KR102334636B1 - Displaying method for rotating and ferris wheel therewith - Google Patents

Abstract

The present invention relates to a display method for rotation and a Ferris wheel using the same, which provides an original function of the Ferris wheel by installing LED modules on the front of Ferris wheel posts and displaying preset expression phrases through the LED modules at the same time, and maximizes display effects and functions by enabling phrase display through the large Ferris wheel. The expression phrase can be accurately displayed in a fixed direction regardless of the rotation of the Ferris wheel, by using location information of each LED module, a rotation angle for each sub-rotation, and virtual pixel coordinates comprising pixels obtained by classifying a Ferris wheel area into a plurality of areas, when looking at the Ferris wheel from the front, thereby accurately displaying the various expression phrases in a rotation space. A controller is configured to determine lighting pixels for each sub-rotation and lighting LEDs in advance when the expression phrase is set, and to generate blinking information according to the determination result, such that the display of the expression phrase is not made based on real-time calculation processing, but the display of the expression phrase is made based on the previously generated blinking information, thereby significantly reducing errors.

Description

Display method for rotating and a Ferris wheel using the same {Displaying method for rotating and ferris wheel therewith}

The present invention relates to a rotating display method and a Ferris wheel using the same, and more particularly, by displaying pre-made text through LED modules installed on the posts of the Ferris wheel, and using virtual pixel coordinates, the Ferris wheel It is configured to display the expression phrases in a fixed exhibition direction regardless of the rotation of the ferris wheel, providing the original function of the Ferris wheel and expressing various texts, characters, marks, etc. in the rotating space to maximize the exhibition effect and function. It relates to an exhibition method and a Ferris wheel using the same.

The Ferris wheel consists of a rotating wheel that rotates, struts that are coupled at intervals on the arc of the rotating wheel, and gondolas that are coupled to each pole for passengers to ride. configured to rotate.

In such a Ferris wheel, as the poles are formed in a long length and at the same time as the gondolas rotate in an arc according to the rotation of the rotating wheel, the passengers on the gondola can move to the left and right high and low positions, so the passengers can comfortably enjoy the scenery of the surrounding space. Due to the advantage of providing a space for people to enjoy, it is widely installed in various amusement parks and tourist attractions, and has been loved as a representative amusement facility for a long time.

On the other hand, since a large number of users visit amusement parks and tourist attractions where the Ferris wheel is installed, it is often necessary to express phrases for various purposes such as guidance, information delivery, advertisements, and attractions. Display means for expressing various phrases are installed on the back.

In particular, the Ferris Wheel is one of the largest amusement facilities with the largest area and height among various amusement facilities.

However, since the poles rotate according to the rotation of the rotating wheel, it is difficult to output the text in a fixed direction.

In Korea Patent Publication No. 10-2020-0136249 (Title of Invention: Entrance structure of cable-stayed bridge with amusement facilities installed) (hereinafter referred to as the first prior art), a pair of pylons installed vertically at intervals in the width direction, and pylons An entrance structure is described that has a special function and scenery by including a rotating shaft installed across the central part of the field, and a play facility installed to enable rotational driving by the rotating shaft.

Domestic Registration Patent No. 10-2110937 (title of invention: amphibious Ferris wheel) (hereinafter referred to as the second prior art) is configured to sequentially move on water and underwater by the rotation of a rotating wheel, so that passengers can An amphibious Ferris wheel that allows you to see the environment sequentially is described.

However, in the first and second prior arts, the technology and method for the phrase expression function for displaying the phrase pre-made in accordance with the rotation are not described at all. In this case, there is a structural limit in which the effect of expression of phrases cannot be expected at all.

The present invention is to solve this problem, and the problem of the present invention is to provide the original function of the Ferris wheel by installing LED modules on the front of the ferris wheel's poles and displaying preset expressions through the LED modules at the same time. It is to provide a rotating display method capable of maximizing display effects and functions by displaying stationery through a large Ferris wheel, and a Ferris wheel using the same.

