KR100367641B1 - Display device using fluid screen - Google Patents

Abstract

The present invention is to supply a fluid to the nozzle tube and the fluid supplied through the nozzle to freely drop to form a fluid screen and the fluid screen irradiating a laser beam or a light source of the projector to the fluid screen to display various advertisements and movies An image display device using the fluid screen, the image display device using the fluid screen nozzle nozzle for forming a screen by discharging the fluid supplied through the nozzle portion in the longitudinal direction to the nozzle portion; A fluid supply tube having one end connected in communication with the nozzle tube and the other end submerged in a supply source fluid to supply fluid to the nozzle tube; An underwater pump installed at the other end of the fluid supply pipe submerged in the supply fluid and forcibly supplying the supply fluid to the fluid supply pipe; And a laser device installed at a predetermined position behind the nozzle tube to display an image by irradiating light to the fluid screen when the fluid discharged to the nozzle part forms a fluid screen.

Here, the nozzle tube and the laser device is characterized in that the space is installed below the upper plate of the bridge installed in the river or the sea so that the water of the river or the sea can be used as a fluid.

Description

Display device using fluid screen}

According to the present invention, when the fluid discharged to the nozzle part of the nozzle tube forms a flat screen, bubbles and spaces present on the screen are suppressed to form a clean screen, and the fluid screen irradiates a laser beam and a light source of a projector to produce various advertisements. And it relates to an image display device using a fluid screen that can be displayed in a high-quality state, and in particular to install a large size in the lower portion of the bridge to maximize the advertising effect.

Conventionally, an image display apparatus using a fluid screen has been developed, which forms a fluid screen by raising a fluid in a vertical direction using a plurality of tubes, and displays an image by irradiating light on the fluid screen.

However, this conventional fractional method simply ejects liquid from a plurality of tubes, so that the rising fluid and the falling fluid are mixed so that the fluid screen is not clean. There was a large difference in contrast between the displayed images.

In practice, this conventional fractional method is used to solve the visual monotony of the monochromatic water column by changing the color of the water in various ways by simply irradiating light on the elevated water column rather than the concept of the fluid screen by the wide spread of the fluid screen. It became.

Therefore, the conventional fountain-type fluid screen has a limitation in function and use by having a compact form because it is formed only by spraying the fluid in the vertical direction without displaying the image cleanly.

Accordingly, the present invention is to solve the conventional problems as described above, the object is to supply the fluid to the nozzle tube installed in a horizontal state with a certain height to remove the bubbles and spaces of the fluid passing through the nozzle portion of the nozzle tube The present invention provides a video display device using a fluid screen that allows a flat screen to be formed in such a state that the fluid screen is irradiated with a laser beam and a light source of a projector so that various advertisements and movies can be displayed cleanly.

Another object of the present invention is to install the image display device for forming such a fluid screen in the lower portion of the bridge to facilitate the fluid supply, and to provide a clear screen by irradiating the intense laser beam on the fluid screen at night It is to provide an image display device using a fluid screen that can maximize the effect.

An image display apparatus using the fluid screen includes: a nozzle tube forming a screen by discharging the fluid supplied through the nozzle part in a longitudinal direction to the nozzle part; A fluid supply tube having one end connected in communication with the nozzle tube and the other end submerged in a supply source fluid to supply fluid to the nozzle tube; An underwater pump installed at the other end of the fluid supply pipe submerged in the supply fluid and forcibly supplying the supply fluid to the fluid supply pipe; And a laser device installed at a predetermined position behind the nozzle tube to display an image by irradiating light to the fluid screen when the fluid discharged to the nozzle part forms a fluid screen.

Here, the nozzle tube and the laser device is characterized in that the space is installed below the upper plate of the bridge installed in the river or the sea so that the water of the river or the sea can be used as a fluid.

1 is a side view of a bridge in which an image display device according to the present invention is installed;

Figure 2 shows a nozzle tube moving means according to the present invention, an embodiment front view of a state in which the nozzle tube is disposed in parallel with the top plate of the bridge,

3 is a longitudinal section of the nozzle tube according to the present invention;

4 is a nozzle cross-sectional plan view according to the present invention;

5 is a cross-sectional view of a nozzle tube and a fluid supply tube according to another embodiment of the present invention;

Figure 6 is a side cross-sectional view of the gearbox for moving the nozzle tube of the present invention,

7 is a plan view schematically illustrating a state in which the nozzle tube of the present invention moves at a right angle and a laser device is moved to one side of the upper plate by a moving means thereof;

Figure 8 is a front sectional view showing a slide portion of the laser device moving means according to the present invention.

