Method of forming sealed refractory joints in metal-containment vessels, and vessels containing sealed joints

The invention claimed is: 1. A vessel for containing molten metal, the vessel formed by two or more refractory vessel sections positioned end to end, wherein each section is formed of a respective section body that is a monolithic trough-shaped part, wherein the vessel includes a sealed joint between adjacent ends of the sections, wherein the sealed joint comprises: a gap between the adjacent vessel sections; a groove within the gap and that extends at least across a bottom of the trough shape of one of the adjacent vessel sections; a mesh body made of metal wires introduced into the gap and located within the groove; and a layer of moldable refractory material overlying the mesh body in the gap and sealing the gap against molten metal penetration between the refractory vessel sections, wherein the mesh body prevents the moldable refractory material from penetrating further in the gap than a lower surface of the groove. 2. The vessel of claim 1 , wherein the mesh body contains a quantity of refractory paste. 3. The vessel of claim 1 , wherein the metal used to form the mesh body is resistant to attack by molten aluminum. 4. The vessel of claim 1 , wherein the metal used to form the mesh body is chosen from the group consisting of Ni—Cr based alloys, stainless steel and titanium. 5. The vessel of claim 1 , wherein the metal wires are woven together to form a woven metal fabric for the mesh body. 6. The vessel of claim 5 , wherein the woven metal fabric has mesh openings having dimensions small enough to resist penetration by molten metal. 7. The vessel of claim 6 , wherein the mesh openings have a size in a range of 1 to 5 mm. 8. The vessel of claim 6 , wherein the mesh openings have a size in a range of 2 to 3 mm. 9. The vessel of claim 1 , wherein the mesh body has a plurality of layers laid one over another. 10. The vessel of claim 9 , wherein the layers of woven metal mesh are rolled up over each other to form an elongated rope. 11. The vessel of claim 10 , wherein the elongated rope is covered with a woven tubular sleeve made of metal. 12. The vessel of claim 11 , wherein the layers of woven metal mesh have mesh openings, and wherein the woven tubular sleeve has mesh openings of the same size or a smaller size than the mesh openings of the one or more layers. 13. The vessel of claim 1 , wherein the moldable refractory material is selected from the group consisting of materials made of silica/alumina and pastes containing aluminosilicate fibers. 14. The vessel of claim 1 , wherein the refractory vessel sections have a molten metal-contacting surface formed therein, and wherein the groove is located beneath the molten metal-contacting surface. 15. The vessel of claim 14 , wherein the mesh body has an uncompressed width wider than the width of the groove. 16. A vessel section for a metal containment vessel, the vessel section comprising a body defining a monolithic trough-shaped part of refractory material and having a metal-contacting surface formed therein, and having a transverse groove at one end of the body, the transverse groove extending across at least the bottom of the trough and having a metal mesh rope pre-positioned in the transverse groove leaving room in the transverse groove for an overlying coating of a moldable refractory material, wherein when vessel sections are placed end to end, the transverse groove is within a gap between the adjacent vessel sections and the metal mesh rope in the transverse groove prevents the moldable refractory material from penetrating further in the gap than a lower surface of the transverse groove. 17. The vessel section of claim 16 , wherein the transverse groove extends at least across a bottom of the trough shape of the vessel section. 18. The vessel section of claim 16 , wherein at least one of: the metal used to form the metal mesh rope is resistant to attack by molten aluminum; the metal used to form the metal mesh rope is chosen from the group consisting of Ni—Cr based alloys, stainless steel and titanium; the metal mesh rope includes metal wires woven together to form a woven metal fabric having mesh openings with dimensions small enough to resist penetration by molten metal; the metal mesh rope has a plurality of layers laid one over another; the metal mesh rope is covered with a woven tubular sleeve made of metal; the transverse groove is located beneath the metal-contacting surface; or the metal mesh rope has an uncompressed width wider than the width of the transverse groove. 19. A vessel section for a metal containment vessel, the vessel section comprising a body of refractory material and having a metal-contacting surface formed therein, and having a transverse groove at one end of the body, the transverse groove extending at least across a bottom of a trough shape of the vessel section and having a metal mesh rope pre-positioned in the transverse groove leaving room in the transverse groove for an overlying coating of a moldable refractory material, wherein when vessel sections are placed end to end, the transverse groove is within a gap between the adjacent vessel sections and the metal mesh rope in the transverse groove prevents the moldable refractory material from penetrating further in the gap than a lower surface of the transverse groove. 20. The vessel of claim 19 , wherein at least one of: the metal used to form the metal mesh rope is resistant to attack by molten aluminum; the metal used to form the metal mesh rope is chosen from the group consisting of Ni—Cr based alloys, stainless steel and titanium; the metal mesh rope includes metal wires woven together to form a woven metal fabric having mesh openings with dimensions small enough to resist penetration by molten metal; the metal mesh rope has a plurality of layers laid one over another; the metal mesh rope is covered with a woven tubular sleeve made of metal; the transverse groove is located beneath the metal-contacting surface; or the metal mesh rope has an uncompressed width wider than the width of the transverse groove.