In addition, another solution to the present invention is to obtain virtual pixel coordinates made up of pixels classified into a plurality of ferris wheel areas, rotation angles for each sub-rotation, and position information of each LED module when the Ferris wheel is viewed from the front. It is to provide a rotating display method and a Ferris wheel using the same that can accurately display various expression phrases in a rotating space by using it to accurately display the expression phrases in a fixed direction regardless of the rotation of the Ferris wheel.

In addition, another solution to the present invention is that when the expression phrase is set, the controller is configured to generate flashing information according to each sub-rotation in advance, after determining the lighting pixels and lighting LEDs for each sub-rotation, so that the expression is displayed based on real-time operation processing. It is to provide a rotating display method and a Ferris wheel using the display method that can significantly reduce errors and errors by displaying the displayed phrases based on previously generated blinking information rather than displaying the phrases.

In addition, another solution of the present invention is to extract the optimal illuminance value according to the current amount of light when the controller generates the flashing information, and then include the extracted optimal illuminance value in the flashing information to set the LED module to the optimal illuminance value corresponding to the current amount of light. An object of the present invention is to provide a rotating display method that can further increase visibility and visibility by lighting, and a Ferris wheel using the same.

The solution of the present invention for solving the above problems is a rotating wheel rotated by a driving unit; Posts vertically installed at intervals on the outer circumferential surface of the rotating wheel; gondolas coupled to the ends of the poles; LED modules installed on at least one of the front and rear surfaces of the posts; Manages and controls the operation of the driving unit and the LED modules, and utilizes the rotational speed of the rotating wheel and the location information of the LED modules to display the preset expression phrases in a fixed display direction. a memory configured to set and store pixel coordinates for classifying the ferris wheel area into pixels when the ferris wheel is viewed from the front; an expression phrase setting unit for setting an expression phrase inputted from an administrator or preset according to a timeline; An expression phrase-based lighting pixel extraction unit further comprising: an expression phrase input module for receiving an expression phrase set by the expression phrase setting unit; a pixel coordinate-based expression phrase matching module for matching the expression phrase input by the expression phrase input module to preset pixel coordinates; and a lighting pixel determining module that determines a lighting pixel (P1), which is pixels included in the expression phrase, when an expression phrase is matched on pixel coordinates by the pixel coordinate-based expression phrase matching module, wherein the controller includes the lighting pixel By using the pixel information of the lighting pixels (P1) determined by the determination module, the rotational speed of the rotating wheel, and the position information of the LED modules, the blinking of the LED module is controlled so that the expression phrase is displayed in a fixed display direction, and , in the memory, when a rotation according to a sub-angle, which is a value obtained by dividing 360° of the rotating wheel by the total number of poles (n), is referred to as a sub-rotation, the rotation angle of each sub-rotation and the number of sub-rotations (n) are preset stored, the controller may include: a lighting pixel location information input module for receiving the pixel location information of a lighting pixel determined by the lighting pixel determining module; Assuming that the sub-rotation from the 1st to the nth order is made, the rotation angle of the sub-rotation of each pole and the position information of each LED module are used to calculate the position information of each LED module at each sub-rotation. LED position calculation module for each sub-rotation; a position comparison module for comparing the position information of the LED module for each sub rotation calculated by the LED position calculation module for each sub rotation with the position information of the lit pixel input by the lit pixel position information input module; Through the position comparison module, extracting the LED modules included in the lighting pixel for each sub-rotation, and further comprising a lighting LED determination module for each sub-rotation that determines the extracted LEDs as lighting LEDs, the controller By utilizing the lighting LEDs for each sub-rotation determined by the lighting LED determination module for each rotation, the blinking of the LED module is controlled to display the expression phrase in a fixed display direction, and the lighting LED determination module for each sub-rotation is located at the position a first determination module for determining, through the comparison module, an LED module included in a lighting pixel for each sub-rotation as a lighting LED; a missing lighting pixel extraction module for extracting missing lighting pixels for each sub-rotation by comparing whether there are missing lighting pixels in which LEDs included in the lighting pixels do not exist in each sub-rotation; After detecting the respective positions of the missing lighting pixels for each sub-rotation extracted by the missing lighting pixel extraction module, the position information of each LED module for each sub-rotation calculated by the LED position calculation module for each sub-rotation an adjacent LED extraction module that extracts the adjacent LED that is the LED module closest to the missing lighting pixel by utilizing it; a shortest distance calculation module for calculating the shortest distance between the adjacent LED extracted by the adjacent LED extraction module and the missing lighting pixel; a second comparison module for comparing the shortest distance calculated by the shortest distance calculating module with a preset set value (TH, Threshold); When the shortest distance in the second comparison module is less than the set value (TH), a second determination module for determining the adjacent LED as a lit LED is included.

