KR102094819B1 - Flame machine control system for performance - Google Patents

Abstract

The flame machine control system for performances according to an aspect of the present invention includes: a flame machine control system for performances including a plurality of flame machines, wherein electronic data for a music score or lighting signal in which electronic data for a music source is recorded is recorded; In synchronization with the recorded lighting score, a console computer generating a flame machine control signal for performing motion control of each flame machine is connected to the console computer and transmits the flame machine control signal to each flame machine by wireless communication. The master communication device and the slave communication device receiving the flame machine control signal transmitted from the master communication device, the igniter operating according to the ignition signal included in the received flame machine control signal, and the received flame machine control signal Fuel valve operating according to the activated fuel valve drive signal It is to include a plurality of flame machines that include a ball.

Description

Flame Machine Control System for Performances {FLAME MACHINE CONTROL SYSTEM FOR PERFORMANCE}

The present invention relates to a flame machine control system for a performance that can perform various performances by applying a wired or wireless communication method to the flame machine according to the performance site situation.

In general, the performance industry refers to a large-scale event industry, such as various types of music and dance, where production and consumption are performed simultaneously through the performance. In this performance industry, a variety of special effects equipment is installed where stages and choreography are required.

Special effect equipment includes flame (firecrackers) or flame launchers for directing lights, lasers, strobe lights, lighting devices that provide lighting effects, dry ice, liquid nitrogen, mist from heated oil, etc. And a fume generating device including smoke, a fire spraying device, a water curtain operating device, and the like.

Among the special effects equipment, the flame launch device is installed in dozens to hundreds of flame launch devices in various places depending on the size of the venue, and is connected by wire to the console computer that controls each flame launch device. When a console computer and N flame launching devices are connected by wire in a large-scale venue, the degree of freedom of directing a flame or fire decreases, and each device needs to be connected by wire, which takes a lot of time to prepare for work.

The console computer must be able to transmit control signals to the N flame launching devices with minimum delay time so that the fire pillar or the flame performance can proceed without time error according to the director's intention. However, when a multi-functional commercial short-range wireless communication module is applied to a console computer and N flame launch devices, the communication delay time is significantly increased compared to wired communication, so the short-range wireless communication module is applied to a console computer and multiple flame launch devices. It is actually a difficult situation.

Korean Registered Patent No. 10-1809153 (Invention name: Integrated control system for large-scale multimedia fireworks performance)

The present invention is to solve the above-described problems of the prior art, one embodiment of the present invention is a console computer or N flame machine to be connected by wired communication or wireless communication depending on the situation of the performance, the dualized fuel tank and An object of the present invention is to provide a flame machine control system for performances that can secure stability and economy by applying a double solenoid valve.

As a technical means for achieving the above technical problem, the flame machine control system for performances according to an aspect of the present invention includes: a flame machine control system for performances including a plurality of flame machines, wherein electronic data for a music source is A console computer generating a flame machine control signal for performing motion control of each flame machine in synchronization with the recorded music score or the lighting score in which electronic data for the lighting signal is recorded, connected to the console computer, and controlling the flame machine A master communication device that transmits a signal to each frame machine by wireless communication, a slave communication device that receives a flame machine control signal transmitted from the master communication device, and operates according to an ignition signal included in the received flame machine control signal Igniter and the received flame machine control scene Depending on the fuel valve drive signal included in to a plurality of flame machine including a fuel valve operation.

According to the above-mentioned problem solving means of the present invention, the console computer or N flame machines can be connected by wired communication or wireless communication according to the situation of the performance, so that various flame machines can be connected in various regions to perform performances. Has the effect of increasing the preparation time.

In addition, the present invention can separate the fuel tank into the main fuel tank and the auxiliary fuel tank to replenish the fuel even during flame firing, to continuously operate the equipment, and to reduce the consumption of fuel, the production time can be extended, and malfunction of the fuel valve There is also an effect that can secure the stability by applying a double solenoid valve to prevent the flame eruption accident.

1 is a view for explaining the overall configuration of a flame machine control system for performances according to an embodiment of the present invention.
2 is a block diagram illustrating the configuration of a flame machine according to a first embodiment of the present invention.
3 is a block diagram illustrating the configuration of a flame machine according to a second embodiment of the present invention.
4 is a view for explaining a flame unit according to an embodiment of the present invention.
5 is an exemplary view for explaining the configuration of the double solenoid valve of FIG. 4.
6 is a view for explaining a wireless transmission / reception mode of a flame machine control system for performances according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains can easily practice. However, the present invention can be implemented in many different forms and is not limited to the embodiments described herein. In addition, in order to clearly describe the present invention in the drawings, parts irrelevant to the description are omitted, and like reference numerals are assigned to similar parts throughout the specification.

