KR102134540B1 - Music fountain control method - Google Patents

Abstract

The present invention relates to a music fountain control method by which precise control can be made while eliminating the inconvenience of conventional control over fountain nozzles, pumps, lights, and lasers by using electric wires. To achieve this, the music fountain control method comprises a device information collection step, a mode setting step, a creating step, and a channel setting step, so that a signal according to data set by a manager means including a control PC is wirelessly transmitted through a transmission means including a DMX controller, a transmission DMX splitter, and a transmitter to a microcomputer installed in each of the fountain nozzles, pumps, lights, and lasers, the wirelessly transmitted data is received in the microcomputer, and the fountain nozzles, pumps, lights, and lasers can be proportionally controlled so as to allow a corresponding function to be performed on the basis of a value extracted by calculating the value according to the received data. According to the present invention, the microcomputer is installed to individually control the fountain nozzles, pumps, lights, lasers, and the like, receives data wirelessly transmitted from the manager PC, and performs a corresponding function on the basis of a value extracted by calculating the value according to the received data, so that precise control is facilitated.

Description

Music fountain control method

The present invention relates to a music fountain control method, and more specifically, to solve the inconvenience of controlling a fountain nozzle, pump, lighting, laser, etc. using an electric wire, a fountain nozzle, a pump, for more precise control. The present invention relates to a music fountain control method in which microcomputers are installed in a lighting, laser, etc., and each device is controlled using proportional control.

In general, a fountain uses a motor to draw water from the lower reservoir of a fountain through a pipe, and then sprays it upward through a nozzle to decorate the surrounding atmosphere beautifully. By varying the shape and type of each fountain nozzle according to the control pattern programmed in units of time, it creates a beautiful atmosphere by controlling the on/off of the motor drive and the dynamics of the driving force, thereby providing a pleasant environment and relaxation to the visitors. To ensure that

Conventional fountain systems are nozzles of various shapes due to the problem that the viewers can easily eat by performing simple operations such as water coming or not through each fountain nozzle through on/off of motor driving. And if you install the piping device and install the electric power necessary to operate it and supply power, it is configured to operate in a control method using a timer or PLC (Programmable Logic Controller), and also a music file to satisfy the aesthetic needs of the viewers. Through the music fountain system that detects the audio signal provided through this stored medium and controls the water injection pressure and the opening and closing state of the nozzle accordingly, and controls the laser for lighting, it can provide a beautiful environment for visitors. have.

The directing system for the conventional music fountain controls the lighting, nozzles and pumps through the PLC, and also sets the playing time of the music through the PLC to give a signal to a separate audio directing system to play music. Directing is performed separately from the fountain by using a separate rendering system. Recently, the driving of the motor and the opening and closing of the nozzle are also performed according to the fountain control pattern pre-programmed in the PLC according to the strength of the audio source output of the CD-ROM using a PC. We are using a system that reproduces the director so that the fountain is directed to the music.

The music fountain system above results in the music and fountain being differently produced by using separate elements in directing the music fountain, so that the audience cannot cause interest and emotion, and the audio of the CD-ROM The system in which the fountain is controlled according to the strength of the sound source output can produce the sound speed and lighting well suited to the music, but in the fountain, the spray speed of water from the nozzle is slower than that of the music sound. There have been problems that are directed differently.

Programming of music fountains using a conventional PLC is usually an expert because individual tasks must be performed with text-oriented programming such as DOS programming of each fractional element (nozzle, lighting, pump, etc.) through a PC keyboard. Even if it takes a long time to program one fraction pattern, and it is impossible to program the fraction system without a program expert, the maintenance cost is excessive because a professional fraction programmer is required to enter a new program every time. If it is not replaced with a new program for a long time, there is a problem that allows the viewer to immediately feel the demonstration.

Accordingly, the music, fountain system, and various music fountain equipment such as lasers, lights, pumps, nozzle motors, nozzles, etc. are programmed and controlled by a single console, and users can easily use Windows ( The need for a system that creates an integrated multimedia music fountain that can be programmed in a graphic-oriented environment such as Windows) is emerging.