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In addition, in the present invention, when the controller is in a stopped state, among the posts, a reference post setting unit for setting a post facing directly above the rotating wheel as a reference post; a blinking information generation unit for generating blinking information including lighting LED information for each sub-rotation determined by the lighting LED determination module for each sub-rotation; After detecting the sub-rotation state of the reference post set by the reference post setting unit, referring to the flashing information generated by the flashing information generating unit, turn on the LEDs corresponding to the current sub-rotation state, and another LED module It is preferable to further include a display control unit for turning off the lights.

In addition, in the present invention, a reference table to which the optimal illuminance values of the LED modules are matched according to the measured light quantity is preset and stored in the memory, the LED modules include a dimming circuit, and the controller includes an illuminance sensor a light quantity measuring unit that measures the current light quantity through and a light source-illuminance value extracting unit that searches the reference table stored in the memory and extracts an optimal light source-illuminance value corresponding to the light quantity measured by the light quantity measurement unit, wherein the blinking information generating unit is the light source-illuminance value The light source-illuminance value extracted by the value extractor is matched to generate blinking information, and the display control unit turns on the lit LEDs according to the light source-illuminance value included in the blinking information generated by the blinking information generator. It is preferable to let

In addition, in the present invention, it is preferable that the Ferris wheel further include auxiliary frames connecting the posts adjacent to each other in an arc shape, and the LED modules are further installed on the front side of the auxiliary frames or the rotating wheel.

According to the present invention having the above problems and solutions, the original function of the Ferris wheel is provided by installing LED modules on the front of the holders of the Ferris wheel, and at the same time, preset expression phrases are displayed through the LED modules. It is possible to display stationery through the display, maximizing the display effect and function.

In addition, according to the present invention, when the Ferris wheel is viewed from the front, the virtual pixel coordinates composed of pixels classified into a plurality of the Ferris wheel area, the rotation angle for each sub-rotation, and the position information of each LED module are used to create a large Since it is possible to accurately display the expression phrases in a fixed direction regardless of the rotation of the Ferris wheel, various expression phrases can be accurately displayed in the rotating space.

In addition, according to the present invention, when the expression phrase is set, the controller is configured to generate flashing information according to the determined pixel and lighting LED for each sub-rotation in advance in advance, so that the display of the expression phrase based on real-time operation processing is performed. Rather than being done, the display of the expression phrase is made based on the previously generated blinking information, thereby remarkably reducing errors and errors.

In addition, according to the present invention, when the controller generates flashing information, after extracting the optimal illuminance value according to the current amount of light, by including the extracted optimal illuminance value in the flashing information, the LED module is turned on with the optimal illuminance value corresponding to the current amount of light. Visibility and visibility can be further improved.

1 is a block diagram showing a Ferris wheel according to an embodiment of the present invention.
FIG. 2 is an exemplary view of FIG. 1 .
FIG. 3 is an exemplary view showing phrases displayed through the LED modules of FIG. 2 .
4 is a block diagram illustrating the controller of FIG. 2 .
FIG. 5 is a block diagram illustrating a lit pixel extraction unit based on expression phrases of FIG. 4 .
FIG. 6 is an exemplary diagram for explaining FIG. 5 .
FIG. 7 is an exemplary view for explaining the reference post setting unit of FIG. 4 .
8 is a block diagram illustrating a lighting LED detection unit for each sub-rotation of FIG. 4 .
9 is a block diagram illustrating a lighting LED determination module for each sub-rotation of FIG. 8 .

