RU53017U1 - SURFACE ANALYZER ANALYZER - Google Patents

Abstract

The utility model is aimed at expanding the arsenal of technical means for determining the sulfur content in oil and oil products on production lines of pipelines, creating a safe device. The specified technical result is achieved in that the in-line sulfur analyzer contains a radiation source, a measuring cell, a proportional x-ray counter associated with the signal processing unit. As a radiation source, we used a circuit consisting of an x-ray tube with two with targets made of antimony and silver placed sequentially one after another between the x-ray tube and the measuring cell. The position of the targets in the analyzer case is fixed so that due to the polarization of the scattered X-ray radiation, only a 22 keV line remains at the circuit output, which is most favorable for the analysis of sulfur in hydrocarbon media.

Description

The utility model relates to devices for measuring the concentration of elements in hydrocarbon liquids based on the interaction of ionizing radiation with a substance, namely, to x-ray absorption analyzers of sulfur in oil and oil products and can be used to measure sulfur concentration directly in process pipelines in the stream.

Known devices: flow seromers firm "Asoma" (http://www.imsholding.ru/equipment/spectro). So the device type 682T-LP consists of two cases: measuring and controller. In the measuring case there is a radiation source - an X-ray tube, a measuring chamber - a flow cell with flanges on both sides for connecting to the production line, a radiation detector - a proportional gas-filled counter. The measuring housing is connected by a cable line to the controller. This model implements an X-ray fluorescence method for determining sulfur, where characteristic sulfur x-ray radiation (HRI) carries information about the sulfur content. HRI of sulfur has a low energy of 2.3 keV and weak penetration.

It is impossible to make a strong measuring chamber that would simultaneously hold the high pressure of the process pipeline and would be so thin that it would not absorb HRI of sulfur. The maximum possible pressure that the measuring chamber of this model holds is 2 atm. This significantly narrows the circle of its technological consumers.

Another line type of seromer of the same company 682T-HP is known. This device also consists of two cases: measuring and controller. In the measuring case there is a radiation source - the radioactive isotope Am-241, located in a protective container with a window, an electric drive to open the protective window, a silver target, measuring

camera - flow cell and radiation detector - proportional X-ray counter. This device implements an X-ray absorption (transmission) method for measuring sulfur content, in which the radiation shines through the measuring chamber — a flow cell with a sample in it. Attenuation of radiation is affected by both density and composition of the sample. For hydrocarbon liquids, in particular oil, the main elements are carbon and hydrogen and (comparable in content) sulfur, the remaining elements are present at the level of trace elements. For an energy line of 22 keV, the absorption cross sections for carbon and hydrogen are equal. Therefore, a change in the intensity of this line as it passes through the sample is affected by the oil density and sulfur content. Knowing the density, you can determine the sulfur content.

In this device, the Am-241 radiation source has an energy line of 26 keV. A silver target was used to obtain an energy line of 22 keV. CHRI silver has an energy of 22 keV. The penetrating power of radiation with an energy of 22 keV is enough to illuminate the measuring chamber (flow cell) made of a pipe withstanding pressure up to 50 atm.

A serious drawback of this model is the use of a radioisotope radiation source.

A device is known - an X-ray absorption analyzer of sulfur in oil and liquid petroleum products, selected by us as a prototype (USSR author's certificate No. 1689817, MKP5 G 01 N 23/00, published November 7, 91. Bull. No. 41), consisting of a radiation source - Cd- 109, a measuring cell, connected in series with a proportional X-ray counter, a detection unit, an amplitude discriminator, a power supply, a switch, a reversible counter, a data setting unit, a computing device, an indication unit, a timer, a clock generator x pulses, the output of the amplitude discriminator is connected to the first input of the switch, the second input switch connected to the first

the output of the reversing counter, the first output of the switch is connected to the second input of the reversing counter, the input of the data setting unit is connected to the second output of the computing device, the first output of the data setting unit is connected to the third input of the reversing counter, the second output of the data setting unit is connected to the second input of the computing device, the second the output of the reversible counter is connected to the first input of the computing device, the third input of the computing device is connected to the second output of the timer, the fourth the input of the computing device is connected to the output of the clock generator and the timer input, the first output of the computing device is connected to the fourth input of the reversible counter, the third output of the computing device is connected to the display unit.

