RU2623983C2 - System for storage of hazardous chemicals - Google Patents

Abstract

FIELD: packaging industry.

SUBSTANCE: system comprises a first container 1 for storing hazardous chemicals 2, a second container 3 containing liquefied gas, supports 4, an exhaust valve 6, an inlet feeder 7, a leak detection device 8 or a temperature sensor, a control system 9, a battery 10, switch 11, transmitter 12 and receiver 18. The transmitter 12 comprises a master oscillator 13, a pseudorandom sequence (PRS) generator 14, a phase manipulator 15, a power amplifier 16, and a transmit antenna 17. The receiver 18 comprises a receiving antenna 19, a high frequency amplifier 20, a local oscillator 21, a mixer 22, a low-pass filter 23, a local oscillator phase locked loop (PLL) 24, a multiplier 25, a phase shifter 26 for 90°, a phase detector 27 and a registration unit 28.

EFFECT: alarm signal is transmitted to the control room using the radio channel and complex signals with phase shift keying.

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Description

The proposed system relates to systems and containers for storing flammable, explosive, toxic corrosive, radioactive or chemically polluting hazardous chemicals, in particular for storing especially hazardous chemicals, such as fluids with low boiling points, and can be used in various chemical industries. industry.

Chemicals are an integral part for industrial production and for people's daily lives. Moreover, most chemicals are hazardous substances and pose a certain danger to human health and life.

During the production, storage, transportation and use of hazardous chemicals, leakage problems sometimes occur due to aging of containers, heat and damage, which can cause damage to the environment and even lead to catastrophic consequences. Quick and effective independent emergency work will give more valuable time for emergency activities, and, therefore, there is an opportunity to reduce damage and avoid catastrophic consequences.

Emergency systems and containers are known (author's certificate of the USSR No. 612.852, 1.252.468, 1.776.744; RF patents No. 2.002.020, 2.186.919, 2.466.075; US patents No. 3.688.200, 4.831.860 5.209.088; French patents Nos. 2,559.193, 2.692.309; German patents Nos. 3.407.128, 3.907.326; Japanese patents Nos. 59-192.167, 60-29.912 and others).

Of the known devices, the closest to the proposed one is the "Automatically triggered by a leak emergency container for storing hazardous chemicals" (RF patent No. 2.466.075, B65D 85/82, 2009), which is selected as a prototype.

The known device comprises a first container for storing hazardous chemicals and a second container installed and secured in the first container. The second container contains a substantially safe liquefied gas and has an opening that can be controlled to communicate with the external environment. When hazardous chemicals leak due to an accident, the liquefied gas in the second container is discharged so that the temperature in the first container decreases and, therefore, the pressure in the first container decreases to prevent leakage or explosion caused by overpressure.

When dangerous chemicals leak, the main thing is not only lowering the pressure in the container for storing and increasing the viscosity of dangerous products in order to lower the leak rate, reduce the total amount of pollution from the leak, but also quickly transmit the alarm signal over the air to the control room for timely taking measures to eliminate the leak of hazardous chemicals and its consequences.

An object of the invention is to expand the functionality of the container by transmitting an alarm to a control room using a radio channel and complex signals with phase shift keying.

The problem is solved in that a system for storing hazardous chemicals, containing, in accordance with the closest analogue, a first container for storing chemicals and a second container installed and secured in the first container, the first container having a leak detection device, which upon detection dangerous chemical leakage controls the automatic exhaust valve for automatic opening, the second container contains essentially safe liquefied gas and has an opening that The unit communicates with the external environment with the possibility of monitoring, differs from the closest analogue in that it is equipped with a transmitter installed in the immediate vicinity of the first container and a receiver installed at the control room, and if a leak of hazardous chemicals is detected, a leak detection device through the control system includes a transmitter, which consists of a serially connected master oscillator, a phase manipulator, the second input of which is connected to the output of the pseudo generator random sequence, power amplifier and transmitting antenna, the receiver contains a receiving antenna, a high-frequency amplifier, a mixer, the second input of which is connected to the first output of the local oscillator, a low-pass filter, a multiplier, the second input of which is connected to the output of the high-frequency amplifier, and a phase detector , the second input of which is connected through a 90 ° phase shifter to the second output of the local oscillator, and the output is connected to the control input of the local oscillator, and a re block is connected to the output of the low-pass filter hysteresis, the frequency ω _{G of the} local oscillator is chosen equal to the frequency ω of _the received signal ω _G = ω _s and is supported by a phase-locked loop system of frequency ω _{G of the} local oscillator, the transmitter and receiver are connected by a radio channel using complex signals with phase shift keying.

