The field of this invention is remanufacturing and salvaging, and more specifically the remanufacturing of hydraulic pumps, and hydraulic pumps amenable to remanufacturing.
Hydraulic pumps produce pressurized hydraulic fluid for many purposes. For example, on construction equipment and heavy machinery hydraulic pumps produce pressurized fluid which actuates implements such as shovels, works as a pilot fluid for operating hydraulic valves, and drives hydraulic motors for fans or propulsion. On engines, hydraulic pumps can also produce pressurized fluid for actuating fuel injectors and other purposes. As a result of these many uses, hydraulic pumps are a staple commodity for construction and other heavy equipment, diesel engines, and other machinery.
The principal components of these pumps may be made from parts that are cast, or begin as stock material, and are then machined extensively to create the features, such as bores, threaded connections, grooves for O-rings, seats for bearings, galleries, etc., that are part of most hydraulic pump designs. A significant investment can be made in manufacturing each of the various components for a pump.
After a certain amount of time in service, some of the components may experience wear and cause the pump to operate inefficiently or to fail. While some components of a pump that has been in service may have worn or failed, other components may be in very good, even like-new condition. If a pump is removed from service and discarded, but only some of its components exhibit serious wear, the investment made in the remaining components that are not seriously worn will be lost.
Remanufacturing seeks, in part, to recuperate the investment in components that are not worn in machinery that is taken out of service. In remanufacturing, the part removed from service is called a core. Typically, the transaction of selling a remanufactured part to a customer also involves taking back a new core which itself will be remanufactured and sold to another customer. Thus, there is usually one core which enters the remanufacturer's operation for each remanufactured part that leaves. In the remanufacturer's operation, the cores are broken into their various components and cleaned and inspected. Seriously worn or failed components may be discarded and replaced with new, original components. The remanufactured part is returned to service with some new components, and some components that were in place during the part's prior service. The discarded parts can be recycled to reuse the metal or other base materials.
Besides saving non-worn parts and replacing only the worn parts, a remanufacturing operation can also seek to salvage the worn parts themselves to further increase efficiency and save costs. Salvaging involves performing various operations on the worn component to bring it back to its original specifications and functionality.
Because of the very common use of hydraulic pumps on construction and other machinery as described above, because these pumps can wear rapidly, and because of the cost savings which can be achieved through remanufacturing, there is a need for developing effective salvage techniques which can be applied to facilitate remanufacturing. Besides the salvage techniques themselves, these pumps could be designed originally in a manner which better facilitates remanufacturing.
A variable displacement hydraulic pump may comprise a barrel which rotates around a rotational axis, a plurality of cylinders formed in the barrel, each cylinder having a longitudinal axis formed generally parallel to the rotational axis, a piston positioned inside of each of the plurality of cylinders for movement relative thereto, the pistons moving back and forth in their respective cylinders to pump hydraulic fluid at a first end of each piston, a yoke, the inclination of the yoke determining the displacement of the pump, a second end of each piston pushing against the yoke when the piston is pumping hydraulic fluid, a separate wear button attached to the yoke; and an actuator which pushes against the wear button to adjust the angle of inclination of the yoke.
An axial piston, variable displacement hydraulic pump may comprise a barrel which rotates around a rotational axis, a plurality of cylinders formed in the barrel, each cylinder having a longitudinal axis formed generally parallel to the rotational axis, a piston positioned inside of each of the plurality of cylinders for movement relative thereto, the pistons moving back and forth in their respective cylinders to pump hydraulic fluid at a first end of each piston, a yoke, the inclination of the yoke determining the displacement of the pump, a second end of each piston pushing against the yoke when the piston is pumping hydraulic fluid, and an actuator which pushes against a first surface of the yoke to adjust the angle of inclination of the yoke. A method of salvaging the pump may comprise forming a wear button, and attaching the wear button to the yoke such that the actuator pushes against the wear button to adjust the angle of inclination of the yoke.
