RU28930U1 - Oil compounding process control system according to several quality parameters - Google Patents

Description

Oil compounding process control system according to several quality parameters

The claimed system relates to means for automating oil transportation processes through various pipelines with different qualities of oil parameters and combining oil flows with monitoring its quality indicators in an oil mixture.

State of the art

Closest to the claimed system is an automated oil compounding process control system, consisting of a unit for measuring sour oil flow parameters, flow meters, a control unit, and an unit for measuring oil flow quality indicators (RU 2158437 C1, G05D 11/02, 10.27.2000).

In the known system, it is ensured that the specified quality indicators of the compounded oil are maintained while controlling the pressure in the oil pipeline with sour oil entering the common line.

However, known systems do not provide control and regulation of compounding for several quality parameters.

The technical result of the claimed system is to regulate the process of compounding oils according to several quality parameters, according to the content of sulfur, and / or according to the density of oil, and / or according to the content of chloride salts, and / or according to the content of water, as well as the consumption of products.

The technical result is achieved by the fact that in the control system for the compounding of oil, containing at least two pipelines designed to transport oil flows and the pipeline designed for a mixed oil flow, damper,

installed in oil pipelines and designed to regulate the corresponding oil flows, oil density meters and / or oil flow meters, and / or oil sulfur meters, and / or chloride salts in oil and / or oil water meters, designed for measuring these parameters of oil in the respective oil flows, characterized in that the system comprises an oil density meter, and / or an oil flow meter, and / or a sulfur content meter in the oil, and / or a meter l the content of chloride salts in oil, and / or a meter of water content in oil, designed to measure the specified parameters of oil in the mixed stream, a calculator of the coefficients of the ratio of the density of oil in each stream to the value of the density of the oil in the mixed stream and / or calculator of the ratio of the ratio of the flow rate oil in each stream to the value of oil consumption in the mixed stream, and / or a calculator for the ratio of the sulfur content in oil in each stream to the value of sulfur content in oil in the mixed stream ke, and / or a calculator of the coefficients of the ratio of the content of chloride salts in the oil in each stream to the value of the content of chloride salts in the oil in the mixed stream, and / or the calculator of the coefficients of the ratio of the content of water salts in oil in each stream to the value of the water content in mixed oil flow, the inputs of each of these computers are connected to the outputs of the respective meters, and the outputs are connected to the corresponding inputs of a microprocessor designed to compare the measured and calculated parameter in a predetermined position and forming flaps regulation signals in respective streams from the comparison results.

Figure 1 shows the functional diagram of the claimed system. The system contains oil pipelines, a mixing tank 5 for mixing oil and transferring the mixed stream to the oil pipeline 10, oil flow meters, density meters, sulfur content meters, 8g8z sulfur content meters, salt chloride meters, meters installed in oil pipelines 41-4z lli-l Water content and flaps 191-19z, booster pump unit 12 with automatic control system (ATS) 13 installed in the pipeline 10 of the mixed oil flow, meter 7 content is tight ty in the mixed stream, meter 8 for the sulfur content in the mixed stream, meter 9 for the content of chloride salts in the mixed stream, meter 11 for the content of water in the mixed stream, associated with the respective meters BRBZ and 6 calculator 14 flow coefficient ratios KQi, KQ2, Krz in each stream in relation to the oil flow rate in the mixed flow of the oil pipeline 10, the calculator 15 of the density ratio coefficients Кр Кр2, Крз in each flow in relation to the density oil in the mixed flow of the oil pipeline 10, connected to the corresponding meters 81-83 and 8, the calculator 16 of the ratio of the sulfur content in each of the flows to the sulfur content in the mixed flow, connected to the corresponding meters 91-9z and 9, the calculator 17 of the ratio of chloride salts in each of the streams to the content of chloride salts in the mixed stream, connected with the corresponding PrIz meters and 11 calculator 18 coefficients of the ratio of the water content in each of the streams to the value of soda holding water in a mixed stream, each of these computers is connected to the corresponding inputs of the microprocessor 20 (with the data bus of the microprocessor), intended for comparison

the above measured and calculated parameters with and between each other according to the algorithms below, and the formation of control signals for the position of the dampers associated with the microprocessor outputs according to the comparison results.