In this device, as well as in a device of type 682T-HP, an X-ray absorption (transmission) method for determining the sulfur content is laid. However, the radioisotope Cd-109 was taken as the radiation source, which for this method provides the most optimal irradiation conditions, since it has only one energy line equal to 22 keV.

However, the use of a radioisotope radiation source is a significant drawback of this device. The use of radioisotope sources is regulated by radiation safety standards (NRB) and imposes stringent requirements on enterprises using radioisotopes. A number of measures are required for the use of radioisotopes, the organization of a radiation safety service, the development of a system for the storage, transportation and use of radioisotopes. These measures are very expensive, the cost of operating the device increases significantly, which practically removes oil companies from the list of consumers.

The objective of this utility model is to expand the arsenal of technical equipment for a similar purpose, to create a safe device.

The problem is solved due to the fact that the in-line sulfur analyzer, as in the prototype, includes a radiation source, a measuring cell, proportional to the X-ray counter associated with the signal processing unit. According to a utility model, a circuit consisting of an x-ray tube and two targets was used as a source of monoenergetic radiation with an energy of 22 keV. These targets are placed sequentially one after another between the x-ray tube and the measuring cell. Their position is fixed in such a way that straight lines directed from the center of the first target to the center of the window of the x-ray tube and to the center of the second target form a right angle. Moreover, the second target downstream of the x-ray tube is made of silver, and the first of the material, the energy of the KRI line of the HXR of which exceeds the energy of the K-absorption edge in silver. Between the second target and the measuring cell, and between the proportional X-ray counter and the measuring cell, collimators are placed so that the holes of the collimators are oriented in a straight line directed from the center of the second target to the window of the proportional X-ray counter. This straight line is directed perpendicular to the plane in which the center of the window of the x-ray tube and the centers of the targets lie. The axis of the measuring cell crosses perpendicular to this straight line. Between the window of the X-ray tube, on the one hand, and the second target, a measuring cell and a proportional X-ray counter, on the other hand, there is a metal screen.

Due to the use of the proposed monoenergetic radiation source with an energy of 22 keV, in which an X-ray tube is used, the safety category of the device, the in-line sulfur analyzer, is changing. When using it, no special safety measures are required. It can be applied in many areas of the national economy.

The irradiation scheme proposed by the claimed device makes it possible to achieve optimal irradiation conditions — the creation of a monoenergetic radiation line with an energy of 22 keV based on an x-ray tube, and to realize

X-ray absorption method for the determination of sulfur in hydrocarbon media.

Figure 1 presents the irradiation scheme proposed to obtain a monoenergetic emission line with an energy of 22 keV in a flow analyzer sulfur. It consists of an X-ray tube 1, two targets 2, 3, two collimators 4, 5, a measuring cell 6, a proportional X-ray counter 7, and a metal screen 8.

The position of the x-ray tube 1 and targets 2, 3 is fixed in the device body so that the straight lines directed from the center of the first target 2 to the window of the x-ray tube 1 and to the center of the second target 3 form a right angle. The collimators 4, 5 of the measuring cell 6 and the proportional X-ray counter 7 are located so that the holes of the collimators 4, 5 are oriented in a straight line directed from the center of the second target 3 to the window of the proportional X-ray counter 7, and this straight line is perpendicular to the plane in which the centers of the targets lie 2, 3 and the center of the window of the x-ray tube 1 and it intersects the measuring cell 6 perpendicular to its axis. Between the window of the X-ray tube 1, on the one hand, and the second target 3, the measuring cell 6, and the proportional X-ray counter, on the other hand, there is a metal screen 8. The proportional X-ray counter 7 is connected to the signal processing unit (not shown in Fig. 1) .