Explanation of symbols on the main parts of the drawings

3: nozzle tube 4: fluid supply pipe

7: laser device 11: pillar

12: guide member 16: cylinder

17,20: gear 18: gearbox

23: rail 24: slide means

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration of each embodiment of the present invention. 1 is a side view of a bridge in which an image display apparatus according to the present invention is installed, and FIG. 2 is a state in which the nozzle and the top plate of the bridge are disposed in parallel.

The image display apparatus using the fluid screen of the present invention is to irradiate a laser beam on the screen using the fluid to display the image on the fluid screen in a clean and high-quality state, and to install the device on the bridge to increase the advertising effect, It is preferable to be installed in a large size in the lower part of the upper plate 2 of the bridge 1 like 1,2.

As shown in the drawing, a nozzle tube 3 for injecting the fluid supplied to one end of the bridge 1 upper plate 2 in the width direction in the longitudinal direction is fixed, and the fluid supply tube 4 substantially in the center of the nozzle tube 3. The fluid is formed by the nozzle tube 3 at the other end of the upper plate 2 opposite to the nozzle tube 3, the connecting end being extended so that its extended end is submerged in the supply source fluid under the bridge 1. The laser device 7 which projects the laser beam 6 on the screen 5 is provided.

The nozzle tube 3 may be fixed to a predetermined position on the bottom surface of the upper plate 2, or may be fixed to a nozzle tube moving unit to be described later and its position may be changed.

The nozzle tube 3 is formed in a hollow pipe shape in which the body is sealed as shown in FIG. 3, and at the lower part thereof, the fluid supplied through the fluid supply pipe 4 is discharged to discharge the fluid screen 5. The nozzle unit 9 is formed in the lower part so as to be formed, and one side wall of the body has a passage 10 through which the fluid supply pipe 4 communicates.

The length and diameter of the nozzle pipe (3) can be set arbitrarily, but it is installed in a large size between the pillar (11) and the pillar (11) under the bridge (1) in consideration of this, the length is 30m and the diameter is 20-30 To cm. Here, the passage 10 of the nozzle tube 3 is formed in the center in the longitudinal direction so that the fluid supplied into the nozzle tube 3 is dispersed to both sides.

One embodiment of the nozzle portion 9 of the nozzle tube 3 is a plurality of discharge holes 8 through each other alternately through at least two rows as shown in Figure 4 these discharge holes 8 when viewed in the transverse direction It is good to arrange so that a space does not generate | occur | produce between), Preferably, it is good to arrange in two rows.

The discharge hole 8 of the nozzle tube 3 guides the fluid supplied through the passage 10 to the discharge hole 8, and at this time, a large amount of fluid is discharged to the discharge hole 8 so that bubbles are formed. Guide member 12 to prevent it is generated is further fixed.

The guide member 12 has an inclined portion 13 in which one end of a pipe-shaped body is inclined, and an open portion of the inclined portion 13 flows in through the passage 10 and is divided into two fluids. Are arranged oppositely. Therefore, the guide members 12 fixed to the discharge hole 8 are fixed in a state in which the openings of the inclined portion 13 face each other based on the passage 10.

And the guide member 12 is properly determined according to the size of the nozzle tube (3), considering the size of the nozzle tube (3) is preferably about 1 cm in diameter. Therefore, it is preferable that the interval between the discharge holes 8 of the nozzle tube 3 is arranged to be 1 cm or less when viewed from the side so that no space is generated between neighboring discharge holes 8.

Therefore, the fluid supplied to the nozzle tube 3 flows into the inclined open portion of the guide member 12 and hits the inner wall and then discharges to the lower portion. At this time, a large amount of fluid is supplied through the inclined open portion. It is supplied with no bubbles and no space is formed to form a clean flat fluid screen.

