WO2015058408A1 - 一种灰控制棒及其中子吸收体和组件 - Google Patents
一种灰控制棒及其中子吸收体和组件 Download PDFInfo
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- WO2015058408A1 WO2015058408A1 PCT/CN2013/085971 CN2013085971W WO2015058408A1 WO 2015058408 A1 WO2015058408 A1 WO 2015058408A1 CN 2013085971 W CN2013085971 W CN 2013085971W WO 2015058408 A1 WO2015058408 A1 WO 2015058408A1
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- neutron absorber
- control rod
- ruthenium
- ash
- reactivity value
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- G—PHYSICS
- G21—NUCLEAR PHYSICS; NUCLEAR ENGINEERING
- G21C—NUCLEAR REACTORS
- G21C7/00—Control of nuclear reaction
- G21C7/06—Control of nuclear reaction by application of neutron-absorbing material, i.e. material with absorption cross-section very much in excess of reflection cross-section
- G21C7/08—Control of nuclear reaction by application of neutron-absorbing material, i.e. material with absorption cross-section very much in excess of reflection cross-section by displacement of solid control elements, e.g. control rods
- G21C7/10—Construction of control elements
- G21C7/103—Control assemblies containing one or more absorbants as well as other elements, e.g. fuel or moderator elements
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- G—PHYSICS
- G21—NUCLEAR PHYSICS; NUCLEAR ENGINEERING
- G21C—NUCLEAR REACTORS
- G21C7/00—Control of nuclear reaction
- G21C7/06—Control of nuclear reaction by application of neutron-absorbing material, i.e. material with absorption cross-section very much in excess of reflection cross-section
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E30/00—Energy generation of nuclear origin
- Y02E30/30—Nuclear fission reactors
Definitions
- the invention relates to the technical field of nuclear power plant reactive control, in particular to a gray control rod and a neutron absorber and assembly thereof.
- control rod assemblies used are generally divided into two categories, black control rod assemblies and gray control rod assemblies.
- the black control rod assembly is mainly used for emergency shutdown, while the gray control rod assembly functions as reactive compensation and load tracking.
- the mechanically compensated operating mode is used for reactive control, ie the use of ash control components instead of chemical compensation (adjusting boron concentration) provides reactive control for the load tracking process and provides reactive control for full power operation, allowing daily handling
- the need for primary reactor coolant is minimized, greatly simplifying the chemical and volume control system and its operation.
- the black control rod assembly includes a plurality of black control rods, the black control rods are encapsulated with a neutron absorber, and the neutron absorber is cylindrical.
- the commonly used black control rod neutron absorber is made of silver-indium-cadmium alloy (Ag-In-Cd alloy, the mass fraction of In is about 15%, the mass fraction of Cd is about 5%, and the balance is Ag).
- the neutron absorbers are often referred to as Ag-In-Cd alloy rods, Ag rods, Dy rods, Hf rods, Er rods, Eu rods, Gd rods, B rods, and B 4 C rods.
- the ash control rod assembly is used for reactive compensation and load tracking, which is required to have lower reactivity value relative to black control rod assemblies primarily used for emergency shutdown.
- a more suitable reactivity value of the gray control rod assembly is about silver-indium -
- the reactivity value of the black control rod assembly of cadmium alloy is 20 ⁇ 45%, preferably 25 ⁇ 40% of the reactivity value of the black control rod assembly of silver-indium-cadmium alloy. . Therefore, the design of the conventional gray control rod assembly adopts the configuration of a typical black control rod assembly, that is, the material of the neutron absorber in the black control rod of the black control rod assembly is used to make the middle of the gray control rod assembly.
- the sub-absorber such that the neutron absorber of the ash control rod has a diameter smaller than the neutron absorber of the black control rod, or the ash control rod has a smaller number than the black control rod, for example, the diameter is 2mm Ag-In-Cd alloy rod, Hf rod or Dy rod as neutron absorber for ash control rod, or 4 standard diameter (8.7mm) Ag-In-Cd Alloy rod as ash control rod for neutron absorber and 20
- a stainless steel rod constitutes a gray control rod assembly.
- the gray rod control rod assembly needs to be inserted into the active area of the reactor for reactivity control for a long time, the elements in the neutron absorber of the gray control rod will be consumed and metamorphosed as the fuel consumption is deepened, and after consumption and metamorphosis, the total The absorption capacity is continuously decreasing or even decreasing rapidly as the fuel consumption is deepened, which will affect the control energy in the mechanical compensation operation mode of the gray control rod assembly.
- Figure 1 shows an Ag-In-Cd alloy rod with a standard diameter (8.7mm), Hf rod, Dy The reactivity value of the rod - the fuel consumption curve, it can be seen that the reactivity value of the Ag-In-Cd alloy rod is reduced by more than 25% (to use the standard diameter Ag-In-Cd) The reactivity value of the alloy rods is benchmarked for comparison).
- the method of reducing the diameter of the neutron absorber of the gray control rod can reduce the initial reactivity value of the gray control rod assembly and achieve weak reactivity control ability, the neutron absorber therein
- the self-screening effect is correspondingly reduced and leads to a faster decline in reactivity, and its reactivity value at the end of the life period will be lower than the minimum necessary to achieve the function of the gray control rod.
- the method of reducing the number of ash control rods therein can reduce the initial reactivity value of the gray control rod assembly and achieve weak reactivity control ability, but its reactivity control ability is unbalanced in the reactor.