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a block diagram showing a Ferris wheel according to an embodiment of the present invention, FIG. 2 is an exemplary view of FIG. 1 , and FIG. 3 is an exemplary view showing phrases displayed through the LED modules of FIG. 2 .

Ferris wheel 1 as an embodiment of the present invention displays pre-made phrases through LED modules installed on the posts of the Ferris wheel, but uses virtual pixel coordinates to display a fixed display regardless of the rotation of the Ferris wheel This is to maximize the function and effect of phrase expression by expressing various phrases, characters, marks, etc. in the rotating space while providing the original function of the Ferris wheel by being configured to display the expression phrases in the direction.

In addition, as shown in FIGS. 1 and 2 , the Ferris wheel 1 of the present invention manages the overall operation of the Ferris wheel 1 and, at the same time, comprises means (3), (4), (5), (6) to be described later. ), (7), (8), (9), a controller (3) for controlling the operation, a rotational driving part (8) such as a motor for generating a rotational motion, and the rotational driving part (8) formed in the shape of a disk Between the rotating wheel 9, which rotates according to the rotation of the rotating driving unit 8 in combination with the rotating shaft, and the posts 4 vertically installed at regular intervals on the outer circumferential surface of the rotating wheel 9, and the adjacent posts (4) Auxiliary frames (5) connecting to the width direction, gondolas (6) coupled to the end of each post (4) to provide a boarding space for passengers, the posts (4) and auxiliary frames (5) It consists of LED modules (7) installed at intervals.

At this time, in FIG. 2, only essential accessories of the Ferris wheel 1 have been described for convenience of explanation, but the Ferris wheel 1 may be configured to include accessories such as commonly used support means and coupling means. Of course.

The rotation driving unit 8 is a means for generating rotational motion, such as a motor, and generates rotational motion according to the control of the controller 3 .

In addition, the rotating wheel 9 is coupled to the rotating shaft of the rotating drive unit 8 by a belt, a chain, or the like.

The rotating wheel 9 is formed in the shape of a disk having a predetermined area, and is disposed at the center of the Ferris wheel 1 .

In addition, the rotary wheel 9 is coupled to the rotation shaft of the rotary drive unit 8 by a belt, a chain, or the like, and rotates according to the rotation of the rotary drive unit 8 .

In addition, the poles 4 are vertically installed at regular intervals on the outer circumferential surface of the rotating wheel 9 , so that the rotational motion generated by the rotating wheel 9 is transmitted to the rotating shaft -> rotating wheel 9 -> supporting posts (4). do.

The posts 4 are made of a long-length rod or frame, and are coupled to the outer circumferential surface of the rotating wheel 9 at regular intervals.

In addition, the posts 4 are longitudinal LED modules 7 are installed on the front and rear surfaces at intervals when the section in which the occupant is boarded is referred to as the front.

In addition, the ends of the poles (4) are coupled to the gondola (6) rotatably.

The gondolas 6 are formed as an enclosure that provides a boarding space for passengers, and are rotatably coupled to the ends of each post 4 .

These gondolas 6 rotate according to the rotation of the rotating wheel 9 and are coupled to the ends of each post 4 at the same time, so that users can enjoy the surrounding scenery while circulating in the left and right high and low directions.

LED modules (7) are installed to be spaced apart in the longitudinal direction on the front and rear of each post (4).

In addition, the LED modules (7) are installed at intervals on the front and rear of each auxiliary frame (5).

In addition, the LED modules (7) include a dimming circuit to emit light by changing the illuminance according to the control of the controller (3).

These LED modules 7 are flickered according to the control of the controller 3, so that when viewed as a whole, as shown in FIG. 3, specific text, marks, logos, etc. are expressed.

4 is a block diagram illustrating the controller of FIG. 2 .