In addition, another embodiment of the nozzle unit 9 of the nozzle tube 3 can be formed into a slot 8a shape by continuously cutting the lower portion of the nozzle tube 3 in a longitudinal direction with a predetermined width as shown in FIG. 5. Could be Here, the width of the cut out slot 8a is determined in the range of approximately 0.5-1 cm.

Thus, the fluid supply pipe 4 which the nozzle part 9 is connected to the nozzle pipe 3 comprised in the slot 8a shape is provided with several branch pipe 4a so that a fluid can be supplied to the slot 8a stably and continuously. ) Is formed, it will be preferable to configure the nozzle tube 3 to be connected at appropriate intervals.

One end of the fluid supply pipe 4 is connected in communication with the passage 10 of the nozzle tube 3, and the other end is arranged to be immersed in the supply source fluid flowing under the bridge 1, so that the submerged water is installed at the other end. The fluid is supplied to the nozzle pipe 3 by the power of the pump P.

The fluid supply pipe 4 may be formed of a metal pipe, but since the nozzle pipe 3 is moved by a nozzle pipe moving means to be described later, the fluid supply pipe 4 should be made of a flexible material.

Here, the nozzle pipe (3) and the fluid supply pipe (4) further has a freezing prevention means for preventing the freezing of the fluid in winter.

The freezing preventing means may be a heater 14 wound around the outer circumferential surface of the nozzle pipe 3 and the fluid supply pipe (4). Since the heat generated by the heater 14 is controlled by a control, the fluid supply pipe 4 is heated so that it is not damaged.

The freezing preventing means may be a normal heat insulating cover (not shown) wrapped in the nozzle tube 3 and the fluid pipe.

The submersible pump P for forcibly supplying fluid to the fluid supply pipe 4 is installed at the end of the fluid supply pipe 4 submerged in the supply source fluid and driven under the control of a control, and the fluid receiving capacity of the nozzle pipe 3 is increased. According to the horsepower (HP) is determined. Therefore, considering the size of the nozzle tube 3, it is preferable to use approximately 1.5HP or more.

And the laser device 7 for displaying an image by irradiating the laser beam 6 to the fluid screen 5 formed by the nozzle tube (3) is behind the nozzle tube (3), that is, the bridge (1) upper plate ( 2) It is fixed at the proper position or its variable position is installed.

The laser device 7 is actively used in various industrial fields, namely, communication, medical, and military fields, and is excellent in monochromatic directionality, energy concentration, and high brightness to display a high quality image when applied to the fluid screen 5. Can be.

The laser device 7 applied to the present invention is manufactured by Samsung Advanced Institute of Technology recently developed and patented, and its feature is for an ultra-large screen capable of displaying high-definition video shapes up to 600 inches using a white laser. It is a laser device. This laser device uses a white laser generated from krypton-argon mixed ion gas as a light source to separate red, green, and blue, modulate it with an optical modulator, and then integrate it into three dichroic optical filters. It is the latest technology to realize laser color image.

According to the present invention configured as described above, the nozzle pipe 3 is fixed to the upper plate 2 of the bridge 1 in parallel with the submersible pump P and the fluid supply pipe 4 by the nozzle pipe 3. Fluid supplied to (3) is discharged through the guide member 12 or the slot (8a) to form a fluid screen (5) while freely falling, wherein the laser device provided behind the fluid screen (5) ( 7) irradiates the fluid screen 5 with the laser beam 6 inputted with the image to display images including various advertisements. In addition, instead of the laser device (7), the projector may be irradiated to the fluid screen (5) to screen a movie.

Therefore, when the image is displayed on the fluid screen 5 at night, a clear image can be seen. Especially, since the length of the nozzle tube 3 becomes approximately 30 m, a large fluid screen 5 is formed to recognize advertisements from a distance. You can do it.

When the nozzle tube 3 is installed in parallel with the bridge 1 and the upper plate 2 as described above, the image can be properly confirmed only in the direction perpendicular to the longitudinal direction of the nozzle tube 3, and the image can be confirmed in the longitudinal direction. There is a difficult problem, which was supplemented with the following examples.

According to another embodiment of the present invention, the nozzle pipe 3 installed in parallel with the bridge 1 upper plate 2 is positioned so as to be converted in a direction perpendicular to the longitudinal direction of the bridge 1 upper plate 2 so that both sides of the bridge 1 In order to be able to see the fluid screen (5) in front.

