the figure original, The camera below the second camera is installed at a position slightly higher than the figure original and is set to face downward from the center of the figure circle and the camera below the third from the top is installed horizontally so as to face the face of the figure circle , The camera below the fourth from the top is tilted downward toward the lower side of the figure circle than the figure circle, and the camera in the middle is installed at the center of the figure circle so that the upper side The camera, which is located at the bottom of the camera in the middle, The third camera from the bottom is oriented downward and the second camera from the bottom is oriented toward the horizontal direction and the bottom camera is installed from the center of the figure to the top .

According to this camera angle structure, there is no square angle at a vertical angle, and stereoscopic imaging becomes possible, and as a result, there is an advantage that a post-vertical angle correction operation is not required.

In one embodiment of the present invention, an image storage and transmission means 181 for storing a video image captured by a camera 110 and transmitting the stored video image to a remote modeling computer 190 is connected to a camera installation member 120).

The image storage and transmission means 181 may be a computer or a microcomputer.

In one embodiment of the present invention, the camera 110 includes input means 171 for inputting an imaging operation command, a signal distributor for distributing an imaging operation command input from the input means 171 to each camera 110, (173) are further included.

In one embodiment of the present invention, a controller 172 connected to the input unit 171 and configured to automatically capture an image at a predetermined time period is further included.

In one embodiment of the present invention, the display device further includes display means (182) installed at one side of the camera installation member for confirming the camera angle at which the camera (110) captures an image. The display means (182) is a monitor.

Next, an imaging method for 3D figure production according to an embodiment of the present invention having the above-described structure will be described.

As shown in the conceptual diagram of photographing while the camera 110 rotates, as shown in FIGS. 1 and 2, a camera 110 (hereinafter referred to as a camera 110) for picking up a figure original Fi on the basis of a figure original Fi ) Is moved to form a closed path (C1) with respect to the figure primitive (Fi), thereby acquiring a plurality of image images.

Specifically, the camera 110 captures a plurality of image images by picking up the figure object Fi while rotating 360 ° about the figure original Fi.

At this time, the camera is installed on the camera mounting member 120 and rotates and moves, and picks up the figure stock Fi multiple times.

If there is only one camera-mounting member 120, it is required to rotate 360 degrees. In the case of a pair of facing camera-facing members as shown in FIG.

The image image obtained by the rotation is transmitted to the image storage and transmission means 181.

It will be apparent to those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or scope of the invention as defined in the appended claims. It is self-evident to those who have.

Therefore, the above-described embodiments are to be considered as illustrative rather than restrictive, and the present invention is not limited to the above description, but may be modified within the scope of the appended claims and equivalents thereof.

Fi: Figurative material S: Stage
110: camera 120: camera installation member
bk: mounting bracket 130: casters member
131: a caster frame 132: a caster
140: rotating body 141: rotating shaft
142: rotating plate 143: mounting plate
B: bottom br1: first bearing
br2: second bearing 150: prime mover
151: casing 152: motor
153: Power transmission means 154:
160: rail gd1: guide member
171: input means 172: controller
173: Signal distributor 181: Image storage and transmission means
182: display means

Claims (7)

The subject of the production of figures A figure production system for photographing a figure original (Fi) as a camera (110), modeling the captured image as 3D data, and outputting a figure as a 3D printer based on the 3D modeling data,
A camera mounting member 120 spaced from the figure original Fi,
And a plurality of cameras (110) provided along the height direction on the camera mounting member (120)
The camera mounting member 120 is moved away from the figure stock Fi to form a closed contour with respect to the figure stock Fi,
The camera 110 picks up the figure stock Fi a plurality of times while the camera mounting member 120 is moved in the closed path,
The camera mounting member 120 is spaced apart from the figure stock Fi and rotates 360 ° with respect to the figure stock Fi,
The camera 110 picks up the figure stock Fi multiple times while the camera mounting member 120 rotates,
A moving means for moving the figure original Fi to a closed path around the figure original Fi,
The camera mounting member 120 is mounted on the moving means and rotates,
The moving means is a rotating body 140 rotating about the figure stock Fi,
The camera mounting member 120 is mounted on the rotating body 140 and rotates,
The rotating body (140)
A rotary shaft 141 rotatably mounted on the floor B and a rotary plate 142 rotatably installed on the rotary shaft 141,
The camera mounting member 120 is mounted on the rotation plate 142 and rotates,
The rotating body (140)
A first bearing br1 installed at the bottom B and a second bearing br2 inserted at the upper end of the rotary shaft 141,
The stage S is sprinkled on the second bearing br2,
In order to facilitate the installation of the first bearing br1, a mounting plate 143 provided at the bottom B is further included,
The first bearing br1 is mounted to the mounting plate 143 and installed at the lower end of the rotation shaft 141,
The camera mounting member 120 is composed of a pole,
The camera mounting member 120 constituted by the poles is installed upright on the rotation plate 142,
Wherein the camera (110) is provided in a plurality of camera mounting members (120) composed of the poles along the height direction.
The method according to claim 1,
The camera mounting members 120 are provided in pairs at mutual intervals d1,
Wherein the camera (110) is provided to correspond to the same horizontal height on the pair of camera mounting members (120).
The method of claim 2,
A plurality of cameras provided on the camera installation member 120 are divided into an upper end camera 110 and a camera 110 installed in three vertical directions of the center camera 110 and the lower end camera 110,
The upper end camera 110 is installed so as to be inclined downward and directed downward,
The center camera 110 is installed to face the front,
Wherein the lower end camera (110) is inclined upward so as to face upward.
The method of claim 3,
The camera mounting member 120, which is composed of the pole,
(120a, 120b, 120c) coaxially and folded or unfolded in multi-stages, and the height thereof is variable.
The method according to claim 2 or 3,
An input means (171) for inputting an imaging operation command of the camera (110)
A signal distributor 173 for distributing an imaging operation command input from the input means 171 to each camera 110,
An image storage and transmission unit 181 for storing a video image captured by the camera 110 and transmitting the stored video image to a remote modeling computer 190,
A controller (172) connected to the input means (171) for automatically capturing an image at a set time period,
Further comprising display means (182) provided on one side of the camera installation member for confirming a camera angle at which the camera (110) picks up an image. delete delete

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