This article was written by Adam McMurtrey, Industrial Field Engineer with ExxonMobil Fuels & Lubricants Company.
As a result of improved filtration, studies show that improving filtration, as measured by the International Organization for Standardization (ISO) cleanliness code, can extend the life of manufacturing equipment by 1.3 to 3 times or more.1 Additionally, as the oil is cleaned through proper filtration, it is common to extend the life of the oil as well.
Ensuring the cleanliness of the oils and lubricants you’re using can help mitigate these issues and lead to longer equipment life, less unscheduled downtime, and reduced maintenance costs.
Oil cleanliness is measured using the International Organization for Standardization (ISO) cleanliness code to measure particle count per milliliter of oil for particles 4, 6, and 14 micron in size. This ISO code is expressed in 3 numbers: 16/14/11. When filtering your lubricant, you remove particles in the oil of all sizes.
Effective oil filtration can be accomplished on almost all types of manufacturing equipment (e.g. pumps, gear boxes, combustion engines, compressors, vacuum pumps, hydraulics, etc.) To extend the life of equipment throughout your facility, an important component is care for the oil in machines. Oil filters are designed to remove contaminants from oil while it circulates through the host machine. This post will share a basic understanding of filter components, highlighting how these critical devices work and what operators should consider when selecting a filter.
Filtration components
A discussion of oil filters should start with the filter media, which is actual material used to capture a contaminant. It is typically in sheet form, folded to expose maximum surface area. The most common media include wire mesh, cellulose, fiberglass or other synthetic materials.
The type of filter media to be used depends on the filtration design. There are two common types of filters:
We recommend you work with your filter OEM, equipment builder or lubricant supplier to understand which filtration design and filter media type is best for your equipment.
Filter efficiency
In addition to filtration design and media type, operators need to consider filter efficiency. Filter efficiency refers to a measure of a filter's ability to collect and retain particles of a specific size, and can be expressed using the nominal, absolute or beta ratings – the most reliable of which is the beta rating.
βx = number of upstream particles greater than (x) microns / number of downstream particles greater than (x) microns.
Efficiency % = [(β - 1) / β] x 100.
Example: if a 5-micron filter element has 1,000,000 particles and allows 1,000 particles through, its Beta ratio is:
1,000,000 (Before Filter) / 1,000 (After Filter) = β1000.
Efficiency % = [(1,000 – 1) / 1,000] x 100 = 99.9% effective.
In addition to size and efficiency, operators must consider a filter’s dirt-holding capacity (DHC). This refers to the total amount of contaminants that may be trapped by the filter and is related to the physical size of the filter.
Why all of these filter fundamentals so important?
We often hear operators in the field describe their filter size, but they don’t always then consider that filter’s beta rating and dirt holding capacity. Without this understanding, operators who think they’re saving money could in fact be losing money over the long-term.
For example, cheaper filters of a given size have lower efficiency and DHC. Depending on the application, this reduced efficiency can lead to poor filtration, which could in turn impact equipment performance. That’s why it’s critical to select the right filter for the job. Operators should work with their equipment OEM, filter OEM or lubricant supplier to determine which filter is best suited for the application.
Selecting the proper filtration to extend the life of equipment is an investment in your facility and the future of your company.
Source
1. http://filtroilcalc.punchbuild.com/