The system operates as follows.

Suppose that it is necessary to carry out the mixing of oil flows of different quality coming through several oil pipelines 4, differing in density parameters (P) and / or in the content of chloride salts (C1) and / or in the content of sulfur (S) and / or water (B). .

Let us denote the numbers of flows 1, 2, and 3 of oil flowing through the first, second, and third oil pipelines, respectively. The indices in the equations below are intended to indicate membership in the stream number or mixed stream, Q is the flow rate.

Let control and compounding regulation be required for several quality parameters, for example, for sulfur content, and / or for density, and / or for the content of chloride salts, and / or water content.

When shifting the flow of oil from different pipelines in the pipeline 10, the quality parameters obey the law of additivity

PlQl + P2Q2 + P3Q3 PcMQcM (1)

PCM is the density, and QCM is the displaced oil flow rate in the oil pipeline 10. Dividing the right and left sides of the equation by QCM, we have

P, KQ, + P2KQ2 + P3KQ3 PcM, (2)

it is obvious that Qi + Q2 + Qs QCM, and the coefficients KQI, Кр2, Кдз are the ratio of expenses for oil pipelines of flows 1, 2, 3 to the total flow rate QCM in the mixed flow of oil pipeline 1.0, obtained by dividing the quantities Qi, Q2, QB by QCM value, respectively. . under THIS, dividing the right and left sides by QCM, we obtain SiKgi + S2KQ2 + 8cKdz SCM, (4). Thus, the ratio of the costs KQI, KQ2, Krz, in the general case KQJ, where i 1-GP (the number of pipelines or the number of mixed flows) is involved in the formulas. Based on the ratio of the above indicators KQ for automatic regulation, these cost ratios are set, for example, based on planned volumes; depending on sulfur content or oil density, etc. Thus, by measuring the flow rate Q in each stream and in the flow of the mixture of oil pipeline 10 from meters 6 and determining in the calculator 14 KQ as the ratio of the flow rate Qi / QcM, KQ for each stream is obtained. In addition, in the calculator 14, Qi + Q2 + QB are summed to obtain the QCM value, the obtained values are sent to the corresponding memory element 21 for use when the microprocessor 20 is maintained. Maintaining the specified parameters when compounding the oil flows for the case of regulation by the draining density indicator ; are as follows. Install in each pipeline 41-4z of each flow meters, density. Moreover, for density control, equation (2) is written in the form: KpiKQi + Kr2Kr2 + KrzKdz 1 (5), where KPI, Kr2, Krz is the ratio of densities in oil pipelines 41-4z to the mixture density in oil pipeline 10, obtained as the ratio PI / PCM, P2 / Rcm, RZ / RSMO These coefficients are determined in the calculator 15 and the obtained values are stored in the memory element 212. The microprocessor 20 compares the values KQI, Kd2, Kdz with the set ones. Let microprocessor 20 determine that the cost ratio has not changed, i.e. KQI, Kd2 and Kdz are in the range of set values.

However, he revealed a change in the ratio of the densities obtained in the calculator 15 from the given values Kr1zad, Kr2zad, Krzzad. The microprocessor compares the obtained Kr from the calculator 15 and the densities from the meters 7 with the given values. Moreover, let it be revealed that, then, it is revealed that the rear and microprocessor 20 generates a control signal for this stream by covering the shutter of the automatic control system 19 (gate valve), i.e. changing the flow ratio until Rcm Rzad The specified flow ratio is stored in the memory element 21.

