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Oil & Lubrication Analysis

Lubricant and wear debris analysis programs that detect internal component degradation months before vibration changes.

40%+Bearing and Gearbox Failures from Lubrication Issues
30-50%Extension of Oil Drain Intervals
4-8 moAdvance Warning of Developing Problems
60%+Reduction in Lubricant-Related Failures

What Is Oil and Lubrication Analysis?

Oil analysis is the laboratory examination of in-service lubricants to evaluate three things simultaneously: the condition of the oil itself, the condition of the machine it is lubricating, and the degree to which the lubrication environment is contaminated. A single oil sample, properly collected and tested against the right slate of tests, provides diagnostic information that no other predictive maintenance technology can replicate — including direct evidence of component wear through metallic particle analysis, lubricant degradation through chemical property testing, and contamination ingression through particle counting and moisture measurement.

The practice works because lubricating oil is in constant, intimate contact with the internal surfaces of the machine. As components wear, microscopic particles of the wear surfaces are carried into the oil stream. As the lubricant ages and degrades under thermal and oxidative stress, its chemical properties shift in measurable ways. As external contaminants — water, dirt, process chemicals, cross-contamination from other lubricants — enter the system, they alter the oil’s particle population and chemistry. These changes are detectable in the laboratory at concentrations far below what would produce visible discoloration, odor, or tactile change — making oil analysis one of the earliest-detection technologies available for lubrication-related and wear-related failure modes.

The analytical techniques used in oil analysis span a range of sophistication. Spectrometric analysis (ICP or RDE) quantifies dissolved and small-particle metals in parts per million — iron, copper, chromium, lead, tin, aluminum, silicon, sodium, and others — each associated with specific machine components and contaminant sources. Particle counting per ISO 4406 quantifies the cleanliness of the oil across defined particle size ranges. Analytical ferrography separates and examines wear particles under microscopy to characterize their type (rubbing, cutting, fatigue, corrosion, sliding), size, metallurgy, and morphology — providing far more diagnostic specificity than elemental analysis alone. Fluid property tests including viscosity, acid number, base number, oxidation, nitration, water content, and additive element levels characterize the lubricant’s ability to continue performing its function.

Oil Sampling: The Most Critical Step in the Process

Sampling quality is the single most common failure point in oil analysis programs, and it is the area where we invest the most training and procedural discipline.

The accuracy and value of every oil analysis result depends entirely on the quality of the sample that reaches the laboratory. A poorly collected sample — taken from the drain port at the bottom of a sump, drawn through a dirty sampling tube, collected in a contaminated bottle, or taken while the machine is shut down and particles have settled — will produce misleading results regardless of how sophisticated the laboratory analysis is. Sampling quality is the single most common failure point in oil analysis programs, and it is the area where we invest the most training and procedural discipline.

Best-practice sampling requires dedicated sampling ports installed at locations that capture oil representative of the circulating system — typically on return lines upstream of filters, or on pressure lines downstream of the pump. Sampling hardware should use minimally intrusive valves (such as Minimess or push-button sampling valves) that allow samples to be drawn from a live system without introducing atmospheric contamination. The first flush of oil through the sampling valve and tubing must be discarded to clear stagnant oil from the dead volume. Sample bottles must be laboratory-clean, and handling procedures must prevent contamination from dirty hands, airborne dust, or contact with non-clean surfaces. These requirements sound basic, but our experience is that sampling discipline is the factor that separates high-value oil analysis programs from programs that generate unreliable data and erode user confidence.

We install permanent sampling hardware on every monitored asset, establish written sampling procedures with photographs for every sampling point, and train your technicians on proper technique. We also audit sample quality through laboratory-side checks — flagging samples where particle counts or water levels are inconsistent with historical trends in ways that suggest contamination during sampling rather than a change in machine condition.

Test Slate Selection: Matching the Analysis to the Application

Not every oil sample requires every available test. Test slate design — selecting the right combination of tests for each machine type, lubricant type, and operating environment — is essential for both cost control and diagnostic effectiveness. A hydraulic system, a turbine bearing, a gearbox, and a diesel engine have different dominant failure modes, different lubricant chemistries, and different contaminant exposure profiles. They require different test slates.

For industrial gearboxes with EP (extreme pressure) gear oils, a typical routine test slate includes spectrometric metals analysis, particle count, viscosity at 40 degrees Celsius, acid number, water by Karl Fischer titration, and oxidation by FTIR. The metals analysis tracks wear from gears (iron, chromium), bearings (iron, copper, tin from bronze cages), and seals or gaskets (silicon, aluminum). The particle count monitors system cleanliness against the target ISO code established for the application. Viscosity trending detects dilution, oxidative thickening, or cross-contamination. Acid number tracks lubricant degradation. Water content at levels above 200-500 ppm in gear oils accelerates micropitting, corrosion, and additive depletion. For machines where abnormal wear is detected, we escalate to analytical ferrography for detailed particle characterization and root cause identification.