In order to achieve this object, the nozzle tube 3 and the laser device 7 are moved by respective moving means so that the nozzle tube 3 is disposed at right angles to the longitudinal direction of the bridge 1 and the upper plate 2. The laser device 7 irradiates light to the fluid screen 5 formed by the nozzle tube 3 so that the displayed image is placed in a proper position where the displayed image is not distorted.

As shown in FIG. 2, the nozzle tube moving unit 15 has a cylinder 16 in which the rod 16a linearly reciprocates in the width direction of the bridge 1 and the upper plate 2 is fixed to the lower portion of the upper plate 2. At the end portion 16a, a gear box 18 is engaged with the gear 17 protruding from the nozzle tube 3 to rotate the nozzle tube 3 at a predetermined angle.

The cylinder 16 has the nozzle tube 3 installed in parallel to the upper plate 2 end, so that the nozzle tube 3 rotates in a direction perpendicular to the upper plate 2 so that the inner end thereof is the upper plate ( 2) It must satisfy the condition of being located outside or more outward. To this end, in consideration of the length of the nozzle tube 3 is 30m and the gear of the nozzle tube 3 protrudes in the center, the movement stroke of the rod 16a is preferably at least 15m or more.

The gearbox 18 has a gear 20 that rotates by a motor 19 therein as shown in FIG. 6, and a gear 17 protruding from the nozzle tube 3 in the gear 20 has an inside. The nozzle tube 3 is rotated in accordance with the rotation of the motor 19 is inserted into the engagement. A thrust bearing 21 is disposed below the gear of the nozzle tube 3 to support the nozzle 17 of the nozzle tube 3 that rotates.

The nozzle tube moving means 22 configured as described above moves the nozzle tube 3 to the upper plate 2 side by moving the rod 16a of the cylinder 16 in a linear motion, and then the motor of the gearbox 18. 19 rotates the pair of gears 17 and 20 which are rotated and engaged by a control (not shown) to rotate the nozzle tube 3 at an arbitrary angle, where the preferred rotation angle is 90 degrees. In this way, the nozzle tube 3 is rotated in a direction perpendicular to the longitudinal direction of the upper plate 2 so that the fluid screen 5 can be seen from the front in both directions of the bridge 1.

As described above, the method of moving the nozzle tube 3 may be performed by the cylinder 16 and the gearbox 18 as described above, but may also use a hydraulic device by an actuator (not shown). In this case, the rod of the hydraulic device may be installed near the center of the nozzle tube 3 to minimize the moving distance.

The laser device moving means 22 faces the laser device 7 located behind the nozzle tube 3 before the movement as close to the longitudinal direction of the nozzle tube 3 as possible, as shown in FIGS. 7 to 8. It is for moving to a predetermined position, that is, a predetermined position on one side of the upper plate 2 adjacent to the nozzle pipe (3).

In this case, the longitudinal center of the moved nozzle tube 3 and the eccentric angle α of the moved laser device 7 are appropriate to the eccentric angle within the range in which the image displayed on the fluid screen 5 is not distorted. α). This is an experimental setpoint and the position may be appropriately specified according to this setpoint.

To this end, the rail 23 extends from the laser device 7 before the movement to the position of the laser device 7 after the movement, and the slide means 24 fixing the laser device 7 moves along the rail 23. When stopped, the laser device 7 faces the fluid screen 5 formed in the moved nozzle tube 3.

The rail 23 should be inclined at a predetermined angle so that the laser device 7 can face the fluid screen 5 at the position where the slide means 24 is stopped as described above.

The slide means 24 is fixed to the slide member 25 to which the laser device 7 is fixed to the rail 23, the motor 26 is fixed to the outside of the slide member 25 A roller 27 fixed to the shaft is interposed between the rail 23 and the slide member 25 to provide power to move the slide member 25 while rotating. In addition, an auxiliary rotary member 29 is further installed between the stepped portions 28 and the rails 23 that are bent inward from the upper portion of the slide member 25 to reduce the friction when the slide member 25 moves. Make it smooth.

Therefore, the laser device moving means 22 is a motor 26 fixed to the slice member 25 to rotate the roller 27 and the roller 27 in contact with the bottom surface of the rail 23 is in contact with the rail 23 The slide member 25 is reciprocated along the rail 23 when the motor 26 rotates forward and reverse because it is rotated in a closed state.

