Radiotracers and Nucleonic Control Systems Applied in Industry — Polish Case

Nuclear and radiation technologies play an important role in Polish power sector, oil industry and mining sector, starting from fossil fuels exploitation, their transport and distribution and finally power generation. Application of environmental isotopes, stable and radioactive, in ground water monitoring in the vicinity of open cast lignite mine, and radon monitor applied for miner’s safety in deep coal mines and nucleonic control systems for ash in coal quality control is often used in mining industry. Other applications of nuclear techniques reviewed, concern the oil industry, oil field recovery, transportation pipelines and refineries. Finally, the application of beta radiation-based gauges for air borne fly ash monitoring and radiation technology for flue gas treatment are the examples of using this technique in power sector equipped with coal and oil fired boilers [1]. The radiotracers techniques were used also in glass industry (determination and optimization parameters of the furnaces), cement industry (test of aggregates for the production of cement and optimization media transport in pipelines), metallurgy of Cu, Pb, Zn (investigation of pyrometallurgy processes and new techniques), cellulose industry, environmental and (mainly hydrological) research etc. [2]. The article is brief review of present status of radiotracer and nucleonic gauges techniques as applied to polish industry.


Introduction
First application of nuclear techniques in Poland was reported nearly 45 years ago, and in 1961, about 200 radioisotope gauges were already installed in Polish industry [3].During the next thirty years, manufacturing, installation and servicing facilities have been built enabling application of the nucleonic control systems (NCS) and radiotracer techniques in the industry on the relatively large scale [4].A main sector where radiation and nuclear technologies in Poland are used: • Medical sealed sources and accelerators, • Industrial and geological field research, • Radioisotope gauges, • Industrial and research laboratories (open sources), • Industrial and research laboratories (sealed sources), • Production, transport and sales of radioactive materials.
Since the 90's decade, profound reconstruction of the Polish economy has started.Introduction of the market economy rules, the gradual introduction of new regulations on the use of radioisotopes and development of new non-radioisotope technologies caused reduced demand from the industry on the radiotracer testing.Such situation influenced that radiotracer techniques had to be considerably reduced.Moreover, competition of the other techniques, strict environmental protection standards and the rise of the anti-nuclear movements had significant impact on the position of radiotracer techniques.
At the moment radiotracers for industrial application mainly are used for leakage tests in refinery (INCT group).Metals recovery application investigated by radiotracers methods are under development as well [5] [6].Radiometric methods are used also for waste water treatment application [7].Sealed sources technologies such as: production and application of radioisotope gauges used for measurements and/or automatic control of such quantities as level, density, thickness, coating thickness, mass flow, ash content, acid concentration and airborne dust are still used as well.There are some specific branches of industry where "traditionally" nucleonic gauges are readily installed, such as sugar-factories (density), sulfuric acid production lines (concentration gauges) or coal mines (ash).The numbers of licenses for using radioisotope and radiation sources are shown in Table 1.

Present Status of Radiotracer and Nucleonic Gauges Techniques as Applied in Industry
The short summary of the present status of using radiotracers and NCS in Poland is showed in Table 2.

Radionuclide Source
National Centre or Nuclear Research POLATOM Radioisotope Centre [8] is a Polish manufacturer and distributor of the isotope used in medicine, science, industry and environmental protection.The Centre produces wide range of products for medicine and for research, and development, technology and environment protection such as: • Radiopharmaceuticals for diagnostic and therapy, • Kits for labelling with Tc-99m, • Radiochemicals (pharmaceutical grade), • Radiopharmaceutical precursor (for the radiolabeling of carrier molecules), • Radionuclide generators, • Wide range of radiochemicals, • Sealed radiation sources for gamma radiography and industrial process control, (Ytterbium-169, Selenium-75, Iridium-192, Cobalt-60), • Standard solutions and sources for electronic measurement devices calibration.
Radioisotopes in Poland are produced at MARIA research nuclear reactor which is currently the sole operated in Poland.Its power amounts to 30 MW.

