RU2284029C1 - Device for examining composition of crude oil - Google Patents

Abstract

FIELD: measurement engineering.

SUBSTANCE: inspection reservoir of the device has its bases fixed onto internal side of lower and top walls of operation microwave chamber. Inspection reservoir, transparent for IR-radiation, is made in form of body restricted by two straight hollow cylinders with different diameters. Axes of cylinders are aligned along main axis of operation microwave chamber. Illuminator is made as IR-radiation source, which is fastened at outer side of lower wall of operation microwave chamber, inside which chamber the mating opening is made for illuminating inspection reservoir. Illuminator is installed in such a way that its optical axis and axis of corresponding technological; opening are aligned with main axis of cylinders which form inspection reservoir. Axes of both electromagnetic rectifiers are perpendicular to concentric central circle of cross-section of inspection reservoir.

EFFECT: improved precision.

6 dwg

Description

The invention relates to the oil industry, in particular to devices for analyzing the composition of crude oil in the technological process of its production, collection, preparation and transportation.

A device for analyzing the composition of crude oil is known (see German Patent No. 19509822 A1, “Oil Concentration Measurement System”, G 01 N 33/26, 10/05/1995), which contains a horizontal illuminator and a hollow cylindrical control tank, two interference filter: one with a passband in the region of the oil absorption spectrum, the other outside it, located in a plane parallel to the base plane of the control tank, from the side opposite the illuminator and installed in front of two photodetectors, while s photodetectors are respectively connected to the inputs of the two amplifiers, the outputs of which via an analog-to-digital converter connected to a computer via an interface.

The operation of the device lies in the fact that the control tank, transparent to infrared radiation in the range of 1-5 μm, is filled with an oil sample, then it is illuminated with radiation of the specified range and recorded using photodetectors, the intensity of the light transmitted through it in the range of the oil absorption spectrum and outside it, recorded intensities are digitized in an analog-to-digital converter, transmitted via an interface to a computer and quantitative ratios of the components of crude oil — oil, water + sediment — are determined.

The prototype of the invention is a device for analyzing the composition of crude oil (see RF patent for utility model U 134253 RU 7 G 01 N 33/26, "Device for analyzing the composition of crude oil", No. 2003114691/20; Claim. 05.21.2003 // Bulletin IMP. 2003. No. 33), consisting of a control tank transparent for microwave and visible radiation, a working microwave chamber made in the form of a rectangular hollow parallelepiped, a microwave radiation source, an illuminator, a television transmitting chamber, two electromagnetic valves, a weight sensor, a measuring converter, electronic switch, analog-to-digital converter, and a computer interface. Moreover, the illuminator, made as a source of visible radiation, a television transmitting camera, the first and second electromagnetic valves are fixed on the outside of the walls of the working microwave chamber, respectively, back, left, right, top and bottom. The control tank is made as a straight hollow cylinder, transparent for visible and microwave radiation and fixed with bases on the inside of the upper and lower walls of the working microwave chamber. At the same time, the corresponding technological holes are made in the walls of the working microwave chamber for introducing the radiation of the microwave source and illuminator, registering the light transmitted through the control tank with a television transmitting chamber, filling the sample tank with crude oil and emptying it, the blocks indicated above are fixed, and the corresponding technological holes made so that the axis of the microwave radiation source and the corresponding technological holes are located with the axis of the central cross section of the control tank, the optical axis of the illuminator, the television transmitting camera and the axis of the corresponding technological holes are perpendicular to it, and the axes of both electromagnetic valves and the corresponding technological holes are aligned with the main axis of the control tank. Moreover, the first electromagnetic valve is the input, and the second is the output of the control tank for sampling crude oil. The illuminator, microwave source, television transmitting camera and both electromagnetic valves have on / off control inputs that are connected through the corresponding outputs of the interface to a computer, and the output of the television transmitting camera is connected to the input of an analog-to-digital converter.

The disadvantage of the prototype is the insufficiently accurate determination of the percentage ratio of the components of crude oil due to strong illumination of the television transmitting camera with a direct illumination channel and glare generated on the walls of the control tank, as well as inefficient use of the working volume of the control tank.

The technical problem to be solved is improving the accuracy of the analysis of the composition of crude oil and the reliability of the device.

