RU2468457C1 - Method for removing radioactive film from object surface - Google Patents

Abstract

FIELD: power industry.

SUBSTANCE: method for removing radioactive film from object surface consists in formation of laser emission beam on object surface, scanning of dirty object surface by means of formed laser emission beam through film material that is transparent for laser emission; at that, the above film material is arranged between laser emission source and dirty surface of the object; after scanning is completed, film material is removed. Prior to scanning operation between object surfaces and transparent film material there created is constant electric field U by means of an electrode such that energy A_e transferred to positively charged particle in electric field exceeds kinetic energy A_k of that particle, and electric field has reverse polarity in relation to particles spread during laser deactivation; value of electric field shall exceed the following value:

where k - Boltzmann constant, T - particle temperature, L - distance between treated surface and mesh, d - distance between treated surface and transparent adsorbing film, q - particle charge.

EFFECT: invention allows increasing the efficiency of radioactive film removal process.

2 cl, 1 dwg

Description

The proposed technical solution relates to the field of processing materials with radioactive contamination, in particular using a laser, and can be used to decontaminate equipment whose surfaces are contaminated with radionuclides.

A known method of surface decontamination and a device for laser decontamination of the surface (RF patent No. 2084978, IPC G21F 9/28, priority date 03.24.92, publication date 07.20.07) (1), in which a pulsed laser beam is formed outside the area of radioactive contamination, transporting the specified beam using optical fiber to the working area of the laser decontamination installation, located in the immediate vicinity of the decontaminated surface, and then direct the laser beam to the deactivated surface. During the laser operation period, a special protective or, in the corresponding sense, active gas is sent to the working area of the laser decontamination installation. The working area of the installation is limited, and during the operation of the laser, the gas contained in this limited space is pumped out.

There is also known a method of removing a radioactive film from the surfaces of an object (RF patent No. 2212067, IPC: G21F 9/00, priority date 12/13/01, publication date 10/09/03) / 2 /, which provides for the formation of a laser beam and subsequent scanning of the formed beam over a contaminated the surface of the object through a layer of a substance that removes the radioactive film, as a substance that removes the radioactive film, use a layer of liquid, the stream of which washed the contaminated surface of the object. During decontamination using the known methods / 1 / and / 2 / there is a great danger of radioactive contamination of the territory outside the treatment area, since the decontamination products are transported by gas or liquid. The volumes of gas or liquid used are large enough. Great is the possibility of the distribution of environmentally harmful cleaning products. So, for example, during the decontamination of bulky equipment, the volume of liquid radioactive waste can reach several thousand cubic meters. Their processing, ensuring environmental safety, is laborious and requires significant financial costs.

The closest in physical essence and technical result achieved and the prototype method of removing radioactive film from the surfaces of the object (RF patent No. 2319238, IPC G21F 9/00, B23K 26/00, priority date 08/23/2005, publication date 02/27/2007) was chosen / 3 /, in which a laser beam is formed and subsequent scanning is performed by the formed beam over the contaminated surface of the object through a film material transparent to laser radiation, which is placed between the laser radiation source and contaminated surface of the object, scan along the entire contaminated surface of the object with a laser beam, and after scanning the film material is removed. The use of a transparent film as a substance that removes radioactive contaminants is more effective than the use of a liquid or gas / 1 / and / 2 / from the point of view of limiting the possibility of distribution of cleaning products and reducing their volume. Nevertheless, during the removal of the radioactive film from the surfaces of the object, some of the products of the destruction of the radioactive film are deposited back onto the surface of the object as a result of the mutual collision of particles of the radioactive film destroyed by laser radiation in the gap between the surface of the object and the transparent film and the formation of a reverse particle flow towards the surface of the object. As a result of this, the complete removal of radioactive material from the surface of the object is not achieved and re-processing is required.

The problem of increasing the efficiency of the process of removing a radioactive film is solved by eliminating the deposition of material removed by laser radiation of the radioactive film back on the surface of the object.