Current main reactor applications [9]:
Table 1.According to data of the National Atomic Energy Agency, the following numbers of licenses for using radioisotope and radiation sources were issued till the end of 2016 [3].• Production of radioisotopes, • Testing of fuel and structural materials for nuclear power engineering, • Neutron transmutation doping of silicon, • Neutron modification of materials, • Research in neutron and condensed matter physics, • Neutron radiography, • Neutron activation analysis, • Neutron beams in medicine, • Training in the field of reactor physics & technology.

Present Examples of Using Radiotracer and Nucleonic Control
Systems Applied to Industry

Leakage Tests
The Institute of Nuclear Chemistry and Technology has been performing for many years in control of the leak-proof-ness of production systems and facilities, underground and ground tanks and underground gas and liquid pipelines by radioisotope marker methods.The field group comprises experienced staff, licensed by the National Atomic Energy Agency.They have got specialized equipment for field generation of various radioisotope markers suitable for marking different types of media.The hardware includes dosing and measuring equipment and detectors for leak-proof-ness tests performed by pig moving inside pipelines.They use special absorptive materials matching the markers [10].
The method is basing on filling the tested facility with (primarily) gaseous methyl bromide labelled with bromine Br-82 (Figure 1).• underground liquid and gas pipelines (Φ200 -600 mm) with cleanout chambers-with sensitivity of up to 0.5 dcm 3 /h for liquids and 5 g/h for gases (output from the smallest detected at localized leak) and underground liquid and gas pipelines (Φ ≥ 600 mm) without cleanout chambers-with sensitivity of up to 1.0 dcm 3 /h for liquids and 10 g/h for gases, • underground and ground pipelines (of all diameters) for gas and liquids without cleanout chambers with sensitivity up to 1.0 dcm 3 /h for liquids and 10 g/h for gas (Figure 2), • gate valves in pipelines for all media, • underground tanks and ground tank bottoms with sensitivity related to the tank volume,  in Płock and other clients stands evidence to the quality of results and efficiency of the method.In terms of costs, using radioisotope markers for leak-proof=ness tests is cheaper than traditional methods.

Radiotracer in Biotechnology Process Investigations
Radiotracer in the form of tritium water (T 1/2 = 4510 days, β radiation-0.018MeV) was used for determination of residence time distribution (RTD) of materials in installation with 42 dm 3 volume and flow rate 0.6 dm 3 /day for biogas production during anaerobic digestion of selected agricultural material or municipal wastes.The scanning technique was applied for measurement of density distribution inside the fermenter and eventually presents of foam inside the fermenter (Figure 3) [12].These experiments were a base for construction of industry scale technology for biogas generation (230 kW).

Coal Mining Industry
Sealed radioactive sources steel is used into polish coal mines.Examples of the use of radioisotope techniques in mines are presented below (Figure 4  Carbon enrichment involves the separation of coal from the stone.This occurs in a thick suspension fluid.To maintain the appropriate density of this liquid, isotopic densitometers are used.The densitometers are most often used when measuring the density of the product flowing in pipeline, detector and container with the source are mounted on a special frame, after both sides of the pipe and is part of the pipeline [2].

Legal Basis
The legal basis for regulating the use of radioactive materials is: Atomic Law.Act of Parliament of 29 November 2000 on the Atomic Law introduced a consistent system ensuring nuclear safety and radiological protection of workers and general public in Poland [14].
Key provisions of the Atomic Law Act regard licensing of activities which involve exposure to ionizing radiation (i.e.licenses issued for activities specified in section "Definition, structure and functions of nuclear safety and radiological protection system") [15], powers vested within heads of organizational entities conducting activities with the use of radiation and powers of the President of World Journal of Nuclear Science and Technology   National Atomic Energy Agency to control and supervise these activities.The Act also identifies other tasks of the PAA President concerning, inter alia, assessment of national radiation situation and procedures applied in radiation emergency.The most important provisions of the aforementioned Act concern issuance of licenses for activities connected with exposure to ionizing radiation (i.e.licenses for activities specified above in the subchapter "Definition, structure and functions of the nuclear safety and radiological protection system"), obligations of heads of organizational units conducting activities which involve radiation and prerogatives of the President of the National Atomic Energy Agency to exercise regulatory control and supervision of these activities [3].

