RU2309323C1 - System for diagnosing technical state of main pipeline having locking and controlling fittings - Google Patents

Abstract

FIELD: controlling and diagnosing technique for detecting leakage of transported gas from main pipelines equipped with locking and controlling fittings.

SUBSTANCE: system has indicator gas dosing device with electric output and injector positioned within main pipeline in front of locking and controlling fittings, upstream of gas flow. Gas parameter sensors are made in the form of indicator gas concentration detectors arranged at different sides relative to locking and controlling fittings, at known distances from injector. Data processing unit has two amplifiers, integrator, four threshold devices, three reference signal units, two amplifiers-restrictors, two timers, and subtracting unit. Outputs of first and second indicator gas concentration detectors are connected through respective amplifiers to first inputs of first and second threshold devices, whose second inputs are connected to output of first reference signal unit and outputs are connected through amplifiers-restrictors to stopping inputs of first and second timers, whose starting inputs are connected to electric input of dosing device and outputs are connected to respective inputs of subtracting unit, whose output is connected to first input of third threshold device, whose second input is switched to output of second reference signal unit and output is switched to first input of registering device. Output of second indicator gas concentration detector is additionally connected through integrator to first input of forth threshold device, whose second input is connected to output of third reference signal unit and output is connected to second input of registering device.

EFFECT: increased efficiency by enabling periodical controlling of locking and output parameters of locking and controlling fittings and sealing properties thereof.

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Description

The invention relates to a control and diagnostic technique for detecting leaks of transported gas (TG).

A known system for a similar purpose, which can be used to solve the problem, containing TG parameters sensors moving along the main gas pipeline (MG) (RF Patent No. 2062394, class F17D 5/02, 1996).

A disadvantage of the known analogue is the need to move the sensors along the MG, which limits the speed of the system.

A known system for a similar purpose, containing several TG sensors connected to the correlator (USSR Author's Certificate No. 1176139, class F17D 5/02, 1985).

The disadvantage of the second analogue is the weak connection used for the diagnosis of the correlation function with the state of shut-off and control valves (ZRA) in the MG.

A known system that can be used to diagnose the technical condition of an MG with a ZRA containing two gas parameter sensors connected by outputs to an information processing unit (BOI) and a recorder (USSR Author's Certificate No. 1216550, class F17D 5/02, 1986).

This system is adopted as a prototype. The prototype has many sensors installed with a given step along the MG and carrying information about the technical condition of the tested technical object.

The disadvantages of the prototype are the need to interrogate many sensors to determine the technical condition of the MG and the low accuracy of the system in the presence of MG ZRA, which is the weakest link in the considered technical object.

The technical result obtained from the use of the invention is to eliminate the disadvantages of the prototype, i.e. improving the accuracy of diagnostics of the technical condition of MG in the presence of the latest air defense system

This technical result is achieved due to the fact that the known system containing two sensors of gas parameters connected by the outputs to the BOI, and the recorder, further comprises an indicator gas dispenser (IG) with an electrical output and an injector located inside the MG upstream of the switchgear upstream of the TG, in this case, the gas parameter sensors are made in the form of IG concentration sensors located on opposite sides of the air defense system at known distances from the injector, and the BOI includes two amplifiers, an integratotor, four threshold devices, tr and a block of reference signals, two amplifier-limiters, two timers and a subtractor, and the outputs of the first and second sensors of concentration of the IG through the corresponding amplifiers are connected to the first inputs of the first and second threshold devices, the second inputs of which are connected to the output of the first block of reference signals, and the outputs through limiters - with stopping inputs of the first and second timers, the triggering inputs of which are connected to the electrical input of the dispenser, and the outputs - to the corresponding inputs of the subtracting device VA, the output of which is connected to the first input of the third threshold device, the second input of which is connected to the output of the second block of reference signals, and the output to the first input of the recorder, and the output of the second IG concentration sensor is additionally connected through the integrator to the first input of the fourth threshold device, the second input which is connected to the output of the third block of reference signals, and the output to the second input of the recorder.

ZRA is equipped with an electric sensor of the valve clearance gap value, while the sensor output is connected to the third input of the recorder.

Halogens are used as IG, and as electrodes of IG concentration, mainly electrodes made in the form of a heated metal spiral located inside an electrically conductive cylindrical surface connected to a corresponding amplifier.

As halogens, for example, freon or carbon tetrachloride are used, and tungsten, copper or platinum as the material of the electrodes of the concentration sensors.

