Patent Number: 047675934
Section: claims

1. A method of fabricating a pressure vessel comprising the steps of attaching a first inner presure vessel having means defining inlet and outlet openings to a top flange,  placing a second inner pressure vessel, having means defining inlet and outlet opening, concentric with and spaced about said first inner pressure vessel and attaching said second inner pressure vessel to said top flange,  placing an outer pressure vessel, having inlet and outlet openings, concentric with and spaced apart about said second inner pressure vessel and attaching said outer pressure vessel to said top flange,  attaching a generally cylindrical inner inlet conduit and a generally cylindrical inner outlet conduit respectively to said inlet and outlet openings in said first inner pressure vessel,  attaching a generally cylindrical outer inlet conduit and a generally cylindrical outer outlet conduit respectively to said inlet and outlet opening in said second inner pressure vessel,  heating the assembled pressure vessel to a temperature above the melting point of a material selected from the group, lead, tin, antimony, bismuth, potassium, sodium, boron and mixtures thereof,  filling the space between said first inner pressure vessel and said second inner pressure vessel with material selected from said group,  filling the space between said second inner pressure vessel and said outer pressure vessel with material selected from said group, and  pressurizing said material filling said spaces between said pressure vessels to a predetermined pressure, said step comprising  pressurizing said spaces to a pressure whereby the wall of said first inner pressure vessel is maintained in compression during steady state operation of said pressure vessel.  heating said outer pressure vessel to a temperature higher than the temperature of said first inner pressure vessel to define a temperature gradient across said first inner, second inner and outer pressure vesels, the temperature between said first inner and said second inner pressure vessels being higher than the melting point of a first filler material selected from said group,  filling the space between said first inner and said second inner pressure vessels with said first molten material selected from said group and then pressurizing said molten material to pre-stress said first inner pressure vessel,  lowering said temperature gradient between said first inner and second inner pressure vessels to below the melting point of said first filler material in said space between said first inner and said second inner pressure vessels, with the temperature gradient between said second inner and said outer pressure vessels above the melting point of said first filler material,  filling the space between said second inner and said outer pressure vessels filled with said first molten material selected from said group and the pressurizing said molten material to pre-stress said second inner pressure vessel,  lowering the temperature gradient between said second inner and said outer pressure vessels to below the melting point of said first filler material in said space between said second inner and said outer pressure vessels.  heating said first inner, second inner and outer pressure vessels to a uniform temperature above the melting point of a first filler material selected from said group of filler materials,  filling the space between said first inner and said second inner pressure vessels with said first molten material selected from said group and pressurizing said molten material to pre-stress said first inner pressure vessel,  lowering said temperature of said first inner, second inner and said outer pressure vessels to below the melting point of said first filler material in said space between said first inner and second inner pressure vessels, and above the melting point of a second filler material selected from said group,  filling the space between said second inner pressure vessel and said outer pressure vessel with said second molten material selected from said group and pressurizing said molten material to pre-stress said second inner pressure vessel,  lowering the temperature of said first inner, second inner and outer pressure vessels to below the melting point of said second material in said space between said second inner and said outer pressure vessels.  a top flange,  a pressure vessel head adapted to engage said top flange, be connected thereto and maintain a seal therebetween,  an inner pressure vessel attached to said top flange,  an outer pressure vessel disposed concentric about said inner pressure vessel, spaced apart therefrom and attached to said top flange,  a reactor coolant inlet port comprising  a generally cylindrical inner inlet conduit attached to said inner pressure vessel and in fluid communication therewith,  a generally cylindrical outer inlet conduit attached to said outer pressure vessel and in fluid communication with the space between said inner pressure vessel and said outer pressure vessel,  a reactor coolant outlet port comprising  a generally cylindrical inner outlet conduit attached to said inner pressure vessel and in fluid communication therewith,  a generally cylindrical outer outlet conduit attached to said outer pressure vessel and in fluid communication with the space between said inner pressure vessel and said outer pressure vessel,  a low melting point, high boiling point material selected from the group, lead, tin, antimony, bismuth, sodium, potassium, boron and mixtures thereof disposed in the space between said inner pressure vessel and said outer pressure vessel, and  means for maintaining said low melting point, high boiling point material at a pressure sufficient to maintain the tensile stresses in the wall of said inner pressure vessel below the yield point of the wall material during transient pressure rises within said pressure vessel, and  means for maintaining said low melting point, high boiling point material at a constant, predetermined multiple of the pressure inside the inner pressure vessel.  