Other Acts of Parliament
Apart from the Atomic Law Act, Polish laws set forth provisions indirectly connected with the issues of nuclear safety and radiological protection, which are included in other Acts of Parliament, in particular in [16]:  In the application for a permit, there must be a description of the test procedure-Technological Instruction.There is a description of the isotope and its form, activity, radioactive waste management, justification of the method, possessed dosimetry equipment, type of source (open, closed), name of the tested installation, what will be tested, how and by what method, how the activity measurement will be performed.With the use of unsealed sources, special attention should be paid to storage and handling of sources and to the potential for contamination of workers and equipment.
The procedure differs slightly when sealed radioactive sources is used.Heads of organizational units performing activity which involves use or storage of sealed radioactive sources or equipment featuring such sources under the relevant authorization granted are obliged to submit copies of records concerning the radioactive sources to the PAA President.Such documents include record sheets containing the following data about sources: radioactive isotope name, activity according to a source certificate, date when the activity was established, certificate number and source type, storage vessel type or device name and place World Journal of Nuclear Science and Technology of the source use or storage.It is also needed emergency procedure if the source is unsealed.Data extracted from the accountancy cards are entered into the register of sealed radioactive sources, used to verify information about individual sources.The information contained in the said register is used to supervise organizational units conducting activity involving exposure to ionizing radiation.The supervision consists in comparing accountancy cards entries with the scope of the given authorization issued.
The application is verified by the Nuclear Supervision Inspector.After the substantive analysis, a permit is issued.
The second step of "the path" is preparation of Technical Procedure of the planned work.This document needs: Certain types of measurements (e.g.leak tests under pressure) may require additional permits such as: Office of Technical Inspection permission for pressure tests.Such permission requires the preparation of many additional documents and procedures, and the UDT certificate procedure may take up to 12 months!
In the next step radioisotope must be ordered from supplier (Maria Reactor) and transported to the laboratory for synthesis of radiotracer (if needed).The contractor performing work with the isotope must be equipped with a radiological laboratory.A special transport must be organized to deliver the isotope to the laboratory and test site.
Only a qualified employee may be allowed to work with the isotope.During fieldwork, a radiological protection inspector must attend them all the time.After completing the work, the inspector has to perform dosimetry measurements and prepare report for PAA inspector.
Additional information: Radioactive waste: if a short-lived isotope is used for tests, it is waiting for its expiration.If it is a long-lived isotope, the waste should be collected and transported to the Radioactive Waste Management Plant, Open sources: usually the activity of the initial isotope is strictly limited, so that after it's spreading in the installation its activity decreases below the norm of acceptable contamination, Time: the measurements on the site in case leak detections take 1 -2 weeks but whole procedure with may take even several months.
Permissions: The Laboratory of Diagnostic Methods at INCT has PAA permission and UDT certificate, which is valid for 2 years (Figure 6).It authorizes to carry out research in the field-leak testing of technical facilities using isotope tracers.Technical devices and objects in industrial installations may be examined like petrochemical and chemical, e.g.pipelines, apparatus, columns, exchangers, boilers, etc.

