Rotary device for nuclear power facility

Abstract

A rotary device for a nuclear power facility, the rotary device being placed in a circuit for coolant containing radioactive nuclides in the nuclear power facility. The rotary device includes: a casing; and a rotary mechanism provided with, in the casing, a rotor and a rotor shaft that come into contact with the coolant containing the radioactive nuclides passing through the casing. Regarding the casing and the rotary mechanism, at least the rotor and the rotor shaft of the rotary mechanism comprise a low-effective diffusion coefficient alloy having a lower effective diffusion coefficient than a polycrystalline alloy.

Claims

1. A rotary device for a nuclear power facility, the rotary device being placed in a circuit for primary cooling helium containing radioactive nuclides in the nuclear power facility, the rotary device comprising: a casing; and a rotary mechanism provided with, in the casing, a rotor and a rotor shaft that come into contact with the primary cooling helium containing the radioactive nuclides passing through the casing, wherein regarding the casing and the rotary mechanism, at least the rotor and the rotor shaft of the rotary mechanism are made of a monocrystalline material which suppresses deep diffusion of the radioactive nuclides into the rotor and the rotor shaft of the rotary mechanism.

2. A rotary device for a nuclear power facility, the rotary device being placed in a circuit for coolant containing radioactive nuclides in the nuclear power facility, the rotary device comprising: a casing; and a rotary mechanism provided with, in the casing, a rotor and a rotor shaft that come into contact with the coolant containing the radioactive nuclides passing through the casing, wherein regarding the casing and the rotary mechanism, at least the rotor and the rotor shaft of the rotary mechanism are composed of an Ni-base alloy doped with an element having a lower lattice diffusion coefficient than Ni to reduce the lattice diffusion coefficient of the Ni-base alloy.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a schematic diagram showing a cooling circuit for a nuclear power plant including a rotary device for a nuclear power facility according to an embodiment of the present disclosure.

(2) FIG. 2 is a side explanatory drawing showing a cross section of a rotary mechanism part of the rotary device shown in FIG. 1.

(3) FIG. 3 is a graph showing the effect of the rotary device for the nuclear power facility according to the embodiment.

(4) FIG. 4 is a graph showing the effect of a rotary device for a nuclear power facility according to another embodiment.

(5) FIG. 5 is a schematic diagram showing crystal grains and crystal boundaries near the surface of a polycrystalline alloy.

DESCRIPTION OF EMBODIMENTS

(6) The present disclosure will be described below with reference to the accompanying drawings.

(7) FIGS. 1 and 2 show an embodiment of a rotary device for a nuclear power facility according to the present disclosure. In this embodiment, the rotary device for the nuclear power facility according to the present disclosure is used as a circulator for a nuclear power plant for explanation as an example.

(8) As shown in FIG. 1, the nuclear power plant includes a primary cooling circuit (circuit) 2 that circulates primary cooling helium, which acts as coolant containing radioactive nuclides, between a high-temperature reactor 1 and a heat exchanger 3, and a secondary cooling circuit 4 that circulates secondary cooling helium, which acts as a power generating fluid, between the heat exchanger 3 and a power generation facility (not shown).

(9) In this nuclear power plant, the primary cooling helium circulating through the primary cooling circuit 2 transmits high-temperature heat (about 950 C.), which is generated by nuclear fission in nuclear fuel in the high-temperature reactor 1, to the heat exchanger 3. In the heat exchanger 3, the heat of the primary cooling helium is transferred to the secondary cooling helium circulating through the secondary cooling circuit 4, and the heat transferred to the secondary cooling helium is transmitted to the power generation facility to generate power.

(10) A circulator (rotary device) 10 used in such a nuclear power plant accelerates the primary cooling helium in the primary cooling circuit 2 between the high-temperature reactor 1 and the heat exchanger 3 after heat is transferred to the secondary cooling helium, and then the circulator 10 returns the primary cooling helium to the high-temperature reactor 1. As shown in FIG. 2, the circulator 10 includes a casing 11 having an inlet 11a and an outlet 11b, an impeller (rotor) 12 accommodated in the casing 11, and a motor 13.