- Ag-In-Cd alloy rods have relatively large neutron absorption cross sections, especially Ag, In and Cd.
- the neutron absorption cross section of the naturally occurring isotopic enthalpy of the three elements is significantly reduced, which will cause the reactivity of the ash control rod assembly to decrease to 80% of the initial value in about 5 years. Left and right, the mechanical compensation mode is no longer required for the reactivity value of the gray control rod assembly, so a new gray control rod assembly must be replaced. If you improve Ag-In-Cd The initial reactivity value of the alloy's ash control rod assembly can compensate for the decrease in the reactivity value after prolonged use, and correspondingly increase its service life.
- the initial reactivity value is significantly increased, when the ash control rod assembly is withdrawn from the fuel assembly, the power level of the fuel rod adjacent to the ash control rod is rapidly increased, and thus is more likely to occur. PCI thus affects the safety of the fuel rod.
- the Ag-In-Cd alloy is irradiated for a short time in the core, a large amount of Sn (tin) and Cd are generated. This causes a large change in material density and causes severe volume expansion, which will cause premature failure of the cladding tube and failure of the ash control rod assembly.
- the time effect of the reactivity value of the ash control rod assembly must be considered. It is required that the ash control rod assembly should have sufficient reactivity value after long-term use until the end of the life to meet the control ability under the mechanical compensation operation mode. However, if the decrease in reactivity is compensated by increasing the initial reactivity value, the reactivity value of the ash control rod assembly significantly exceeds the minimum rod value required, which affects the power distribution of the core, for example, in the core. Excessive uneven power distribution of the fuel assembly PCI effect, etc. Therefore, the rate of reactive loss of these black control rod absorber materials must be slowed down, i.e., by appropriate means to compensate for this decrease in reactivity as the fuel burns deepen.
- the neutron absorption cross section of ⁇ -187 is larger than the parent isotope and almost equally compensates for the slow loss of all absorbing isotopes originally present in tungsten, not GRCA Neutron absorption has a negative impact. It can be seen that the technical solution compensates the reactivity value of the tungsten element with the use time by the reactivity value of the progeny element generated by the tungsten element enthalpy change in the gray control rod, and obtains a substantially flat reactivity value loss characteristic. This solved the adoption The ash control rod assembly of the Ag-In-Cd alloy has a problem of rapid loss and peak local power.
- the material of the neutron absorber used in the technical solution disclosed in the above patent application is a high-density material, which is limited by the high density of tungsten, in order to ensure that the weight of the gray control rod assembly does not exceed CRDM.
- the load-bearing limit can be filled with less tungsten in the control rod cladding tube, and can not be filled up to 6.4mm in diameter.
- the tungsten rod and considering that the remaining space in the cladding must be filled with the support tube material made of iron, nickel, zirconium-based alloy (the weight is also considerable), the amount of tungsten must be further reduced, thereby further reducing tungsten The maximum reactivity value that the neutron absorber can provide.
- the neutron absorption capacity is not strong, for example 10 to 30
- the neutron absorbing material of the microscopic absorption cross section of the target even if the space in the cladding tube of the ash control rod is completely filled, no equivalent or more than 5 standard Ag-In-Cd can be obtained.
- the reactivity value of the alloy rod is not strong, for example 10 to 30
- those skilled in the art are directed to developing a gray control rod and its neutron absorber and assembly that achieve greater reactivity value and achieve substantially flat reactivity value loss characteristics.
- the technical problem to be solved by the present invention is to provide a The ash control rod and the neutron absorber and the assembly thereof, the material of the neutron absorber of the black control rod with large neutron absorption cross section and strong neutron absorption capacity is used as a component of the neutron absorber of the gray control rod, And by adding other components for compensation and adjustment, a gray control rod and its components with a larger range of reactivity values can be obtained.
- the present invention provides a neutron absorber of a gray control rod characterized by comprising at least one first component and at least one second component, the reactivity of the first component The value increases as the use time of the neutron absorber increases, and the reactivity value of the second component decreases as the use time of the neutron absorber increases; the reactivity of the neutron absorber Value with the use time of the neutron absorber The increase is not more than 15%; the use time is no more than 20 years.
- the first component is a metal ruthenium, a metal ruthenium, a metal nickel, or a compound of ruthenium, osmium, or nickel, or an alloy containing ruthenium, osmium, and nickel; and the second component is a metal silver or a metal ruthenium.
- First component, second component, and neutron absorber It may be porous, or reduced in density, or diluted, or in the form of an alloy, or a compound.
- the first component is metal ruthenium, or ruthenium oxide, or strontium titanate, or a ruthenium alloy.
- the neutron absorber is a tantalum alloy, or a sintered block of a mixture of cerium oxide and cerium oxide, or a sintered mass of a mixture of barium titanate and barium titanate.
- the neutron absorber is a cylinder, and the diameter of the cylinder is D, 1.0 mm ⁇ D ⁇ 8.7 mm, D The unit is mm; the mass percentage of lanthanum in the neutron absorber is x, -0.0688 ⁇ D+0.6388 ⁇ x ⁇ -0.0026 ⁇ D+0.8626
- the reactivity value of the neutron absorber varies by no more than 10% as the use time of the neutron absorber increases.
- the reactivity value of the neutron absorber varies by no more than 5% as the use time of the neutron absorber increases.