As shown in FIG. 4 , the controller 3 includes a control unit 30 , a memory 31 , a communication interface unit 32 , a boarding and alighting management unit 33 , a Ferris wheel operating unit 34 , an expression phrase setting unit 35 . ), pixel coordinate matching unit 36, expression phrase-based lighting pixel position extraction unit 37, reference post setting unit 38, sub-rotation lighting LED detection unit 39, light quantity measurement unit 40, light source-illuminance It consists of a value extraction unit 41 , a blinking information generation unit 42 , and a display control unit 43 .

The control unit 30 is an OS (Operating System) of the controller 3, and the control target 31, (32), (33), (34), (35), (37), (38), (39) , (40), (41), (42), (43) are managed and controlled.

In addition, when a new character, mark, etc. is set by the expression phrase setting unit 35 , the control unit 30 executes the expression phrase-based lighting pixel extraction unit 37 .

In addition, when the blinking information is generated by the blinking information generating unit 42 , the control unit 30 inputs the generated blinking information to the display control unit 43 to correspond to the blinking information according to the control of the display control unit 43 . (7) makes the blinking.

In the memory 31, the rotation speed of the corresponding rotating wheel and the angle at which each pole 4 rotates until moving to the next pole in the rotational direction (hereinafter referred to as sub-rotation) when in a stopped state are preset and stored

In addition, location information of each of the LED modules 7 is preset and stored in the memory 31 .

Also, in the memory 31, the position and identification information of each pixel in the pixel coordinates are matched and stored. In this case, the pixel coordinates are composed of pixels obtained by classifying a plurality of areas of the Ferris wheel when viewed from the front.

Also, the blinking information generated by the blinking information generating unit 42 is temporarily stored in the memory 31 .

In addition, a reference table in which the optimal illuminance value of the LED module 7 according to the measured light quantity is matched is preset and stored in the memory 31 .

The getting on and off management unit 33 manages getting on and off of the gondola 6 when the operation of the Ferris wheel 1 is stopped.

The Ferris wheel operation unit 34 manages the overall operation of the Ferris wheel 1 .

Since the getting on and off management unit 33 and the Ferris wheel operating unit 34 are technologies commonly used in the Ferris wheel operating system, detailed descriptions thereof will be omitted.

The expression phrase setting unit 35 sets phrases, characters, marks, etc. to be displayed through the LED modules 7 . In this case, the expression phrase may be set in advance according to the timeline or input by an administrator.

In addition, the expression phrase setting unit 35 is preferably executed when the operation of the Ferris wheel is stopped.

Also, when the expression phrase is set by the expression phrase setting unit 35 , the control unit 30 executes the expression phrase-based lighting pixel extraction unit 37 .

FIG. 5 is a block diagram illustrating an expression phrase-based lit pixel extraction unit of FIG. 4 , and FIG. 6 is an exemplary diagram for explaining FIG. 5 .

As shown in FIG. 5 , the expression phrase-based lighting pixel extraction unit 37 includes an expression phrase input module 371 , a pixel coordinate-based expression phrase matching module 372 , and a lighting pixel determination module 373 .

The expression phrase input module 371 receives the expression phrase set by the expression phrase setting unit 35 .

The pixel coordinate-based expression phrase matching module 372 matches the expression phrase input by the expression phrase input module 371 to preset pixel coordinates, as shown in FIG. 6 . In this case, the term matching means writing the expression phrase on pixel coordinates.

When the expression phrase is matched on the pixel coordinates by the pixel coordinate-based expression phrase matching module 372, the lighting pixel determining module 373 determines pixels included in the expression phrase as the lighting target pixel P1 to be turned on.

For example, assuming that the expression phrase is 'X', the lit pixel determining module 373 determines lit pixels P1 included in 'X'.

FIG. 7 is an exemplary view for explaining the reference post setting unit of FIG. 4 .

As shown in FIG. 7 , the reference post setting unit 38 sets, among the posts 4 , a post facing the directly upper part from the rotating wheel 9 as the reference post 400 .