"DMK 512-based multimedia music fountain system and its directing method" of published patent No. 10-2008-0077747 (published on Aug. 26, 2008) as a prior document for solving the above problems is a channel of all equipment of music fountain Specify the function of the equipment of the specified channel, set the operating speed of the pump motor and nozzle motor, combine all the functions of the specified equipment to create a musical fountain directing pattern, and the musical fountain directing pattern to music A DMX512 control console that outputs and reproduces the program edited with the sequencer in the form of the DMX512 protocol, and applies a control signal to the pump inverter unit, the nozzle control unit, the lighting control unit, and the nozzle motor inverter unit through the DMX512 interface unit; A laser output unit that reproduces output data applied from a DMX512 control console to output a laser beam; An amplifier and a speaker unit that amplifies and outputs an audio signal provided from the DMX512 control console; A DMX512 interface unit that converts DMX512-based music fountain directing program data transmitted from the DMX512 control console into a contact signal and transmits it to each device; A pump inverter unit that controls each motor pump to be driven; A nozzle control unit that controls each nozzle; A lighting control unit that controls each lighting; It consists of a nozzle motor inverter unit that controls each nozzle driving motor.

Since the prior document constituted as described above is connected to each through a cable (wire) using a USB 20 port for applying program data for directing music fountains, the installation is very complicated, as well as a product treated with waterproofing. There is a problem in that the purchase price of the cable is increased.

In addition, since the cable for applying the data is installed and the program data for directing the music fountain is applied, the labor cost is high due to the connection of the fountain nozzle, pump, lighting, and laser. There is a problem that can not be done properly.

Published Patent No. 10-2008-0077747 (published on August 26, 2008)

The present invention for solving the above problems solves the inconvenience of controlling a fountain nozzle, pump, lighting, laser, etc. by using an electric wire, and micom a fountain nozzle, pump, lighting, laser, etc. for more precise control. The objective of the present invention is to provide a musical fountain control method in which the control is performed by wirelessly applying a data signal to a fountain nozzle, pump, lighting, laser, etc. using the proportional control of the installed microcomputer.

In addition, according to the present invention, a microcomputer is installed to individually control fountain nozzles, pumps, lights, lasers, etc. to receive data transmitted wirelessly from a control PC, and calculate values according to the received data based on the extracted values. The purpose is to provide a method for controlling a musical fountain to perform a corresponding function.

The present invention as a means for achieving the above object

DMX controller, transmission DMX splitter sends the signal according to the data set by the administrator means including the control PC so that it can control more precisely while resolving the inconvenience of controlling the fountain nozzle, pump, lighting, and laser by using the electric wire. And a wireless transmission to a microcomputer installed in each of a fountain nozzle, a pump, an illumination, and a laser through a transmission means including a transmitter, receiving data transmitted wirelessly from the microcomputer, and calculating and extracting a value according to the received data Music fountain control method characterized by including device information collection process, mode setting process, directing process and channel setting process so that proportional control of fountain nozzle, pump, lighting and laser can be performed based on the value. Gives

The device information collecting process of the present invention comprises: a device variable initialization process for initializing a variable so as to initialize a preset value through a fractional control program installed in the control PC 11 so as to set a new data value; A check and time setting process for setting a check and time to set a new data value after performing the device variable initialization process; A PC time transmission process for setting a transmission value by setting a data value in a control PC after performing the check and time setting process; It characterized in that it comprises; after the PC time transmission process, the upload process for determining whether the data has been uploaded by the control PC.

