The present disclosure relates generally to a component and, more particularly, to a component having a cladding surface and a method of applying same.
Commercial slurry pumps contain internal components that are subject to abrasive and erosive wear from interactions between slurry solids and surfaces of the pump components. Over time, the surfaces of the pump components can wear out. In some instances, the surfaces of the components develop gouges from abrasive and erosive interactions with the slurry. To extend the useful life of the slurry pump components, some surfaces of the pump components are coated with wear resistant materials.
Typical wear resistant materials are applied through a cladding process. For example, tungsten carbide disposed in a nickel matrix is clad on surfaces of slurry pump components.
Tungsten carbide in a nickel matrix, however, has a high melting point, which can cause cracks in the base material of the pump component because the base material is heated and cooled rapidly during the cladding process. These cracks can propagate in components that are subject to centrifugal stresses during operation (i.e., impellers and volutes) and ultimately result in catastrophic failure of the pump.
The manufacturing process of the present disclosure solves one or more of the problems set forth above and/or other problems in the art.
In one aspect, the present disclosure is directed toward a slurry pump component. The slurry pump component may include a base member with a cladding surface. The cladding surface may include a brazing alloy inner layer, a ductile intermediate layer and a wear resistant outer layer.
In another aspect, the present disclosure is related to a method of manufacturing a slurry pump component. The method may include laser cladding a brazing alloy inner layer onto a base member surface of the slurry pump component, then laser cladding a ductile intermediate layer over the brazing alloy inner layer. The method may additionally include laser cladding a wear resistant layer over the ductile intermediate layer.
Slurry pump 1 may include a suction plate 8, a cover plate 2, and a frame plate 3, which together may form a slurry pump housing. The slurry pump housing may be formed by mounting suction plate 8 to cover plate 2, and then mounting cover plate 2 to frame plate 3. Inside the slurry pump housing, a throat bush 4 may mount to suction plate 8 at an inlet. Impeller 5 may mount to a shaft 10, which provides the rotational force to move impeller 5. Impeller 5 may reside in a volute 6. As slurry enters throat bush 4 via an opening 11, it may flow into impeller 5 and be pushed by centrifugal force through volute 6 to exit slurry pump 1 through an opening 11 in volute 6. Frame plate liner 7 may be placed between volute 6 and frame plate 3, and a seal 43 may be placed between frame plate liner 7 and frame plate 3 to help keep slurry from leaking out of volute 6. A bearing assembly 9 may help to reduce friction between shaft 10 and the pump housing while impeller 5 is rotating.
Base 12 may include a conical end 17 located axially opposite collar 15. In one embodiment, as shown in
The slurry pump components may be formed from durable materials. For example, throat bush 4, impeller 5, volute 6, and frame plate liner 7 may be made of an iron or steel. In one embodiment, throat bush 4, impeller 5, volute 6, and frame plate liner 7 may be made of white iron. Conical end 17 and inner annular surface 18 of throat bush 4 and axial end 23 of frame plate liner 7 may be covered with a cladding surface to help reduce wear from abrasive and erosive interactions during operation of slurry pump 1. The cladding surface may include a wear resistant material disposed in a tool steel matrix. In one embodiment, the wear resistant material may have a melting point greater than about 3000° C. and be made from at least one of titanium carbide, zirconium carbide, hafnium carbide, or titanium diboride. In another embodiment, the wear resistant material may be spherical or crushed titanium carbide, and be present in an amount between about 30 and 70 percent by volume, with the remainder being tool steel matrix. The wear resistant material morphology may be agglomerated, agglomerated and sintered, water atomized, gas atomized, or mechanically coated (porously coated).
The tool steel matrix may include iron and one or more of carbon, manganese, chromium, cobalt, vanadium, tungsten, silicon, sulfur, nickel, or molybdenum. For example, the tool steel matrix may include iron and a weight percent composition of about 1.6% carbon, about 0.3% manganese, about 4.0% chromium, about 5.0% cobalt, about 4.9% vanadium, about 12.00% tungsten, about 0.30% silicon, and about 0.06% sulfur.