Throughout the specification, when a part is "connected" to another part, this includes not only "directly connected" but also "electrically connected" with another element in between. . Also, when a part “includes” a certain component, this means that other components may be further included rather than excluding other components, unless otherwise specified.

1 is a view for explaining the overall configuration of a flame machine control system for performances according to an embodiment of the present invention, and FIG. 2 is a block diagram for explaining the configuration of a flame machine according to a first embodiment of the present invention, 3 is a block diagram illustrating the configuration of a flame machine according to a second embodiment of the present invention, FIG. 4 is a view illustrating a flame unit according to an embodiment of the present invention, and FIG. 5 is a double solenoid valve of FIG. 4 It is an exemplary view for explaining the configuration of.

1 to 5, the flame machine control system for performance includes a console computer 100, a master communication device 200, and N flame machines 300.

The console computer 100 generates a flame machine control signal that performs motion control of each flame machine 300 in synchronization with a music score in which electronic data for a music source is recorded or a lighting score in which electronic data for a lighting signal is recorded. Output. The console computer 100 includes a directing editing function that enables the director to design and edit the directing effect in advance. At this time, the console computer 100 may provide a synchronization function with equipments such as a script composer and cue signal interpreter in addition to the music score or lighting score.

In addition, the console computer 100 may determine a communication mode and fuel supply with the flame machine 300 by checking a wireless transmission / reception state, an electrical connection state, a fuel amount, and the like.

The master communication device 200 is connected to the console computer 100 and transmits a flame machine control signal to each flame machine 300 by wireless communication. The master communication device 200 may be a yagi-da antenna, and the slave communication device 310 may use a dipole antenna.

The flame machine 300 includes a slave communication device 310 and a flame unit 320. At this time, the slave communication device 310 receives the flame machine control signal transmitted from the master communication device 200, and the flame unit 320 performs a flame firing operation according to the flame machine control signal.

The slave communication device 310 and the flame unit 320 may be combined in a one-to-one form as shown in FIG. 2, and a plurality of flame units 320 in one slave communication device 310 as shown in FIG. ) May be one-to-many. Therefore, the slave communication device 310 is installed in the case of one-to-one combination depending on the performance site environment or the type of the flame unit 320, but M (M <N) is installed when combined in a one-to-many form. Because it can be done, flexible design changes are possible during installation work, and time and effort required for installation work can be reduced.

In addition, in the case of the flame unit 320 using the valve opening and closing method, as shown in FIG. 3, the flame unit 320 having various flame shapes may be combined with the slave communication device 310. Therefore, the flame machine 300 may be applied with different types of flame units 320 from a minimum of 1 to a maximum of N.

4, the flame unit 320 includes, but is not limited to, a pressurizing portion 321, a main fuel tank 322, an auxiliary fuel tank 323, a fuel valve 325 and an igniter 326. Does not.

Fuel is stored in the main fuel tank 322, and the pressurizing portion 321 is coupled to the front end of the main fuel tank 322 to supply nitrogen gas to the main fuel tank 322. The pressurizing portion 321 includes a regulator for adjusting the pressure of nitrogen gas.

The auxiliary fuel tank 323 is coupled to the rear end of the main fuel tank 322 and supplies fuel delivered from the main fuel tank 322 to the fuel valve 325. At this time, the fuel valve 325 is a dual solenoid valve 325 including a master valve 325a and a sub-valve 325b that operate simultaneously according to a fuel valve drive signal included in the flame machine control signal. Since the fuel valve driving signal includes information on the opening time of the fuel valve 325, the fuel valve maintains an open state for the opening time included in the fuel valve driving signal and locks the fuel valve after the opening time ends. do.

5, the solenoid valve 325 is a type in which the master valve 325a and the slave valve 325b are connected in series, and a fuel valve driving signal is provided to the master valve 325a and the slave valve 325b. It is delivered at the same time.

In the flame machine 300, the fuel valve is opened by the fuel valve driving signal and the flame must be ejected. When the flame is not ejected, or the fuel valve is closed by the fuel valve driving signal, the flame ejection must be stopped and the flame is continuously ejected. In the event of a malfunction, the performance of the fuel valve may not continue due to malfunction of the fuel valve, or a risk of fire may occur. In particular, in the case of a malfunction in which the flame is continuously ejected because the fuel valve is not closed, in addition to an accident in which the performance flow is interrupted, it may lead to a fatal accident in which human / physical damage occurs. Therefore, the double solenoid valve 325 has a master valve 325a and a slave valve 325b connected in series, so that the possibility of malfunction of the closing of the fuel valve is reduced by 1/2, thereby securing stability.