The mode setting process of the present invention includes: a mode variable initialization process for initializing a variable according to the mode setting so that a new data value can be set by initializing a preset value on the mode setting screen of the fractional control program installed on the control PC; A setting value input process for setting an operation mode, a DMX channel mode, and a timer mode after performing the process of initializing the mode variable; A port setting process for setting a port so that a data signal (or data value) can be transmitted through the DMX channel after performing the setting value input process; After setting the port, a download process of downloading the set mode to a microcomputer installed in a fountain nozzle, pump, lighting, laser through a transmission means including a DMX controller, a transmission DMX splitter and a transmitter through a DMX channel; Through the DMX channel, the control PC determines whether there is a data signal uploaded by the data value downloaded to the microcomputer installed in the fountain nozzle, pump, lighting, laser through a transmission means including a DMX controller, a transmission DMX splitter, and a transmitter. It characterized in that it comprises a; judgment process.

The presenting process of the present invention comprises: a initialization variable initializing process for initializing a variable according to the rendering setting so as to initialize a preset value on a mode setting screen of a fractional control program installed on a control PC and to set a new data value; A reload determination process for determining whether information according to the location of the location where the fountain is installed is reloaded; This includes the process of setting the scene, setting the fade to make the sound, lighting or fountain fade away, setting the wait, setting the operating hours or minutes of the sound, lighting or fountain, and setting the color of the lighting. Direction setting process; A process for setting up a sound, lighting, or fountain that was first performed, to perform the operation again, or to stop the operation and proceed to the next step; A directing adding process of inserting an operation according to the directing of sound, lighting, or fountain, or selecting to add another function; It is characterized in that it includes a process of changing the direction in which the preset sound, lighting, or fountain is operated to operate with new content or deleting the preset content.

The channel setting process of the present invention comprises: a channel variable initialization process for initializing a variable according to the channel setting so that a new data value can be set by initializing a preset value on a channel setting screen of a fractional control program installed in the control PC; A lighting setting process for setting lighting for red, green, blue, and white; A channel confirmation process for determining whether channels according to the set lighting are set respectively; It is characterized in that it includes an illumination signal output process in which signals for illumination for red, green, blue, and white are respectively transmitted to channels set through the channel confirmation process.

The present invention solves the inconvenience of controlling a fountain nozzle, pump, lighting, laser, etc. by using an electric wire, and installs a micom on the fountain nozzle, pump, lighting, laser, etc., so that more precise control can be performed. It is easy to control the fountain because it is controlled by applying the data signal wirelessly to the fractional nozzle, pump, lighting, laser, etc. using the proportional control. This has the effect of reducing labor costs.

In addition, according to the present invention, a microcomputer is installed to individually control fountain nozzles, pumps, lights, lasers, etc. to receive data transmitted wirelessly from the manager PC, calculate values according to the received data, and extract the extracted values. On the basis of that, it is possible to perform the corresponding function, so that precise control is easy.

1 is a flow chart showing a process of checking information of a device by the present music fountain control method.
Figure 2 is a flow chart showing the process of setting the mode by the music fountain control method according to the present invention.
Figure 3 is a flow chart showing a process for producing a fountain nozzle, pump, lighting, laser through the music branch control method according to the present invention.
Figure 4 is a flow chart showing a channel setting process for controlling a fountain nozzle, pump, lighting, laser through the music branch control method according to the present invention.
5 is a block diagram showing a process of converting data set through the process of FIGS. 1 to 4 into a DMX signal to be wirelessly transmitted.
6 is a configuration diagram showing a fountain nozzle, pump, lighting, laser control system through the music branch control method according to the present invention.

Hereinafter, a method for controlling a musical fountain of the present invention will be described in detail.

However, it should be noted that the technical terms used in the present invention are only used to describe specific embodiments, and are not intended to limit the present invention.

In addition, technical terms used in the present invention should be interpreted as meanings generally understood by a person having ordinary knowledge in the technical field to which the present invention belongs, unless otherwise defined in the present invention. It should not be interpreted as a meaning or an excessively reduced meaning, and when the technical term used in the present invention is a wrong technical term that does not accurately represent the spirit of the present invention, it is a technical term that can be correctly understood by those skilled in the art. It should be understood as a substitute, and general terms used in the present invention should be interpreted as defined in the dictionary or in context before and after, should not be interpreted as an excessively reduced meaning, and the singular number used in the present invention Expressions of the terms include a plurality of expressions unless the context clearly indicates otherwise, and in the present invention, terms such as “consisting of” or “comprising” necessarily include all of the various elements or steps described in the present invention. It should not be construed as, and some of the components or steps may not be included, or should be construed as further including additional components or steps, and related arts in describing the present invention. If it is determined that the detailed description may obscure the subject matter of the present invention, the detailed description is omitted.