The solution of the technical problem in a device for analyzing the composition of crude oil containing a control tank transparent for microwave radiation, a working microwave chamber made in the form of a rectangular hollow parallelepiped, a microwave radiation source, an illuminator, a television transmission chamber, two electromagnetic valves, a weight sensor, a measuring transducer , an electronic switch, an analog-to-digital converter, an interface and a computer, the control tank being fixed with bases with an internal the sides of the upper and lower walls of the working microwave chamber, the weight sensor is fixed on the outer side of the lower base of the control tank and the inner side of the lower wall of the working microwave chamber, and the microwave source, television transmission chamber, the first and second electromagnetic valves are fixed on the outside of the walls of the working microwave chamber respectively back, right, top and bottom, while the corresponding technological holes are made in the walls of the working microwave chamber for inputting radiation from a microwave source, recording a illuminator of radiation transmitted through a control tank by a television transmitting chamber, filling a sample of crude oil with a sample of a control tank and emptying it, the blocks indicated above are fixed, and the corresponding technological holes are made so that the axis of the microwave radiation source and the corresponding technological holes located coaxially to the axis of the Central cross section of the control tank, the optical axis of the television the transmitting chamber and the corresponding axis of the technological hole are perpendicular to it, while the output of the weight sensor is connected to the input of the measuring transducer, the outputs of which and the television transmitting camera are connected respectively to the first and second signal inputs of the electronic switch, the address input of which is connected through the corresponding interface output to the computer , and the output is to the input of the analog-to-digital converter, while the first electromagnetic valve is the input, and the second is the output to of a control tank for sampling crude oil, an illuminator, a microwave source, a television transmitting camera and both electromagnetic valves have on / off control inputs that are connected to the computer through the corresponding outputs of the interface and the outputs of the analog-to-digital converter through its inputs are reached the fact that the control tank is made transparent to infrared radiation in the form of a volume bounded by two straight hollow cylinders of different diameters, the axis of the cat They are arranged coaxially with the main axis of the working microwave chamber, the illuminator is made as an infrared source mounted on the outer side of the bottom wall of the working microwave chamber, in which a corresponding technological hole is made for illuminating the control tank, and the illuminator is installed so that its optical axis and the axis of the corresponding technological hole is aligned with the main axis of the cylinders forming the control tank, and the axis of both electromagnetic valves axis corresponding technological holes perpendicular to the median circumference concentric control tank cross section.

Figure 1 shows a structural diagram of a device for analyzing the composition of crude oil.

Figure 2 shows a sample of crude oil in a control tank when it is full.

Figure 3 shows the structure of the video signal at the output of the television transmitting camera, corresponding to the sample of crude oil in the control tank when it is full.

Figure 4 shows the dependence of the weight of the sample of crude oil on the type of its emulsion state and gas content in it, which determines the maximum weight of the sample of crude oil P _max , the weight of the sample of crude oil P _gas requiring preliminary degassing, and the minimum weight of the sample of crude oil P _min , in accordance with which the options for the operation of the device are determined.

Figure 5 shows the structure of the separated crude oil in a control tank when determining the percentage of components.

Figure 6 shows the structure of the video signal at the output of the television transmitting camera, corresponding to the structure of the separated crude oil in the control tank when determining the percentage of components.