In addition, the auxiliary fuel tank 323 includes N fuel supply pipes 324 for supplying fuel to N flame machines, respectively. The auxiliary fuel tank 323 is connected to the main fuel tank 322 in a one-to-one manner, but in some cases, one or more auxiliary fuel tanks 323 are connected to one main fuel tank 322, which is economical and operational efficiency. Can be maximized.

The igniter 326 is operated according to the ignition signal included in the flame machine control signal to generate a flame.

The pressure transmitted to the upper portion of the main fuel tank 322 through the pressing portion 321 pressurizes the fuel inside the main fuel tank 322, and the pressurized fuel is transmitted to the lower portion of the main fuel tank 322, It is delivered to the auxiliary fuel tank 323 using a high pressure hose.

The fuel thus pressurized is supplied to the auxiliary fuel tank 323 and is ejected through an injection nozzle (not shown) through the fuel valve 325. At this time, the igniter 326 is operated at the same time as the fuel is ejected to ignite the high-pressure fuel that is ejected.

At this time, the flame unit 320 may be configured to appropriately arrange a control valve so that a different pressure can be applied to the fuel supply site as needed, so that various fire height adjustments are possible.

The flame unit 320 is made of stainless steel to prevent rust and light weight due to rain and wind, and can be manufactured to be compatible with the lower support and the upper mounting type by designing an exterior to separate the main body and the floor.

As such, the flame machine 300 can be manufactured in a compact and light weight by simplifying the external structure of the slave communication device 310 and the internal structure of the flame unit 320, and replacement and maintenance of parts can be facilitated. .

 6 is a view for explaining a wireless transmission / reception mode of a flame machine control system for performances according to an embodiment of the present invention.

First, as illustrated in FIG. 6, the slave communication device 310 includes a wireless data transmission / reception module 311, a first dip switch 312 for selecting an input signal, and a second dip switch 323 for selecting a relay mode. , An input terminal 314 and an output terminal 315.

When the first dip switch 312 is set to the first state ('0'), the slave communication device 310 is directly wired connected to the console computer 100 or other external equipment through the input terminal 314 for input. The mode is set to receive a signal. The console computer 100 may perform flame firing control to a plurality of channels through a digital multiplexing (DMX) output terminal.

When the first dip switch 312 is set to the second state ('1'), it is set to a mode for receiving an input signal through the wireless data transmission / reception module 311.

Meanwhile, when the second dip switch 313 of the slave communication device 310 is set to the first state ('0'), the second dip switch 313 is set to a mode that does not relay data to another slave communication device. When is set to the second state ('1'), it is set to a mode for relaying data to another slave communication device through a wired connection through the wireless data transmission / reception module 311 or the output terminal 315.

Referring to FIG. 6A, in the slave communication device 310, the first dip switch 312 is set to the first state ('0'), and the second dip switch 313 is set to the second state ('1'). When set, the console computer 100 or other external equipment is directly wired connected through the input terminal 314 to receive an input signal, and through a wired connection through the wireless data transmission / reception module 311 or the output terminal 315. It is set as a first mode for relaying data to another slave communication device, that is, a wired input wireless relay mode.

In the first mode, the frame machine 300 located at the closest position from the console computer 100 is connected to the console computer 100 through wired communication, and from the next frame machine 300 is connected to the console computer 100 through wireless communication. Make it usable. The first mode may be applied when wireless transmission / reception is not smooth because the frame computer connected to the console computer for the first time is more than a certain distance.

Referring to FIG. 6B, when the first dip switch 312 is set to the second state ('1') and the second dip switch 313 is set to the first state ('0'), the wireless data transmission / reception module An input signal is received through 311 and is set to a second mode in which data is not relayed to another slave communication device, that is, a wired input mode.

In the second mode, when the wireless transmission / reception state is smooth, there is an advantage in that the distance is not limited by connecting and using wireless communication between the console computer 100 and the N flame machines 300.

Referring to FIG. 6C, when the first dip switch 312 is set to the second state ('1') and the second dip switch 313 is set to the second state ('1'), the wireless data transmission / reception module In the third mode for receiving an input signal through 311 and relaying data to another slave communication device through a wired connection through a wireless data transmission / reception module 311 or an output terminal 315, that is, a wireless input wired relay mode Is set.