- the invention also discloses an ash control rod comprising a cylindrical cladding tube and an upper end plug and a lower end plug for closing the two ends of the cladding tube, the encapsulation tube being encapsulated with a neutron absorber, the characteristics of which are characterized
- the neutron absorber comprises at least one first component and at least one second component
- the reactivity value of the first component increases as the use time of the ash control rod increases.
- the reactivity value of the second component decreases as the use time of the gray control rod increases; the reactivity value of the neutron absorber varies with the increase of the use time of the gray control rod by no more than 15%; the use time is no more than 20 years.
- the first component is a metal ruthenium, a metal ruthenium, a metal nickel, or a compound of ruthenium, osmium, or nickel, or an alloy containing ruthenium, osmium, and nickel; and the second component is a metal silver or a metal ruthenium.
- First component, second component, and neutron absorber It may be porous, or reduced in density, or diluted, or in the form of an alloy, or a compound.
- the neutron absorber is a tantalum alloy, or a sintered block of a mixture of cerium oxide and cerium oxide, or a sintered mass of a mixture of barium titanate and barium titanate.
- the neutron absorber is a cylinder, and the diameter of the cylinder is D, 1.0 mm ⁇ D ⁇ 8.7 mm, D The unit is mm; the mass percentage of lanthanum in the neutron absorber is x, -0.0688 ⁇ D+0.6388 ⁇ x ⁇ -0.0026 ⁇ D+0.8626
- the reactivity value of the neutron absorber varies by no more than 10% as the use time of the ash control rod increases.
- the reactivity value of the neutron absorber varies by no more than 5% as the use time of the ash control rod increases.
- the invention also discloses an ash control rod assembly comprising a plurality of ash control rods, each of the ash control rods comprising a cylindrical cladding tube and an upper end plug and a lower end plug for closing both ends of the cladding tube
- the hull tube is encapsulated with a neutron absorber, wherein the neutron absorber comprises at least one first component and at least one second component, and the reactivity value of the first component
- the neutron absorber comprises at least one first component and at least one second component
- the reactivity value of the first component As the use time of the ash control rod assembly increases, the reactivity value of the second component decreases as the use time of the ash control rod assembly increases; the reactivity value of the neutron absorber
- the magnitude of change with the increase in the use time of the gray control rod assembly is not greater than 15%; the use time is no more than 20 years.
- the first component is a metal ruthenium, a metal ruthenium, a metal nickel, or a compound of ruthenium, osmium, or nickel, or an alloy containing ruthenium, osmium, and nickel; and the second component is a metal silver or a metal ruthenium.
- First component, second component, and neutron absorber It may be porous, or reduced in density, or diluted, or in the form of an alloy, or a compound.
- the neutron absorber is a tantalum alloy, or a sintered block of a mixture of cerium oxide and cerium oxide, or a sintered block of a mixture of barium titanate and barium titanate;
- the neutron absorber is a cylinder, The diameter of the cylinder is D, 1.0mm ⁇ D ⁇ 8.7mm, the unit of D is mm;
- the mass percentage of lanthanum element in the neutron absorber is x, -0.0688 ⁇ D+0.6388 ⁇ x ⁇ -0.0026 ⁇ D+0.8626; the reactivity value of the neutron absorber varies with the increase of the use time of the gray control rod assembly is not greater than 10%.
- the reactivity value of the neutron absorber varies by no more than 5% as the usage time of the ash control rod assembly increases.
- a neutron absorber of a gray control rod comprising a first component and a second component
- the first component is a metal ruthenium or ruthenium compound or a ruthenium-containing alloy
- the second component is a metal ruthenium or osmium compound, or a ruthenium-containing alloy, or Silver - indium - cadmium alloy.
- the bismuth alloy rod was analyzed as a neutron absorber. Specifically, it has different mass percentages for bismuth (30%, 50%, 68%, 70%, and 90%).
- tantalum alloy rods have different diameters (1mm, 2mm, 3mm and 8.7mm)
- the reactivity value of the ash alloy rod as the neutron absorber ash control rod assembly at different time of use was calculated, and the corresponding reactivity value versus time of use was obtained (see Figure 3). ).
- the present invention analyzes the above calculation results (see Figure 4). And the fitting formula is given, so that the reactivity value required for the ash control rod assembly with the bismuth alloy rod as the neutron absorber and the required change of the reactivity value with the use time can be estimated.
- the mass percentage and diameter of the crucible required for the rod see figure) 5 and 6).
- the present invention accordingly provides a ash control rod and a ash control rod assembly employing the above neutron absorber.
- the present invention forms a neutron absorber by using a component whose reactivity value increases with the increase of use time and a component whose reactivity value decreases with an increase in use time, and by appropriately adjusting the neutron absorber.
- a ratio of each component can obtain a neutron absorber having a substantially flat reactivity value loss characteristic; and by increasing or decreasing the amount of the material of the neutron absorber, a ash having a desired reactivity control ability can be obtained.
- Control rods and their components This is in contrast to the ash control rod and its components disclosed in the patent CN 101504872A.
- an isotope of tungsten 186 W is 187 Re due to enthalpy change, and the sub-absorption cross section is greater than 186 W, thereby compensating for the slow decline in the reactivity value caused by other isotopes of tungsten.
- Re elements naturally exist in two kinds of nuclide, one is 185 Re with abundance of 37.4%, and the other is 187 Re with abundance of 62.6%.
- 185 Re was transformed into 186 Re by enthalpy change, and then 186 Os was formed by ⁇ decay.