A device for analyzing the composition of crude oil (figure 1, 2, 3, 4, 5, 6), contains a control tank 1, transparent for microwave radiation, a working microwave chamber 2 made in the form of a rectangular hollow parallelepiped, a microwave radiation source 3, illuminator 4, a television transmitting chamber 5, two electromagnetic valves 6-7, a weight sensor 8, a measuring transducer 9, an electronic switch 10, an analog-to-digital converter 11, an interface 12 and a computer 13. Moreover, the control tank 1 is fixed with bases with an internal sides of the upper and lower walls of the working microwave chamber 2. Weight sensor 8, mounted on the outer side of the lower base of the control tank 1 and the inner side of the lower wall of the working microwave chamber 2. Microwave source 3, television transmission chamber 5, the first 6 and second 7 electromagnetic valves fixed from the outside of the walls of the working microwave chamber 2, respectively, back 14, right 15, upper 16 and lower 17. In this case, the corresponding technologies are made in the walls of the working microwave chamber 2 RP G openings (18-22) for inputting the microwave radiation source 3, recording television transmitting camera 5 transmitted through the control tank 1 4 illuminator radiation filling crude sample control tank 1 and its emptying. Moreover, the above blocks are fixed, and the corresponding technological holes (18-22) are made so that the axis 23 of the microwave source 3 and the corresponding axis 24 of the technological hole 18 are aligned with the axis 25 of the Central cross section of the control tank 1, the optical axis 26 of the television transmitting cameras 5 and the corresponding axis 27 of the technological hole 19 are perpendicular to it, while the output of the weight sensor 8 is connected to the input of the measuring transducer 9, the outputs of which and the TV the isionic transmitting chamber 5 is connected respectively to the first and second signal inputs of the electronic switch 10, the address input of which is connected through the corresponding output of the interface 12 to the computer 13, and the output to the input of the analog-to-digital converter 11, while the first electromagnetic valve 6 is the input, and the second 7 - the output of the control tank 1 for sampling crude oil, illuminator 4, a microwave source 3, a television transmitting chamber 5 and both 6 and 7 electromagnetic valves have control inputs turning on / off, which are connected to the computer 13 through the corresponding outputs of the interface 12, and the outputs of the analog-to-digital converter 11 through its corresponding inputs, is achieved by the fact that the control tank 1 is made transparent for infrared radiation in the form of a volume limited by two straight hollow cylinders of different diameters, axis 28, 29 of which are aligned with the main axis 30 of the working microwave chamber 2. The illuminator 4 is made as a source of infrared radiation, mounted on the outside of the lower 17 of the wall the barrel of the microwave chamber 2, in which a corresponding technological hole 20 is made for illuminating the control tank 1. In this case, the illuminator 4 is mounted so that its optical axis 31 and the axis 32 of its corresponding technological hole 20 are aligned with the main axis 33 of the cylinders forming the control tank 1, and axes 34, 35 of both electromagnetic valves 6-7 and axes 36-37 of the corresponding technological holes 21, 22 are perpendicular to the concentric mid-circle of the cross section of the control reservoir macaw 1.

The microwave radiation source 3, the corresponding technological hole 18 and the connection of the interface 12 to it are shown by a dashed line, since these elements 3, 18 are located on the rear 14 of the wall of the working microwave chamber 2. Axes 23, 24 are shown in a projection perpendicular to the plane of FIG.

The control tank 1 is made of two cylinders, the diameters of which are selected from the condition d1 = (3.4-3.6 cm) + d2, where d1 is the diameter of the outer cylinder of the control tank 1, d2 is the diameter of the inner cylinder of the control tank 1. The difference between the diameters 3.4-3.6 cm selected from the conditions for the effective penetration of electromagnetic radiation into the oil-water emulsion.

Figure 2 presents a sample of crude oil 38 inside the control tank 1. The characteristic boundaries necessary to determine the height of the column of the sample of crude oil 38 filling the control tank 1 are the lower boundary 39 of the control tank 1 and the upper boundary 40 of the crude oil sample 38. To determine boundaries analyzed line decomposition image aa of the television transmitting camera 5, corresponding to the main axis 33 of the cylinders forming the control tank 1.

When filling the control tank 1 with a breakdown of crude oil, the video signal of line AA located parallel to the main axis 33 of the control tank 1 received from the television transmitting chamber 5 is shown in FIG. 3. Characteristic changes in the video signal that are essential for the operation of the device are changes in its amplitude between the white level (UB) and the black level (UCH) at the lower boundary 39 of the control tank 1 and the upper boundary 40 of the crude oil sample 38. The crude oil sample 38 is less transparent for radiation from the illuminator 4, than the empty space of the control tank 1, respectively, the amplitude of the video signal at the upper boundary 40 of the crude oil sample 38 will change stepwise. The pixel numbers of the image for determining the boundaries are counted from the trailing edge of the horizontal blanking pulse (SGI), which coincides in time with the beginning of the image of the lower border 39 of the control tank 1. For it, the number corresponds to A0 and is assumed to be 0. For the upper border 40 of the crude oil sample 38 equal to A _Vpr . The number of pixels laid computer to determine the limits of control of filling of the tank 1-A _{(4/5) v,} corresponding to (4/5) V, and _V A, the appropriate V, and the required fill volume _Vpost A corresponding V _post.