8 is a block diagram illustrating a lighting LED detection unit for each sub-rotation of FIG. 4 .

As shown in FIG. 8, the lighting LED detection unit 39 for each sub rotation includes a lighting pixel position information input module 391, an LED position calculation module 392 for each sub rotation, a position comparison module 394, and each sub It consists of a turn-on LED determination module 394 for each rotation.

The lighting pixel position information input module 391 receives the position (pixel) information of the lighting pixels determined by the lighting pixel determining module 373 of FIG. 6 described above.

The LED position calculation module 392 for each sub rotation calculates the position information of each LED, assuming that each sub rotation is made.

In this case, the sub-rotation refers to a rotation according to a value obtained by dividing 360° by the total number of poles (n), and one rotation of the entire Ferris wheel 1 is made through n-th sub-rotations.

For example, when the total number of poles (n) is ‘48’, the rotation angle of each sub-revolution is 7.5°, and one rotation of the Ferris wheel 1 is made through 48 sub-rotations.

That is, the LED position calculation module 392 for each sub-rotation determines the position of each LED module at the time of the first sub-rotation, assuming that the entire rotation of the corresponding Ferris wheel 1 consists of the first to n-th sub-rotations. By calculating the information and repeating this method, the position information of each LED module is calculated during the nth sub-rotation.

At this time, since the controller 3 knows in advance the angle of the sub-rotation of each pole and the position information of each LED, it is possible to calculate in advance the change in the position of the LED module for each sub-rotation.

The position comparison module 393 includes the position information of the LED module for each sub rotation calculated by the LED position calculation module 392 for each sub rotation, and the position of the lit pixel input by the lit pixel position information input module 391 . Compare the information.

9 is a block diagram illustrating a lighting LED determination module for each sub-rotation of FIG. 8 .

As shown in Fig. 9, the lighting LED determination module 394 for each sub-rotation includes a first determination module 3941, a missing lighting pixel extraction module 3942, an adjacent LED extraction module 3943, and a shortest distance calculation module. 3944 , a comparison module 3945 , and a second determination module 3946 .

The first determination module 3941 determines the LED module included in the lighting pixel for each sub-rotation as a lighting LED through the position comparison module 393 of FIG. 8 described above.

The missing lighting pixel extraction module 3942 compares whether there is a missing lighting pixel in which an LED included in the lighting pixel does not exist at each sub-rotation, and extracts the missing lighting pixel for each sub-rotation.

The adjacent LED extraction module 3943 detects the positions of the missing lighting pixels for each sub-rotation extracted by the missing lighting pixel extraction module 3942, and then the LED position calculation module for each sub-rotation of FIG. 392), by utilizing the location information of each LED module for each sub-rotation, the LED modules closest to the missing lighting pixel (hereinafter referred to as adjacent LEDs) are extracted.

The shortest distance calculation module 3944 calculates the shortest distance between the adjacent LED extracted by the adjacent LED extraction module 3943 and the missing lighting pixel.

The second comparison module 3945 compares the shortest distance calculated by the shortest distance calculation module 3944 with a preset set value (TH, Threshold). In this case, the set value TH means the maximum value of the shortest distance between the missing lighting pixel and the adjacent LED, which can be determined as the LED module corresponding to the missing lighting pixel.

When the shortest distance from the second comparison module 3945 is less than the set value (TH), the second determining module 3946 determines the adjacent LED to be a lit LED.

As described above, when the expression phrase is set, the controller 3 of the present invention is configured to detect the lighting LEDs capable of expressing the expression phrase for each sub-rotation in advance, thereby displaying the expression phrase in the same display direction regardless of rotation. be able to

The light quantity measuring unit 40 measures the current light quantity through an illuminance sensor or the like.

The light source-illuminance value extraction unit 41 searches the reference table stored in the memory 31 , and extracts an optimal light source-illuminance value corresponding to the light quantity measured by the light quantity measurement unit 40 .