A functional diagram of an emergency container for storing hazardous chemicals and a structural diagram of a transmitter installed in the immediate vicinity of the container are shown in FIG. 1. A block diagram of a receiver installed at a control room is shown in FIG. 2.

The serpentine tubular second container 3 is fixed in the first container 1 for storing hazardous chemicals 2. The second container 3 contains liquefied gas 5. The first container 1 is mounted on supports 4. The second container 3 has an exhaust valve 6, which communicates with the external environment with control and an inlet feed device 7 through which liquefied gas is supplied. The second container 3 may have one or more outlet channels 6 and one or more input supply devices 7. The first container 1 has a leak detection device or a temperature sensor 8 connected through the control system 9 to an exhaust valve and to a switch 11 that provides the transmitter 12 with voltage battery power 10.

The transmitter 12 contains a serially connected master oscillator 13, a phase manipulator 15, the second input of which is connected to the output of the pseudo-random sequence generator 14, a power amplifier 16 and a transmitting antenna 17.

The receiver 18 contains a series-connected receiving antenna 19, a high-frequency amplifier 20, a mixer 22, the second input of which is connected to the first output of the local oscillator 21, a low-pass filter 23, a multiplier 25, the second input of which is connected to the output of the high-frequency amplifier 20, and a phase detector 27 , the second input of which is connected through a phase shifter 26 through 90 ° to the second output of the local oscillator 21, the output is connected to the control input of the local oscillator 21. A registration unit 28 is connected to the output of the low-pass filter 23.

The proposed system for storing hazardous chemicals works as follows.

When the leak detection device or temperature sensor 8 detects that the first container 1 is leaking or is at risk of exposure to high temperature, the detection signal is supplied to the control system 9. The control system 9 automatically commands the opening of the automatic exhaust valve 6 and the closure of the switch 11. The open exhaust valve 6 provides the release of liquefied gas 5 located in the second container 3. During the release of the liquefied gas 5 absorbs environmental heat (i.e. the first container 1 ) so that the temperature of the first container 1 decreases and, consequently, the pressure in the first container 1 decreases so as to prevent leakage or explosion of the first container 1 caused by overpressure or an increase viscosity be dangerous chemicals to reduce the leakage 2 when it occurs speed.

The second container 3 has an inlet feed device 7 through which liquefied gas is supplied.

When the switch 11 is closed, the battery 10 is connected to the transmitter 12. The master oscillator 13 generates a high-frequency oscillation

U _c (t) = V _c ⋅cos (ω _c + ϕ _s ), 0≤t≤T _s ,

where U _c , ω _s , ϕ _s , T _s is the amplitude, carrier frequency, initial phase, and duration of the high-frequency oscillation that arrives at the first input of the phase manipulator 15, the second input of which is supplied with the modulating code M (t), contains the container identification number 1 and its installation location.

At the output of the phase manipulator 15, a complex signal with phase shift keying (PSK) is formed

U ₁ (t) = V _c ⋅cos [ω _c t + ϕ _k (t) + ϕ _c ], 0≤t≤T _s ,

where ϕ _k (t) = {0, π} is the manipulated phase component that displays the phase manipulation law in accordance with the modulating code M (t), which, after amplification in the power amplifier 16, enters the transmitting antenna 17 and is radiated by it, is captured the receiving antenna 19 at the control room and through the high-frequency amplifier 20 is supplied to the first input of the mixer 22, the second input of which supplies the local oscillator voltage 21

U _Г (t) = V _Г ⋅cos (ω _Г + ϕ _Г ).

Moreover, the frequency ω _{G of the} local oscillator 21 is chosen equal to the frequency ω _{s of the} received FMN signal (ω _s = ω _s ). The output voltage of the mixer 22 produces the following voltages:

U ₂ (t) = V _H ⋅cosϕ _k (t) + V _H ⋅cos [2ω _c t + ϕ _k (t) + 2ϕ _c ],

Where

The low-pass filter 23 emits a low-frequency voltage (zero frequency voltage)

U _H (t) = V _H ⋅cosϕ _k (t), 0≤t≤T _c ,

proportional to the modulating code M (t). This voltage is detected by the registration unit 28, and then appropriate measures are taken.

