KR810002062B1 - Sound simulator - Google Patents

Abstract

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Description

Sound simulator

1 is a block diagram showing a conventional acoustic simulation apparatus.

2 is a waveform diagram showing an example of a simulated sound of a thermal power plant.

FIG. 2A is a waveform diagram showing a dark noise, and FIG. 2B is a waveform diagram showing a safety valve steam jet sound of a boiler.

2v is a waveform diagram showing a generator moving sound.

3 is a waveform diagram showing the volume of a specific simulation sound for explaining the operation of the conventional acoustic simulation apparatus.

4 is a block diagram illustrating an embodiment of the invention.

5 is a block diagram showing an acoustic simulation apparatus of the present invention.

FIG. 6 is a waveform diagram when the amplitude of the sound shown in FIG. 2 is obtained by a water generation program of a calculator. FIG.

7 is a flowchart illustrating a general irrigation generating program.

8 is a waveform diagram showing the volume of a specific simulation sound for explaining the operation of the acoustic simulation apparatus of the present invention.

9 is a flowchart for explaining the operation of the acoustic simulation apparatus according to the embodiment of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a sound simulation apparatus used for operator training in various plants. The invention relates to an amplitude adjustment apparatus for inputting a sound signal of a predetermined level output from a sound reproducing apparatus and sequentially setting according to a program of an electronic calculator. Acoustic signals of a predetermined amplitude are adjusted by the amplitude adjusting device so that the sound is simulated by the sound output device.

A description will be given below of an example of a thermal power plant as various plants. In general, in order to operate a thermal power plant, it is necessary to train the operator in advance, and the operator trains the thermal power plant simulation apparatus on how to cope with what may actually happen in the thermal power plant. In this training, the thermal power plant simulation apparatus notifies the training driver of the plant status, such as various indicators and alarm lamps, as if the actual thermal power plant was in operation according to the operation of the training operator. In parallel with this, having the training operator hear the sound that can be detected in the actual thermal power plant central control room gives the training driver a feeling of being on-site and at the same time hears the sound produced by the training operator's operation. At the same time, it brings good results to the training of the operator. The present invention relates to a sound simulation apparatus for such a training operator to hear the sound that can occur according to the state of the thermal power plant.

1 shows an acoustic simulator for use in a conventional thermal power plant simulation apparatus. The sound reproducing apparatus 1 uses the self-recording tape according to the type of sound detected in the plant central control room according to the various conditions of the actual thermal power plant in order to simulate the pre-simulated sound for the training operator. 1a) to (1v), which are used for reproducing the recorded simulation sound to a reproduction signal. The regeneration device 1a is a recording set of a cow sound detected in an actual thermal power plant's central control room, and the yin and yang signal of the cow sound is generated in various thermal power plants as shown in FIG. 2A. This is a constant level of mixed white noise. Similarly, the regeneration device 1b is a recording set of a safety valve steam blowing sound generated by manual operation or automatically when the safety valve of a boiler is opened. The sound signal of the safety valve steam blowing sound is as shown in FIG. 2B. When the safety valve is opened, it is raised to the maximum level, and then to a constant level. Similarly, the regeneration device 1v is a recording set of the generator mover input sound generated when the synchronization with the system does not coincide with the generator input. The sound signal of the generator mover input sound is generated as shown in FIG. It is raised to the maximum level at the time of input and then gradually eliminated by being synchronized with the system.

The electronic calculator 2 selects the playback apparatuses 1a to 1v in which the simulation sounds to be simulated by external commands are recorded among the plurality of playback apparatuses 1a to 1v. Here, the external command is generated in accordance with various state quantities of the thermal power plant simulation apparatus which the training operator proceeds by operating the thermal power plant simulation apparatus 10.

The sound output device 3 is for power amplifying the reproduction sound from the sound reproducing apparatus 1 selected by the electronic calculator 2 so as to have a predetermined volume, and generating sound in the speaker.

Next, the operation of the conventional acoustic simulation apparatus shown in FIG. 1 will be described with reference to FIG. ₃ shows the volume of sound produced in each plant when the training operator opens the safety valve of the boiler at time t ₁ , closes the safety valve at time t ₂ , and turns on the generator when no synchronization is achieved at time t ₃ . It is shown.

