Abstract: A control rod drive apparatus may include a cylindrical housing structure having a proximal end and an opposing distal end. A drive assembly including a drive piston and an index tube may be arranged within the cylindrical housing structure. A flange may be connected to the proximal end of the cylindrical housing structure and may define a vacancy therein. A check valve ball may be disposed within the vacancy, wherein the vacancy may be configured to facilitate a displacement of the check valve ball between an open position and a closed position. The control rod drive apparatus may also include a collet assembly within the cylindrical housing structure. The check valve ball and/or the collet assembly may be made of an alloy having less than 2% cobalt by weight.

Abstract: Example embodiments relate to a method and apparatus for reducing electrostatic deposition of charged particles on wetted surfaces that are exposed, periodically or substantially continuously, to high velocity fluid flow within a coolant flow path in a nuclear reactor. The method may include depositing a first or base dielectric layer and a second or outer dielectric layer on a conductive surface that forms a portion of a high velocity flow path to attain the apparatus. The first dielectric layer material is selected to provide improved adhesion and insulation to the conductive surface and the second dielectric layer material is selected to provide suitable adhesion to the first dielectric layer and improved corrosion and/or mechanical resistance in the anticipated operating environment.

Abstract: Example embodiments relate to a method and apparatus for reducing electrostatic deposition of charged particles on wetted surfaces that are exposed, periodically or substantially continuously, to high velocity fluid flow within a coolant flow path in a nuclear reactor. The method may include depositing a first or base dielectric layer and a second or outer dielectric layer on a conductive surface that forms a portion of a high velocity flow path to attain the apparatus. The first dielectric layer material is selected to provide improved adhesion and insulation to the conductive surface and the second dielectric layer material is selected to provide suitable adhesion to the first dielectric layer and improved corrosion and/or mechanical resistance in the anticipated operating environment.

Abstract: A slip joint of the jet pump assembly inlet-mixer is the interface between a diffuser and an inlet-mixer. The diffuser is coated with a first hardfacing alloy, and the inlet-mixer is coated with a second hardfacing alloy different from the first hardfacing alloy. The first hardfacing alloy may be a cobalt-based alloy and the second hardfacing alloy may be a cobalt-free alloy, i.e., at least one of an iron-based and nickel-based hardfacing alloy.

Abstract: A method of protecting a reactor component from fouling includes forming an oxide layer on a metal foil to achieve an antifouling liner. The antifouling liner may be manipulated into a shape that conforms to one or more surfaces of the reactor component that are contacted by a fluid during reactor operation. The metal foil portion of the antifouling liner is secured to the surface(s) of the reactor component by suitable means. As a result, the oxide layer portion of the antifouling liner is exposed to the fluid in the reactor, thereby reducing or preventing the fouling of the component.

Abstract: A method of forming an oxide coating for reducing the accumulation of radioactive species on a metallic surface exposed to fluids containing charged particles is disclosed. The method includes preparing an aqueous colloidal suspension containing about 0.5 to about 35 weight percent of nanoparticles that contain at least one of titania and zirconia, and about 0.1% to about 10% 2-[2-(2-methoxyethoxy)ethoxy]acetic acid (C7H14O5) or polyfluorosufonic acid in water, depositing the aqueous colloidal suspension on the metallic surface, drying the aqueous colloidal suspension to form a green coating, and then heating the green coating to a temperature of up to 500° C. to densify the green coating to form an oxide coating having a zeta potential less than or equal to the electrical polarity of the charged particles so as to minimize deposition of the charged particles on the metallic surface. The nanoparticles have a diameter of up to about 200 nanometers.

Abstract: Disclosed is a method for reducing electrostatic deposition of charged particles on wetted surfaces that are exposed, periodically or substantially continuously to high velocity fluid flow within a coolant flow path in a nuclear reactor. The method includes depositing a first or base dielectric layer and a second or outer dielectric layer on a conductive surface that forms a portion of a high velocity flow path. The first dielectric layer material is selected to provide improved adhesion and insulation to the conductive surface and the second dielectric layer material is selected to provide suitable adhesion to the first dielectric layer and improved corrosion and/or mechanical resistance in the anticipated operating environment.

Abstract: A method of protecting a reactor component from fouling includes forming an oxide layer on a metal foil to achieve an antifouling liner. The antifouling liner may be manipulated into a shape that conforms to one or more surfaces of the reactor component that are contacted by a fluid during reactor operation. The metal foil portion of the antifouling liner is secured to the surface(s) of the reactor component by suitable means. As a result, the oxide layer portion of the antifouling liner is exposed to the fluid in the reactor, thereby reducing or preventing the fouling of the component.

Abstract: Method of treating a surface of a steam line plug grip wherein the surface is subjected to chemical vapor deposition (CVD) treatment to introduce a hard oxide material into pores and cracks in the surface.