A method of manufacturing and remanufacturing a hydraulic pump may comprise manufacturing a hydraulic pump having a barrel which rotates around a rotational axis, a plurality of cylinders formed in the barrel, each cylinder having a longitudinal axis formed generally parallel to the rotational axis, a piston positioned inside of each of the plurality of cylinders for movement relative thereto, the pistons moving back and forth in their respective cylinders to pump hydraulic fluid at a first end of each piston, a yoke, the inclination of the yoke determining the displacement of the pump, a second end of each piston pushing against the yoke when the piston is pumping hydraulic fluid, and an actuator which pushes against a first surface of the yoke to adjust the angle of inclination of the yoke. The method may further comprise placing the hydraulic pump in service with an end user, receiving the hydraulic pump back from an end user after it has been in service, and remanufacturing the hydraulic pump. Remanufacturing the pump may comprise removing the first surface, preparing a wear button, and attaching the wear button to the yoke in place of the first surface such that the actuator pushes against the wear button to adjust the angle of inclination of the yoke.
The following is an exemplary description of the remanufacture of a hydraulic pump illustrating the principles of the invention. These details are not to be taken as a description of the invention's scope, but rather as specific examples provided to teach the broader principles of the invention.
Fluid is supplied to the pump 10 from an inlet 11, drawn into the cylinders of a pump barrel 12, and pushed out of the pump barrel 12 under pressure by pistons 13. The pressurized fluid leaves the pump 10 at outlet 14. Pump barrel 12 includes a plurality of cylinders 121. A piston 13 is received inside of each cylinder 121. A shaft 15 engages the pump barrel 12 at a central opening 122. The shaft 15 rotates the pump barrel 12 and its associated rotating group around an axis of rotation A1.
The pistons 13 move back and forth in the cylinders 121 and complete one complete pump cycle per revolution of the pump barrel 12. A first end 131 of the piston 13 pushes against the fluid to pressurize it during the latter half of the pump cycle. A second end 132 of the piston 13 is operatively associated with a yoke 16. Yoke 16 is pivotally mounted inside the pump. The yoke 16 pivots about a pivot axis A2 (see
The power to rotate pump barrel 12 and its associated rotating group is transferred from shaft 15. Shaft 15 engages the pump barrel 12 through a spline arrangement. External splines 151 are formed on the shaft 15, and corresponding internal splines 123 are formed on the pump barrel 12. Splines are a convenient method for transferring power from the shaft 15 to the pump barrel 12 and are readily machined. However, the internal splines 123 on the pump barrel 12 can wear more rapidly than other parts of the pump barrel as a result of the tremendous concentration of stresses that can occur there.
The inclination angle of the yoke 16 is adjusted by a control system of the pump 10 to correct the pump's displacement. A great amount of force is applied by the pistons 13 against the yoke 16. The yoke 16 is moved to and held at a particular inclination angle by a spring and ball joint assembly 17 on one side, and an actuation piston 18 on the other, as best seen in
The splines 123 on pump barrel 12 and the tab 161 on yoke 16 have proven to be among the parts of the pump 10 that wear at a rate faster than other parts. When any single component of the pump 10 becomes too worn and the pump ceases to work properly, it may be necessary to take the pump out of service. While some components of the pump 10 may be worn, a large portion of the remaining components of pump 10 may still be in good condition. Thus, it may be desirable to remanufacture pump 10 for cost savings by replacing components that are worn, such as pump barrel 12 and yoke 16. Or pump barrel 12 and yoke 16 may be salvaged for additional cost savings by bringing them back into compliance with their original specifications.
Remanufacturing of Pump Barrel
The problem of worn splines 123 on pump barrel 12 can be overcome by replacing or rebuilding splines 123 with new splines. One method of replacing splines 123 is described below.