First, assuming that the thermal power plant to be simulated in a predetermined stable state at time t ₀ , the electronic instrument 2 is in the predetermined stable state in the thermal power plant simulation apparatus 10, it is required to output a cow sound, The playback device 1a in which the sound of the playback device 1 is recorded is selected, and an operation signal for instructing start is output. The reproducing apparatus 1a, which has received the operation signal from the computer 2, reproduces the previously recorded dark sound, and outputs the dark sound from the sound output device 3. Generally, this noise is always heard in the central operating room during the operation of the thermal power plant, so the regeneration device 1a outputs the noise during the operation of the thermal power plant to be simulated. Next, at the time t ₂ , the thermal power plant simulation apparatus 10 is in a state in which the safety valve of the boiler is opened by the operation of the training operator, so that the electronic calculator 2 generates a safety valve steam jet sound as shown in FIG. When asked to output, the playback device 1b is selected to output an operation signal. The reproducing apparatus 1b received by the operation signal from the calculator 2 reproduces the pre-recorded safety valve steam blowing sound. The dark sound signal and the safety valve vapor ejection sound signal reproduced by the reproducing apparatuses 1a and 1b are mixed and input to the sound output apparatus 3 at the volume L as indicated in t ₁ to t ₂ of FIG. The sound is mixed with the noise of the cow and the safety valve steam. This mixed sound is output until the safety valve is closed. When the safety valve is closed at time t ₃ , the calculator 2 stops the playback of the regeneration device 1b and rewinds the magnetic recording tape. The playback device 1b is set to the initial state. In addition, when the playback device 1b is stopped, the sound is similarly output from the sound output device 3. Next, at the time t ₃ , the thermal power plant simulation apparatus 10 is turned on by the operation of the training operator, so that the electronic calculator 2 is required to output the generator mover input sound as shown in FIG. The playback device 1v is selected to output the operation signal. The reproducing device 1v receiving the operation signal operates in the same manner as described above, and outputs a mixed sound of the cow sound and the generator mover input sound from the sound output device 3. In addition, as shown in FIG. 2V, the generator mover input sound becomes less than the volume of the cow sound after a predetermined time has elapsed, and stops when the predetermined time has elapsed since the start of operation. Set 1v) to the initial state.

The above description has described a very limited example, and the general operation of the one shown in FIG. 2 is as follows. The electronic calculator 2, which has received a sound simulation request by a command signal (not shown) from the outside, selects the sound reproducing apparatus 1 which sets a magnetic recording tape on which the simulation sound to be simulated is recorded, and starts up. Outputs an operation signal indicating. The selected sound reproducing apparatus 1 receives the operation signal from the electronic calculator 2 and reproduces the simulation sound recorded in advance, and this reproducing signal is input to the sound output apparatus 3 and converted into a sound.

Since the conventional sound apparatus is constructed as described above, the simulation sound is limited to only the sound recorded on the magnetic recording tape, and in order to generate various kinds of simulation sounds, the magnetic recording tape and the sound reproducing apparatus are respectively applied to various kinds of the simulation sound. Therefore, since a plurality of units are required, there is a drawback of a large-scale device. In addition, it was necessary to rewind the magnetic recording tape after the simulation sound was generated or stopped.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned shortcomings, and it is unnecessary to rewind a magnetic recording tape, and to provide an acoustic simulation apparatus capable of realizing various kinds of simulations with one magnetic recording tape and a sound reproducing apparatus. will be.

That is, the present invention inputs a sound signal having a predetermined volume reproduced by the sound reproducing apparatus to the amplitude adjusting device, and adjusts the predetermined amplitude sound signal by the amplitude adjusting device so as to have an amplitude value sequentially set according to the program of the electronic calculator. It is configured to output the simulation sound from the sound output device.

According to the present invention, by controlling the control of the amplitude of the constant amplitude signal by the control signal of the computer, various kinds of simulation signals can be realized by one sound reproducing apparatus. In addition, since an endless recording material is used as the source of the constant amplitude signal, the tape rewinding operation is unnecessary.

Hereinafter, a sound simulation apparatus according to an embodiment of the present invention is shown and described in FIG.