The sound pressure fraction control method according to the present invention will be described in detail through the accompanying drawings.

1 is a flow chart showing a process of checking information of a device by the music fountain control method, FIG. 2 is a flow chart showing a process of setting a mode by the music fountain control method according to the present invention, and FIG. 3 is the present invention Flowchart showing a process for directing a fractional nozzle, pump, lighting, and laser through the music branching control method according to FIG. 4 is a flowchart for controlling a fountain nozzle, pump, lighting, and laser through the music branching control method according to the present invention. Flowchart showing a channel setting process for, Figure 5 is a block diagram showing a process of converting the data set through the process of Figures 1 to 4 into a DMX signal to be wirelessly transmitted, Figure 6 is a music division according to the present invention It is a configuration diagram showing a system in which a fountain nozzle, a pump, lighting, and a laser are controlled through a control method.

When described in detail with reference to Figures 1 to 6, the negative pressure fraction control method according to the present invention to solve the inconvenience of controlling the fountain nozzle, pump, lighting, laser using a conventional wire so that more precise control Fractional nozzle through the transmission means 20 including the DMX controller 21, the transmission DMX splitter 22 and the transmitter 23, the signal according to the data set by the management means 10 including the control PC 11 , It transmits wirelessly to the microcomputer 40 installed in each of the pump, lighting, and laser, receives the data transmitted wirelessly from the microcomputer 40, calculates a value according to the received data, and corresponds to the value based on the extracted value. Including the device information collection process (S100), mode setting process (S200), directing process (S300), and channel setting process (S400) so that the proportional control of the fractional nozzle, pump, lighting, and laser can be performed so that the function is performed It is characterized by.

The device information collecting process (S100) performs a device variable initialization process (S110) of initializing a variable so that a new data value can be set by initializing a preset value through a fractional control program installed in the control PC 11, and the After performing the device variable initialization process (S110), a check and time setting process (S120) is performed to set a check and time to set a new data value, and control is performed after performing the check and time setting process (S120). The PC 11 performs a PC time transmission process (S130) for setting a transmission time by setting a data value, and after performing the PC time transmission process, the control PC determines whether data has been uploaded (S140) ).

In addition, the check and time setting process (S120) includes checking the device name, checking the version, updating the usage time, checking the LED board temperature, checking the temperature of the main board, checking the time set in the fountain control program itself installed in the control PC 11 and controlling the current control PC. (11) It checks its own time and performs the process of inputting the time set by the operator directly using the program through the fractional control program installed in the control PC (11).

As described above, the device information is input through a fractional control program installed in the control PC, and then a mode setting process is performed.

The mode setting process (S200) is a mode variable initialization process (S210) of initializing a variable according to the mode setting so that a new data value can be set by initializing a preset value on the mode setting screen of the fraction control program installed on the control PC 11 (S210) ), and after performing the process of initializing the mode variable, performs the set value input process (S220) for setting the operation mode, DMX channel mode, and timer mode, and after performing the set value input process (S220). Performs a port setting process (S230) for setting a port so that a data signal can be transmitted through the DMX channel, and after setting the port, the set mode is set through the DMX channel, the DMX controller 21, the transmitting DMX splitter 22, and A download process (S240) of downloading to a microcomputer installed in a fountain nozzle, pump, lighting, laser through a transmission means 20 including a transmitter 23 is performed, and the DMX controller 21 and the transmission DMX are transmitted through the DMX channel. The control PC 11 determines whether or not there is a data signal uploaded by the data value downloaded to the microcomputer installed in the fountain nozzle, pump, lighting, laser through the transmission means 20 including the splitter 22 and the transmitter 23. Performing the judgment of the judgment process (S250).