The third block of reference signals is made with a controlled input connected to the electrical output of the dispenser.

The output of the first timer is connected to the fourth input of the recorder.

The invention is illustrated by drawings. Figure 1 presents a General view of the system; figure 2 is a block diagram of its electronic equipment; figure 3 is a timing diagram explaining the principle of operation of the system.

The system contains ZRA1 (figure 1) installed in MG2. ZRA1 is equipped with an electric sensor 3 valve throughput clearance values.

There is also an IG dispenser made, for example, in the form of a pneumatic accumulator 4 and a metering valve 5. The IG dispenser is pneumatically connected to the IG injector located inside MG2, upstream of the TG from ZRA1.

At known distances from the injector 6 on different sides of the ZRA 1 in MG 2 there are sensors 7 and 8 of the concentration (DK7 and DK8) of the IG in the TG stream.

The outputs of DK7 and DK8 are connected to the inputs "a" and "b" of BOI 9. The electrical output of the metering valve 5 is connected to the input "to" BOA 9. The electrical output of the sensor 3 of the passage gap value ZRA1 is connected to the input "g" of BOA 9.

BOI 9 contains the following electronic devices (figure 2): amplifiers 10, 11, threshold devices 12, 13, 14, 15 (PU12, PU13, PU14, PU15), blocks 16, 17, 18 of the reference signals (BOS 16, BOS 17 , BOS 18), timers 19, 20, a subtractor 21 (VU21), an integrator 22, limiting amplifiers 23, 24 and a recorder 25, made, for example, in the form of a microprocessor.

Communications electronic blocks 10 ... 25 shown in figure 2.

The outputs of the DC 7 and DC 8 are connected respectively to the inputs of the amplifiers 10 and 11 (inputs "a" and "b" BOI 9). The outputs of the amplifiers 10, 11 are connected to the first inputs of the controllers 12 and PU 13, the second inputs of which are connected to the output of the BOS 16, and the outputs to the stop inputs of the timers 20, 19 through the amplifier-limiters 23, 24.

The triggering inputs of the timers 19, 20 are connected to the electrical output of the metering valve 5 (for BOI 9 - the input is in).

The outputs of the timers 19, 20 are connected to the first and second inputs of the VU 21, the output of which is connected to the first input of the PU 15, the second input of which is connected to the output of the biofeedback 18.

The output of the PU 15 is connected to the first input of the recorder 25.

The output of the DC 8 through the integrator 22 is connected to the first input of the control unit 14, the second input of which is connected to the output of the BOS 17, and the output to the second input of the recorder 25, the third input of which is connected to the output of the electric sensor 3 of the clearance gap ZRA 1 (input "g" ), and the fourth with a timer output of 20.

BOS 17 is made with a controlled input connected to the electrical output of the metering valve 5.

Halides (for example, freon or carbon tetrachloride) can be used as IGs, and electrodes made, for example, in the form of a heated metal spiral (cathode) located inside an electrically conductive cylindrical surface (anode) can be used as IGs; The cathode can be made of tungsten, and the anode is made of copper.

The system may include several DCs, similar to DC 7, DC 8, located along two parallel sections of TG2 at the most characteristic points of TG.

In this case, BOI 9 will also include several additional similar chains of blocks 10 ... 24 connected to various inputs of the recorder 25.

The system operates as follows.

After the expiration of the scheduled work of the ZRA or in case of emergency situations in its work, the following actions are performed.

With a fixed position of the crane ZRA 1 open the metering valve 5 and run in MG 2 through the dispenser a portion of IG 26 (Fig. 1). IG 26 is carried downstream of the TG, passes DK 7, ZRA 1 and DK 8. At the same time, when the metering valve 5 is opened, the command signal is sent to the triggering inputs of the timers 19, 20 (input “to”), which opens the countdown by timers 19, 20.

The cloud of IG 26 drifts downstream of the TG at a speed of V, passes sequentially DK7, ZRA, DK8. At the same time, signals appear at the outputs of DK7 and DK8, which, after amplification in amplifiers 10, 11, are fed to the first inputs of PU12 and PU13. These signals are conventionally shown under the positions 27, 28 in figure 3, at the top.

At the same time, a constant threshold signal 29 with BOC 16 is sent to the second inputs of PU12 and PU13. The output signals from PU12 and PU13 are parts of signals 27, 28 that rise above threshold signal 29. After amplification in limiting amplifiers 23, 24, these signals are sent to stop inputs of timers 19, 20.

Figure 3 (below) shows the signals at the stopping inputs of the timers 20, 21 under positions 30, 31.