It is desirable to have the training source listen to the sound sensed in the central control room according to various conditions of the actual thermal power plant. Here, when focusing on the sounds to be simulated, for example, the safety valve steam blowing sound and the generator mover sound, these sounds are composed of frequency components and amplitude (acoustic) components as shown in Figs. 2B and 2V. In order to simulate the sound of the signal, it is preferable to simulate by the frequency component and the amplitude component. However, it is possible to fully understand what kind of sound is heard by the listener, including all white noise-included audible frequency components and the amplitude components of the simulated sounds as shown in Figures 2B and V. We found that we could get enough training effect by letting the training driver listen.

The sound reproducing apparatus 4 has a sound level detected in the central control room of an actual thermal power plant, that is, a sound containing all audible frequency components, which are white noise, is recorded and set at a certain level on an endless magnetic recording tape. The noise is reproduced by a certain level of noise signal. The electronic calculator 95 has a built-in program for outputting an amplitude control signal for instructing the amplitude of the simulated sound to simulate the amplitude of the sound recorded at a predetermined level.

The amplitude adjusting device 6 controls the amplitude of the cow sound reproduction signal in the sound reproducing apparatus 14 to approximately the same amplitude as the sound to be simulated based on the amplitude control signal in the electronic calculator 5, and reproduces the sound as a simulation sound signal. Output to the output device. The sound output device 3 that inputs the simulated sound signal, like the conventional one, amplifies the power at a constant amplification rate and outputs the simulated sound from the speaker.

n

8)이 되도록 설정된 것이다.A detailed circuit configuration of the amplitude adjusting device 6 will be described with reference to FIG. The resistance group 60 is composed of the output resistor R ₀ and the split resistors R ₁ to R ₈ for setting the amplitude, and the split resistor value R _{n has} a value of R _n = R ₀ ㆍ 2 ^n-1 (but 1

n

8) is set to be.

The switch group 61 is composed of switches SW ₁ to SW ₈ set corresponding to the division resistors R ₁ to R _{8. When the} switch group 61 corresponds to the binary digital output of the calculator 5, the switch is turned ON. If the corresponding divisional resistance is shorted and " 0 ", the switch is turned off to open the corresponding divisional resistance.

The operation of specific amplitude adjustment of the amplitude adjustment device 6 will be described. The input voltage Vi of the input terminal 62 is made constant, and the output voltage of the output terminal 63 is set to V ₀ . When the digital output "00000001" corresponding to N = 1 in decimal in the calculator 5 is set in the switch group 61, the switch SW ₁ is turned OFF, the SW ₂ to SW ₈ are turned on, and the split resistor R ₂ ~ R ⁸ is valid. Because of this, the output voltage V ₀

It becomes

When the digital output "00001010" corresponding to N = 10 in decimal in the calculator 5 is set in the switch group 61, the output voltage V ₀ is similarly

In general, when the decimal number in the calculator (5) is N, the output voltage V ₀ is

(Where N is an integer from 1 to 255).

In this way, the amplitude adjusting device 6 adjusts the dark tone signal having a constant amplitude output from the sound reproducing apparatus 4 by the amplitude control digital signal output from the calculator 5 to be the amplitude of the sound to be simulated.

Next, a program of the calculator 5 which outputs the amplitude adjustment signals of the simulated noise, safety valve steam blowing sound, and generator mover injection sound will be described. The noise to be simulated, the safety valve steam blowing sound, and the generator mover sound are obtained by a program that generates water irrigation close to the amplitude value as shown in FIG. 2, and will be described according to FIG. .

FIG. 6A shows the irrigation curve for simulating the noise, which is set at an initial time ta = 0 ₀ and represented by an irrigation of L (t) = a ₁ (where a ₁ is an integer).

FIG. 6B shows the irrigation curve for simulating the safety valve steam blowing sound, which is set at an initial time tb ₀ = 0,

However, b ₁ , b ₂ , and ~ C ₁ ~ C ₄ are represented by integer watering.

Figure 6v shows the irrigation curve to simulate the generator mover input sound, it is set at the initial time tv _{0 =} 0,

However, v ₁ , v ₂ , and C ₅ are represented by an integral number of integers.

信號) (도시하지 않음)에 의하여 기동되고, 모의하는 경우는 해당하는 관수 L(t)를 계산기에 의해 발생시켜, 진폭조정신호 N=CL(t)의 디지털신호를 출력한다.Since the simulated volume L (t) is interpreted and obtained in advance as shown in FIG. 6, the volume L (t) can obtain the amplitude adjustment signal N (t) as the calculator output by the program of the calculator. FIG. 7 shows the general flowchart art. In order to simulate the simulated volume that changes every moment in real time, the program uses a timer assignment signal (割) installed in the calculator (5).