- the reactivity value showed a slow decline, and 186 Os produced 187 Os again.
- the reactivity value increased slowly, and the formation of 188 Os stopped slowly.
- the use of the neutron absorber such as the Dy-Tb alloy of the present invention has at least the following advantages over the use of a tungsten-based neutron absorber.
- the thermal neutron absorption cross section of the Dy element (930 target) is large, and the thermal neutron absorption cross section (25.5 target) and resonance absorption cross section (418 target) of the Tb element are large, and the sub-absorption capacity is much higher.
- the density of Dy element ( 8.54 g /cm 3 ) and Tb element ( 8.23g /cm 3 ) is small, even smaller than the density of Ag-In-Cd alloy (10.17g /cm 3 ), the amount of niobium alloy will be It is not limited by density.
- the use of the alloy as a neutron absorber can significantly increase the maximum reactivity value that the ash control rod assembly can provide.
- the reactivity value of the Dy element decreases approximately linearly with the increase in burnup, as shown by the reactivity value of the Dy element shown in Figure 1 versus the time of use; while the reactivity value of the Tb element is deepened with the fuel consumption ( That is, the increase in usage time) exhibits an approximately linear rise.
- the ratio of Dy element to Tb element in the neutron absorber for example 1:1 (Dy-50Tb as shown in Fig. 2, the mass percentage of Tb in the neutron absorber is 50%, the rest is Dy)
- a flatter reactivity value loss characteristic than tungsten is obtained, and the risk of PCI is lower.
- Tb elements to Ag-In-Cd alloy rods or by combining them in a certain structure, such as Ag-In-Cd-50Tb shown in Fig. 2, the neutron absorber
- the mass percentage of medium Tb is 50%, and the rest is Ag-In-Cd alloy.
- the maximum reactivity value that the alloy's ash control rod assembly of the neutron absorber of the present invention can provide is far greater than the maximum reactivity value that can be provided by prior art ash control rod assemblies that use tungsten as a neutron absorber.
- the maximum relative reactivity values of Dy-50Tb alloy rods and Ag-In-Cd-50Tb alloy rods as neutron absorber control rod assemblies are 1.37 and 1.23, respectively.
- the maximum relative reactivity value of the ash control rod assembly using a tungsten rod as the neutron absorber is 0.27. Therefore, it is easy to obtain the required ash control rod assembly by reducing the diameter of the Dy-Tb alloy rod.
- Dy-Tb Alloy rods act as control rod assemblies for neutron absorbers, and their relative reactivity values are distributed over a wide range (0.18 ⁇ 1.37).
- the relative reactivity value can be maintained by a certain proportion of chemical composition and specific diameter, maintaining a relatively flat or even flatter reactivity value loss characteristic than tungsten. Therefore, it is easy to obtain the required gray control rod assembly
- the relative reactivity value of 0.20 ⁇ 0.45, and the relative reactivity value of 0.25 ⁇ 0.40 For example, use a 2mm diameter Dy-70Tb
- the alloy rod is used as the ash control rod assembly of the neutron absorber to obtain a relative reactivity value of 0.27.
- a Dy-68Tb alloy rod with a diameter of 3 mm can be used as a ash control rod assembly for a neutron absorber.
- the relative reactivity value of 0.40.
- a gray control rod assembly having a large reactivity value can be obtained, for example, 0.30.
- the relative reactivity value which not only facilitates the strategic choice of the mechanical compensation operation mode, but also significantly reduces the number of steps of the gray control rod assembly, reduces the wear of the gray control rod cladding tube, and prolongs the gray control. The life of the rod assembly.
- the Tb element is relatively rare, relatively expensive, and its thermal neutron absorption cross section is not high (25.5 target), but its resonance absorption cross section (418 target) is large, especially after metamorphosis, it will produce strong absorption capacity.
- 160 Tb (525 target) and 161 Dy (600 target) so it is generally not considered as an absorbent material for gray control rods.
- a strong absorber element such as Dy
- the amount of use thereof is small.
- Figure 1 shows a prior art standard diameter pure Hf rod, pure Dy rod and Ag-In-Cd
- the reactivity value of the alloy rod as the ash control rod assembly of the neutron absorber is relative to the time of use.
- the reactivity value shown in the figure is Ag-In-Cd relative to the standard diameter.
- Figure 2 shows the use of tungsten rods, Dy-70Tb alloy rods and (Ag-In-Cd)-Tb
- the reactivity value of the alloy rod as the ash control rod assembly of the neutron absorber is relative to the time of use.
- the reactivity value shown in the figure is Ag-In-Cd relative to the standard diameter.
- Figure 3 shows Dy-Tb with different diameters and Tb mass percentage
- the reactivity value of the alloy rod as the ash control rod assembly of the neutron absorber is relative to the time of use.
- the reactivity value shown in the figure is Ag-In-Cd relative to the standard diameter.
- Figure 4 shows Dy-Tb with diameters of 1.0mm and 8.7mm. The relationship between the reactivity value of the ash control rod assembly of the alloy rod as the neutron absorber relative to the time of use versus the mass percentage of Tb.
- Figure 5 shows the corresponding neutron absorbers when the reactivity value varies by no more than 5% and 10% over time.
- Figure 6 shows the relative value of the reactivity value of the Dy-Tb alloy rod as the ash control rod assembly of the neutron absorber in Dy-Tb.