Figure 4 shows the dependence of the weight of the sample of crude oil 38 on the type of its emulsion state and gas content in it, according to which the choice of options for the operation of the device. Crude oil in sample 38 may be in the form of an emulsion of types oil-in-water (1 to 50% oil) and water-in-oil (50 to 99% oil) with or without occluded gas. Essential to the operation of the device is the determination of the weight P _ave crude sample 38 and comparing its value with the values laid down in the computer P _max, P _min and P _gas. P _max corresponds to the maximum weight of a non-carbonated sample of crude oil 38 and is determined in the presence of an oil-in-water emulsion in it at a 1% oil content. P _gas corresponds to the weight of a non-carbonated sample of crude oil 38 - in the presence of an oil-in-water or water-in-oil emulsion in it at a 50% oil content. In the case of occluded gas, the weight of the sample of crude oil 38 will not be less than the value of P _gas with a gas content of L lying in the range from 0 to L1 for specific values of oil-in-water emulsions. For emulsion-type "oil in water" or "water in oil" situation when _gas P ≥R _pr> F _min, but no gas content exceeds L1 (shaded area). This should be especially taken into account when choosing device operation options. P _min corresponds to the weight of the crude oil sample 38, at which the analysis of its composition is completed, since the inclusion of the microwave radiation source 3 in this case is unacceptable, since its failure is possible. As a rule, P _min is determined by the requirements of the microwave source 3.

Figure 5 shows the structure of the separated crude oil inside the control tank 1 after processing it with radiation from a microwave source 3. At the bottom of the control tank 1 there is sediment 41, water 42 and oil 43 above. The characteristic boundaries necessary for the analysis of the composition of crude oil are the lower boundary 44 of the control tank 1, the sludge-water interface 45, the water-oil interface 46, the upper boundary of the separated oil 47. To determine the boundaries, the decomposition line A-A is analyzed, respectively etstvuyuschaya main axis 33 of the tank 1 control.

When determining the percentage of components of crude oil, the video signal of line AA located parallel to the corresponding main axis 33 of the control tank 1, obtained from the television transmission camera 5, is presented in Fig.6. Typical changes in the video signal that are essential for the operation of the device are changes in its amplitude between the white level (UB) and black level (UCH) at the interfaces of various oil components. Sediment 41 and pure oil 43 are less transparent for radiation from illuminator 4 than water 42, respectively, the amplitude of the video signal at the media interfaces will change stepwise. Characteristic changes in the amplitude correspond to the lower boundary 44 of the control tank 1, the sediment-water interface 45, the water-oil interface 46 and the upper boundary of the separated oil 47. The pixel numbers of the image for determining the boundaries are counted from the trailing edge of the horizontal blanking pulse (SGI) ), which coincides in time with the beginning of the image of the lower boundary 44 of the control tank 1. For it, the number corresponds to A0 and is assumed to be 0. For the sludge-water interface 45, the number is A1, for the water-not interface be "room 46 is A2, the upper limit of the separated oil room 47 is A3.

Consider the operation of a device for analyzing the composition of crude oil.

To fill the control tank 1, a breakdown of crude oil 38 from the computer 13 through the interface 12, the command for controlling the first electromagnetic valve 6 is turned on. The algorithm for controlling the computer 13 of the operation of the individual units of the device is presented in Appendix 1.

Filling the tank 1 the reference crude oil sample 38, shown in Figure 2, from a pipeline or container in which the crude oil can be carried out within 4 / 5≤V _pr / V <1. These limits are selected based on the conditions for ensuring high accuracy of the analysis, getting the analyzed sample of crude oil 38 and the entire control tank 1 into the field of view of the television transmitting chamber 5 and the impossibility of transfusion of the control tank 1 when filling. However, the filling of the control tank 1 within the specified limits, determined only by the filling time, with a variable flow rate of crude oil can cause a difference in volume and weight between samples in adjacent measurements. Then either a larger sample with the selected microwave separation mode cannot completely separate into components, or a smaller sample can be overheated, which will lead to its boiling and mixing. In both cases, the accuracy of the analysis of the composition of crude oil will be low. Therefore, the filling of the control tank 1 breakdown of crude oil 38 is carried out to a constant value of V _CR = V _post .