It should be noted that the choice of the frequency ω _{G of the} local oscillator 21 equal to the frequency ω _{from the} received QPSK signal (ω _G = ω _s ) provides a combination of two procedures: converting the received QPSK signal to zero frequency and isolating the low-frequency voltage U _H (t), proportional to the modulating code M (t), i.e. synchronous detection of the received QPSK signal using a mixer 22, a local oscillator 21 and a low-pass filter 23. This circuit design allows you to get rid of the additional reception channels inherent in a superheterodyne receiver, and the phenomenon of “reverse operation” inherent in the well-known demodulators of complex FMN signals (Pistolkors A.A., Siforov V.I., Kostasis D.F., Travina G.A.) (Dikarev V.I. Methods and technical solutions for receiving and processing radio signals. Textbook, St. Petersburg, 2000, p. 145-149).

Since the frequency ω _{from the} received QPSK signal can change under the influence of various destabilizing factors, including the Doppler effect, then to perform and maintain the equality ω _Г = ω _с , the PLL system 24 is used, consisting of a multiplier 25, a phase shifter 26 by 90 ° and a phase detector 27. Moreover, in the multiplier 25 there is a reverse manipulation of the received PSK signal U1 (t), which allows the formation of a non-manipulated oscillation, which is then filtered by the PLL system. Since the multiplication occurs at a high frequency, a conventional balanced modulator can be used as the multiplier 25. The reverse manipulation system has the additional capabilities of improving noise immunity due to the post-detector signal processing used to eliminate phase manipulation.

Thus, the proposed system in comparison with the prototype provides the transmission of an alarm signal to a control room using a radio signal and complex signals with phase shift keying.

These signals have high energy and structural secrecy. The energy secrecy of complex QPSK signals is due to their high compressibility in time and spectrum with optimal processing, which reduces the instantaneous radiated power. As a result, a complex QPSK signal at the receiving point may be masked by noise and interference. Moreover, the energy of a complex QPSK signal is by no means small; it is simply distributed in frequency — the time domain, so that at each point in this region the signal power is less than the power of noise and interference.

The structural secrecy of complex QPSK signals is due to the wide variety of their shapes and significant ranges of parameter changes, which makes it difficult to optimize or at least quasi-optimal processing of complex QPSK signals of an a priori unknown structure in order to increase the sensitivity of the receiver.

In addition, the proposed system provides increased noise immunity of reception and reliability of synchronous detection of PSK signals. This is achieved by suppressing false signals (interference) received via additional (mirror and Raman) channels, eliminating the phenomenon of “reverse operation” by converting the received PSK signals to zero frequency. The specified conversion also allows you to select the modulating codes from the received PSK signals. The combination of these two procedures is provided by a local oscillator, a mixer, and a low-pass filter, which simultaneously serve as a frequency converter and a synchronous demodulator of the received PSK signal. Such a circuit design is free of additional reception channels and the phenomenon of “reverse operation”, and the phase-locked loop system for the frequency ω _{G of the} local oscillator provides automatic tracking of changes in the carrier frequency ω _{from the} received FMN signal, which can occur under the influence of various destabilizing factors, including and the Doppler effect.

Thus, the functionality of the known device is expanded.

Claims (1)

A system for storing hazardous chemicals, comprising a first container for storing chemicals and a second container mounted and secured in the first container, the first container having a leak detection device that, when a leak of hazardous chemicals is detected, controls an automatic outlet for automatic opening, the second the container contains a substantially safe liquefied gas and has an opening that can be controlled with the external environment, In that it is equipped with a transmitter installed in the immediate vicinity of the first container and a receiver installed at the control room, and when a leak of hazardous chemicals is detected, the leak detection device through the control system includes a transmitter, which consists of a serially connected master oscillator, a phase manipulator , the second input of which is connected to the output of the pseudo-random sequence generator, power amplifier and transmitting antenna, the receiver contains after the receiver antenna, a high-frequency amplifier, a mixer, the second input of which is connected to the first output of the local oscillator, a low-pass filter, a multiplier, the second input of which is connected to the output of the high-frequency amplifier, and a phase detector, the second input of which is connected through 90 ° to the phase shifter the second output of the local oscillator, and an output connected to the control input of the oscillator to the output of the lowpass filter is connected the recording unit, the frequency ω LO _T is selected equal to the frequency ω _{from the} reception signal ω _r = ω _s and prying alive phase-locked oscillator system frequency ω _r, a transmitter and a receiver interconnected radio channel using complex signal with phase shift keying.

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