KR102070601B1 - Image-form variable type floating hologram display device - Google Patents

Abstract

The present invention relates to a floating hologram display device and, more specifically, to an image type variable floating hologram display device in which an image projected from an image output device and displayed on a clear screen can be viewed in various forms. According to the present invention, the display device comprises: a box-type device body having an implementation space of a hologram image; the image output device configured to project an image in a defined direction while being provided at a predetermined position in the device body; a first reflecting panel and a second reflecting panel arranged to refract the image projected from the image output device in a defined direction in the device body while being disposed at a predetermined position in the device body; a projection screen in which the final refracted image is projected through the second reflecting panel while being pulled in the center of the device body; and a projection varying unit which varies the form of the image projected on the clear screen by installation of the second reflecting panel and the clear screen and location, angle and direction adjustment of the clear screen and angle adjustment of the second reflecting panel corresponding thereto and implements various hologram images based on the variation.

Description

Image-type variable floating hologram display device {IMAGE-FORM VARIABLE TYPE FLOATING HOLOGRAM DISPLAY DEVICE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a floating hologram display device, and more particularly, to an image type variable floating hologram display device in which an image projected from an image output device and displayed on a clear screen can be displayed in various forms.

Today's multimedia contents are combined with cutting-edge technology to form a variety of expressions and new systems. It is called the 4th Industrial Revolution, and the emergence of Mixed Reality (MR) followed by Virtual Reality (VR) and Augmented Reality (AR) has attracted more attention to the immersive content. .

In particular, hologram is a next-generation image technology that allows the virtual to be perceived as reality, and many researches and developments have been made, and hologram technology has been applied in various fields.

The virtual reality (VR) and augmented reality (AR) is used in multimedia content, but there is a limit to use a dedicated device for the experience. However, the hologram is used in various fields such as exhibitions, concerts, advertisements, musicals, etc. because it has the advantage of viewing three-dimensional image effects without wearing a dedicated device.

1 is a schematic view showing the principle of the hologram, the hologram, as shown in Figure 1, the two beams are projected by the laser (image output) and the reference beam (reference beam) directly shining on the film (projection screen) When a reference beam) and an object beam shining directly on an object meet on a film, interference fringes are recorded on the film due to a phase difference.

In addition, the method of viewing the image generated by diffraction and interference effects of light at 360 ° is called a real hologram, which is difficult to commercialize due to the limitations of numerous data processing and optical technologies. Similar holograms are used, which produce a similar effect. Such a hologram can be divided into a free format hologram method and a floating hologram method according to projection and installation methods.

Among the aforementioned similar holograms, the core of the floating hologram method uses a foil, which is a transparent film on which an image is formed, as shown in FIG. 2, and when the projector projects an image toward the floor Reflected by the reflector (hereinafter referred to as the "reflective panel") is formed in a transparent foil (hereinafter referred to as "projection screen") to form an image that looks like an object floating in the air.

Using this floating hologram principle, overseas concerts of famous musicians continue as the Hologram Hall was created in 2014, including the Michael Jackson Memorial.

Here, to briefly explain the principle of the floating hologram, as shown in Figure 3 (a), when projecting the image by making the projection screen 45 ° tilted pyramid shape as if the original image is reflected in the floating four plate center empty air As shown in FIG. 3 (b), the box has a box-like structure, and when the projector is tilted at an angle of 45 °, the image is reflected and appears to float in the air.

In connection with this, various types of floating hologram display devices are disclosed through Korean Patent Registration No. 10-1532327, Korean Patent Publication No. 10-2016-0019193, Korean Patent Application Publication No. 10-2016-0017908, and the like. Korean Patent Laid-Open Publication No. 10-2016-0017908 discloses a slim floating hologram display device having a thin depth by simplifying an arrangement structure of an optical system that generates a hologram image.

The conventional floating hologram display device can reduce the size of the device by simplifying an arrangement structure of an optical system for generating a holographic image to have a thin depth, and receive an image wirelessly from a nearby terminal and display it as a holographic image. In addition, it can be embedded in a TV, such as a holographic image of the video-related content displayed on the screen to induce viewers to have fun and interest.