The blinking information generating unit 42 matches the lighting LED information for each sub rotation detected by the lighting LED detection unit 39 for each sub rotation and the light source-illuminance value extracted by the light source-illuminance value extraction unit 41, Generates blinking information.

At this time, the blinking information generated by the blinking information generating unit 42 is input to the display control unit 43 under the control of the control unit 30 .

The display control unit 43 detects the sub-rotation state of the reference post set by the reference post setting unit 38 . In this case, the sub-rotation state means what number of sub-rotations the current position is from the reference position, and may be calculated by comparing the time according to one sub-rotation of each holding and the elapsed time, or may be calculated through various methods.

In addition, when the current sub-rotation state is detected, the display control unit 43 turns on the lighting LEDs corresponding to the current sub-rotation with reference to the blinking information input from the blinking information generating unit 42, and the other LED modules 7 are By turning off the lights, it is possible to display the expression phrases in the same display direction through the LED modules (7).

As described above, the Ferris wheel 1 according to an embodiment of the present invention provides the original function of the Ferris wheel by installing LED modules on the front of the poles and displaying preset expressions through the LED modules at the same time. It is possible to display stationery through the display, maximizing the display effect and function.

In addition, when the Ferris wheel 1 of the present invention is viewed from the front, virtual pixel coordinates composed of pixels classified into a plurality of areas of the Ferris wheel, the rotation angle for each sub-rotation, and location information of each LED module By using , it is possible to accurately display the expression phrases in a fixed direction regardless of the rotation of the Ferris wheel, so that various expression phrases can be accurately displayed in the rotational space.

In addition, the Ferris wheel 1 of the present invention is configured to generate flashing information according to the controller after determining the lighting pixels and lighting LEDs for each sub-rotation in advance when the expression phrase is set, so that based on real-time calculation processing. Instead of displaying the expression phrase, the expression phrase is displayed based on the previously generated blinking information, so that errors and errors can be significantly reduced.

In addition, the Ferris wheel 1 of the present invention extracts the optimal illuminance value according to the current amount of light when the controller generates the flashing information, and then includes the extracted optimal illuminance value in the flashing information to provide the LED module with the optimal illuminance value corresponding to the current amount of light. By turning on the light, visibility and visibility can be further improved.

1: Ferris wheel 3: Controller 4: Post
5: Sub frame 6: Gondola 7: LED module
8: Rotary drive part 9: Rotating wheel
30: control unit 31: memory 32: communication interface unit
33: Boarding and alighting management department 34: Ferris wheel operation department 35: Expression phrase setting department
37: expression phrase-based lighting pixel position extraction unit 38: reference post setting unit
39: LED detection unit for each sub-rotation 40: light quantity measurement unit
41: light source-illuminance value extraction unit 42: flashing information generation unit 43: display control unit

Claims (7)