To do this, during filling, the control tank 1 is additionally illuminated with radiation from the illuminator 4, the intensity of the radiation transmitted through the control tank 1 is recorded by the television method - by recording by the television transmitting camera 5 the video signal of the image line located along the main axis 33 of the control tank 1. For this, from the computer 13 through the interface 12 commands are given to control the inclusion of the illuminator 4 and the television transmitting camera 5, as well as a command to the address input of the electronic switch Ora 10 to connect to the input of an analog-to-digital converter 11 of the signal from the output of the television transmitting camera 5. The video signal structure received from the television transmitting camera 5 and corresponding to the crude oil sample 38 filling the control tank 1 shown in FIG. 2 is shown in FIG. 3.

Next, the filling volume V _{pr of the} control tank 1 is determined by the breakdown of crude oil 38 and the moment it reaches the value of V _post according to the algorithm given in Appendix 2. First, by lowering the amplitude of the video signal digitized in the analog-to-digital converter 11 and transmitted through the interface 12 to the computer 13, the lower border 44 of the control tank 1 and the upper border 47 of the sample of crude oil 38, as the numbers of the corresponding pixels of the video signal, respectively A0 and A _Vpr .

Characteristic changes in the video signal that are essential for the operation of the device are changes in its amplitude between the white level (UB) and the black level (UCH) at the lower boundary 44 of the control tank 1 and the upper boundary 47 of the crude oil sample 38. The crude oil sample 38 is less transparent for radiation from the illuminator 4, than the empty space of the control tank 1, respectively, the amplitude of the video signal at the upper boundary 47 of the crude oil sample 38 will change stepwise. The entire length of the line is divided by the number of pixels that fit into it. The pixel numbers of the image for determining the boundaries are measured from the trailing edge of the horizontal blanking pulse (SGI), which coincides in time with the beginning of the image of the lower border 44 of the control tank 1. For it, the number corresponds to A0 and is assumed to be 0. When analyzing the video signal, the pixel number A _{Vpr is} determined, in which there was a jump in the amplitude of the video signal at the upper boundary 47 of the crude oil sample 38.

The computer 13 laid numbers of pixels to determine the limits of control of filling of the tank 1-A _{(4/5) v,} corresponding to (4/5) V, and _V A, the appropriate V, and the required fill volume _Vpost A corresponding V _post. When the equality is fulfilled, _Vpr -A _Vpost = 0 and conditions A _{(4/5) V} ≤A _Vpr <A _{V the} filling of the control tank 1 with the breakdown of crude oil 38 is completed, for which, from the computer 13, through the interface 12, a command is issued to turn off the first electromagnetic valve 6 .

Next, determine the weight P _ave crude sample 38, a control reservoir filled the volume V 1 to _{a post.} To do this, from the computer 13 through the interface 12, a command is sent to the address input of the electronic switch 10 to connect the output of the measuring transducer 9 to the analog-to-digital converter 11, the input of which is connected to the weight sensor 8.

Choosing the options for the operation of the device is based on the value of the measured weight P _CR and the values of P _max , P _gas and P _min previously stored in the computer 13, according to the algorithm presented in Appendix 3.

The choice of the values of P _max , P _gas and P _min can be carried out according to the dependence shown in figure 4. Crude oil in sample 38 may be in the form of an emulsion of types oil-in-water (1 to 50% oil) and water-in-oil (50 to 99% oil) with or without occluded gas. P _max corresponds to the maximum weight of a non-carbonated sample of crude oil 38 and is determined in the presence of an oil-in-water emulsion in it at a 1% oil content. P _gas corresponds to the weight of a non-carbonated sample of crude oil 38 - in the presence of an oil-in-water or water-in-oil emulsion in it at a 50% oil content. In the case of occluded gas, the weight of the sample of crude oil 38 will not be less than the value of P _gas with a gas content of L lying in the range from 0 to L1 for specific values of the oil-in-water emulsion. For emulsion-type "oil in water" or "water in oil" situation when _gas P ≥P _pr> F _min, but no gas content exceeds L1 (shaded area). This will be especially taken into account when choosing options for the operation of the device. P _min corresponds to the weight of the crude oil sample 38, at which the analysis of its composition ceases, since the inclusion of the microwave radiation source 3 in this case is unacceptable, since its failure is possible. As a rule, P _min is determined by the requirements of the microwave source 3.