However, the prior art is characterized in that the device is slim and compact in order to display various contents necessary for real life as a hologram image, as described above, and no means for implementing other functions are provided. It is just a common floating hologram display device without any difference from what is widely known so far.

As a result, in order to provide a realistic and realistic content service in line with the rapid development of the content industry, for example, by diversifying the form of the image projected on the projection screen, consumers (spectators) enjoy holographic images from various perspectives. There is a need for research and development of such a floating holographic technology-based display device.

(Document 1) Republic of Korea Patent Registration No. 10-1532327 (Registration Date: 2015.06.23) (Document 2) Republic of Korea Patent Publication No. 10-2016-0019193 (published date: 2016.02.19.) (Document 3) Republic of Korea Patent Publication No. 10-2016-0017908 (published date: 2016.02.17.)

SUMMARY OF THE INVENTION An object of the present invention is to solve the above problems, and is provided with a projection variable stage for adjusting the position, angle, and orientation of a projection screen on which an image is projected, and the projection screen. The present invention provides an image-type variable floating hologram display device capable of implementing various holographic image techniques by diversifying vertical ratio and horizontal ratio expression as well as image enlargement / reduction.

In order to achieve the above object, the present invention, a box-shaped device body having a realization of the holographic image; An image output unit configured to project an image in a defined direction while being installed at a predetermined position in the device body; A first reflecting panel and a second reflecting panel arranged to refract the image projected from the image output device in a defined direction in the device body while being disposed at a predetermined position in the device body; A projection screen in which the final refracted image is projected through the second reflection panel while being pulled in the center of the device body; And varying the shape of the image projected on the projection screen by installing the second reflection panel and the projection screen, adjusting the position, angle, direction of the projection screen, and adjusting the angle of the second reflection panel corresponding thereto. And a projection variable stage for implementing various holographic images based on the same.

In addition, the projection variable stage includes a position adjuster for adjusting the position, angle, and direction of the projection screen together with the traction of the projection screen, and corresponding to the position, angle, and direction change of the projection screen by the position adjuster. And an angle adjuster for adjusting an angle of the second reflection panel so that an image can be accurately projected in the center of the projection screen, and the angle adjustment of the second reflection panel corresponding to the position adjuster is performed by a motion sensor. And the second reflection panel communicate with each other, and the direction angle of the second reflection panel is automatically adjusted toward the center of the projection screen based on the signal system detected by the motion sensor.

In addition, the position adjuster may be combined with a position adjusting unit for moving the front and rear positions of the projection screen, an inclination adjusting unit for changing the upper and lower angles of the projection screen, and a direction adjusting unit for changing the left and right directions of the projection screen. The position adjusting unit may include at least one guide rail for guiding a position movement of the projection screen in a state of being installed at a predetermined position in the device body, and assembled to the guide rail for position movement of the projection screen. And a first drive motor mounted and fixed on the transport rail, the first drive motor generating power required for the transport of the transport rail in a state associated with the guide rail.

In addition, the inclination adjustment unit, the second drive motor to rotate the drive at the time of power supply, the drive pulley to rotate at the same time when the rotary shaft rotates in a state coupled to the rotation axis of the second drive motor, the power from the drive pulley The first and second interlocking pulley, the third interlocking pulley and the third interlocking pulley, and are connected to the drive pulley and the first, second, third interlocking pulley, the rotational power of the drive pulley to the first, It consists of a first belt, a second belt and a third belt to transfer to the 2,3 interlocking pulley.

In addition, the direction adjusting unit, the rotation plate is a horizontal rotation relative to the center of the magnetic center in the state attached to the center of the conveying table, and the horizontal rotation at the time of rotation of the rotating plate in the state of being connected to the lower side of the rotating plate A hinge connector assembled to the rotating table and hinged to the upper side of the projection screen to allow the fitting engagement of the upper end of the projection screen and the angle adjustment of the projection screen to be carried out; It consists of a third drive motor for generating the power required for the rotation of the rotating plate.

In addition, the upper end of the guide rail, a rack gear is formed along the longitudinal direction, the rotational axis of the first drive motor, the conveying by running in the rack gear during the rotation of the rotating shaft in the state engaged with the rack gear The first pinion gear, which is configured to move along the guide rail, is axially coupled.