Consider the option when the pre-crisis, its ratio of the ratio of expenses has not changed, i.e. the microprocessor 20 determined that the specified flow ratio is within the specified values, however, it revealed that, AND WHAT .back, then the microprocessor 20 generates a signal for regulation of this flow by opening the valve 19; ATS, i.e. changing the ratio of costs.

Let the microprocessor 20 revealed that the density ratio. .back; .set, and Rcm Rzad- Determine the flow ratio in the calculator 14 and the microprocessor 20 controls the flow ratio, if it is detected. the back, the microprocessor 20 generates a control signal to cover the corresponding shutter 19i on the stream i (i 1, 2, 3), t. e., reducing the cost ratio. On the contrary, if the rear is detected and there is a margin of quality Rcm Rcm-ass5, then the microprocessor generates a signal to open the shutter 19i and regulation is carried out until the PCM "Rcm-ass We consider the compounding process when controlling by sulfur parameter.

similar to density control. In this case, apply

formula (4).

SiKgi + S2KQ2 + 8cdc SCM,

OR, dividing all parts of the equation by SCM, we get:

KsiKgi + Ks2KQ2 + KssKgs 1. (6)

Thus, by installing sulfur meters 8, 81-83 in each of the oil flows (oil pipelines, and oil pipeline 10), connecting meters 81-83 and 8 with calculator 16, we obtain the sulfur content in each stream relative to the mixed stream, t .e. KSI SI / SCM, Ks2 S2 / ScM and Ks3 S3 / ScM- The outputs of the calculator 16 are connected to the comparator 20 (microprocessor) for controlling the sulfur content in the same way as for density or consumption.

However, sulfur meters 8, 81-83 are expensive, its equipment, so it is advisable to limit their quantity. For example, to reduce the cost of regulation by sulfur index, one meter can be installed on the upstream flow (i.e., on the flow of the oil mixture). Then, in a known manner, the streams of sulfur and sour crude oil are detected, and meters are installed on the streams of sour oil, for example, in streams 2 and 3. The streams of sour crude can be combined in order to simplify the control system (see FIG. 2) using one meter 8 .

The system for the case of controlling the sulfur content (Fig. 1) works as follows. The sulfur content in the streams is determined for a given moment in time and the ratio of the flow rates KQI, Kd2, Kdz at which is calculated by the formula (4) in the calculator 14. These cost ratios are stored in the microprocessor memory cell.

Suppose that the microprocessor 20 has revealed that, then, it generates a signal to cover the shutter 19i in the sour oil stream x х in the oil pipeline, for example, 1, in which the flow ratio is violated, i.e. in which the microprocessor 20 has established that Kd1 Kzad. If the comparison microprocessor 20 has revealed that, then it implements a similar control algorithm for the oil pipeline, in which Kd1 Kzad, ONLY the shutter 19i in the corresponding stream opens slightly until the microprocessor 20 determines that with -cM -aZ Consider the case when the cost ratio determined by microprocessor 20 has not changed, but he found that. Therefore, in one of the streams, the sulfur content increased. After identifying the stream number in which the sulfur content has increased, the microprocessor generates a signal to cover the shutter 19; on one of the sour oil streams. If the microprocessor 20 has revealed that the cost ratio has not changed, but it is found that, i.e. on one of the streams, the sulfur content decreased, the microprocessor 20 determines the stream in which the density decreased compared to the set one, and generates a signal to open the shutter 19 and a new (different) flow ratio is established. Consider the regulation or streamline flow of the content of chloride salts. If the content of chloride salts is installed in the respective flows of meters 91–9z and 9, the control process is similar to the density control process described above. We use the following ratio C1, Q, + C12Q2 + ClsQs ClcMQcM, (7) CliKgi + C12KQ2 + С1зКдз ClcM, (o) KcilQl + Kc, 2Q2 + Goats QcM (9)