(11) The impeller 12 is fixed to an output shaft 13a (rotor shaft) of the motor 13 and constitutes a rotary mechanism with the output shaft 13a. The impeller 12 rotates in response to the output of the motor 13, accelerates the primary cooling helium introduced into the casing 11 through the inlet 11a of the casing 11 from the heat exchanger 3, and discharges the helium to the high-temperature reactor 1 from the outlet 11b.

(12) In this case, regarding the casing 11 and the rotary mechanism of the circulator 10, at least the impeller 12 and the output shaft 13a of the rotary mechanism comprise a low-effective diffusion coefficient alloy having a lower effective diffusion coefficient than a polycrystalline alloy (normally-grained crystalline material), that is, a coarsely-grained crystalline material with a larger grain size to have a lower effective diffusion coefficient prepared by reducing a cooling speed in solidification of molten metal or performing heat treatment.

(13) In this case, regarding the casing 11 and the rotary mechanism of the circulator 10, at least the impeller 12 and the output shaft 13a of the rotary mechanism may be made of a monocrystalline material having a lower effective diffusion coefficient prepared by solidifying molten metal from its one end in one direction.

(14) In the circulator 10 according to the present embodiment, the radioactive nuclides of a fission product generated in the high-temperature reactor 1 and a radioactive corrosion product generated by corrosion of a core internal-structure material may be contained in the primary cooling helium and may be introduced into the casing 11 so as to be deposited in contact with the impeller 12 and the output shaft 13a of the rotary mechanism. Even in this case, the impeller 12 and the output shaft 13a of the rotary mechanism are made of a coarsely-grained crystalline material or a monocrystalline material having a lower effective diffusion coefficient than a polycrystalline alloy (normally-grained crystalline material), which can suppress deep diffusion of radioactive nuclides into the impeller 12 and the output shaft 13a of the rotary mechanism.

(15) This can reduce the cost of maintenance. Additionally, the impeller 12 and the output shaft 13a of the rotary mechanism are hardly contaminated by radioactive nuclides, thereby reducing the amount of radioactive waste during the dismantlement of the facility.

(16) The content of radioactive nuclides in the use of a polycrystalline alloy (normally-grained crystalline material) for the impeller 12 and the output shaft 13a of the rotary mechanism of the circulator 10 was compared with the content of radioactive nuclides in the use of the coarsely-grained crystalline material described above. As shown in the graph of FIG. 3, in the case of using a polycrystalline alloy (normally-grained crystalline material), radioactive nuclides are deeply diffused from the surface of the impeller 12 or the output shaft 13a, whereas in the case of using a coarsely-grained crystalline material, radioactive nuclides are not deeply diffused.

(17) In the case of using a monocrystalline material with an effective diffusion coefficient reduced to one hundredth of that of a polycrystalline alloy (normally-grained crystalline material), in particular, it is found that the content of radioactive nuclides in a deep portion is reduced to one tenth.

(18) This proved that the circulator 10 according to this embodiment can prevent radioactive nuclides from deeply diffusing into the impeller 12 and the output shaft 13a of the rotary mechanism.

(19) In the embodiment described above, the impeller 12 and the output shaft 13a of the rotary mechanism are made of a coarsely-grained crystalline material or a monocrystalline material having a lower effective diffusion coefficient than that of a polycrystalline alloy (normally-grained crystalline material). According to another embodiment, the impeller 12 and the output shaft 13a of the rotary mechanism may be made of a lattice diffusion coefficient reducing material prepared by doping Ni with an element having a lower lattice diffusion coefficient than Ni. According to still another embodiment, a coarsely-grained crystalline material containing a monocrystalline material having a lower effective diffusion coefficient may be combined with a lattice diffusion coefficient reducing material prepared by doping Ni with an element having a lower lattice diffusion coefficient than Ni.

(20) The content of radioactive nuclides in the use of a polycrystalline alloy (normally-grained crystalline material) for the impeller 12 and the output shaft 13a of the rotary mechanism of the circulator 10 was compared with the content of radioactive nuclides in the use of the reduced lattice diffusion coefficient material according to the another embodiment. As shown in the graph of FIG. 4, in the case of using a polycrystalline alloy (normally-grained crystalline material), radioactive nuclides are deeply diffused from the surface of the impeller 12 or the output shaft 13a, whereas in the case of using a lattice diffusion coefficient reducing material, radioactive nuclides are not deeply diffused.