In addition, a ring gear is formed at an upper edge portion of the rotating plate, and the rotating plate of the third driving motor rotates by driving the ring gear when the rotating shaft rotates while the ring gear is engaged with the rotating shaft. The second pinion gear is axially coupled.

As apparent from the above description, the image-type variable floating hologram display device of the present invention has a diversification effect of the image shape reflected on the projection screen by the operation of the position adjuster at the projection variable stage.

Particularly, the image enlargement / reduction expression displayed on the projection screen may be diversified according to the operation of the position adjuster in the position adjuster configuration, and the image vertical ratio expression reflected on the projection screen may be achieved by the tilt adjuster in the position adjuster configuration. It is possible to achieve diversification, and it is possible to diversify the representation of the image horizontal ratio change reflected on the projection screen according to the operation of the direction adjusting unit during the configuration of the position adjuster. Thus, various floating holographic imaging techniques can be realized by expressing various images. There is an effect that is possible.

In addition, by achieving the above-described effects, it is possible to provide consumers with a realistic content service that allows visitors to experience holographic images from various perspectives, and to develop and revitalize the content industry as well as content providers. It is a very useful invention that can contribute greatly.

1 and 2 is a technical overview showing the principle and method of the hologram.
Figure 3 (a) (b) is an exemplary photograph showing an embodiment of the content using a floating hologram method.
4 and 5 are a side cross-sectional view and a front cross-sectional view showing the configuration of the image type variable floating holographic display device according to the present invention.
6 is a main perspective view showing the configuration of the position adjuster among the projection variable stages in the image type variable floating hologram display device according to the present invention;
Fig. 7 is an excerpt of an essential part showing a configuration relationship of a direction controller in a position controller in the image type variable floating hologram display device according to the present invention.
8 is a main perspective view showing the configuration relationship between the inclination adjustment unit of the position adjuster in the image type variable floating hologram display device according to the present invention.
9 is an exemplary cross-sectional view showing an embodiment of an image type variable floating hologram display device according to the present invention;
10A and 10B are operation state diagrams showing an operation relationship of a position adjuster in the image type variable floating hologram display device according to the present invention;
11 (a), (b) and (c) illustrate an example of a shape of a holographic image that is differently projected on a projection screen according to an operation of a position adjuster in an image type variable floating hologram display device according to the present invention. .

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

First of all, in adding reference numerals to the components of the drawings, it should be noted that the same reference numerals have the same reference numerals as much as possible even if displayed on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

4 and 5 are side cross-sectional views and a front cross-sectional view showing the configuration of the image variable-type floating hologram display device according to the present invention, Figure 6 is a projection variable in the image variable-type floating hologram display device according to the present invention Fig. 7 is an essential part perspective view showing the configuration relationship of the position adjuster among the means, and Fig. 7 is an excerpt view showing the construction relationship of the orientation adjuster among the position adjusters in the image type variable floating hologram display device according to the present invention, and Fig. 8 FIG. 9 is an essential part perspective view illustrating a configuration relationship of an inclination adjusting unit of a position adjuster in the image variable-type floating hologram display device according to the present invention. FIG. 9 is an exemplary cross-sectional view showing an embodiment of the image type variable floating hologram display device according to the present invention. 10b is an image type according to the present invention Figure 11 (a) (b) (c) is an operation state diagram showing the operation relationship of the position adjuster in the variable floating hologram display device according to the operation of the position adjuster in the image type variable floating hologram display device according to the present invention This is a projection example showing the shape of a holographic image that is differently reflected on the image.

As shown in Figure 4 and 5, the image type variable floating hologram display device (A) according to the present invention, a box-shaped device body (1) having an implementation space of the hologram image, and in the device body (1) The image output unit (2) for projecting the image in a defined direction in a state installed at a predetermined position, and the image projected from the image output unit (2) in a state arranged at a predetermined position in the device body (1) 1) a plurality of reflective panels 3 refracting in a defined direction and a projection in which the final refracted image is projected through any one of the reflective panels 3 while being towed in the center of the device body 1; In addition to the screen 4 and the installation of any one of the reflective panel 3 and the projection screen 4, the position, angle, direction of the projection screen 4 is adjusted, and the angle of the reflective panel 3 corresponding thereto. Reflected on the projection screen (4) by adjustment A projection is a variable means (5) to diversify the type and on the colorful holographic images based implement them.