Norms and Standards Used in Poland [18]
•

Services:
• Detection irradiated foods, • Radiation Sterilization Plant, • Nuclear Techniques Laboratory, Diagnostic Methods Group: underground liquid and gas pipelines (Φ200 -600 mm) with cleanout chambers-with sensitivity of up to 0.5 dcm 3 /h for liquids and 5 g/h for gases (output from the smallest detected at localized leak) and underground liquid and gas pipelines (Φ ≥ 600 mm) without cleanout chambers-with sensitivity of up to 1.0 dcm 3 /h for liquids and 10 g/h for gases, -underground and ground pipelines (of all diameters) for gas and liquids without cleanout chambers with sensitivity up to 1.0 dcm  ALFA-06/T-ash meter and calculating calorific value, use backscattering.
ALFA-06/2E-on-line ash monitor, use absorption of a dual energy gamma ray transmission.Makes it possible to measure ash content in coal with a grain size of 0 -200 mm and in carbon layers with a thickness of 50 -300 mm.The ash content is determined by measuring the attenuation of two concentrated beams of radiation passing through the coal layer, which come from two different radiation sources placed between the conveyor belts.This ash meter can be used in a situation where different coal sizes lie on a belt in a layered system.
ALFA-06/3E-Absorption system for on-line monitoring of coal quality (ash content, moisture) and calculating calorific value of coal transported on conveyor belt.Use absorption of a dual energy gamma ray transmission utilized in loading places and controlling the enrichment process (Figure 7).
Modern versions of density meters have been developed at the EMAG Centre.
Accurate measurement of density and values being density functions for a substance with an altered chemical composition was obtained thanks to applied measuring method using of absorbing and scattering radiation gamma.A cha-racteristic feature of the meters is that the isotope gauge is an element a pipeline with an internal diameter equal to the internal diameter of pipeline.The EMAG Centre was developed several types of gauge intended for various applications.C and CA (caesium and americium) type isotope density meter are designed for measurement of high density substances.
C-type gauge provides continuous measurement of the density of substances transported by pipelines; measurement of other qualities of these substances calculated on the basis of the measured density (Figure 8).
B and BA (133Ba and 241Am) type density meter are provided for measuring of substances with slightly larger or smaller density than water.
CA-type density meter gauge was applied in "Jaworzno" mining where it is utilized for automatic control work of pumps which receive a concentrated sludge from a radial thickener and for control the process of preparing a backfilling mixture.
These devices ensure full safety of use-no restricted zone due to the use of isotope with very low activity.Application in automation systems process control: • flotation, • coal enrichment in a heavy liquid (especially C-type gauge), • water and mud circuit, • preparation and transport mixtures flooring.
Previously generation of devices produced by EMAG-MPKF radiometric ash meter: enable fast (100 s) measurement of ash content in samples with granulation 0 -10 (20) mm.The measurement is based on low-energy forward-scattering gamma rays of Am-241.This type of fully automated devices is used in 18 mining plants to control the quality of raw coal and enrichment products (Figure 9).
The company was founded in 1988 and offers stationary devices as well a series of on-line devices for work directly on belt conveyors and devices co-operating with coal samplers.In the field of on-line measuring, the WILPO offers a number of solutions, adapted to various installation and measurement conditions.WILPO C 212-radiometric under belt ash meter (Figure 10) is especially prepared for ash content measurement in a run of a mine of hard and brown coal.It can be employed in an open pit (i.e.directly on excavators), power stations and mines.The WILPO C212UG version is the first ash meter in Poland approved for operation in underground conditions (sign WUG: DE-111/99).

