HOUSTON (Feb. 23, 2021) Gardner Denver High Pressure Solutions (GD), the leading total solutions provider for the drilling, well servicing and frac pumps market, has announced the new GD 2500Q Heavy Duty Frame (HDF) quintuplex pump, designed to extend pump service life through an optimized power end frame design. The frame upgrade has been developed to increase component thickness and allow for larger, stronger welds, to boost structural integrity.
Today’s pumping conditions have pushed power end frames of all makes to their limits. The upgrade was designed with the aim of reducing stress in vulnerable areas.
Top and bottom skin plates increased in thickness, offering more structural support for nose plate loads.
Main bearing plates have increased in thickness and protrude between skin plates larger, stronger welds, reducing overall frame and weld stress.
Stronger support structure for nose plate to reduce deflection around nose place welds.
Significant nose plate weld size increased, reducing stress in critical nose plate joint by more than 20%.
Deep bevelling around outer main bearing plates, giving much deeper weld throat.
Eliminated snap ring bearing retainer and replaced with stronger, bolt-on outer main bearing retainer, giving improved axial tolerances for improved gear timing.
As a result of our commitment to continuous innovation and product improvement, we have now simplified the geometry from our legacy design and made the welds stronger and larger, resulting in longer pump life. These upgrades will save our customers a significant amount of time and expense as they improve the service life of their pumps."
Edward Bayhi, vice president and general manager, HPS, said, "As units are pumped for longer with heavier concentrations of sand, customers have found it increasingly difficult to get longevity out of their power ends. GD's engineering team stepped up to the challenge with the GD 2500Q HDF and added strength to our legacy design to increase fatigue life and improve manufacturability, both of which are critical in meeting the challenges of today’s harsh frac environments."