The device body 1 is a housing for unifying the device configuration and realizing the floating hologram image. The device body 1 has an inner space where the hologram image is implemented, and a box whose front side is opened so that the viewer can see the hologram image. It is desirable to form a structure.

The image output unit 2 is an optical device for reproducing (outputting) various images and expanding and projecting them to a human being, and the image output unit 2 defines an image in a state of being installed at a predetermined position in the device body 1. It is preferred to be a projector suitable for projecting in the direction.

The reflective panel 3 is used to refract the image projected from the image output unit 2 to be projected onto the projection screen 4 disposed in the apparatus body 1, and is projected from the image output unit 2. A first reflection panel 31 which first refracts the image in a defined direction, and a second reflection panel 32 which refracts the image refracted from the first reflection panel 31 toward the projection screen 4. .

The first and second reflecting panels 31 and 32 are adapted to receive an image projected from the image output unit 2 and to be refracted (reflected) in a defined direction and to be projected on the projection screen 4 without decrement. It is preferable that it is a mirror.

The projection screen 4 is intended to cause the holographic image projected through the image output device 2 and refracted by the reflective panel 3 to float as if floating in the air inside the device body 1. It is a transparent plate that can be seen from the background and is towed at a predetermined position in the device body 1 while being inclined forward to receive a holographic image from the second reflection panel 32.

The projection variable stage 5 is to diversify the shape of the image projected on the projection screen 4 and to realize various hologram shapes based on the projection screen 4, as shown in FIGS. 5 to 8, the projection screen 4 Position controller 51 for adjusting the position, angle, and direction of the projection screen 4 and the position, angle, and direction change of the projection screen 4 by the position adjuster 51. It consists of an angle adjuster 52 for adjusting the angle of the second reflection panel 32 so that the image is accurately reflected in the center of the projection screen (4).

Here, the angle adjustment of the second reflection panel 32 corresponding to the position adjuster 51 is performed by a motion sensor (not shown) and the projection screen 4 and the second reflection panel 32. This is possible by communicating with each other and allowing the direction of the second reflection panel 32 to be automatically adjusted toward the center of the projection screen 4 based on the signal system sensed through those motion sensors.

The position adjuster 51, as shown in Figures 6 to 8, the position adjusting unit 51-1 for moving the front and rear of the projection screen 4, the upper and lower of the projection screen 4 An inclination adjustment unit 51-2 for changing the angle and a direction adjustment unit 51-3 for switching left and right directions of the projection screen 4 are combined.

As illustrated in FIG. 7, the position adjusting unit 51-1 includes at least one guide rail for guiding the position movement of the projection screen 4 in a state of being installed at a predetermined position (ceiling) in the device body 1. 51-11 and a feed table 51-12 which is moved along the guide rail 51-11 in a state of being assembled to the guide rail 51-11 for moving the projection screen 4. And a first drive mounted and fixed on the conveyer 51-12 and generating power required to move the conveyer 51-12 when power is supplied in a state associated with the guide rail 51-11. It consists of the motors 51-13.

On the upper end of the guide rail 51-11, a rack gear 51-111, which is engaged with a first pinion gear axially coupled to a rotation shaft of the first driving motor 51-13, to be described later, is long along the longitudinal direction. Formed.

The first driving motor 51-13 is an angle proportional to the number of pulses given to the pulse in the step state in consideration of the precise position movement of the feed table 51-12. It is preferable that the stepping motor rotates as much as possible, but not necessarily limited thereto, and if it is a mechanical (and electronic) element exhibiting the same working relationship and working effect, it may be adopted differently.

In addition, the rack gear 51-111 is rotated to the rotation shaft 51-130 of the first driving motor 51-13 when the rotation shaft 51-130 is rotated while being engaged with the rack gear 51-111. The first pinion gear 51-131 is coupled to the feed pin 51-12 so as to move along the guide rail 51-11.