As targets 2, 3, square plates 1 mm thick with a side of 6 mm were used. Antimony was used as the material of the first target; tellurium or other materials whose XRD K line exceeds the K absorption edge in silver can be used. As collimators 4, 5, silver cylinders with a diameter of 10 mm and a height of 5 mm and a hole diameter of 2 mm were used. An X-ray tube with a silver anode BH-10 with a working current of 1 mA and an anode voltage of 30 kV was used. Screen 8 was made of lead. An dural pipe with flanges at the ends was used as a measuring cell. Proportional

X-ray counter 7 is selected type SI-11P. The signal processing unit is used the same as in the prototype, but it is possible to use other known signal processing units.

Using the flanges of the measuring cell 6, the in-line sulfur analyzer is connected to the bypass line of the process pipeline filled with oil. When you turn on the device, the radiation of the x-ray tube 1 hits the first target 2, the metal screen 8, and the walls of the body. The screen 8 protects the second target 3, the measuring cell 6, and the proportional X-ray counter 7 from the direct impact of the radiation of the X-ray tube 1. On the first target 2, the radiation of the X-ray tube 1 is scattered and excites antimony CRI of 26 keV. From direct radiation from the first target 2, the measuring cell 6 and the proportional X-ray counter 7 are also protected by a screen 8 and collimators 4, 5. The radiation of the X-ray tube 1, scattered on the first target 2, is already polarized on the second target 3, since scattering occurs at right angles. Such is the geometry of the mutual arrangement of targets 2, 3 and x-ray tube 1. Thus, the plane of polarization passes through the center of the window of x-ray tube 1 and the centers of the targets 2, 3. For polarized radiation, there is a prohibition on scattering in the direction perpendicular to the plane of polarization, that is, when scattering by the second target 3, the radiation of the x-ray tube 1 cannot be scattered along the straight line connecting the center of the second target 3 and the window of the proportional x-ray counter 7. HXR of the first target 2 hit the second target 3 floor it is absorbed by the second silver target 3, since the photoelectric effect cross section is two orders of magnitude larger than the scattering cross section.

Thus, the measuring cell is only visible through the XRI of the second 3 target, with an energy of 22 keV.

The signal from the proportional X-ray counter 7 enters the signal processing unit, where the sulfur content C _S (in%) is calculated by the formula (the same as in the prototype):

where ρ is the density of the sample in g / cm ³ ;

K ₁ , K ₂ - calibration factors, the value of which is determined from calibration measurements using standard samples with known sulfur content;

N _f - the number of background pulses;

N ₀ , N is the number of pulses in the absence and presence of a sample in the measuring cell.

Claims (1)

A sulfur flow analyzer containing a radiation source, a measuring cell, a proportional X-ray counter connected to a signal processing unit, characterized in that a 22-keV mono-energy radiation source uses a circuit consisting of an X-ray tube and two targets placed one after the other another between the x-ray tube and the measuring cell so that the straight lines directed from the center of the first target to the center of the window of the x-ray tube and to the center of the second target are s at a right angle, the second target downstream of the x-ray tube is made of silver, and the first is a material whose K-line energy of characteristic X-ray radiation exceeds the energy of the K-absorption edge in silver, between the second target and the measuring cell, and between the proportional X-ray the counter and the measuring cell are placed collimators so that the holes of the collimators are oriented in a straight line directed from the center of the second target to the window of the proportional X-ray counter, and this straight line is directed perpendicular to the plane in which the centers of the targets and the center of the window of the x-ray tube lie, and the axis of the measuring cell crosses perpendicular to this straight line, while between the window of the x-ray tube, on the one hand, and the second target, the measuring cell and the proportional x-ray counter, on the other hand, a metal screen is located.