Technical specifications:
• Granulation of tested carbon: 0 -300 mm, • Required thickness of the carbon layer: min.100 mm (homogeneous, without a layer of coal), • Radiation source: Cs-137 with activity 3.7 GBq.WILPO C 411A-radiometric ash meter is designed for continuous measurement of the ash content in coal directly on the conveyor belt, especially in carbonaceous mixtures with a layered structure and in the coal with the layer height on the conveyor belt from 50 to 250 mm and grains up to 80 mm (Figure 11).
The measurement is possible on sloping, reversing and even passable belts.The small size and the non-contact measurement method predispose it to be used in technological nodes of mines, as well as in power plants, heating plants, coking plants, etc. WILPO C 431-measuring system designed for on-line measurements of ash content, moisture content and determination of the calorific value directly on the conveyor belt (Figure 12).The basic applications of the system are related to the measurement possibilities, among others: carbon mixtures with a layered structure, variable granulation coal, technological nodes, points with relatively small amounts of coal, etc.  of any construction width.The innovative, scattering-absorbing measuring method used in the ash meter makes it possible to carry out measurements, which is a complete novelty, on conveyor belts with steel cords.This predisposes this type of ash meter for applications on long, open transport routes, especially in open-cast coal mines (Figure 13).
WILPO C 532hc-coal quality parameters measurement system.Continuous measurement of ash content in coal is conducted using the innovative radiometric scattering and absorption method developed by WILPO in 2009 (Figure 14).The method is based on irradiating a layer of coal (from above) with low-energy gamma rays and on recording the intensity of gamma radiation reaching a set of detectors arranged under the conveyor belt.Instead of one detector, a system of two appropriately positioned detectors has been introduced: one to measure scattered radiation, the other to measure absorbed radiation.This enabled the gathering of data on ash content variability and surface density of the coal analysed using one radiation source.The applied configuration provided measurement advantages which were unattainable until now, while retaining the valuable features of radiometric ash meters used before.Continuous measurement of moisture content in coal is carried out with use of the technology that consists in absorption of microwaves.WILPO C 732 measurement system (Figure 15).This rapid measurement system of coal quality parameters which can cooperate with the samplers is designed • Granulation of carbon: issued by the sampler crusher, • Volume of the measuring chamber: 5 L, • Measuring method of ash content: dispersion of gamma radiation, • Radiation source: Am-241 with activity 3.7 GBq.
WILPO CG 111-isotope density meter is designed for on-line determination of density of liquids or slurries transported in industrial pipelines, especially in ash slurries.Density meter is practically maintenance-free device, mounted directly on the pipelines transporting the slurries.The measuring system consists of controller unit, which can work autonomously or work together with an external PC unit as well as consist of the isotope head and detection unit.
The on-line coal quality monitors and users are shown in Table 3 and Table 4. SysKon 50-is a control device that allows on-line measure the density of fluids, pulp, mules, etc. transported in pipelines (Figure 16).
The measurement principle is based on the determination of the high energy gamma radiation absorption by the material under study.The gauge is installed directly on the ascending section of the pipeline, which guarantees that the pipe cross-section is filled with the tested material.• liquid flow speed: unlimited, • transport performance: unlimited, • maximum granulation: unlimited, • density range: unlimited, • measurement time: about 1 min, • radiation source: Cs-137.
SysKon 202-a control device that measures a content of flammable parts in fly ash.The probe is installed in the flue gas duct, using the negative pressure prevailing there, continuously samples the ash.The sample weighing about 10 g is directed to the measuring container, where it is scanned with gamma radiation, while its dielectric parameters are measured.From the relation between the absorption of gamma radiation and dielectric properties, the content of flammable parts is calculated.After measurement, the sample is expelled back into the flue gas duct and a new cycle begins.
Technical specifications: • range of flammable parts: 0% -16%, • measurement time: 3 -5 min, • radiation sources: Cs-137.SysKonSystem (Figure 17) and SysKonSystemSkan (Figure 18)-a devices controlling the quality of coal transported by a belt conveyor (ash content, moisture, calculation of calorific value).The device measures the coal in the middle of the conveyor belt-this is the main feature that differs from the SysKonSystem-Skan.The Skan version of device, in the case of a non-uniform stream of material on the conveyor, thanks to the lateral scanning of this stream, better averages the measured values-this is the main feature that differs from    Gauges are designed to measure the density or concentration of liquid media and suspensions in tanks.They use the absorption method of measurement.The measurement head of the densitometer or concentration meter is made up of a system of source and radiation detector assemblies installed on a suitable mechanical construction.Measured medium must completely fill the space between the source and detector assembly in the tank.Depending on the thickness of the tank wall, the distance between the source and the detector, the type and density of the medium being measured and the meter's required metrological parame-World Journal of Nuclear Science and Technology lack of moving parts and the ability to detect level without physical contact with the tested medium.The gauge registers changes in the radiation dose rate as a result of the presence of the medium in the measurement space between the isotope source and the detector.The gauges are used for contactless, continuous level measurements of liquid, powders, aggregates and solids.
Area of applications: measuring the level of concentrated acids, bases, salt solutions and suspensions; monitoring the crystallization process and polymerization; measuring the level of solids including aggregates on conveyor belts; powder level measurement; measurement of filling level of tanks, cylinders.
Technical specifications of MP are shown in Table 7.