The directing process (S300) analyzes data from the microcomputer 40 installed in the fractional nozzle, pump, lighting, and laser by the data signal set through the mode setting process (S200), and based on the analyzed data value, the fractional nozzle, Set to produce a pump, light, and laser.

The directing process (S300) initializes the preset value on the directing setting screen of the fractional control program installed in the control PC 11 to initialize the variable according to the directing setting so that new data values can be set (S310). And, reload judgment process (S320) to determine whether the information according to the location of the location where the fountain is installed, and scene setting, sound, lighting, or fade setting that causes the fountain to disappear gradually, wait Directing setting process (S330) including setting, setting the operating hours or minutes of the sound, lighting or fountain, and setting the color of the lighting, and the operation of the previously performed sound, lighting or fountain to be performed again by turning to the previous step Performing or stopping the operation and proceeding to the next stage, the setting of the production progress (S340), and adding the operation according to the production of sound, lighting, or fountain, or adding another function (S350), and a preset It includes a directing change process (S360) of changing the directing content at the time of operation of the sound, lighting, or fountain to operate with new content, or deleting preset content.

The channel setting process (S400) initializes a preset value on a channel setting screen of a fractional control program installed in the control PC 11 to initialize a new data value so that the variable according to the channel setting is initialized (S410) ), and performs a lighting setting process (S420) for setting the lighting for red, green, blue, and white, and performs a channel checking process (S430) for determining whether channels according to the set lighting are respectively set, Through the channel confirmation process, a signal signal for red, green, blue, and white lighting is transmitted to a channel set through the channel confirmation process (S440 ), and a time signal is applied.

If the preset variable is used as it is while the data value for the preset channel is not initialized in the initializing process for the channel variable 410, a preset channel variable determination process (S450) is performed.

The pre-channel variable determination process (S450) is a pre-channel data output process (S451) so that the pre-set variable can be applied as the light without initializing the variable for the parameterized channel, and the variable is not initialized. If a channel is properly set according to the preset channel setting process (S452) and the preset channel setting process (S453), determining whether the channel is properly set through the fractional control program of the control PC 11, the preset channel Performs the pre-channel data output (S453) for applying the data according to the lighting.

In addition, if each channel according to the lighting set in the channel checking process (S430) has not been set, the control PC can check this and simultaneously reset the channel variable initialization process (S410) in the channel setting screen of the fractional control program. In order to perform it, a channel resetting process (S460) for inputting a channel is performed.

In the channel resetting process (S460), if the channel setting according to the lighting for red, green, blue, and white is not properly performed, data values according to the channel for which the setting has not been made are input, and the setting of the history channel is re-established. Reset channel input process to be set (S461), and whether the channel is set properly according to a data value in which the channel is not set is determined again, and if not, the reset channel input process (S461) is performed again. And, if the channel is set up properly, reset channel determination process (S462) and reset channel determination process (S462) to apply the channel data value to the reset channel data output process (S463) so that the variable of the data value for the channel can be initialized. In step S410, a reset channel data output process (S463) for applying a data value according to a channel is performed to initialize a variable of a data value according to a channel applied in ).

The operation of the music fraction control method according to the present invention configured as described above will be described.

First, a pattern can be set by using a program on the control PC 11 of the management means 10 so as to be described in an organic form with music in various patterns such as a fountain nozzle, pump pressure, light irradiation, laser irradiation, and the like. Information about the device is collected through the device information collection process (S100).

The control PC 11 collects information about the device through the device information collection process, and initializes the preset value on the mode setting screen of the fountain control program installed on the control PC 11 to set a new data value. Initialize the variables according to the settings. In addition, after performing the process of initializing the mode variable, set the operation mode, DMX channel mode, and timer mode, and then set the port so that data signals can be transmitted through the DMX channel.