For example, consider weight analysis of samples for crude oil from the Romashkinskoye field. The Republic of Tatarstan (the data for the calculation are taken from the book Baykov N.M. Pozdnyshev G.N., Mansurov R.I. "Collection and field preparation of oil, gas and water", Moscow: Nedra, 1981).

For emulsion crude oils, the density is calculated based on the additivity rule by the formula

ρ _e = ρ _H (1-φ _in ) + ρ _in (1-φ _Н ),

where φ is the volume fraction of the dispersed phase φ _in = ν _in / (ν _Н + ν _in ), φ _Н = ν _Н / (ν _Н + ν _in ),

ρ _e , ρ _in , ρ _N - respectively, the density of the emulsion system, water and pure oil, kg / m ³ .

For gas-saturated emulsion oils with sufficient accuracy, the density of the system is calculated by the formula

ρ _cm = ρ _e (1-L) + Lρ _g ,

where ρ _g - gas density, L - gas content.

In addition, the proportion of sediment in crude oil samples is insignificant, and we will not take it into account in these calculations.

For the Romashkinskoye field, ρ _Н ≈800 kg / m ³ , ρ _in ≈1200 kg / m, ρ _g ≈2 kg / m. Then, for the filling volume of the control tank 1, V = 0.5 dm ³ , P _max will be determined by a mass of 0.6 kg, P _gas - 0.5 kg, and P _min - 0.2 kg (for a magnetron source of microwave radiation). The gas content of L1 will be 10%, which ensures high accuracy in determining the percentage ratio of oil components, since in the presence of occluded gas up to 10% of the emulsion is degassed by microwave separation. In the case of the presence of occluded gas with a fraction of more than 10%, a high accuracy in determining the percentage ratio of the components of crude oil can be ensured by preliminary degassing.

If P _max ≥P _pr > P _gas , they proceed to separate the crude oil sample 38, which filled the control tank 1, into components - sediment, water, pure oil, irradiating it with radiation from a microwave source 3. For this, from computer 13 via interface 12 a command is given to control the inclusion of a microwave radiation source 3. Separation of crude oil into components occurs under the influence of gravitational forces, accelerated by the influence of microwave radiation on the weakening of the intermolecular bonds of water and oil at temperatures of 60-90 ° C. The duration of the on and the mode of operation of the microwave source 3 are determined by the volume of the control tank 1, the type of oil and its initial temperature. As a result of separation in the control tank 1, a structure of separated oil is formed, shown in FIG.

Next, the control tank 1 is illuminated in the infrared range of electromagnetic radiation and the television method records the intensity of the radiation transmitted through the control tank 1 in the form of a video signal of an image line located along the main axis 33 of the control tank 1. To this end, control commands for turning on the illuminator 4 are sent from the computer 13 through the interface 12 and a television transmitting camera 5, as well as a command for the address input of the electronic switch 10 to connect to the input of the analog-to-digital converter 11 of Tell signal output from the television camera 5. The structure of the transmitting video signal obtained with the television camera 5 and the separated oil corresponding structure shown in Figure 5, is shown in Figure 6.

Next, determine the percentage ratio of the components of crude oil according to the algorithm given in Appendix 4. First, by changing the amplitude of the video signal digitized in the analog-to-digital converter 11 and transmitted via the interface 12 to the computer 13, the lower boundary 44 of the control tank 1, the “sediment-water” interface, are determined 45 and “water-oil” 46, the upper boundary of the separated oil 47, as the numbers of the corresponding pixels of the video signal, respectively A0, A1, A2, A3.

Typical changes in the video signal are changes in its amplitude between the white level (UB) and the black level (UCH) for the interfaces of various oil components. Sediment 41 and oil 43 are less transparent for radiation from illuminator 4 than water 42, respectively, the amplitude of the video signal at the media interfaces will change stepwise. Typical changes in the amplitude correspond to the lower boundary 44 of the control tank 1, the sediment-water boundary 45, the water-oil boundary 46 and the upper boundary of the separated oil 47. The pixel numbers of the image for determining the boundaries are counted from the trailing edge of the horizontal blanking pulse (GIS), which coincides in time with the beginning of the image of the lower boundary of the control tank 1 and is taken as 0. The entire length of the line is divided by the number of pixels that fit into it. When analyzing the video signal, the number of the pixel is determined, in which a jump in the amplitude of the video signal at the oil component interface occurs. Suppose in our example this corresponds to:

the lower boundary of the control tank 44-A0 = 0;

the precipitate-water interface 45-A1 = 40;

water-oil interface 46-A2 = 160;

the upper boundary of the separated oil 47-A3 = 360.