Industrial gauges of thickness and basis weight
The industrial (on-line) thickness and basis weight gauges operate in a non-contact manner and do not destroy of the tested sample (Figure 25).The partial absorption of radiation by the sample is used for the measurement-after passing through the tested medium falls on detector that converts radiation Table 6.Technical specifications of MPP type gauges [26].

MPP-xx
Measurement range [g/cm 3 ] Function 01 0 -60 The system of continuous measurement of coal dust concentration, composed of three density gauges type GM-01C, intended for application in storage rooms, mines, etc.   10.

A
. G. Chmielewski et al.DOI: 10.4236/wjnst.2019.9200329 World Journal of Nuclear Science and Technology Following mixing with the control or working medium the marker flows to the leak site and is captured World Journal of Nuclear Science and Technology by either natural (soil, thermal insulation) or artificial (special materials installed before test) adsorbent.In case of soil adsorption, the marker migrates towards the surface.Radiometric detection can be carried out through layers of soil up to 5 meters thick and enables identification and precise positioning of the leak.Special follow-up detectors moving inside the pipeline together with the control medium are used for tests of underground pipelines with cleanout chambers.No absorbents are used for tests of valves and exchangers.They are performing leak-proof-ness tests including precise localization of leaks using radioisotope marker methods at [11]:

Figure 1 .
Figure 1.Equipment needed for generation of gaseous methyl bromide from pre-activated potassium bromide.

Figure 2 .
Figure 2. Detector for detection of leaks in underground pipelines with cleanout chambers.

Figure 3 .
Figure 3.Comparison of experimental and model RTD results and scheme of scanning measurement and distribution of the density inside the fermenter [12].

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Parliament on Shipment of Hazardous Goods, • Act of Parliament on Marine Safety, • Act of Parliament on Technical Supervision, • Plus 34 secondary legislation to the Atomic Law for example: -Regulation of the Council of Ministers of July 12, 2006 on detailed conditions of safe work with sources of ionizing radiation (Journal of Laws from 2006 No. 140 item 994), -Regulation of the Council of Ministers of December 23, 2002 on the requirements for dosimetric equipment (Journal of Laws of 2002 No. 239, item 2032), World Journal of Nuclear Science and Technology -Regulation of the Council of Ministers of December 3, 2002 on radioactive waste and spent nuclear fuel (Journal of Laws of 2002 No. 230 item 1925), Regulation of the Council of Ministers of February 20, 2007 on basic requirements for controlled and supervised areas (Journal of Laws of 2007 No. 131, item 910).

3. 2 .
How to Perform Industrial Research Using Radioisotopes in Poland-An Example of a Path The first step is to get permission for work with isotopes from the PAA President [17].Drafts of the PAA President's licenses for performance of activities involving exposure to ionizing radiation and other decisions in matters considered important for nuclear safety and radiological protection were prepared by the Radiological Protection Department (DOR) of PAA.Issuance of a license, an annex to a license or receipt of a notification is always preceded by the analysis and assessment of the documentation submitted by users of ionizing radiation sources.Apart from the said documentation, a detailed analysis is also conducted to cover the following issues: substantiation for the commencement of the activity involving exposure, utility dose limits proposed, quality assurance program in connection with the activity conducted Supervision of the use of ionizing radiation sources and an internal emergency plan for cases of radiation emergency.In cases, in which activity involving ionization radiation exposure does not require a license, decisions are issued on acceptance of notification of activity involving exposure to ionizing radiation.These cases have been listed in the Regulation of the Council of Ministers of 6 August 2002 concerning cases, in which activity involving exposure to ionizing radiation is not subject to the license or notification obligation and cases, in which it may be conducted on the basis of a notification (Journal of Laws No. 137, item 1153 as amended).
Positive opinion of the competent State Sanitary Inspector of technological work instructions, • Permission of the PAA President to conduct works radioactive source in the field, • Written consent of the site administrator to perform works on its premises with source of radiation, • Notification of the competent State Sanitary Inspector on the date and place of performing works with radioactive source, • The program of protection against ionizing radiation in the transport of radioactive materials, • Emergency plan.