- the relationship between the diameters of the alloy rods and the reactivity values shown in the figures is the relative value of the initial reactivity value of the ash control rod assembly as the neutron absorber relative to the standard diameter Ag-In-Cd alloy rod.
- the present invention analyzes the case where the tantalum alloy rod is used as a neutron absorber, specifically, has a different mass percentage (30%, 50%, 68%, 70% and 90%) and tantalum alloy rods have different diameters (1mm, 2mm, 3mm and 8.7mm)
- the reactivity value of the ash alloy rod as the neutron absorber ash control rod assembly at different usage times is calculated.
- the calculation results are shown in Fig. 3.
- Dy-50Tb ( ⁇ 1.0mm) means The bismuth alloy rod with a diameter of 50% and a diameter of 1.0 mm is the same as that of the other alloy rods, and will not be described here.
- the figure shows Dy-Tb with different diameters and Tb mass percentages.
- the reactivity value of the alloy rod as the ash control rod assembly of the neutron absorber is relative to the time of use curve, where the reactivity value shown is Ag-In-Cd relative to the standard diameter.
- the relative value of the initial reactivity value of the alloy rod as the ash control rod assembly of the neutron absorber that is, the initial reactivity value of the ash control rod assembly with the standard diameter Ag-In-Cd alloy rod as the neutron absorber is 1.0. .
- the reactivity values (relative values) and relative reactivity values are relative values of the initial reactivity values of the ash control rod assembly of the neutron absorber relative to the standard diameter of the Ag-In-Cd alloy rod. .
- Use time is not greater than 20 In the year, since the neutron absorber is encapsulated in the cladding tube of the gray control rod, the control rod is a component of the gray control rod, so the use time may be the use time of the neutron absorber, or may be a gray control rod. The time of use or the time of use of the gray control rod assembly.
- Will ash control rod assembly full life (20
- the ratio of the difference between the maximum value and the minimum value of the reactivity value to the minimum value ie, the ratio of the maximum value to the minimum value minus 1) It is called the magnitude of change in the reactivity value relative to the time of use (referred to as the magnitude of change, the magnitude of change in the value of reactivity).
- the change is less than 10% Changes in reactive value do not affect the strategy of the mechanically compensated operating mode or significantly increase the PCI risk.
- the variation of the reactivity value of the alloy rod as the ash control rod assembly of the neutron absorber is obtained by fitting Dy-Tb with diameters of 1.0 mm and 8.7 mm as shown in Fig. 4.
- the range of change of 10% can also be expressed as: -0.0688 ⁇ D + 0.6388 ⁇ x ⁇ - 0.0026 ⁇ D + 0.8626, 1.0mm ⁇ D ⁇ 8.7mm .
- the combination can obtain a variation range of no more than 5%, and the range can also be expressed by the formula: -0.0571 ⁇ D + 0.7371 ⁇ x ⁇ 0.0039 ⁇ D + 0.7261 , 1.0 mm ⁇ D ⁇ 8.7mm.
- the relationship between the reactivity value and the diameter of the ash control rod assembly for the Dy-70Tb alloy rod as the neutron absorber is shown in Fig. 6.
- D 6 It can be seen that the corresponding Dy-70Tb alloy rod has a diameter of 1.3 mm and a relative reactivity value of 0.45 when the reactivity value (relative value, or relative reactivity value) is 0.20.
- the corresponding Dy-70Tb alloy rod has a diameter of 3.3 mm.
- the relative reactivity value is 0.25
- the corresponding Dy-70Tb alloy rod has a diameter of 1.8mm
- the relative reactivity value is
- the corresponding Dy-70Tb alloy rod has a diameter of 3.0 mm at 0.40.
- the main factor affecting the reactivity value of the gray control rod assembly is Dy-Tb as a neutron absorber.
- the diameter of the alloy rod as long as the reactivity value of the ash control rod assembly changes by no more than 10%, even if the Tb content changes greatly, Dy-70Tb can still be used.
- the initial reactivity value determined by the alloy rod is estimated by the curve shown in Fig. 6 as the diameter of the alloy rod.
- the results in Figure 5 are further limited to 0.20 ⁇ 0.45 required to meet the gray control rod assembly.
- the relative reactivity value, and the preferred relative reactivity value of 0.25 to 0.40 corresponds to the diameter: 1.3mm ⁇ D ⁇ 3.3 mm; a preferred 0.25 to 0.40 relative reactivity value of the Tb-Dy alloy rod corresponding to a diameter of: 1.8 mm ⁇ D ⁇ 3.0 mm.
- Tb-Dy with a relative reactivity value of 0.20 ⁇ 0.45 and a variation of no more than 10% required for the gray control rod assembly
- the parameter range of the alloy rod is: -0.0688 ⁇ D+0.6388 ⁇ x ⁇ -0.0026 ⁇ D+0.8626, 1.3mm ⁇ D ⁇ 3.3mm.
- the range of parameters for Tb-Dy alloy rods with a relative reactivity value of 0.25 to 0.40 and a variation of no more than 10% is: -0.0688 ⁇ D+0.6388 ⁇ x ⁇ -0.0026 ⁇ D+0.8626, 1.8mm ⁇ D ⁇ 3.0mm.
- the parameter range of the alloy rod is: -0.0571 ⁇ D + 0.7371 ⁇ x ⁇ 0.0039 ⁇ D + 0.7261, 1.3 mm ⁇ D ⁇ 3.3 mm.