Next, the difference between the pixel numbers is calculated to determine the height of the columns respectively of sediment 41, water 42 and pure oil 43, referred to the height of the full column of separated oil.

In our example, this corresponds to:

precipitate - (A1-A0) / (A3-A0) = 40/360 = 0.11;

water - (A2-A1) / (A3-A0) = 120/360 = 0.33;

Pure oil - (A3-A2) / (A3-A0) = 200/360 = 0.56.

Then the quantitative ratio of the components of the crude oil will be equal to

11%: 33%: 56% (sediment: water: pure oil).

In conclusion, the crude oil sample is poured through the second electromagnetic valve 7, for which a command is turned on to its control input from the computer 13 via interface 12. The duration of the second electromagnetic valve 7 is determined by the duration of the complete emptying of the control tank 1.

If R _max <R _min ≤R _etc., analysis of the crude oil sample 38 is completed, for which the second solenoid valve 7 serves enable command from the computer 13 via the interface 12 and empty the tank 1. Case Control P _ave ≤R _min, as indicated above , can lead to failure of the microwave radiation source 3 (option to work on an inconsistent load, the requirements of the microwave radiation source, for example magnetron, at the minimum load). The case P _max ≤ P _pr indicates the ingress into the control tank 1 of components other than oil, water and sludge, which can also lead to failure of the microwave source 3. In addition, this fact can be used to signal the presence of foreign particles in the pipeline tel.

If F _{gas etc.} ≥P> P _min, crude oil sample 38 pre razgaziruyut briefly irradiating it with microwave radiation. To do this, from the computer 13 via the interface 12, a command for controlling the switching on of the microwave radiation source 3 is sent. The degassing of crude oil occurs under the influence of microwave radiation on the weakening of the intermolecular bonds of gas and water, gas and oil. The duration of the on and the mode of operation of the microwave source 3 are determined by the volume of the control tank 1, the type of oil, the weight of the sample and its initial temperature. Moreover, the selected values of the duration and mode of operation are significantly less than those necessary for the separation of the sample of crude oil 38, which was discussed above.

Then again determined V _pr. Here, if the volume change after degassing the crude oil sample 38 satisfy the condition V _pr> 0,9V _post are transferred to the separation of crude oil sample into its components. Such a case is possible for crude oil emulsions as "oil in water" or "water in oil" where F _{gas etc.} ≥R> _Pmin, but the gas content does not exceed 10% (hatched area in Figure 4). If V _pr <0,9V _post controlling tank 1 complement crude oil to a value V _position, thereafter again determined sample weight P _etc. and the obtained value is compared with predetermined values in the computer 13, P _max, P _min and P _gas.

To implement a device for analyzing the composition of crude oil can be used:

- illuminator 4 - an LED matrix composed of infrared LEDs of the brand L-53F3, the number of which is selected from the condition of sufficient illumination of the control tank 1;

- a working microwave chamber 2 and a source of microwave radiation 3 - microwave oven "Electronics - SP23 - POSIS" with an M-136 magnetron;

- television transmitting camera 5 - mono-board company Kodak with a resolution of 360 · 480 pixels;

- the first 6 and second 7 electromagnetic valves - valve EMV-43 s-Du15-220 / 27 (Penza);

- interface 12 - the upgraded control unit and time intervals of the microwave oven "Electronics - SP23 - POSIS";

- computer 13 - PC AT 386 and higher, or any specialized microcontroller;

- weight sensor 8 - strain gauge ET486 (NIIFI, Moscow);

- measuring transducer 9 - bridge device for processing analog signals from strain gauges CMJ from Scaime;

- electronic switch 10 based on the integrated circuit of the 590 series (590KN2, 590KN4).

Compared to existing crude oil analysis devices, microwave separation provides higher component separation quality. The microwave energy absorbed by water excites water molecules, enhancing their rotation, and heats the water enclosed in an emulsion matrix. Water particles are emitted from the emulsion due to differences in surface tension and phase density contained in crude oil. Pure oil and precipitated water are formed.