Under position 32, a signal characterizing the injected IG26 in the region of injector 6 is conditionally presented, and under position 33, a signal that starts the operation of timers 19, 20 through the inputs to.

The start and stop operation of the timers 19, 20 is carried out, for example, by the leading edges of the pulses 33, 31, 30, respectively. Moreover, timers 20, 19 measure the times t ₁ and t _2, respectively.

The signal t ₁ , which carries information about the speed V of the TG stream in MG2 before ZRA 1, is sent to the recorder 25 and to the second input (subtracted) VU21. The signal t ₂ from the output of the timer 19 is sent to the first input of VU21. The difference signal τ = t ₂ -t ₁ from the output of VU21, which carries information about the transit time of IG26 ZRA 1 (interval MG2 from DK7 to DK8), is sent to PU15, where it is compared with nominal value of τ _n embedded in BOS 18. Comparison results are recorded by the recorder 25. At the same time, time τ characterizes the shut-off and pass-through parameters of the tested ZRA1.

At the same time, the output signal 28 with DC8 after amplification in the normalizing amplifier (included in the integrator 22, therefore not shown in the drawing) is integrated and compared in ПУ14 with a predetermined threshold value of the signal coming from the BOS 17. The threshold value of the latter is set automatically based on the initial concentration IG26 introduced into the flow of TG using a metering valve 5. The comparison results from the output of PU 14 are sent to the recorder 25.

The concentration of IG 26 in the area of DK8 carries information about the tightness of ZRA 1.

The tests of ZRA 1 described above are carried out for different values of the TG flow velocity V and for different positions of the adjusting screw of ZRA 1 (different sizes of the clearance gap of ZRA 1). If any of the parameters of ZRA 1 go beyond the nominal values, the latter must be replaced.

As shown by experiments, the most suitable indicator gas are halogens, such as freon or carbon tetrachloride. In this case, it is convenient to use a cathode from a tungsten helix located in a copper cylinder used as an anode as a DC.

When a small amount of halogen enters the interelectrode space, the current value instantly increases compared to the "background current". The magnitude of the current depends on the concentration of the halogen. This makes it possible to use not only the well-known time-of-flight method, but also concentration methods /P.P. Kremlevsky "Flow meters and quantity counters" when researching ZRA. L .: Mechanical engineering, L.O., 1989, 520-555 /.

Claims (6)

1. A system for diagnosing the technical condition of a main gas pipeline with valves for regulating valves, comprising two gas parameter sensors connected by outputs to an information processing unit, and a registrar, characterized in that it further comprises an indicator gas dispenser with an electric output and an injector located inside the main gas pipeline in front of the shut-off and control valves upstream of the transported gas, while the gas parameters sensors are made in the form of concentration sensors indicator gas located on opposite sides of the stop valves at known distances from the injector, and the information processing unit includes two amplifiers, an integrator, four threshold devices, three reference signal blocks, two limiter amplifiers, two timers and a subtractor, moreover, the outputs of the first and second sensors of the concentration of indicator gas through the respective amplifiers are connected to the first inputs of the first and second threshold devices, the second inputs of which are connected to the output of the first block of reference signals, and the outputs through limiting amplifiers - with stopping inputs of the first and second timers, the triggering inputs of which are connected to the electrical input of the dispenser, and the outputs - to the corresponding inputs of the subtracting device, the output of which is connected to the first input of the third threshold device, the second input of which is connected to the output of the second block of reference signals, and the output is to the first input of the recorder, and the output of the second indicator gas concentration sensor is additionally connected through the integrator to the first input Werth threshold device, a second input coupled to an output of the third block of a reference signal, and an output - to a second input of the recorder. 2. The system according to claim 1, characterized in that the shut-off and control valves are equipped with an electric sensor of the passage clearance of the valve, while the output of the sensor is connected to the third input of the recorder. 3. The system according to claim 1, characterized in that halogens are used as an indicator gas, and mainly electrodes made as a heated metal spiral located inside an electrically conductive cylindrical surface connected to an appropriate amplifier as indicator gas concentration sensors. 4. The system according to claim 3, characterized in that freon or carbon tetrachloride is used as the halogen, and tungsten, or copper, or platinum is used as the material of the electrodes of the concentration sensors. 5. The system according to claim 1, characterized in that the third block of reference signals is made with a controlled input connected to the electrical output of the dispenser. 6. The system according to claim 1, characterized in that the output of the first timer is connected to the fourth input of the recorder.

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