As shown in FIG. 8, the inclination adjustment unit 51-2 includes a second drive motor 51-21 that rotates when power is supplied, and a rotation shaft 51-of the second drive motor 51-21. Drive pulley 51-22 which rotates simultaneously when the rotary shafts 51-210 rotate in a state coupled to the shaft 210, and a first interlocking pulley that receives power from the drive pulley 51-22 and rotates together. 51-23, the second interlocking pulley (51-24) and the third interlocking pulley (51-25), and the driving pulley (51-22) and the first, second, third interlocking pulley (51-25) The first belt (51-26) and the first to transfer the rotational power of the drive pulley (51-22) to the first, second, third interlocking pulley (51-23) (51-24) (51-25) It consists of two belts 51-27 and a third belt 51-28.

The second drive motor 51-21 considers the precise rotational movement of the drive pulley 51-22 and the first, second, and third linked pulleys 51-23, 51-24, and 51-25. Thus, it is preferable that the stepping motor is the same as the first driving motor 51-13. However, the present invention is not limited thereto, and mechanical (and electronic) elements exhibiting the same working relationship and working effects may be employed differently. .

As shown in FIG. 6, the direction adjusting unit 51-3 performs a bidirectional horizontal rotation based on a magnetic center in a state in which the direction adjusting unit 51-3 is assigned to the center of the feed table 51-12 of the position adjusting unit 51-1. The rotating plate 51-31, and the rotating table 51-32 which horizontally rotates together with the rotating plate 51-31 in a state in which the rotating plate 51-31 is arranged and connected to the lower side of the rotating plate 51-31, and the rotating table ( A hinge connector 51-33 which is assembled to a hinge 51-32 so that the fitting engagement of the upper end of the projection screen 4 and the angle adjustment of the projection screen 4 thus coupled can be performed; And a third driving motor 51-34 that is mounted on and fixed to the -12 and generates power required for rotation of the rotary plate 51-31 when the power is supplied in a state associated with the rotary plate 51-31.

A ring gear 51-311 is formed at the upper edge portion of the rotating plate 51-31 to engage with a second pinion gear axially coupled to the rotation shaft of the third driving motor 51-34, which will be described later.

On each of the front end portions of the swivel table 51-32, arms 51-321 for fitting engagement between both ends of the hinge connector 51-33 and for configuring the inclination adjustment unit 51-2 are formed.

The third drive motor 51-34 is a stepping motor similarly to the first and second drive motors 51-13 and 51-21 in consideration of the precise rotational movement of the rotary plate 51-31. However, the present invention is not limited thereto, and mechanical (and electronic) elements exhibiting the same working relationship and working effects may be employed differently.

In addition, the ring gear 51-311 when the rotation shaft 51-340 is rotated in the state in which the rotation shaft 51-340 is engaged with the ring gear 51-311 of the third driving motor 51-34. The second pinion gear 51-341, which causes the rotating plate 51-31 to rotate, is axially coupled.

The angle adjuster 52 is installed at a predetermined position (bottom) of the device body 1 for installation coupling of the first reflection panel 32, and the orientation angle of the first reflection panel 32 is the projection screen. It is preferable that it is a motor operated hinge apparatus which automatically adjusted according to the position, angle, and direction of (4).

Unexplained symbol (b) is provided in a portion where the feed table and the rotating plate contact each other, and a portion where the arm of the rotating table and the shaft of the first, second, and third interlocking pulleys come into contact with each other. It is a bearing that helps the rotation of the machine.

The operation of the image-type variable floating hologram display device A according to the present invention having the above configuration will now be described in detail.

First, as shown in FIGS. 9 to 10B, the image type variable floating hologram display device A according to the present invention moves the front and rear positions of the projection screen 4, and adjusts the upper and lower angles and the left side. By changing the right direction, various holographic imaging techniques by varying the shape of the image projected from the image output unit 2 and refracted by the reflective panel 3 and finally projected on the projection screen 4 Implementation of is possible.