The calculator 17 determines the ratio of the content of chloride salts in the streams relative to the mixed stream obtained from the meters and 9 and the ratio of the flow rates in relation to the mixed stream obtained in the meters 61-63 and 6. If the microprocessor 20 reveals that upon receipt of these values there is a deviation of any value with respect to the given one, the microprocessor 20 generates a signal to change the flow ratio at the point where the deviation of the parameter of the content of chloride salts from the set value, or ec and there is a margin of quality for this parameter in a mixed flow, then the flow ratio increases for the corresponding oil pipeline (for those flows where the shutters were in the closed position), i.e., the shutters 19i are opened (under the margin of quality for this parameter (component ) understand a certain value of the content of the component in the mixture, which is less than the specified value).

Regulation or restriction of the flow by water content is drained by installing moisture meters (PrPz meters in flows 1-3 and meter 11 in a mixed stream), the regulation process is similar to the density regulation process.

The following ratio is used:

B, Q, + B2Q2 + B3Q3-BeMQcM, (I)

this leads to this equation

KBiKgi + Kv2Kd2 + KvzKdz 1 (12)

where KBI BI / BCM, Kv2-B2 / Vsm, Kvz-Vz / Vsm Determine the specified coefficients using calculator 18. The data from the calculation results are sent to the microprocessor 20, which compares the values received from all calculators with the set ones, and with a corresponding change, carries out the process of regulating the position of the shutter 19 in the corresponding

flow according to a control algorithm similar to a density control algorithm.

In the case of simultaneous regulation and control of all of the above quality parameters on a mixed stream, the compounding process control system selects and sets such a ratio of expenses in oil pipelines with respect to the total flow of the oil mixture at which the value of each quality parameter controlled in the mixed stream will not exceed a predetermined value.

The regulation of the content of quality parameters in the mixed stream (sulfur content, density, chloride salts, water and others) is drained in any case; it is carried out by changing the ratio of costs. Therefore, the cost ratio should not be rigidly set, but it is necessary to remember the previous cost ratio in the steady state, when the quality parameters to be regulated on the mixed flow were within the specified values. Remember the previous ratio of costs is necessary in order to determine in the next time the reason for the change of quality parameters from the given values: by changing the ratio of costs from previous values, by changing the quality parameter in the pipeline from which the stream enters the mixing tank.

In this technical solution, as well as in the system according to patent RU 2 158437 C1, there remains the need to control and maintain pressure on oil pipelines above a threshold value, below which a two-phase flow can occur, i.e., the release of oil vapor, which will affect the accuracy of accounting for turbine flow meters. Therefore, when controlling the parameters of oil quality, the system monitors and maintains the pressure in the oil pipelines i within the specified values.

Claims (1)

An oil compounding process control system comprising at least two oil pipelines for transporting oil flows and an oil pipeline for a mixed oil flow, dampers installed in the respective oil pipelines and for regulating the corresponding oil flows, oil density meters, and / or meters of oil consumption, and / or meters of sulfur content in oil, and / or meters of chloride salts in oil, and / or meters of water content in oil, started to measure the specified parameters of oil in the respective oil streams, characterized in that the system comprises a calculator of the coefficients of the ratio of the density of oil in each stream to the value of the density of the oil in the mixed stream, and / or a calculator of the coefficients of the ratio of the oil consumption in each stream to the oil consumption in a mixed stream, and / or a calculator for the ratio of the sulfur content in the oil in each stream to the value of sulfur content in the oil in the mixed stream, and / or the coefficient the ratio of the value of the content of chloride salts in the oil in each stream to the value of the content of chloride salts in the oil in the mixed stream, and / or a calculator of the coefficients of the ratio of the water content in oil in each stream to the value of the water content in oil in the mixed stream, inputs of each of these calculators are connected to the outputs of the respective meters, and the outputs are connected to the corresponding inputs of the microprocessor, designed to compare the measured and calculated parameters with the set and the formation of the signal the control valves for the position of the dampers in the respective flows according to the results of comparison.