The problem is solved due to the fact that in the method of removing the radioactive film from the surface of the object, including the formation of a laser beam and subsequent scanning of the formed beam along the contaminated surface of the object through a film material transparent to laser radiation, which before scanning is placed between the laser radiation source and the contaminated surface object, then scan along the entire contaminated surface of the object with a laser beam, and after scanning The film material is removed, in addition, in the method of removing the radioactive film from the surface of the object between the surface of the object and the transparent film material, a constant electric field is created using an electrode made in the form of a metal mesh, the mesh size of which is less than the distance between the network and the surface to be treated, created by a metal grid constant electric field such that the energy transmitted to a positively charged particle in an electric field exceeds the kinetic energy of this the particle,.

In addition, the electrode is made in the form of a metal mesh, the mesh size of which is less than the distance between the mesh and the work surface.

The efficiency of the deposition of microparticles on the film material is ensured by the fact that a reverse voltage (negative) with respect to the microparticles of polarity is applied to the metal mesh.

The creation of a constant electric field between the treated surface and the transparent film, in particular, using a grid with a negative electric charge, significantly reduces the number of particles of a radioactive film vaporized by laser radiation due to the attraction of positively charged particles ionized during evaporation, which acquire momentum in mutual collision movement towards the work surface. Thus, the degree of purification of radioactive material from the surface during its laser decontamination increases. The likelihood of radioactive pollution of the environment and the defeat of personnel involved in the decontamination process is reduced. In addition, there is no need for surface reprocessing, which increases the productivity of the process by at least two times. The above advantages can significantly reduce the cost of decontamination of equipment.

In the proposed method, a constant electric field is created in the region between the transparent film and the surface to be treated. A beam of laser radiation is scanned over the contaminated surface of the object through a film material that is transparent to laser radiation. In this case, the radioactive contaminated film on the treated surface evaporates and the resulting plasma, consisting of ionized positively charged particles and electrons, moves away from the treated surface. In the process of movement, the particles collide with each other and some of the particles after the collision acquire a momentum of movement towards the surface to be treated. In a constant electric field, particles acquire an additional momentum of motion. In order to direct particles moving to the treated surface after the collision towards the transparent adsorbing film, it is necessary that the energy A _e transmitted to the positively charged particle in the electric field exceeds the kinetic energy of the particle A _k moving after the collision towards the treated surface. The energy A _{e is} determined by the charge of the particle q, the electric field strength in the gap between the treated surface and the transparent absorbent film E and the distance between the processed surface and the transparent absorbent film d:

A _e = q E d.

In this case, the electric field in the gap between the treated surface and the transparent absorbent film E when grounding the object to be processed is determined by the voltage on the electrode U:

,

,

.where L is the distance between the treated surface and the electrode, h is the thickness of the transparent adsorbing film, ε is the dielectric constant of the film. For

.

The kinetic energy of the particles A _to = mν ^2/2, where m - mass of the particle, ν - its speed. Thus, the voltage across the grid must be negative in sign and magnitude corresponding

.

.

, где k - постоянная Больцмана, Т - температура частицы, m - масса частицы.For almost all particles, the velocity does not exceed ten times the most probable velocity

where k is the Boltzmann constant, T is the temperature of the particle, m is the mass of the particle.

Thus, the voltage across the electrode exceeds

.

.

For singly ionized particles at a temperature of T = 3300 K with a distance between the treated surface and a transparent adsorbing film d = 10 mm and a distance between the treated surface and the electrode L = 15 mm, the voltage across the grid exceeds 900 V.

After scanning with laser radiation over the entire surface of the treated object, the film material with the radioactive film deposited on it is removed from the treatment area and placed, for example, in a container.

It is technologically expedient to use a metal mesh as an electrode.

It was experimentally established that when the mesh size of the mesh exceeds the distance between the mesh and the treated surface, the amount of waste collected on the film material begins to decrease due to the fact that the electric field between the mesh and the treated surface becomes substantially inhomogeneous and part of the particles returns to the treated surface. To affect all products of the destruction of a radioactively infected film, the electric field must be uniform, therefore, the mesh size of the mesh should not exceed the distance between the mesh and the treated surface.

The proposed method is illustrated in the drawing, where in FIG. a diagram of the process of removing a radioactive film from the surface of an object is presented, where: 1 - a processed object (main material), 2 - a laser beam, 3 - an electrode for creating a constant electric field, 4 - film material (adsorbing) transparent to laser radiation, 5 - radioactive film on the contaminated surface of the object, V _SC - scanning speed. The arrow indicates the direction of movement of the laser beam.