said means for maintaining said low melting point, high boiling point material at a constant, predetermined multiple of the pressure inside the inner pressure vessel comprises  a first generally cylindrical bellows closed at one end and having its open end attached to said inner pressure vessel with the interior of said first bellows in fluid communication with the space between said inner pressure vessel and said outer pressure vessel, said first bellows projecting into said inner pressure vessel,  a second generally cylindrical bellows closed at one end disposed concentric about said first bellows and spaced apart therefrom and having its open end attached to the inside surface of said inner pressure vessel, the closed end of said second bellows being in contact with the closed end of said first bellows,  compressible fluid disposed in the space between said first bellows and said second bellows, and  means for maintaining said compressible fluid at a predetermined pressure.  a top flange,  a pressure vessel head adapted to engage said top flange, be connected thereto and maintain a seal therebetween,  an inner pressure vessel attached to said top flange,  an outer pressure vessel disposed concentric about said inner pressure vessel and spaced apart therefrom and attached to said top flange,  a reactor coolant inlet port comprising  a generally cylindrical inner inlet conduit attached to said inner pressure vessel and in fluid communication therewith,  a generally cylindrical outer inlet conduit attached to said outer pressure vessel and in fluid communication with the space between said inner pressure vessel and said outer pressure vessel,  a reactor coolant outlet port comprising  a generally cylindrical inner outlet conduit attached to said inner pressure vessel and in fluid communication therewith,  a generally cylindrical outer outlet conduit attached to said outer pressure vessel and in fluid communication with the space between said inner pressure vessel and said outer pressure vessel,  a low melting point, high boiling point material selected from the group, lead, tin, antimony, bismuth, sodium, potassium, boron and mixtures thereof disposed in the spaced between said inner pressure vessel and said outer pressure vessel, and  means for maintaining said incompressible fluid contained in the space between said inner and outer pressure vessel at a predetermined pressure whereby the material of said wall of said inner pressure vessel in maintained in compression during steady state operation of said pressure vessel.  means for maintaining said low melting point, high boiling point material at a constant, predetermined multiple of the pressure inside the inner pressure vessel.  a first generally cylindrical bellows closed at one end and having its open end attached to said inner pressure vessel with the interior of said first bellows in fluid communication with the space between said inner pressure vessel and said outer pressure vessel, said first bellows projecting into said inner pressure vessel,  a second generally cylindrical bellows closed at one end disposed concentric about said first bellows and spaced apart therefrom and having its open end attached to the inside surface of said inner pressure vessel, the closed end of said second bellows being in contact with the closed end of said first bellows,  compressible fluid disposed in the space between said first bellows and said second bellows, and  means for maintaining said compressible fluid at a predetermined pressure.  a top flange,  a pressure vessel head adapted to engage said top flange, be connected thereto and maintain a seal therebetween,  a first inner pressure vessel attached to said top flange,  a second inner pressure vessel disposed concentric about said first inner pressure vessel and spaced apart therefrom and attached to said top flange,  an outer pressure vessel disposed concentric about said second inner pressure vessel and spaced apart therefrom and attached to said top flange,  a reactor coolant inlet port comprising  a generally cylindrical inner inlet conduit attached to said first inner pressure vessel and in fluid communication therewith,  a generally cylindrical outer inlet conduit attached to said second inner pressure vessel and in fluid communication with the space between said first inner pressure vessel and said second inner pressure vessel,  a reactor coolant outlet port comprising  a generally cylindrical inner outlet conduit attached to said first inner pressure vessel and in fluid communication therewith,  a generally cylindrical outer outlet conduit attached to said second inner pressure vessel and in fluid communication with the space between said first inner pressure vessel and said second inner pressure vessel,  a low melting point, high boiling point material selected from the gorup, lead, tin, antimony, bismuth, sodium, potassium, boron and mixtures thereof disposed in the space between said first inner pressure vessel and said second inner pressure vessel, and between said second inner pressure vessel and said outer pressure vessel, and  means for maintaining said low melting point, high boiling point material at a pressure sufficient to maintain the tensile stresses in the wall of said inner pressure vessel below the yield point of the material of said wall during transient pressure rises within said pressure vessel, and  means for maintaining said low melting point, high boiling point material at a constant, predetermined multiple of the pressure inside the inner pressure vessel.  