- the range of parameters for Tb-Dy alloy rods with a relative reactivity value of 0.25 to 0.40 and a variation of not more than 5% is: -0.0571 ⁇ D + 0.7371 ⁇ x ⁇ 0.0039 ⁇ D + 0.7261, 1.8 mm ⁇ D ⁇ 3.0 mm.
- a sintered block of a mixture of cerium oxide and cerium oxide can also be used as a neutron absorber, which is a ceramic material having a ratio Dy-Tb
- the alloy has better corrosion resistance. Since the ability of oxygen to absorb neutrons is almost zero, it is easy for those skilled in the art to utilize the Tb content of the above Dy-Tb alloy -
- the range of parameters for the diameter derives the range of parameters for the yttrium-diameter required for the ash control rod assembly.
- FIG. 2 A neutron absorber of a metal Tb having a mass percentage of 50% added to a silver-indium-cadmium alloy is shown, which has an improved reactivity value as a function of time of use.
- a metal ruthenium, or ruthenium oxide, or a barium titanate, or a first component other than a ruthenium alloy for example Metal ruthenium, metallic nickel, or a compound of ruthenium or nickel, or an alloy containing ruthenium or nickel. They all have the property that the reactivity value increases with increasing use time.
- the present invention accordingly provides a ash control rod consisting of an elongated cladding tube and an upper end plug and a lower end plug for sealing the ends thereof.
- the cylindrical neutron absorber is encapsulated in the cladding tube and made of a tantalum alloy.
- the ash control rod is covered with a cladding tube made of stainless steel or a nickel-based alloy.
- the mass percentage of Tb in the tantalum alloy rod is 70%, and the diameter of the tantalum alloy rod is 2 mm.
- the reactivity value of the ash control rod assembly using the alloy rod as the neutron absorber is 0.27, and the relative reactivity value of the ash control rod assembly using the tungsten rod as the neutron absorber is 0.27, but the former variation is 2.8%. , better than 3.9% of the latter, as shown in Figure 3.
- the niobium alloy may also have no more than 2% of Ho, Fe, Ca, Si, Cl, O, etc. Impurity component.
- the neutron absorber using bismuth alloy as the ash control rod is also advantageous in that the change in the properties of the material of the neutron absorber during the design life of the gray rod is small, and the bismuth alloy undergoes long-term irradiation inside the core. After that, the ⁇ element is reduced, the ⁇ element is increased, and the ⁇ element is also generated. Both the lanthanum element and the lanthanum element have a higher density than the lanthanum element, and the crystal structures of these elements are the same and solid solution to each other, and no other phases are formed, so that volume expansion due to a change in material density does not occur.
- the present invention also provides a ash control rod assembly for a reactor, the ash control rod assembly including 24 Root ash control rod.
- the ash control rod is composed of an elongated cladding tube and an upper end plug and a lower end plug for sealing both ends thereof.
- the cylindrical neutron absorber is encapsulated in the cladding tube and made of a tantalum alloy.
- the ash control rod is covered with a cladding tube made of stainless steel or a nickel-based alloy.
- the mass percentage of Tb in the tantalum alloy rod is 68%, and the diameter of the tantalum alloy rod is 3 mm.
- the relative reactivity value of the ash control rod assembly using the alloy rod as the neutron absorber is 0.40, which is greater than the relative reactivity value of 0.27 of the ash control rod assembly using the tungsten rod as the neutron absorber, and the variation is only 1.8%, as shown in Figure 3.
- the advantage of the ash control rod assembly is that it can meet the demand for the reactivity value of a larger power reactor, significantly reducing the number of steps of the gray control rod assembly, reducing the wear of the gray control rod cladding tube, and prolonging the ash. Control the life of the rod assembly.
- the present invention also provides a ash control rod assembly for a reactor, the ash control rod assembly including 24 Root gray stick.
- the gray rod is composed of a slender casing tube and an upper end plug and a lower end plug for sealing both ends.
- the ash control rod is covered with a cladding tube made of stainless steel or a nickel-based alloy.
- the Ag-In-Cd-Tb alloy rod has a Tb composition of 50%, Ag-In-Cd-Tb.
- the alloy rod has a diameter of 3 mm.
- the relative reactivity value of the ash control rod assembly using the alloy rod as the absorber was 0.32 with a variation of 8%.