a rotating wheel rotated by the driving unit;
Posts vertically installed at intervals on the outer circumferential surface of the rotating wheel;
gondolas coupled to the ends of the poles;
LED modules installed on at least one of the front and rear surfaces of the posts;
Manages and controls the operation of the driving unit and the LED modules, and utilizes the rotational speed of the rotating wheel and the location information of the LED modules to display the preset expression phrases in a fixed display direction. comprising a controller to control
the controller is
a memory in which pixel coordinates obtained by classifying the ferris wheel area into pixels are preset and stored when the ferris wheel is viewed from the front;
an expression phrase setting unit for setting an expression phrase inputted from an administrator or preset according to a timeline;
Further comprising an expression phrase-based lighting pixel extraction unit,
The expression phrase-based lighting pixel extraction unit
an expression phrase input module for receiving an expression phrase set by the expression phrase setting unit;
a pixel coordinate-based expression phrase matching module for matching the expression phrase input by the expression phrase input module to preset pixel coordinates;
and a lit pixel determining module for determining a lit pixel (P1), which is pixels included in the expression phrase, when the expression phrase is matched on the pixel coordinates by the pixel coordinate-based expression phrase matching module,
the controller is
By utilizing the pixel information of the lighting pixels (P1) determined by the lighting pixel determining module, the rotation speed of the rotating wheel, and the position information of the LED modules, the LED module flickers to display the expression text in a fixed display direction. to control,
in the memory
When the rotation according to the sub-angle, which is a value obtained by dividing 360° of the rotating wheel by the total number of poles (n), is referred to as a sub-rotation, the rotation angle of each sub-rotation and the quantity (n) of the sub-rotation are preset and stored,
the controller is
a lighting pixel position information input module for receiving pixel position information of a lighting pixel determined by the lighting pixel determining module;
Assuming that the 1st to nth sub-rotations are made, it is possible to calculate the position information of each LED module at each sub-rotation by using the rotation angle of the sub-rotation of each pole and the position information of each LED module. LED position calculation module for each sub-rotation;
a position comparison module for comparing the position information of the LED module for each sub rotation calculated by the LED position calculation module for each sub rotation with the position information of the lit pixel input by the lit pixel position information input module;
Through the position comparison module, extracting the LED modules included in the lighting pixel for each sub-rotation, and further comprising a lighting LED determination module for each sub-rotation that determines the extracted LEDs as lighting LEDs,
the controller is
By utilizing the lighting LEDs for each sub-rotation determined by the lighting LED determination module for each sub-rotation, the blinking of the LED module is controlled to display the expression phrase in a fixed display direction,
The lighting LED determination module for each sub-rotation is
a first determination module for determining, through the position comparison module, an LED module included in a lighting pixel for each sub-rotation as a lighting LED;
a missing lighting pixel extraction module for extracting missing lighting pixels for each sub-rotation by comparing whether there are missing lighting pixels in which LEDs included in the lighting pixels do not exist at each sub-rotation;
After detecting the position of each of the missing lighting pixels for each sub-rotation extracted by the missing lighting pixel extraction module, the position information of each LED module for each sub-rotation calculated by the LED position calculation module for each sub-rotation an adjacent LED extraction module that extracts the adjacent LED that is the LED module closest to the missing lighting pixel by utilizing it;
a shortest distance calculation module for calculating the shortest distance between the adjacent LED extracted by the adjacent LED extraction module and the missing lighting pixel;
a second comparison module for comparing the shortest distance calculated by the shortest distance calculation module with a preset set value (TH, Threshold);
and a second determination module for determining the adjacent LED as a lit LED when the shortest distance from the second comparison module is less than a set value (TH). delete delete delete The method of claim 1, wherein the controller
When in a stopped state, among the poles, a reference pole setting unit for setting a pole facing the upper part from the rotating wheel as a reference pole;
a blinking information generation unit for generating blinking information including lighting LED information for each sub-rotation determined by the lighting LED determination module for each sub-rotation;
After detecting the sub-rotation state of the reference post set by the reference post setting unit, referring to the flashing information generated by the flashing information generating unit, turn on the LEDs corresponding to the current sub-rotation state, another LED module The Ferris wheel, characterized in that it further comprises a display control unit to turn off the lights. The method according to claim 5, wherein a reference table to which optimal illuminance values of the LED modules according to the measured light quantity are matched is preset and stored in the memory;
The LED modules include a dimming-circuit,
the controller is
a light quantity measuring unit that measures the current light quantity through the illuminance sensor;
Further comprising: a light source-illuminance value extraction unit that searches the reference table stored in the memory and extracts an optimal light source-illuminance value corresponding to the light quantity measured by the light quantity measurement unit;
The blinking information generating unit
generating blinking information by matching the light source-illuminance value extracted by the light source-illuminance value extraction unit;
The display control unit
The Ferris wheel, characterized in that the lighting LEDs are turned on according to the light source-illuminance value included in the blinking information generated by the blinking information generator. The method of claim 6, wherein the Ferris wheel
Further comprising auxiliary frames connecting between the adjacent posts in an arc shape,
The LED modules are
The Ferris wheel, characterized in that it is further installed in front of the auxiliary frames or the rotating wheel.

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