To replace or rebuild worn splines 123, the splines are first machined away by a mill or lathe. The splines 123 are removed by machining and enlarging the size of central opening 122. A spline insert 124, shown in
The use of spline insert 124 to repair the worn splines 123 on the pump barrel 12 has several advantages. The spline insert 124 is relatively inexpensive to manufacture. Spline insert 124 is small so it can be stocked in a small amount of space to await pump cores. Its size also facilitates effective heat treating. Appropriate heat treating procedures, such as case hardening, can extend the life of splines 125. Because of the size of spline insert 124, the appropriate heat treating steps can be completed inexpensively, and the heat treating can penetrate deep into the part. Spline insert 124 allows for the splines 124 to be made from a material different from the rest of pump barrel 12. The material used in spline insert 124 may be more heat treatable than the material used in pump barrel 12. The difference in materials can allow for a finer tuning or properties and characteristics better suited for each environment.
An effective process for replacing the splines 123 has been found to include the following steps: a) mill the worn splines 123 out of pump barrel 12, b) machining new threads 126 in the interior of pump barrel 12, c) screwing and tightening the heat-treated spline insert 124 into pump barrel 12, and d) final machining of the top surface of the spline insert 124. The final machining of the top surface of the spline insert may be desirable to bring the overall length of the pump barrel 12 and spline insert 124 assembly into compliance with the original specifications, and to make the surface perpendicular to the rotational axis A1 of the pump barrel.
A separate pump barrel 12 and spline insert 124 may even be an advantageous design for original manufacturing of pump 10. The two-part design permits spline insert 124 to be made from a desirable material so splines 125 can be effectively heat treated, while the remainder of the pump barrel 12 can be manufactured from a different material more suitable to its purpose.
However, the original manufacturing of the pump barrel 12 in two parts may be too expensive to be cost efficient. An effective life cycle for pump barrel 12 may be to a) originally manufacture it as one solid part with integral splines 123, b) use the pump 10 in service, c) receive the part back from service as a core, d) if the pump merits remanufacturing, replacing the splines 123 with a spline insert 124 and new splines 125, and e) use the pump in service a second time. If the pump 10 fails again or becomes overly worn in service, the insert 124 can be removed by unscrewing it, and a new insert 124 provided. This may be an effective life cycle for efficiently using resources such as materials, labor, and energy.
By effectively replacing splines 123, pump barrel 12 can be salvaged and the majority of the investment in creating an original pump barrel 12 is saved. Replacing splines 123 with a spline insert 124 having new splines 125 can cost approximately 40% of the cost of a new pump barrel 12. The cost savings alone make salvaging the pump barrel 10 beneficial. In addition to the cost savings, as discussed above, a separate spline insert 124 can actually result in splines 125 being more durable than splines 123.
Remanufacturing of Yoke
The problem of a worn tab 161, shown in
To replace or rebuild tab 161, the top surface 162 is first machined down to a new top surface 163 shown in
Tab button 164 can be manufactured from a steel that is well adapted for the kind of abrading wear it will experience from the actuating piston 18. Tab button 164 can also be manufactured from a steel that is amenable to a heat treating process that will enhance its wear properties for this environment.
By effectively rebuilding tab 161, yoke 16 can be salvaged and the majority of the investment in creating an original yoke 16 is saved. Rebuilding tab 161 of yoke 16 with tab button 164 as described above can cost approximately 15% of the cost of a new yoke 16. The cost savings alone make salvaging yoke 16 by replacing tab 161 beneficial. In addition to the cost savings, tab button 164 can actually be made more wear resistant than the original tab 161.
For this reason, it may be advantageous to manufacture yoke 16 originally with tab button 164. This would permit the bulk of the yoke 16 to be made from a material well suited for that purpose, while tab button 164 can be made from a material better suited for its environment of abrasive wear.
However, the original manufacturing of yoke 16 with tab button 164 may be cost prohibitive. For this reason, an effective life cycle for yoke 16 may be to a) manufacture it first as a single-piece part with an integral tab 161 as shown in