Stick electrode

The invention claimed is: 1. A modified tip-protected stick electrode comprising an essentially rigid elongated metal rod or wire made from a weld filler metal, the metal rod or wire defining a strike end having an exposed metal tip, a proximal end opposite the strike end and lateral surfaces extending between the strike end and the proximal end, the stick electrode further comprising a protective coating covering the exposed metal tip of the strike end, wherein the protective coating comprises a binder and metal particles, wherein the amount of metal particles in the protective coating is 10-30 wt. % of the protective coating on a dry weight basis, wherein the amount of inorganic binder in the protective coating is 70-90 wt. % of the protective coating on a dry weight basis, wherein the metal particles comprise one of Al particles and Al alloy particles and one of Mg particles and Mg alloy particles, and wherein a weight ratio of the one of Al particles and Al alloy particles to the one of Mg particles and Mg alloy particles is 0.6-2.5. 2. The stick electrode of claim 1 , further comprising a flux coating covering the lateral surfaces of the metal rod or wire. 3. The stick electrode of claim 1 , wherein the metal rod or wire is essentially solid. 4. The stick electrode of claim 3 , wherein the lateral surfaces of the metal rod or wire carry a coating of copper metal. 5. The stick electrode of claim 1 , wherein the metal rod or wire defines a hollow core, the stick electrode further comprising a welding flux in the hollow core. 6. The stick electrode of claim 1 , the binder is inorganic. 7. The stick electrode of claim 6 , wherein the inorganic binder is sodium silicate. 8. The stick electrode of claim 1 , wherein the weight ratio of the one of Al particles and Al alloy particles to the one of Mg particles and Mg alloy particles is 1.0-1.5. 9. The stick electrode of claim 1 , wherein the amount of metal particles in the protective coating is 15-25 wt. % of the protective coating on a dry weight basis, and further wherein the amount in organic binder in the protective coating is 75-85 wt. % of the protective coating on a dry weight basis. 10. The stick electrode of claim 9 , wherein the amount of metal particles in the protective coating is 18-20 wt. % of the protective coating on a dry weight basis, and further wherein the amount in organic binder in the protective coating is 80-82 wt. % of the protective coating on a dry weight basis. 11. A shielded metal arc welding process, comprising: forming a weld metal layer from the stick electrode of claim 2 , wherein forming the weld metal layer comprises forming a molten flux, wherein the molten flux comprises a metal oxide formed from the metal particles and a metal oxide formed from the flux coating comprising the same metal oxide as the metal oxide formed from the metal particles. 12. The stick electrode of claim 1 , wherein the protective coating is essentially free of graphite. 13. The stick electrode of claim 12 , wherein the protective coating is free of added graphite. 14. The stick electrode of claim 1 , wherein the total amount of electrically conductive particles in the protective coating is no greater than 25 wt. % based on the weight of the protective coating on a dry weight basis. 15. The stick electrode of claim 14 , wherein the protective coating is essentially free of graphite. 16. The stick electrode of claim 15 , wherein the protective coating is free of added graphite. 17. The stick electrode of claim 2 , wherein the stick electrode is configured such that, upon welding using the stick electrode in a shielded metal arc welding (SMAW) process, a molten flux is formed, the molten flux comprising a metal oxide formed from the metal particles and a metal oxide formed from the flux coating comprising the same metal oxide as the metal oxide formed from the metal particles. 18. The stick electrode of claim 1 , wherein the metal particles comprise the Al alloy particles that contain at least 80 wt % Al, and comprise the Mg alloy particles that contain at least 80 wt % Mg.