Then, after setting the port, the set mode is transmitted to the fountain nozzle, pump, light, and laser through the DMX controller 21, the transmitting DMX splitter 22, and the transmitting means 20 including the transmitter 23 through the DMX channel. Control PC (11) whether there is a data signal that is uploaded by the data value downloaded to the microcomputer (40) installed in, and downloaded to the microcomputer (40) installed in the fountain nozzle, pump, lighting, laser through the transmission means (20) To be able to judge.

Initialize the preset value on the mode setting screen of the fountain control program installed on the control PC (11) to initialize the variable according to the direction of setting so that a new data value can be set, and whether the information according to the place where the fountain is installed is reloaded. After judging, the scene setting, the fade setting, the wait setting, the operation time or minute setting of the sound, lighting or fountain, and the color of the lighting are set so that the sound, lighting, or fountain gradually disappears.

Then, the operation of the sound, lighting, or fountain performed first is re-implemented, or the operation is stopped and the next step is performed. At this time, the operation according to the rendering of the sound, lighting, or fountain is inserted, or another function is selected. .

In addition, it is possible to operate with new content by changing the presentation content at the time of operation of the preset sound, lighting, or fountain, or to delete the preset content.

Initialize the preset value on the channel setting screen of the fountain control program installed in the control PC 11 to initialize the variable according to the channel setting to set a new data value, and set the lighting for red, green, blue, and white After determining whether the channels according to the set lighting are set, the signals for the red, green, blue, and white lights are respectively transmitted to the set channels.

As described above, the pattern according to the direction processes (or matches) data to receive a data signal from each micom 40 in a state in which a channel is set, and transmits the data to the DMX controller 21 of the transmitting means 20. Approve.

The DMX controller 21 divides the data signal applied from the control PC 11 into a control range from 0 to 255 steps (black and white binarization) so that settings can be made, and conforms to the DMX communication standard so that a unique address is input here. After matching, the data signal is applied to the transmitting DMX splitter 22.

In order to wirelessly transmit the data signal set through the above process from the control PC 11 through RS232, data is applied to the DMX controller 21 of the transmitting means 20, and the DMX controller 21 provides the above data. Convert the data signal to a DMX signal.

The process of matching data in the DMX controller 21 with the data value applied through the RS232 is as shown in FIG. 5.

As shown in the data sheet shown in FIG. 5, it is generated in the control PC 11, the first of the data sheet is composed of empty spaces, and the second, which is next to the spaces, is header data containing information of a file, and header data. Next is the length data to set the extruded rule so that the data can be compressed by what technique, and the third is the control PC (11) as well as the control message including the address (address, address) is set. ) Is a protocol message that controls the driving of each fractional nozzle, pump, light, and laser by the microcomputer 40, and the next data to which the protocol message is set is a checksum (Cheksum), which is the header data set at the tip of the data. This is data for correcting errors by double-checking and length data, and the last data is set as ASCII code as a line feed so that it is located in the next row when data values are entered.

The length data is digitally processed (sampled, quantized), and 1 or 0 pixels are continuously formed from image signals converted into pulses of 1 or 0.

The line feed is used when inputting the source code, which is set in the control PC 11 according to the rule of length data.

As described above, the data value set in the control PC 11 is set to communicate with the input/output channel or the internal memory of the control PC so that the DMX controller 21 communicates with the outside, as well as the control PC 11 and the DMX controller. It is a data break that allows data flow to match between (21), and is a start code for asynchronous transmission so that data received by the receiving means can be expressed in accordance with the system prescribed by MICOM, and the next data of the start code is transmitted. AAHeader, a gateway that extracts an address through a data value applied through a means and enables communication in a network band, is next to the header data so that it can grasp by which technique the data is compressed. It is the length data to set the extruded rule, and the control message including the address (address, address) is set next to the length data, as well as each of the fountain nozzles, pumps, lights, and lasers set in the control PC 11. A protocol message that controls the driving by the microcomputer 40, and the next data to which the protocol message is set is a checksum to check the header data and length data set at the tip of the data in duplicate to correct an error. Data.