Specifically, the above-described shape diversification is achieved by operating the projection variable stage 5 so that the position, angle, and direction of the projection screen 4 are adjusted. The position of the projection screen 4 is moved by the operation of the position adjusting unit 51-1 of FIG. 51, so that the image projected on the projection screen 4 is enlarged or reduced to the audience as shown in FIG. 11 (a). It can be shown as

That is, when the first driving motor 51-13 is driven and supplied with power when the position adjusting unit 51-1 operates, the shaft is formed on the rotation shaft 51-130 of the first driving motor 51-13. The combined first pinion gear 51-131 travels along the longitudinal direction of the guide rail 51-11 in the rack gear 51-111 on the top of the guide rail 51-11. As the driving motor 51-13 is mounted and fixed, the transfer table 51-12 moves backward or forward in consideration of the rotation direction of the first pinion gear 51-131, so that the projection screen 4 ), The position of the image reflected on the projection screen 4 may be enlarged or reduced in various ways.

Then, by adjusting the inclination adjusting unit 51-2 of the position adjuster 51 to adjust the upper and lower angles of the projection screen 4, as shown in Figure 11 (b), the projection screen 4 is reflected The vertical ratio of the image can be shown to the viewer in a different form. When the second driving motor 51-21 is driven with electric power during the operation of the inclination adjusting unit 51-2, the second driving The driving pulleys 51-22 axially coupled to the rotary shafts 51-210 of the motors 51-21 are rotated, thereby allowing the first, second and third belts 51-26 (51-27) ( The first, second, and third interlocking pulleys 51-23, 51-24, and 51-25 are connected to each other by 51-28 so that they are directly connected to the third interlocking pulley 51-23. Since the hinge connector 51-33 of the direction adjusting unit 51-3 rotates, the inclination of the projection screen 4 is changed so that the vertical ratio of the image reflected on the projection screen 4 may be variously modified. .

In addition, the left and right directions of the projection screen 4 are switched by the direction adjusting unit 51-3 of the position adjuster 51, and as shown in FIG. 11 (c), the projection screen 4 is reflected on the projection screen 4. The horizontal ratio of the image can be shown to the viewer in a different form, when the third driving motor (51-34) is supplied with power during operation of the direction adjusting unit (51-3), the first The second pinion gear 51-341 axially coupled to the rotary shafts 51-340 of the three-drive motor 51-34 travels on the ring gear 51-311 at the upper end of the rotary plate 51-31, As a result, the rotating plate 51-31 is rotated as the third driving motor 51-34 is mounted and fixed, and thus the direction of orientation of the projection screen 4 is changed to reflect the projection screen 4. The horizontal ratio of the lost image may be variously modified.

In addition, when the position, angle, and direction of the projection screen 4 are changed according to the above-described process, the angle adjuster 52 of the projection variable stage 5 is operated in response to the change. Accordingly, the direction of the second reflection panel 32 of the reflective panel 3 installed on the upper side is automatically adjusted so as to be projected from the image output device 2 and refracted by the first reflection panel 31. As the corrected image is accurately refracted to the center of the projection screen 4, it is possible to project an error-free image.

In summary, according to the image-type variable floating hologram display device A of the present invention, it is possible to diversify the shape of the image projected on the projection screen 4 based on the operation of the projection variable stage 5.

In particular, it is possible to diversify the image enlargement / reduction expression reflected on the projection screen 4 according to the operation of the position adjustment unit 51-1, and the projection screen 4 by the operation of the inclination adjustment unit 51-2. ), The image vertical ratio change expression can be diversified, and according to the operation of the direction adjusting unit 51-3, the image horizontal ratio change expression reflected on the projection screen 4 can be diversified. As a result, various floating holographic imaging techniques can be realized by expressing various images.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains various modifications, changes, and substitutions without departing from the essential characteristics of the present invention. will be. Accordingly, the embodiments disclosed in the present invention and the accompanying drawings are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by the embodiments and the accompanying drawings. . In addition, the protection scope of the present invention should be interpreted by the claims below, and all technical ideas within the equivalent scope should be construed as being included in the scope of the present invention.