said means for maintaining said low melting point, high boiling point material at a constant, predetermined multiple of the pressure inside the inner pressure vessel comprises  a first generally cylindrical bellows closed at one end and having its open end attached to said inner pressure vessel with the interior of said first bellows in fluid communication with the space between said inner pressure vessel and said outer pressure vessel, said first bellows projecting into said inner pressure vessel,  a second generally cylindrical bellows closed at one end disposed concentric about said first bellows and spaced apart therefrom and having its open end attached to the inside surface of said inner pressure vessel, the closed end of said second bellows being in contact with the closed end of said first bellows,  compressible fluid disposed in the space between said first bellows and said second bellows, and  means for maintaining said compressible fluid at a predetermined pressure.  a top flange,  a pressure vessel head adapted to engage said top flange, be connected thereto and maintain a seal therebetween,  a first inner pressure vessel attached to said top flange,  a second inner pressure vessel disposed concentric about said first inner pressure vessel and spaced apart therefrom and attached to said top flange,  an outer pressure vessel disposed concentric about said second inner pressure vessel and spaced apart therefrom and attached to said top flange,  a reactor coolant inlet port comprising  a generally cylindrical inner inlet conduit attached to said first inner pressure vessel and in fluid communication therewith,  a generally cylindrical outer inlet conduit attached to said second inner pressure vessel and in fluid communication with the space between said first inner pressure vessel and said second inner pressure vessel,  a reactor coolant outlet port comprising  a generally cylindrical inner outlet conduit attached to said first inner pressure vessel and in fluid communication therewith,  a generally cylindrical outer outlet conduit attached to said second inner pressure vessel and in fluid communication with the space between said first inner pressure vessel and said second inner pressure vessel,  a low melting point, high boiling point material selected from the group, lead, tin, antimony, bismuth, sodium, potassium, boron and mixtures thereof disposed in the spaced between said first inner pressure vessel and said second inner pressure vessel, and between said second inner pressure vessel and said outer pressure vessel, and  means for maintaining said incompressible fluid contained in the space between said inner and second inner pressure vessel at a predetermined pressure whereby the material of said wall of said inner pressure vessel in maintained in compression during steady state operation of said pressure vessel.  means for maintaining said low melting point, high boiling point material at a constant, predetermined multiple of the pressure inside the inner pressure vessel.  said means for maintaining said low melting point, high boiling point material at a constant, predetermined multiple of the pressure inside the inner pressure vessel comprises  a first generally cylindrical bellows closed at one end and having its open end attached to said inner pressure vessel with the interior of said first bellows in fluid communication with the space between said inner pressure vessel and said outer pressure vessel, said first bellows projecting into said inner pressure vessel,  a second generally cylindrical bellows closed at one end disposed concentric about said first bellows and spaced apart therefrom and having its open end attached to the inside surface of said inner pressure vessel, the closed end of said second bellows being in contact with the closed end of said first bellows,  compressible fluid disposed in the space between said first bellows and said second bellows, and  means for maintaining said compressible fluid at a predetermined pressure.  means for detecting leakage of fluid from within said first inner pressure vessel disposed in the spaces between said first inner pressure vessel and said outer pressure vessel.  a leak detection channel disposed about the inner periphery of said outer pressure vessel proximate the welded connections thereof to other parts thereof, and  a conduit in fluid communication with said leak detection channel and the exterior of said pressure vessel.  a leak detection channel disposed about the outer periphery of said first inner pressure vessel proximate the weled connections thereof to other parts thereof, and  a conduit in fluid communication with said leak detection channel and the exterior of said pressure vessel. 2. The method of fabricating the pressure vessel as claimed in claim 1 further comprising the steps of 3. The method of fabricating the pressure vessel as claimed in claim 1 further comprising the steps of 4. A pressure vessel comprising 5. The pressure vessel as claimed in claim 4 wherein 6. A pressure vessel comprising 7. The pressure vessel as claimed in claim 6 further comprising 8. The pressure vessel as claimed in claim 7 wherein said means for maintaining said low melting point, high boiling point material at a constant, predetermined multiple of the pressure inside the inner pressure vessel comprises 9. A pressure vessel comprising 10. The pressure vessel as claimed in claim 9 wherein 11. A pressure vessel comprising 12. The pressure vessel as claimed in claim 11 further comprising 13. The pressure vessel as claimed in claim 11 wherein 14. The pressure vessel as claimed in claim 11 further comprising 15. The pressure vessel as claimed in claim 14 wherein said means for detecting leakage of fluid comprises 16. The pressure vessel as claimed in claim 14 wherein said means for detecting leakage of fluid comprises