On the other hand, since the present invention is installed in the bridge (1) as described above, the fluid screen (5) is located between the pillars 11 of the bridge (1) to display an image, in order to enhance the atmosphere at this time A separate lighting device 30 is further attached to the 11, and a sound system may be further equipped to listen to the sound by adjusting the FM frequency set in the radio.

The lighting device 30 is already used as a decorative lighting device for irradiating a variety of light, its detailed description will be omitted.

On the other hand, using the technical idea of the present invention, the image display device of the present invention can be installed in any place where people pass frequently. That is, since the fluid mainly uses water, a separate means for collecting water used as a fluid screen in a predetermined space is circulated to circulate the collected water in the nozzle tube, and instead of a bridge in which the device is installed. When installing the structure to install the nozzle tube (3), the fluid supply pipe (4) and the laser device (7) to the structure will be possible to install regardless of the location and size. For example, the present invention may be installed around a highway on which a large billboard is installed.

In the image display apparatus using the fluid screen of the present invention configured as described above, a large amount of fluid supplied to the nozzle tube is supplied through the guide member 12 to form a fluid screen, thereby forming a space between the fluids forming the screen. At the same time, the bubble is significantly reduced and thus a clear flat fluid screen can be formed.

Further, by installing the nozzle tube 3 forming the fluid screen in close proximity to the lower portion of the bridge top plate 2, the fluid screen 5 becomes the fluid screen 5 from the point of discharge from the nozzle tube 3 to the distance at which the fluid falls. By making the length of the nozzle tube 3 approximately 30 m or more, the super-large fluid screen 5 is formed, so that advertisements or images displayed from a distance can be viewed.

Therefore, the laser device 7 or a projector can be used to irradiate light on the fluid screen to display various images such as advertisements, movies, or animations. In the case of displaying an advertisement by irradiating an intense laser beam on the fluid screen, it has the advantage of maximizing the advertisement effect by focusing the attention of the occupants of the driving car or the people around the bridge.

Claims (7)

A nozzle tube forming a screen by discharging the fluid supplied through the nozzle portion in the longitudinal direction to the nozzle portion; A fluid supply tube having one end connected in communication with the nozzle tube and the other end submerged in a supply source fluid to supply fluid to the nozzle tube; An underwater pump installed at the other end of the fluid supply pipe submerged in the supply fluid and forcibly supplying the supply fluid to the fluid supply pipe; And a laser device installed at a predetermined position behind the nozzle tube to display an image by irradiating light to the fluid screen when the fluid discharged to the nozzle part forms a fluid screen. Here, the image display device using a fluid screen, characterized in that the nozzle tube and the laser device is installed at a lower portion of the upper plate of the bridge installed in the river or the sea so that the water of the river or the sea can be used as a fluid. The fluid screen of claim 1, wherein the nozzle unit of the nozzle tube is disposed so that the discharge holes are alternately arranged in at least two rows so that no space is generated between the discharge holes when viewed in a transverse direction. Image display device used. The image display apparatus according to claim 1, wherein the nozzle unit of the nozzle tube is continuously cut in the longitudinal direction from the lower portion of the nozzle tube in a longitudinal direction to form a slot. According to claim 2, wherein the nozzle pipe is to guide the fluid supplied through the fluid supply pipe to the discharge hole And a guide member having an inclined portion at one end of the pipe-shaped body, and an open portion of the inclined portion of the guide member is further fixed to each discharge hole so as to face the fluid supply direction. The image display apparatus of claim 1, wherein the nozzle tube and the fluid supply tube are wound around an outer circumferential surface of the nozzle tube and the fluid supply tube to prevent freezing of the supplied fluid. The nozzle apparatus of claim 1, wherein the nozzle tube and the laser apparatus are moved by respective moving means such that the nozzle tube is disposed at an arbitrary position within a maximum perpendicular direction with respect to the longitudinal direction of the bridge top plate, and the laser apparatus is moved to the moved nozzle tube. And irradiating light to the fluid screen formed by the light screen, the displayed image being disposed at an appropriate position of the bridge which is not distorted. The image display apparatus using a fluid screen according to claim 1, further comprising a pillar predetermined position lighting device of the bridge.