As shown in
All surfaces of impeller 5 and the surface of inner cavity 37 of volute 6 may be covered with a cladding surface 38 to help reduce wear from abrasive and erosive interactions during operation of slurry pump 1. The cladding surface 38 may be multi-layer to inhibit cracking of the base material and help reduce failure of the slurry pump 1 from centrifugal stress. For example, as shown in
In one embodiment, brazing alloy layer 44 may include one or more metals selected from the group consisting of copper, gold, lead, manganese, nickel, phosphorus, silver and tin, and have a melting point of less than 700° C. In another embodiment, ductile intermediate layer 45 may include iron and one or more elements selected from the group consisting of carbon, chromium, copper, magnesium, manganese, nickel, phosphorus and sulfur. In an alternative embodiment, ductile intermediate layer 45 may include a nickel based alloy with a weight composition of about 0 to 30% chromium, 0 to 3% manganese, 0 to 30% molybdenum, 0 to 40% copper, 0 to 40% iron, and a balance of nickel.
Wear resistant layer 46 may include a wear resistant material disposed in a metal matrix. In one embodiment, the wear resistant material may include at least one of tungsten carbide, titanium carbide, zirconium carbide, hafnium. carbide, or titanium diboride. The wear resistant material may be spherical or crushed titanium carbide. In another embodiment, the wear resistant material morphology may be agglomerated, agglomerated and sintered, water atomized, gas atomized, or mechanically coated (porously coated).
In another embodiment, wear resistant layer 46 may include a nickel or tool steel matrix. The tool steel matrix may include iron and one or more of carbon, manganese, chromium, cobalt, vanadium, tungsten, silicon, sulfur, nickel, or molybdenum. In another embodiment, titanium carbide may be present in an amount between about 30 and 70 percent by volume, with the remainder being tool steel matrix. The tool steel matrix may include iron with a weight percent composition of about 1.6% carbon, about 0.3% manganese, about 4.0% chromium, about 5.0% cobalt, about 4.9% vanadium, about 12.00% tungsten, about 0.30% silicon, and about 0.06% sulfur. In another embodiment, the nickel based matrix may include nickel with one or more of chromium, silicon, or boron. Each of brazing alloy layer 44, ductile intermediate layer 45, and wear resistant layer 46 may have a thickness of between about 0.2 mm and 6 mm.
The disclosed components may have use in any slurry pump application or in any other similar application. The configurations of the disclosed components may provide a number of benefits, including haying increased wear resistance and life. A process of manufacturing the wear resistant components will now be described in detail.
The process of manufacturing throat bush 4 and frame plate liner 7 may include laser cladding a base component with a tool steel matrix and at least one of titanium carbide, zirconium carbide, hafnium carbide, or titanium diboride. This process is shown generally in
In one embodiment, the cladding powder may be delivered to nozzle 42 of
The process of manufacturing impeller 5 and volute 6 may include using laser cladding apparatus 39 to form each of (referring to
The slurry pump component manufacturing process described above may be performed to increase the wear resistance and life of the components. The slurry pump component manufacturing process may also help inhibit the formation of cracks in the base material because the brazing alloy has a low melting point, which lowers strain caused by heating and cooling of the base material. The presently described manufacturing process may be performed to protect slurry pump components from abrasive and erosive interactions during operation and reduce the risk of catastrophic failure of the slurry pump.
It will be apparent to those skilled in the art that various modifications and variations can be made to the disclosed pump components without departing from the scope of the disclosure. Other embodiments of the components will be apparent to those skilled in the art from consideration of the specification and practice of the pump components herein. It is intended that the specification and examples be considered as exemplary only, with a true scope of the disclosure being indicated by the following claims and their equivalents.