The DMX controller 21 sets a data signal applied through RS232 from a control PC to a hexadecimal code value consisting of a combination of 0 or 1 in accordance with the rules of the DMX communication protocol, as a value for black and white binarization of 0 to 255. The conversion to DMX signal is performed through matching that converts.

As described above, the matched data signal (or data value) in the DMX controller 21 is converted into an MDX signal (or DMX data signal), and the changed data value can be produced by each fractional nozzle, pump, light, or laser. It is controlled by the microcomputer 40 by a pattern set to be.

The transmitting DMX splitter 22 distributes the data signal and divides the signal to receive the signal to each receiver, and applies the data signal to the transmitter 23 again.

The data signal applied to the transmitter 23 applies a signal to the receiver 31 of the receiving means 30 using short-range wireless communication using Wi-Fi, Bluetooth or Zigbee, and the receiver 31 receives the data signal Is applied again to the receiving DMX splitter 32.

The signal applied to the receiving DMX splitter 32 receives a data signal with a unique address input from a microcomputer 40 installed in a fountain nozzle, pump, lighting, laser, and receives a unique address corresponding to itself from the header of the data signal. After comparison and comparison, only data signals having the same unique address are received.

The microcomputer 40 that has received the data signal through the receiving DMX splitter 32 controls each fractional nozzle, pump, lighting, and laser based on the data signal, and programs it at the control PC 11 of the management means 10. The fountain nozzle, pump, lighting, and laser are self-directed while performing the function according to the pattern set by using, and are also described in an organic form with the sound transmitted through the speaker.

As described above, by connecting the control PC and the fountain nozzle, pump, lighting, and laser using a cable, the labor cost of installation is high, installation time is long, and noise is not properly controlled. There is an advantage that can solve all the problems can not be.

In addition, by controlling the various communication methods used for each fountain nozzle, pump, lighting, and laser into one and controlling them, there is an advantage that the compatibility between devices is enhanced and the whole musical fountain is naturally harmonized.

In addition, the present invention can prevent the risk of an electric leakage from increasing as additional connections of the interface equipment for connecting the fountain nozzle, the pump, the lighting, and the laser by using a cable increase, as well as through the interface device as in the prior art. Since it is deviated from the method of applying power using an applied DC power supply, it has the advantage of controlling the music fountain by a very simple installation.

This specification includes details of many specific implementations, but these should not be understood as limiting on the scope of any invention or claim, but rather as a description of features that may be specific to a particular embodiment of the particular invention. It should be understood. Certain features that are described in this specification in the context of separate embodiments may be implemented in combination in a single embodiment. Conversely, various features described in the context of a single embodiment may also be implemented in multiple embodiments individually or in any suitable subcombination. Furthermore, although features may operate in a particular combination and may initially be depicted as so claimed, one or more features from the claimed combination may in some cases be excluded from the combination, and the claimed combination subcombined. Or sub-combinations.

On the other hand, the embodiments of the present invention disclosed in the specification and drawings are merely presented as specific examples to aid understanding, and are not intended to limit the scope of the present invention. It is apparent to those skilled in the art to which the present invention pertains that other modified examples based on the technical idea of the present invention can be implemented in addition to the embodiments disclosed herein.

10: Management means 11: Control PC
20: Transmission means 21: DMX controller
22: transmit DMX splitter 23: transmitter
30: receiving means 31: receiver
32: receive DMX splitter 40: microcomputer
S100: Device information collection process S110: Device variable initialization process
S120: Check and time setting process S130: PC time transfer process
S140: Upload process S200: Mode setting process
S210: Mode variable initialization process S220: Set value input process
S230: Port setting process S240: Download process
S250: Upload judgment process S300: Directing process
S310: Initialization process of directing variables S320: Reload judgment process
S330: Director Setting Process S340: Director Setting Process
S350: Directing Addition Process S360: Directing Change Process
S400: Channel setting process S410: Channel variable initialization process
S420: Lighting setting process S430: Channel confirmation process
S440: Lighting signal output process S450: Pre-channel variable determination process
S451: Pre-channel data output process S452: Pre-channel setting process
S453: Pre-channel data output S460: Channel reset process
S461: Reset channel input process S462: Reset channel determination process
S463: Reset channel data output process