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- High Energy & Nuclear Physics (AREA)
- Monitoring And Testing Of Nuclear Reactors (AREA)
Abstract
Description
Claims (24)
- 一种灰控制棒的中子吸收体,其特征在于,包括至少一种第一组分和至少一种第二组分,所述第一组分的反应性价值随所述中子吸收体的使用时间的增加而增加,所述第二组分的反应性价值随所述中子吸收体的使用时间的增加而减少;所述中子吸收体的反应性价值随所述中子吸收体的使用时间的增加而变化的幅度不大于15%;所述使用时间不大于20年。
- 如权利要求1所述的灰控制棒的中子吸收体,其中所述第一组分为金属铽、金属镨、金属镍,或铽、镨、镍的化合物,或含有铽、镨、镍的合金;所述第二组分为金属银、金属镝、金属铪、金属铒、金属铕,或银、镝、铪、铒、铕、硼的化合物,或含有银、镝、铪、铒、铕的合金。
- 如权利要求2所述的灰控制棒的中子吸收体,其中所述第一组分为金属铽,或氧化铽,或钛酸铽,或铽合金。
- 如权利要求3所述的灰控制棒的中子吸收体,其中所述中子吸收体为铽镝合金,或氧化铽和氧化镝的混合物的烧结块,或钛酸镝和钛酸铽的混合物的烧结块。
- 如权利要求4所述的灰控制棒的中子吸收体,其中所述中子吸收体为圆柱体,圆柱体的直径为D,1.0mm≤D≤8.7mm,D的单位为毫米;所述中子吸收体中铽元素的质量百分比为x,-0.0688×D+0.6388≤x≤-0.0026×D+0.8626;所述中子吸收体的反应性价值随所述中子吸收体的使用时间的增加而变化的幅度不大于10%。
- 如权利要求5所述的灰控制棒的中子吸收体,其中所述中子吸收体中,-0.0571×D+0.7371≤x≤0.0039×D+0.7261;所述中子吸收体的反应性价值随所述中子吸收体的使用时间的增加而变化的幅度不大于5%。
- 如权利要求5或6所述的灰控制棒的中子吸收体,其中1.3mm≤D≤3.3mm。
- 如权利要求7所述的灰控制棒的中子吸收体,其中1.8mm≤D≤3.0mm。
- 如权利要求8所述的灰控制棒的中子吸收体,其中D=2mm;x=70%;所述中子吸收体的反应性价值随所述中子吸收体的使用时间的增加而变化的幅度不大于2.8%。
- 一种灰控制棒,包括圆柱形的包壳管和用于封闭所述包壳管的两端的上端塞和下端塞,所述包壳管内封装有中子吸收体,其特征在于,所述中子吸收体包括至少一种第一组分和至少一种第二组分,所述第一组分的反应性价值随所述灰控制棒的使用时间的增加而增加,所述第二组分的反应性价值随所述灰控制棒的使用时间的增加而减少;所述中子吸收体的反应性价值随所述灰控制棒的使用时间的增加而变化的幅度不大于15%;所述使用时间不大于20年。
- 如权利要求10所述的灰控制棒,其中所述第一组分为金属铽、金属镨、金属镍,或铽、镨、镍的化合物,或含有铽、镨、镍的合金;所述第二组分为金属银、金属镝、金属铪、金属铒、金属铕,或银、镝、铪、铒、铕、硼的化合物,或含有银、镝、铪、铒、铕的合金。
- 如权利要求11所述的灰控制棒,其中所述中子吸收体为铽镝合金,或氧化铽和氧化镝的混合物的烧结块,或钛酸镝和钛酸铽的混合物的烧结块。
- 如权利要求12所述的灰控制棒,其中所述中子吸收体为圆柱体,圆柱体的直径为D,1.0mm≤D≤8.7mm,D的单位为毫米;所述中子吸收体中铽元素的质量百分比为x,-0.0688×D+0.6388≤x≤-0.0026×D+0.8626;所述中子吸收体的反应性价值随所述灰控制棒的使用时间的增加而变化的幅度不大于10%。
- 如权利要求13所述的灰控制棒,其中所述中子吸收体中,-0.0571×D+0.7371≤x≤0.0039×D+0.7261;所述中子吸收体的反应性价值随所述灰控制棒的使用时间的增加而变化的幅度不大于5%。
- 如权利要求13或14所述的灰控制棒,其中1.3mm≤D≤3.3mm。
- 如权利要求15所述的灰控制棒,其中1.8mm≤D≤3.0mm。
- 如权利要求16所述的灰控制棒,其中D=2mm;x=70%;所述中子吸收体的反应性价值随所述灰控制棒的使用时间的增加而变化的幅度不大于2.8%。
- 一种灰控制棒组件,包括多个灰控制棒,所述各个灰控制棒皆包括圆柱形的包壳管和用于封闭所述包壳管的两端的上端塞和下端塞,所述包壳管内封装有中子吸收体,其特征在于,所述中子吸收体包括至少一种第一组分和至少一种第二组分,所述第一组分的反应性价值随所述灰控制棒组件的使用时间的增加而增加,所述第二组分的反应性价值随所述灰控制棒组件的使用时间的增加而减少;所述中子吸收体的反应性价值随所述灰控制棒组件的使用时间的增加而变化的幅度不大于15%;所述使用时间不大于20年。
- 如权利要求18所述的灰控制棒组件,其中所述第一组分为金属铽、金属镨、金属镍,或铽、镨、镍的化合物,或含有铽、镨、镍的合金;所述第二组分为金属银、金属镝、金属铪、金属铒、金属铕,或银、镝、铪、铒、铕、硼的化合物,或含有银、镝、铪、铒、铕的合金。
- 如权利要求19所述的灰控制棒组件,其中所述中子吸收体为铽镝合金,或氧化铽和氧化镝的混合物的烧结块,或钛酸镝和钛酸铽的混合物的烧结块;所述中子吸收体为圆柱体,圆柱体的直径为D,1.0mm≤D≤8.7mm,D的单位为毫米;所述中子吸收体中铽元素的质量百分比为x,-0.0688×D+0.6388≤x≤-0.0026×D+0.8626;所述中子吸收体的反应性价值随所述灰控制棒组件的使用时间的增加而变化的幅度不大于10%。
- 如权利要求20所述的灰控制棒组件,其中所述中子吸收体中,-0.0571×D+0.7371≤x≤0.0039×D+0.7261;所述中子吸收体的反应性价值随所述灰控制棒组件的使用时间的增加而变化的幅度不大于5%。
- 如权利要求20或21所述的灰控制棒组件,其中1.3mm≤D≤3.3mm。
- 如权利要求22所述的灰控制棒组件,其中1.8mm≤D≤3.0mm。
- 如权利要求23所述的灰控制棒组件,其中D=2mm;x=70%;所述中子吸收体的反应性价值随所述灰控制棒组件的使用时间的增加而变化的幅度不大于2.8%。
Priority Applications (5)
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US15/031,865 US10650930B2 (en) | 2013-10-25 | 2013-10-25 | Gray control rod having a neutron absorber comprising terbium and dysprosium |
PCT/CN2013/085971 WO2015058408A1 (zh) | 2013-10-25 | 2013-10-25 | 一种灰控制棒及其中子吸收体和组件 |
GB1608739.7A GB2535391B (en) | 2013-10-25 | 2013-10-25 | Gray control rod and neutron absorber thereof, and gray control rod assembly |
BR112016009175-2A BR112016009175B1 (pt) | 2013-10-25 | 2013-10-25 | Barra de controle cinza possuindo um absorverdor de nêutrons compreendendo térbio e disprósio |
