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HYDRAULICS & PNEUMATICS FEATURE


BEYOND CERTIFICATION Specifying a replacement hydraulic pump


Jonathan Walker, engineering manager at Oilgear, explores the innate features and processes that can ensure hydraulic pump performance is not simply defined by basic certification, but also offers benefits to the application that reduce the risk of downtime


P


umps for hydraulic applications are typically highly specialised towards


certain applications and environments, a reality that must be noted by the maintenance, repair and operations (MRO) professional. While a pump m ay achieve certain certifications such as those outlined by DNV GL, Lloyds and API, which can guarantee a certain level of competency, how does this actually translate to specifying a replacement for a particular application? A primary consideration when assessing certifications is to realise that they simply represent a bare minimum. The certification for a particular industry or environment will denote that a product could be used in a certain application, but will offer no guarantees as to its continued performance in that chosen environment. While a low duty pump may be certified for use in a marine environment, you would not automatically integrate it in a heavy- duty winching application, for example. As a maintenance professional, simply specifying a certified product offers little reassurance that the chosen solution will be up to a particular task. The first step to specifying a reliable


replacement hydraulic pump is to pick a specialist with pedigree. Hydraulic pumps are utilised in a wide range of industries from subsea to mobile vehicles, so selecting a manufacturer that has a proven track record in multiple industries is a good start. A suitable manufacturer will aim to achieve a balance between reliability, quality and cost-effectiveness across its pump range, which will incorporate features that tackle specific application challenges. Even in the same industry, operational demands vary widely, so defining an appropriate product with characteristics suited to the system is paramount to ensuring reliability. This may increase initial purchase costs, but this is nothing in comparison to the cost of repeated periods of downtime. A manufacturer that is able to offer


unique design advantages in a range of pumps, usually takes an entirely in- house approach to the origination of


products. Choosing a supplier that combines design, manufacturing and testing facilities in-house ensures increased consistency of production, reduced lead times and a more cost effective approach – which transmits savings to the purchaser. Specifying from a manufacturer who


employs rigorous product testing policies can ensure that a selected product will display the utmost reliability. Utilisation of a range of standard and bespoke test rigs, to accurately recreate certain operational conditions, can greatly increase confidence in a product as it has been proven to perform under the stresses of certain applications. A fully tested product, tailored to your application, will provide greater durability and performance than a product that is simply certified. Hydraulics is a mature sector, so selecting a manufacturer that utilises certain technologies to achieve an operational advantage is good policy to


/ DESIGNSOLUTIONS


ensure a replacement pump provides ultimate performance. Specifying a supplier with an integrated approach will mean that they have a greater capability to offer these technological advantages, due to increased expertise. The implementation of new material technologies has enabled the latest designs to offer durability when operating with low lubricity fluids, a situation usually encountered in the offshore or marine sectors. Utilising equally hardened, specialised alloy surfaces that run opposed to each other, from the valve plate to cylinder barrel or the steel shoes to swash bloc k, for example, can increase durability in operation. It also safeguards pump performance when running at higher temperatures, while enabling greater contamination resistance. This is a specialist technology that is specifically designed for high application demands in challenging environments and would not be signposted by a typical certification. Similar technologies include the use of hydro-dynamic bearings in hydraulic pumps, which also serve to enhance durability. The cylinder barrel runs on a thin film of fluid instead of using rolling contact bearings. This lack of contact between moving parts ensures almost infinite bearing life, while also eliminating a potential source of contamination of the hydraulic fluid. This simplicity of design approach ensures increased reliability and a reduced number of parts that can possibly fail, which is ideal for a maintenance team. An installed pump is therefore going to require less maintenance, and will operate effectively for a very long time, lowering the total cost of ownership and overall maintenance expenditure. Design features, such as a pressure


lubricated swash block, can offer pumps that are perfectly adapted to very demanding applications. This design provides constant lubrication to the saddle bearings for high pressure and high cycling applications. Other benefits include a reduction in overall pump hysteresis. Again, this specific design can bring significant increases in service life


DESIGN SOLUTIONS | JUNE 2017 13


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