(21) This proved that the circulator 10 according to this embodiment can prevent radioactive nuclides from deeply diffusing into the impeller 12 and the output shaft 13a of the rotary mechanism.

(22) In the embodiment described above, the rotary device for the nuclear power facility according to the present disclosure is used as a circulator for a nuclear plant for explanation as an example. The present disclosure is not limited to this configuration and is also applicable to a centrifugal circulator (pump), an axial-flow circulator (pump), a steam turbine, a gas turbine, or a gas compressor in a nuclear fuel reprocessing facility or a nuclear fuel fabrication facility.

(23) In the embodiment described above, a low-effective diffusion coefficient alloy having a lower effective diffusion coefficient than that of a polycrystalline alloy is used only for the impeller 12 and the output shaft 13a of the rotary mechanism. The present disclosure is not limited to this configuration. In another configuration, a low-effective diffusion coefficient alloy having a lower effective diffusion coefficient than that of a polycrystalline alloy is also applicable to the casing 11.

(24) The configuration of the rotary device for the nuclear power facility according to the present disclosure is not limited to the configuration of the embodiment described above. For example, the rotor of the rotary mechanism may be a blade or the rotary mechanism may include a turbine disc, a bearing, or a sealing member.

(25) A first aspect of the present disclosure is a rotary device for a nuclear power facility, the rotary device being placed in a circuit for coolant containing radioactive nuclides in the nuclear power facility, the rotary device including a casing and a rotary mechanism provided with, in the casing, a rotor and a rotor shaft that come into contact with the coolant containing the radioactive nuclides passing through the casing. Regarding the casing and the rotary mechanism, at least the rotor and the rotor shaft of the rotary mechanism comprise a low-effective diffusion coefficient alloy having a lower effective diffusion coefficient than a polycrystalline alloy (normally-grained crystalline material).

(26) According to a second aspect of the present disclosure, the low-effective diffusion coefficient alloy is a coarsely-grained crystalline material containing a monocrystalline material with a larger grain size to have a lower effective diffusion coefficient than the polycrystalline alloy.

(27) According to a third aspect of the present disclosure, the low-effective diffusion coefficient alloy is a lattice diffusion coefficient reducing material prepared by doping Ni with an element having a lower lattice diffusion coefficient than Ni.

(28) According to a fourth embodiment of the present disclosure, the low-effective diffusion coefficient alloy is a combination of a coarsely-grained crystalline material containing a monocrystalline material with a larger grain size to have a lower effective diffusion coefficient than the polycrystalline alloy and a lattice diffusion coefficient reducing material prepared by doping Ni with an element having a lower lattice diffusion coefficient than Ni.

(29) In the rotary device for the nuclear power facility according to the present disclosure, the nuclear power facility includes a nuclear power plant having a nuclear reactor, a nuclear fuel reprocessing facility, and a fuel fabrication facility.

(30) In the rotary device for the nuclear power facility according to the present disclosure, the rotary device includes a centrifugal circulator (pump), an axial-flow circulator (pump), a steam turbine, a gas turbine, and a gas compressor.

(31) In the rotary device for the nuclear power facility according to the present disclosure, the coolant containing radioactive nuclides may be helium, water, or sodium.

(32) In the rotary device for the nuclear power facility according to the present disclosure, the radioactive nuclides of a fission product generated in the nuclear reactor and a radioactive corrosion product generated by corrosion of a core internal-structure material may be contained in the cooling fluid and may be introduced into the casing so as to be deposited in contact with the impeller and the rotor shaft of the rotary mechanism. Even in this case, regarding the casing and the rotary mechanism, at least the rotor and the rotor shaft of the rotary mechanism are made of a low-effective diffusion coefficient alloy having a lower effective diffusion coefficient than a polycrystalline alloy (normally-grained crystalline material), which can suppress the deep diffusion of radioactive nuclides into the rotor and the rotor shaft of the rotary mechanism.

(33) Additionally, regarding the casing and the rotary mechanism, at least the rotor and the rotor shaft of the rotary mechanism are hardly contaminated by radioactive nuclides, thereby reducing the amount of radioactive waste during the dismantlement of the facility.