ZA2016/03538A ZA201603538B (en) | 2013-10-25 | 2016-05-24 | Gray control rod having a neutron absorber comprising terbium and dysprosium. |
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PCT/CN2013/085971 WO2015058408A1 (zh) | 2013-10-25 | 2013-10-25 | 一种灰控制棒及其中子吸收体和组件 |
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BR (1) | BR112016009175B1 (zh) |
GB (1) | GB2535391B (zh) |
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Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
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US3185652A (en) * | 1960-04-29 | 1965-05-25 | Nuclear Corp Of America | Refractory rare earth material |
EP0055371A1 (en) * | 1980-12-27 | 1982-07-07 | Kabushiki Kaisha Toshiba | Neutron absorber, neutron absorber assembly utilizing the same, and other uses thereof |
JPS61159191A (ja) * | 1984-12-30 | 1986-07-18 | 株式会社東芝 | 高速増殖炉用制御棒 |
CN101369468A (zh) * | 2007-08-17 | 2009-02-18 | 西屋电气有限责任公司 | 核反应堆鲁棒灰控制棒 |
CN101504872A (zh) * | 2008-02-08 | 2009-08-12 | 西屋电气有限责任公司 | 先进灰棒控制组件 |
CN102915772A (zh) * | 2012-04-27 | 2013-02-06 | 上海核工程研究设计院 | 一种长寿命灰控制棒及吸收体 |
CN102915773A (zh) * | 2012-04-27 | 2013-02-06 | 上海核工程研究设计院 | 一种灰控制棒及吸收体 |
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US3280329A (en) * | 1962-08-08 | 1966-10-18 | Dow Chemical Co | Process for controlling thermal neutron concentration in an irradiated system |
US3423375A (en) * | 1963-11-29 | 1969-01-21 | Dow Chemical Co | Neutron radiation sorbers |
US3891852A (en) * | 1972-11-03 | 1975-06-24 | Agfa Gevaert Nv | Neutron detection and radiography |
US5112534A (en) * | 1990-03-05 | 1992-05-12 | The United States Of America As Represented By The United States Department Of Energy | Yttrium and rare earth stabilized fast reactor metal fuel |
-
2013
- 2013-10-25 US US15/031,865 patent/US10650930B2/en not_active Expired - Fee Related
- 2013-10-25 GB GB1608739.7A patent/GB2535391B/en not_active Expired - Fee Related
- 2013-10-25 WO PCT/CN2013/085971 patent/WO2015058408A1/zh active Application Filing
- 2013-10-25 BR BR112016009175-2A patent/BR112016009175B1/pt active IP Right Grant
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2016
- 2016-05-24 ZA ZA2016/03538A patent/ZA201603538B/en unknown
Patent Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3185652A (en) * | 1960-04-29 | 1965-05-25 | Nuclear Corp Of America | Refractory rare earth material |
EP0055371A1 (en) * | 1980-12-27 | 1982-07-07 | Kabushiki Kaisha Toshiba | Neutron absorber, neutron absorber assembly utilizing the same, and other uses thereof |
JPS61159191A (ja) * | 1984-12-30 | 1986-07-18 | 株式会社東芝 | 高速増殖炉用制御棒 |
CN101369468A (zh) * | 2007-08-17 | 2009-02-18 | 西屋电气有限责任公司 | 核反应堆鲁棒灰控制棒 |
CN101504872A (zh) * | 2008-02-08 | 2009-08-12 | 西屋电气有限责任公司 | 先进灰棒控制组件 |
CN102915772A (zh) * | 2012-04-27 | 2013-02-06 | 上海核工程研究设计院 | 一种长寿命灰控制棒及吸收体 |
CN102915773A (zh) * | 2012-04-27 | 2013-02-06 | 上海核工程研究设计院 | 一种灰控制棒及吸收体 |
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US10650930B2 (en) | 2020-05-12 |
GB201608739D0 (en) | 2016-06-29 |
GB2535391B (en) | 2020-07-29 |
BR112016009175A2 (zh) | 2017-08-01 |
ZA201603538B (en) | 2022-05-25 |
GB2535391A (en) | 2016-08-17 |
BR112016009175B1 (pt) | 2021-12-14 |
US20160268008A1 (en) | 2016-09-15 |
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