Claims (5)

Data signals (or data) set by the management means (10) including the control PC (11) for more precise control while resolving the inconvenience of controlling the fountain nozzle, pump, lighting, and laser by using the electric wire Value) to the microcomputer 40 installed in each of the fountain nozzle, pump, lighting, and laser through the transmission means 20 including the DMX controller 21, the transmission DMX splitter 22, and the transmitter 23. Proportional control of fractional nozzles, pumps, lights, and lasers to transmit wirelessly, receive wirelessly transmitted data from the microcomputer 40, calculate values according to the received data, and perform corresponding functions based on the extracted values In the music fountain control method, characterized in that it comprises a device information collection process (S100), mode setting process (S200), directing process (S300) and channel setting process (S400) to be made,
The device information collection process (S100),
A device variable initialization process (S110) of initializing a variable so as to initialize a preset value through a fractional control program installed in the control PC 11 so as to set a new data value;
A check and time setting process (S120) for setting a check and time to set a new data value after performing the device variable initialization process (S110);
A PC time transmission process (S130) for setting a transmission time by setting a data value in the control PC 11 after performing the check and time setting process (S120);
After the PC time transmission process (S130), the upload process (S140) to determine whether the control PC 11 has uploaded the data;
Music fountain control method comprising a. delete According to claim 1,
The mode setting process (S200),
A mode variable initialization process (S210) of initializing a variable according to the mode setting so that a new data value can be set by initializing a preset value on the mode setting screen of the fraction control program installed in the control PC 11;
A setting value input process (S220) for setting an operation mode, a DMX channel mode, and a timer mode after performing the process of initializing the mode variable;
A port setting process (S230) for setting a port so that a data signal can be transmitted through the DMX channel after performing the setting value input process (S220);
After setting the port, the set mode is set through the DMX channel through the DMX controller 21, the transmitting DMX splitter 22 and the transmitting means 20 including the transmitter 23. A downloading process (S240) of downloading to (40);
Data value downloaded to the microcomputer 40 installed in the fountain nozzle, pump, lighting, laser through the transmission means 20 including the DMX controller 21, the transmission DMX splitter 22 and the transmitter 23 through the DMX channel. An upload determination process (S250) in which the control PC 11 determines whether there is a data signal uploaded by the control PC 11;
Music fountain control method comprising a. According to claim 1,
The directing process (S300),
Performing a directing variable initialization process (S310) for initializing variables according to the directing settings so that a new data value can be set by initializing a preset value on the mode setting screen of the fountain control program installed in the control PC 11,
Reload determination process (S320) to determine whether the information according to the location of the location where the fountain is installed, and
This includes the process of setting the scene, setting the fade to make the sound, lighting or fountain fade away, setting the wait, setting the operating hours or minutes of the sound, lighting or fountain, and setting the color of the lighting. Directing setting process (S330),
The operation of the sound, lighting, or fountain that was first performed is turned to the previous stage to be re-executed, or the production progress setting process (S340) is stopped and the next stage is performed.
Directing adding process (S350) for inserting an operation according to the directing of sound, lighting, or fountain, or selecting to add another function;
A directing change process (S360) of changing the directing content at the time of operation of the preset sound, lighting, or fountain to operate with new content or deleting the preset content;
Music fountain control method comprising a. According to claim 1,
The channel setting process (S400),
A channel variable initialization process (S410) of initializing a variable according to the channel setting so that a new data value can be set by initializing a preset value on the channel setting screen of the fraction control program installed in the control PC 11;
A lighting setting process (S420) for setting lighting for red, green, blue, and white; A channel confirmation process (S430) for determining whether channels according to the set lighting are respectively set;
A lighting signal output process in which signals for lighting for red, green, blue, and white are respectively transmitted to channels set through the channel checking process (S440);
Music fountain control method comprising a.

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