Method and system of increasing wear resistance of a part of a rotating mechanism exposed to fluid flow therethrough

What is claimed is: 1. A method of increasing wear resistance of at least one part of a rotating mechanism, comprising: manufacturing the at least one part of the rotating mechanism with a portion thereof configured to be exposed to wear during fluid flow associated with the rotating mechanism having a dimension different from that of a final dimension by a thickness of a protective coating to be applied thereon; melting the protective coating of an aluminum bronze alloy to the portion having the different dimension through welding deposition, the aluminum bronze alloy having a chemical composition of 6-10% aluminum and 9.5-18% of a plurality of metals including manganese, iron and nickel, with copper constituting a remaining chemical composition thereof, and the welding being one of: Metal Inert Gas welding and Metal Active Gas welding; mechanically treating the melted protective coating; applying at least one layer of solid-alloy over the mechanically treated melted protective coating through electro-erosion deposition, the electro-erosion involving: maintaining a micro-solidness of the at least one layer of solid-alloy by constraining the percentage of cobalt between 6-12%, minimizing a fragility of the at least one layer of solid-alloy by constraining the percentage of cobalt between 6-12%, utilizing an electrode made of the solid alloy having a chemical composition of 6-12% cobalt and 88-94% carbides of a plurality of metals including tungsten carbide, chromium carbide and vanadium carbide, and transferring particles of the solid alloy onto the mechanically treated melted protective coating in accordance with the utilization of the electrode; and continuing the mechanical treatment of at least one of the melted protective coating and the applied at least one layer of the solid-alloy after the solid-alloy deposition to obtain the final dimension of the portion. 2. The method of claim 1 , comprising applying a plurality of layers of the solid-alloy over the mechanically treated melted protective coating through the electro-erosion deposition. 3. The method of claim 2 , comprising applying the plurality of layers such that one of: each layer of the plurality of layers of the solid-alloy has a same chemical composition, and one layer of the plurality of layers of the solid-alloy has a chemical composition different from at least one other layer of the plurality of layers of the solid-alloy. 4. The method of claim 1 , comprising performing the welding deposition through an electric arc. 5. The method of claim 1 , wherein the rotating mechanism is a centrifugal pump, and wherein the part of the rotating mechanism is one of: an impeller and a seal ring of the centrifugal pump. 6. A part of a rotating mechanism having increased wear resistance to fluid flow associated with the rotating mechanism comprising: a portion configured to be exposed to wear during the fluid flow associated with the rotating mechanism, the portion being manufactured to have a dimension different from that of a final dimension thereof by a thickness of a protective coating to be applied thereon, and the portion comprising: a protective coating of an aluminum bronze alloy melted on the portion having the different dimension through welding deposition, the aluminum bronze alloy having a chemical composition of 6-10% aluminum 9.5-18% of a plurality of metals including manganese, iron and nickel, with copper constituting a remaining chemical composition thereof, the welding being one of: Metal Inert Gas welding and Metal Active Gas welding, and the melted protective coating being mechanically treated after the welding deposition, and at least one layer of solid-alloy applied over the mechanically treated melted protective coating through an electro-erosion deposition process, the electro-erosion involving: maintaining a micro-solidness of the at least one layer of solid-alloy by constraining the percentage of cobalt between 6-12%, minimizing a fragility of the at least one layer of solid-alloy by constraining the percentage of cobalt between 6-12%, utilization of an electrode made of the solid alloy having a chemical composition of 6-12% cobalt and 88-94% carbides of a plurality of metals including tungsten carbide, chromium carbide and vanadium carbide, and transfer of particles of the solid alloy onto the mechanically treated melted protective coating in accordance with the utilization of the electrode, wherein the mechanical treatment of at least one of the melted protective coating and the at least one layer of the solid-alloy is continued after the solid-alloy deposition to obtain the final dimension of the portion. 7. The part of claim 6 , wherein the portion includes a plurality of layers of the solid-alloy deposited over the mechanically treated melted protective coating through the electro-erosion deposition process. 8. The part of claim 7 , wherein the plurality of layers is deposited such that one of: each layer of the plurality of layers of the solid-alloy has a same chemical composition, and one layer of the plurality of layers of the solid-alloy has a chemical composition different from at least one other layer of the plurality of layers of the solid-alloy. 9. The part of claim 6 , wherein the welding deposition of the aluminum-bronze alloy is performing using an electric arc. 10. The part of claim 6 , wherein the part of the rotating mechanism is one of: an impeller and a seal ring of a centrifugal pump. 11. A rotating mechanism, comprising: a part having an increased wear resistance to fluid flow associated with the rotating mechanism, the part comprising: a portion configured to be exposed to wear during the fluid flow associated with the rotating mechanism, the portion being manufactured to have a dimension different from that of a final dimension thereof by a thickness of a protective coating to be applied thereon, and the portion comprising: a protective coating of an aluminum bronze alloy melted on the portion having the different dimension through welding deposition, the aluminum bronze alloy having a chemical composition of 6-10% aluminum and 9.5-18% of a plurality of metals including manganese, iron and nickel, with copper constituting a remaining chemical composition thereof, the welding being one of: Metal Inert Gas welding and Metal Active Gas welding, and the melted protective coating being mechanically treated after the welding deposition, and at least one layer of solid-alloy applied over the mechanically treated melted protective coating through an electro-erosion deposition process, the electro-erosion involving: maintaining a micro-solidness of the at least one layer of solid-alloy by constraining the percentage of cobalt between 6-12%, minimizing a fragility of the at least one layer of solid-alloy by constraining the percentage of cobalt between 6-12%, utilization of an electrode made of the solid alloy having a chemical composition of 6-12% cobalt and 88-94% carbides of a plurality of metals including tungsten carbide, chromium carbide and vanadium carbide, and transfer of particles of the solid alloy onto the mechanically treated melted protective coating in accordance with the utilization of the electrode, wherein the mechanical treatment of at least one of the melted protective coating and the at least one layer of the solid-alloy is continued after the solid-alloy deposition to obtain the final dimension of the portion. 12. The rotating mechanism of claim 11 , wherein the portion includes a plurality of layers of the solid-alloy deposited over the mechanically treated melted protective coating through the electro-erosion depositi