4. 3 .
EMAG [13] Institute of Innovative Technologies EMAG, and Centre of Technology Transfer EMAG Ltd. (CTT EMAG, http://www.cttemag.pl/,Leopolda 31, 40-189 Katowice).For over 40 years, the Institute of Innovative Technology EMAG has specialized in the development and construct of systems and equipment for on-line monitoring and laboratory measurements of coal quality parameters, as well as in the implementation of these devices in mines and power plants.The systems based inter alia on the radiation detection techniques, such as: backscattering of gamma radiation (ALFA-06 and ALFA-06/T systems) and absorption of a dual energy gamma ray transmission (ALFA-06/2E ash meter, ALFA-06/3E system), have found wide application in Poland.At present, over 100 systems and devices for analysis are used in Polish hard and brown coal mines.
Technical specifications:• Coal type: hard,• Granulation of carbon: 0 -70 mm,• Required thickness of the carbon layer: 50 -250 mm (500 mm if only ash content),• Radiation source: Am-241 with activity 3.7 -18.5 GBq and energy 60 keV.The new design of the measuring system, most importantly that of the ash meter which includes a single and low-energy (60 keV) Am-241 radiation source, is perfectly safe.The device has been approved for manufacturing by WILPO by the Polish National Atomic Energy Agency (PAA) in Warsaw (permit No. D-17222 of 24 June 2009).WILPO also holds a permit issued by PAA for the turnover, installation and transportation of equipment comprising sources of radiation (permit No. D-15512 of 14 January 2005, annex No.1 of 26 May 2008).

4. 6 .
TD-ELECTRONICS Tomasz Dudek [25]Blatona 1/63, 01-494 Warszawa, http://www.td-electronics.pl.Exists since 1998 and specializes in software development, construction and implementation of electronic, isotope, measuring equipment for industry, laboratories and environmental measurements.Isotope measurements are carried out by means of the TDI series.These are meters containing a radioactive source and an ionizing radiation detector.It is possible to measure (where xx can be Am-241, Cs-137, Co-60, Kr-85, Cd-109, Pm-147, Sr-90): TDI-xx-GT-Traversing thickness or basis weight (Figure 21) is intended for continuous, non-contact measurement of the thickness profile of film, paper, and sheets (depending on the radiation source used).It uses the absorption method of measurement.The radioactive source is placed under while the detector assembly over the measured of material tape.The traverse mechanism (scanner) enables synchronous movement of the source-head system, across the produced tape, between the parametrically determined turning points.TDI-xx-GR-Stationary thicknesses or basis weight is designed for continuous, non-contact measurement of thickness or basic weight of film, paper, sheets, and plates (depending on the radiation source used) directly on the production line.It uses the absorption method of measurement.The measuring head system (source-detector) of the thickness or basis weight World Journal of Nuclear Science and Technology

Table 2 .
Status of radiotracer and nucleonic gauges in Poland.
NCBJ offers a broad range of research/engineering services for both domestic and foreign customers.They have accumulated vast experience in producing ionizing radiation detectors and materials for their construction; the detectors are used by the most eminent equipment manufacturers and research labs in the world.They have been constructing unique electronic instruments to cooperate with ionizing radiation detectors, including individual circuits and entire systems for LHC in CERN, Geneva, which is the largest research facility built by the mankind.The Institute is also operator of the Maria Reactor.The part of the institute is POLATOM Radioisotope Centre which is a Polish manufacturer and distributor of the isotope used in medicine, science, industry and environmental protection.Research is a research and development.The Centre produces wide range of products for medicine and for research and development, technology and environment protection.

Table 4 .
Installations-Export by WILPO [23].World Journal of Nuclear Science and Technology According to data from 2009, in national mining works about 100 on-line radiometric ash meters from various companies, based on transmission and backscattering methods of gamma radiation, including over 60 WILPO solutions.The radiation level on the surface of the source container is well below the level allowed by the PAA regulations, i.e. 2 mSv/h.Measurements are made automatically and no employee is required near the device.