In the case of simulation (not shown) and simulating, a corresponding irrigation water L (t) is generated by a calculator to output a digital signal of amplitude adjustment signal N = CL (t).

Next, as a result of the operation by the training driver, the volume curve of the volume to be simulated is shown in FIG. 8, and the operation of the amplitude adjustment signal N generated by the program will be described according to the flowchart of FIG. The outline of the operation is substantially the same as that described in FIG.

t＜t₁에서는 화력발전 플랜트가 동작상태에서 안전밸브는 닫혀지고, 발전기의 이동기투입도 행해지지 않고 있으므로, 계산기(5)에 설치된 100msec 마다 발생하는 타이머 할입신호에 의해 진폭제어신호 N은 일정한 모의암소음진폭제어신호 Na를 출력한다.Time t ₀

t in <t ₁ in the thermal power plant operating states the safety valve is closed and the mobile device In the generator also because not performed, the calculator 5, the amplitude control signal and N is a constant simulated by a timer interruption signal generated every 100msec installed in Outputs the dark amplitude control signal Na.

Since the safety valve is opened at time t = t ₁ , the watering generation program for simulating the safety valve steam blowing sound is started by the timer assignment signal generated at this time. The value of the simulated safety valve steam blow-out sound amplitude control signal Nb obtained by this is added to the value of the noisy amplitude control signal Na, and is output by the calculator as amplitude control signal N = Na + Nb. Similarly, since the generator mover input is performed at the time t ₄ to t ₅ , the amplitude control signal N becomes the digital signal output to which the value of the noise generator control signal Na and the simulated generator mover input noise amplitude control signal Nv are added.

Thus, the amplitude control digital signal N outputted from the program of the calculator 5 is given to the above-described amplitude adjusting device 6, and the amplitude of the constant dark tone reproduced by the sound reproducing apparatus 4 according to the digital signal N is obtained. Then, the sound output device 3 generates a simulated sound equivalent to the volume shown in FIG.

In summary, the present invention calculates, by the program, an amplitude control signal instructing the electronic calculator 5 to be the amplitude of the simulation sound to be simulated, which has been requested by the acoustic simulation according to the state of the simulation apparatus such as a plant. The amplitude control signal is received by the amplitude adjusting device 6 to adjust the amplitude of the reproduction signal input from the sound reproduction device 4 to generate an acoustic signal such as the amplitude of the simulated sound to be simulated. It is input to 3) and converted into a simulation sound.

In the above description, the magnetic recording tape is used as the recording material having a constant amplitude sound. However, it is obvious that any recording material recorded with a magnetic disk, an optical film, or a constant amplitude may be used. In addition, although the sound of the constant amplitude is described as the noise detected in the central operation room of the thermal power plant, the sound is not limited thereto, and in fact, other sounds may be used without recording the sound from the plant to be simulated. It may be electrically synthesized.

In addition, although the amplitude adjusting device has been described as being divided by resistance, the resistance of the rotary variable converter may be varied by a motor, or may be configured to control the amplification degree of the amplifier to a desired amplitude.

The means for outputting the amplitude control signal by the calculator is not limited to the embodiment of the present invention, and a general calculator processing method is adaptable. For example, the amplitude of the sound to be simulated is approximated as the first order but is approximated as the higher order. It is also possible to configure the irrigation generation program.

In addition, a combination of an acoustic reproducing apparatus and an amplitude adjusting apparatus may be provided by providing a plurality of units such as two or three units. In addition, it is a matter of course that it is not limited to the simulation apparatus of the plant, and can be used also for the general simulation apparatus training apparatus.

Claims (1)

A sound simulation apparatus that generates one or a plurality of sounds of different types consecutively as described above in the main text shown in the drawing, which reproduces a recording medium having a plurality of frequency components and recording a sound having a predetermined amplitude. An amplitude calculator and an amplitude adjusting device for adjusting an amplitude of a reproduction signal reproduced by the sound reproduction apparatus in accordance with the amplitude control signal and an electronic calculator for outputting an amplitude control signal specific to a predetermined sound in accordance with the sound reproduction apparatus and the program. A sound simulation device comprising: an audio output device for converting and outputting an output signal from an adjustment device into a sound.

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