A: hologram display device, 1: device body
2: Image output device, 3: Reflective panel
4: projection screen, 5: projection variable stage
31: first reflective panel, 32: second reflective panel
51: position adjuster, 52: angle adjuster
51-1: Position adjusting unit, 51-2: Inclination adjusting unit
51-3: direction adjuster, 51-11: guide rail
51-12: feeder, 51-13: first drive motor
51-21: 2nd drive motor, 51-22: drive pulley
51-23: 1st linked pulley, 51-24: 2nd linked pulley
51-25: 3rd interlocking pulley, 51-26: 1st belt
51-27: 2nd belt, 51-28: 3rd belt
51-31: rotating plate, 51-32: rotating table
51-33: Hinge connector, 51-34: 3rd drive motor
51-111: Rack gear, 51-131: First pinion gear
51-311: Ring gear, 51-321: Arm
51-341: 2nd Pinion Gear

Claims (7)

A box-type device body having an implementation space of a hologram image; An image output unit configured to project an image in a defined direction while being installed at a predetermined position in the device body; A first reflecting panel and a second reflecting panel arranged to refract the image projected from the image output device in a defined direction in the device body while being disposed at a predetermined position in the device body; A projection screen in which the final refracted image is projected through the second reflection panel while being pulled in the center of the device body; And varying the shape of the image projected on the projection screen by installing the second reflection panel and the projection screen, adjusting the position, angle, direction of the projection screen, and adjusting the angle of the second reflection panel corresponding thereto. And a projection variable stage for implementing a holographic image based on the same;
The projection variable stage includes a position adjuster for adjusting the position, angle, and direction of the projection screen along with the pulling of the projection screen, and the projection screen in response to a change in the position, angle, and direction of the projection screen by the position adjuster. And an angle adjuster for adjusting an angle of the second reflecting panel so that an image can be accurately projected in the center. The angle adjusting of the second reflecting panel corresponding to the position adjuster is performed by a motion sensor. And the two reflection panels communicate with each other, and the direction of the second reflection panel is automatically adjusted toward the center of the projection screen based on a signal system detected by the motion sensor.
delete The method of claim 1,
The position adjuster is combined with a position adjusting unit for moving the front and rear positions of the projection screen, an inclination adjusting unit for changing the upper and lower angles of the projection screen, a direction adjusting unit for changing the left and right directions of the projection screen,
The position adjusting unit, at least one guide rail for guiding the position movement of the projection screen in a state installed at a predetermined position in the device body,
A transfer table for moving the position along the guide rail while being assembled to the guide rail to move the projection screen;
And a first driving motor mounted and fixed on the carriage and generating power for moving the position of the carriage in a state associated with the guide rail.
The method of claim 3,
The inclination adjustment unit, and a second drive motor for rotationally driven when the power supply;
A driving pulley which rotates simultaneously when the rotating shaft rotates while being coupled to the rotating shaft of the second driving motor;
A first interlocking pulley, a second interlocking pulley, and a third interlocking pulley that rotates by receiving power from the driving pulley;
A first belt, a second belt, and a third belt are configured to transmit rotational power of the drive pulley to the first, second, and third linked pulleys while being connected to the drive pulley and the first, second, and third linked pulleys. Image type variable floating hologram display device characterized in that.
The method of claim 3,
The direction adjusting unit, and the rotating plate to achieve a bi-directional horizontal rotation based on the magnetic center in the state assigned to the center of the transfer table,
In the state connected to the lower side of the rotating plate, the rotary table for horizontal rotation in addition to the rotation of the rotating plate,
A hinge connector which is hinged to the swivel table so that the fitting coupling of the upper end of the projection screen and the angle adjustment of the projection screen can be performed;
And a third driving motor mounted and fixed on the transfer table and connected to the rotating plate to generate power required for rotating the rotating plate.
The method of claim 3,
At the upper end of the guide rail, a rack gear is formed along the longitudinal direction,
The first pinion gear is coupled to the rotating shaft of the first drive motor by the first pinion gear, which moves the carriage along the guide rail by driving the rack gear when the rotating shaft rotates while being engaged with the rack gear. Image type variable floating hologram display device.
The method of claim 5,
A ring gear is formed in the upper edge portion of the rotating plate,
Image-type variable floating hologram, characterized in that the second pinion gear for rotating the rotating plate is rotated by driving the ring gear when the rotating shaft is rotated in the state in which the ring gear is engaged with the rotating shaft of the third drive motor. Display device.

Images