Compared with existing devices, the error in determining the boundaries of the separation of components of crude oil after its separation using a television camera is 1 / N, where N is the number of pixels in the line of the video signal. With a standard resolution of 480 pixels, the error will be 0.1%, when using specialized Kodak cameras with a number of pixels up to 2000, the error will be 0.05% of the control tank to a predetermined level, which can significantly reduce the analysis error caused by the uneven filling of the control tank, which leads either to incomplete separation of the crude oil sample into components, or to its overheating and possible boiling.

Determining the presence of occluded gas in crude oil, estimating its quantity by weight of the sample, and deciding whether to use the preliminary degassing mode can eliminate or significantly reduce the component of the measurement error caused by the presence of the specified gas in the crude oil. The termination of the analysis of the composition of crude oil with a sample weight less than the critical weight, characteristic from the point of view of the coordinated load for the used sources of microwave radiation and a working microwave chamber, can improve the reliability of the method and the operability of the device for its implementation.

The control tank, made in the form of a volume limited by two straight hollow cylinders of different diameters, allowed to more effectively separate the samples of crude oil and increased the separation speed ≈ 1.2 ÷ 1.5 times in comparison with the prototype.

The performance of the illuminator in the infrared range of electromagnetic radiation made it possible to get rid of glare on the walls of the control tank, and placing it on the bottom wall of the working microwave chamber eliminated strong flashes by the direct illumination channel of the control tank.

Tests of the experimental device showed that filling the control tank in the form of a volume limited by two straight hollow cylinders of different diameters, determining the weight of the sample and taking into account the presence of occluded gas in crude oil, using the preliminary degassing and rejection of samples by weight, using the infrared illuminator as a backlight electromagnetic radiation in addition to the advantages of microwave separation and television measurement methods allowed to increase accurately the measurement and reliability of the device for analyzing the composition of crude oil in comparison with the specified prototype and laboratory devices used in the practice of the oil industry.

Claims (1)

A device for analyzing the composition of crude oil containing a control tank transparent for microwave radiation, a working microwave chamber made in the form of a rectangular hollow parallelepiped, a microwave radiation source, an illuminator, a television transmission chamber, two electromagnetic valves, a weight sensor, a measuring transducer, an electronic switch, an analog-to-digital converter, interface and computer, and the control tank is fixed with bases on the inside of the upper and lower ok working microwave chamber, the weight sensor is mounted on the outer side of the lower base of the control tank and the inner side of the lower wall of the working microwave chamber, and the microwave source, television transmission chamber, the first and second electromagnetic valves are fixed on the outside of the walls of the working microwave chamber, respectively, back, right , upper and lower, while in the walls of the working microwave chamber corresponding technological holes are made for introducing microwave radiation of a new source, registration of a illuminator’s radiation transmitted through the control tank with a television transmitting chamber, filling the sample tank with crude oil and emptying it, the above blocks are fixed, and the corresponding technological holes are made so that the axis of the microwave radiation source and the axis of the technological hole corresponding to it are located coaxial to the axis of the central cross section of the control tank, the optical axis of the television transmitting camera and correspondingly The axis of the technological hole corresponding to it is perpendicular to it, while the output of the weight sensor is connected to the input of the measuring transducer, the outputs of which and the television transmitting camera are connected respectively to the first and second signal inputs of the electronic switch, the address input of which is connected through the corresponding interface output to the computer, and the output - to the input of the analog-to-digital Converter, while the first electromagnetic valve is the input, and the second is the output of the control tank for crude oil sampling, illuminator, microwave source, television transmitting camera and both electromagnetic valves have on / off control inputs that are connected to the computer through the corresponding outputs of the interface and the outputs of the analog-to-digital converter, characterized in that the control the tank is made transparent for infrared radiation in the form of a volume bounded by two straight hollow cylinders of different diameters, the axes of which are located coaxially with the main axis of the working microwave chamber, the illuminator is made as an infrared radiation source mounted on the outside of the bottom wall of the working microwave chamber, in which a corresponding technological hole is made for illuminating the control tank, the illuminator is installed so that its optical axis and the axis of the corresponding technological the holes are aligned with the main axis of the cylinders forming the control tank, and the axes of both electromagnetic valves and the axes of the corresponding hnologicheskih holes perpendicular concentric middle circle control tank cross section.

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