In the third mode, if the size of the venue or the wireless transmission / reception status is not smooth, wireless transmission / reception is performed from the first flame machine to the M-th flame machine, and if the wireless transmission / reception of the M + 1th flame machine is not achieved, the M-th frame You can use the machine and the M + 1th frame machine by wired connection.

Referring to FIG. 6D, when the first dip switch 312 is set to the first state ('0') and the second dip switch 313 is set to the first state ('0'), the console computer 100 ) Or other external equipment is directly connected to the wire through the input terminal 314 to receive an input signal, and is set to a fourth mode that does not relay data to another slave communication device, that is, a wired input mode.

The fourth mode is a state in which the console computer 100 and the N flame machines 300 are all connected by wire, and may be applied to a small venue or an area where wireless transmission / reception is impossible.

On the other hand, the master communication device 100 and the slave communication device 310 do not use the existing 433 MHz wireless communication frequency band, but communicate with the master communication device 100 by using the 447.925 MHz wireless communication frequency band. In point-to-multipoint wireless communication between the slave communication devices 310, N (for example, 256) channels may be supported, and when using a wireless communication frequency band of 433 MHz, an effective radiated power of 3 mW or less has a wireless communication frequency of 447.925 MHz. When the band is used, it has an advantage of being less than 10 mW, which can be reduced in terms of transmission power.

As described above, the flame machine control system for a performance according to an embodiment of the present invention may be in a case where the radio transmission / reception status is not smooth, for example, various radio frequency bands are mixed or out of the wireless transmission range during an outdoor performance or a large-scale event. In this case, the dip switch can be adjusted to properly mix and use a wired input / wireless input, wired relay / wireless relay.

The above description of the present invention is for illustration only, and a person having ordinary knowledge in the technical field to which the present invention pertains can understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope of the present invention is indicated by the following claims rather than the above detailed description, and it should be interpreted that all changes or modified forms derived from the meaning and scope of the claims and equivalent concepts thereof are included in the scope of the present invention. do.

100: console computer 200: master communication device
300: flame machine 310: slave communication device
320: flame unit

Claims (6)

In the flame machine control system for a performance comprising a plurality of flame machine,
A console computer generating a flame machine control signal that performs motion control of each flame machine in synchronization with a music score in which electronic data for a music source is recorded or a lighting score in which electronic data for a lighting signal is recorded,
A master communication device connected to the console computer and transmitting the flame machine control signal to each flame machine by wireless communication;
Slave communication including a wireless data transmission / reception module, a first dip switch for selecting an input signal, a second dip switch for selecting a relay mode, an input terminal and an output terminal for receiving a frame machine control signal transmitted from the master communication device A plurality of flame machines including a device, an igniter operating according to an ignition signal included in the received flame machine control signal, and a fuel valve operating according to a fuel valve drive signal included in the received flame machine control signal, ,
The slave communication device of the flame machine
When the first dip switch is set to the first state and the second dip switch is set to the second state, the console computer or other external equipment is directly wired through the input terminal to receive an input signal, It is set to a first mode for relaying data to another slave communication device through a wired connection through the wireless data transmission / reception module or the output terminal,
When the first dip switch is set to the second state, and the second dip switch is set to the first state, an input signal is received through the wireless data transmission / reception module, and data is not relayed to another slave communication device. Is set to 2 mode,
When the first dip switch is set to the second state and the second dip switch is set to the second state, an input signal is received through the wireless data transmission / reception module, and through the wireless data transmission / reception module or the output terminal. It is set to the third mode for relaying data to another slave communication device through a wired connection,
When the first dip switch is set to the first state and the second dip switch is set to the first state, the console computer or other external equipment is directly wired through the input terminal to receive an input signal, Flame machine control system for performances set in a fourth mode that does not relay data to other slave communication devices. According to claim 1,
The fuel valve is a double solenoid valve including a master valve and a sub-valve that operate simultaneously according to the fuel valve driving signal. The method of claim 1 or 2,
The fuel valve driving signal includes information on the opening time of the fuel valve,
The fuel valve maintains an open state for an opening time included in the fuel valve driving signal, and performs an operation of locking the fuel valve after the opening time ends. delete delete According to claim 1,
The flame machine control system for the performance
Main fuel tank where fuel is stored,
It is coupled to the front end of the main fuel tank, the pressurizing unit for supplying nitrogen gas to the main fuel tank and
It is coupled to the rear end of the main fuel tank, including an auxiliary fuel tank for supplying the fuel delivered from the main fuel tank to the fuel valve of the flame machine,
The auxiliary fuel tank is a flame machine control system for a performance that includes N fuel supply pipes for supplying fuel to each of the N flame machines.

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