The proposed method was tested when cleaning steel fragments of a dismantled nuclear reactor. We used λ = 1.06 μm, τ = 10 ns, and a Nd: YAG laser.

, где k=1,38·10^-23 Дж/К - постоянная Больцмана, Т=3300 К - температура частицы, L=15 мм - расстояние между обрабатываемой поверхностью и сеткой, d=10 мм - расстояние между обрабатываемой поверхностью и прозрачной адсорбирующей пленкой, q=7,5·10^-17 Кл - заряд частицы. Электрод выполнен в виде латунной сетки, толщина проволоки сетки составляла 0,4 мм, размер ячейки 1 мм, отсюда U>-900 В. На сетку было подано постоянное напряжение -1000 В, что соответствует расчетному условию для данных условий сканирования. Обрабатываемый объект был заземлен.Using this laser, a beam is formed on the surface of the object being processed. Before scanning with a laser beam between the source of laser radiation and the contaminated surface of the treated object 1 with a radioactive film 5 at a distance of 10 mm from the contaminated surface, film material 4 is placed (by gluing) on the movable carriage, in particular a polyester with an adhesive base, from the side facing the treated surface further from the outside of the transparent film material, an electrode was also placed at a distance of 15 mm by gluing on the second carriage, creating a constant electric field with apryazheniem

, where k = 1.38 · 10 ^-23 J / K is the Boltzmann constant, T = 3300 K is the temperature of the particle, L = 15 mm is the distance between the surface to be treated and the mesh, d = 10 mm is the distance between the surface to be processed and the transparent adsorbent film, q = 7.5 · 10 ^-17 C - particle charge. The electrode is made in the form of a brass grid, the thickness of the grid wire was 0.4 mm, the mesh size was 1 mm, hence U> -900 V. A constant voltage of -1000 V was applied to the grid, which corresponds to the design condition for these scanning conditions. The object being processed was grounded.

The intensity of laser radiation on the surface of the treated object was 100 MW / cm ² . The size of the laser radiation spot on the surface of the object was 6 mm ² . In the process of scanning, the radioactive film 5 evaporated, forming a plasma, which, under the action of an electric field created by the voltage applied to the grid, moved towards the film material 4 and adhered tightly to it, forming a layer of radioactive film 5. After the scanning, the film material was removed using a special rewinder and placed in a container, which completely eliminates the spread of environmentally harmful cleaning products.

Based on the foregoing, the claimed combination of features allows us to solve the problem of increasing the efficiency of the process of removing a radioactive film from the surface of an object.

Information sources

1. Patent of the Russian Federation No. 2084978, the application. 03.24.92, publ. 07.20.07, IPC ⁶ : G21F 9/28. "A method of surface decontamination and a device for laser decontamination of the surface."

2. Patent of the Russian Federation No. 22212067, decl. 12/13/01, publ. 09/10/03, IPC ⁷ : G21F 9/00. "A method of removing a radioactive film from the surfaces of an object and a device for its implementation."

3. Patent of the Russian Federation No. 2319238 claimed. 08/23/2005, publ. 02.27.2007, IPC ⁷ : G21F 9/00, ⁷ B23K 26/00. "The method of removing radioactive film from the surfaces of the object" is a prototype.

Claims (2)

1. The method of removing a radioactive film from the surface of an object, which consists in forming a laser beam on the surface of the object, scanning the generated laser beam over the entire contaminated surface of the object through a film material transparent to laser radiation, placed between the laser radiation source and the contaminated surface of the object, after scanning film material is removed, characterized in that before scanning between the surfaces of the object and the transparent film pictures create a static electric field U by the electrode such that the energy of A _e, imparted to the positively charged particle in an electric field that exceeds the kinetic energy of the particles A _k, and the electric field has an inverse polarity with respect to the scatter in the laser decontamination of the particles, the magnitude of the electric fields must exceed the following value:

,
where k is the Boltzmann constant, T is the temperature of the particle, L is the distance between the surface to be treated and the grid, d is the distance between the surface to be treated and a transparent adsorbing film, q is the particle charge, 2. The method of removing a radioactive film from the surface of an object according to claim 1, characterized in that the electrode is made in the form of a metal mesh, the mesh size of which is less than the distance between the mesh and the surface to be treated.