For hydraulic systems, the test slate emphasizes cleanliness above all else. Hydraulic components — servo valves, proportional valves, variable-displacement pump pistons — have tight internal clearances (as small as 1-5 micrometers in servo valves) that make them extremely sensitive to particulate contamination. Particle counting at 4, 6, and 14 micrometer thresholds per ISO 4406 is the primary monitoring parameter, with target cleanliness codes established based on the most contamination-sensitive component in the system. Water content, viscosity, and acid number round out the routine slate, with spectrometric metals added for systems with bronze or brass components where copper and zinc trending provides early warning of pump or valve wear.


What Are the Signs Your Facility Needs Oil Analysis Services?

Oil analysis is valuable in any facility that operates lubricated equipment — which encompasses virtually every industrial operation. The following indicators suggest that professional oil analysis services would address gaps in your current maintenance approach.

  • Lubricant changes are performed on fixed time intervals or operating hour schedules established years ago, without any data to confirm whether the oil has actually degraded to the point of needing replacement — this approach typically results in changing oil that is still serviceable while occasionally leaving degraded oil in service too long
  • You have experienced bearing or gearbox failures where the post-failure investigation found evidence of lubricant contamination, wrong lubricant, lubricant degradation, or inadequate lubrication — failures that oil analysis would have flagged before they progressed to component damage
  • Your facility uses multiple lubricant types and brands, and cross-contamination events have occurred due to mislabeling, shared transfer equipment, or unclear lubrication procedures
  • You have large-volume lubricant sumps — gearboxes, hydraulic reservoirs, turbine bearing systems — where the cost of the oil itself is substantial and extending drain intervals through condition-based changes would produce direct savings
  • Equipment operates in environments with high contamination exposure — dusty atmospheres, high humidity, process chemical vapors, wash-down areas — and you lack a method to verify that sealing and breather systems are keeping contaminants out
  • Your vibration monitoring program has detected wear-related conditions, but you lack the complementary oil analysis data that would confirm and further characterize the wear mechanism
  • Slow-speed equipment (below 300 RPM) — such as kiln support rollers, large gear drives, paper machine rolls, or cooling tower gearboxes — is part of your critical asset base, and vibration monitoring has limited sensitivity at these operating speeds
  • Your facility has recently changed lubricant suppliers or product lines and needs verification that the new products are performing as specified in the actual operating environment
  • Hydraulic system reliability is a concern — hydraulic failures frequently trace back to contamination issues that particle counting and fluid analysis would detect in their early stages

Our Oil Analysis Approach

Our oil analysis services are designed to produce clear, actionable maintenance intelligence — not just laboratory data. We manage the entire process from sampling hardware installation and procedure development through sample collection, laboratory analysis, data interpretation, and corrective action recommendations. Our clients receive diagnoses, not just data tables.

Contamination Control Philosophy

We approach lubrication with a contamination control mindset that extends beyond testing to address the root causes of lubricant degradation and contamination. The most effective oil analysis program in the world cannot compensate for an environment where contaminants are entering the system faster than they can be detected and corrected. Our contamination control recommendations typically address breather upgrades (replacing open-atmosphere breathers with desiccant breathers to block moisture and particle ingression), seal condition assessment, filtration system evaluation and optimization, lubricant storage and handling practices, and fill-point protection.

Setting and maintaining target cleanliness levels is central to this philosophy. We establish ISO 4406 cleanliness targets for each lubricated system based on the component sensitivity — a servo-valve hydraulic system might target 16/14/11 while a splash-lubricated gearbox might target 19/17/14. Every oil analysis report evaluates the current particle count against the target, and deviations trigger investigation into the contamination source. Over time, this discipline drives a measurable reduction in contamination-related failures and extends both lubricant and component life.

Condition-Based Oil Changes

One of the highest-return outcomes of a mature oil analysis program is the transition from time-based to condition-based lubricant replacement. Time-based oil change intervals — change the gearbox oil every 12 months, change the hydraulic fluid every 5,000 hours — are inherently imprecise. They assume a constant rate of lubricant degradation that rarely matches reality. A gearbox operating in a temperature-controlled indoor environment with clean, dry air and moderate loads may have oil that remains fully serviceable for three or four years. The same gearbox operating outdoors in a humid, dusty environment with frequent thermal cycling may degrade its oil in six months.

For facilities with large-volume systems (100-gallon and above), the savings from extended drain intervals frequently exceed the cost of the oil analysis program within the first year.

Oil analysis provides the objective data needed to make change decisions based on actual lubricant condition. We establish condemning limits for each critical parameter — viscosity change percentage, acid number threshold, oxidation level, water content, and additive depletion rates — and the oil is changed only when the data indicates that one or more parameters has reached or is approaching the condemning limit. For facilities with large-volume systems (100-gallon and above), the savings from extended drain intervals — reduced lubricant procurement, reduced disposal costs, reduced maintenance labor, and reduced production interruption for oil changes — frequently exceed the cost of the oil analysis program within the first year.

Varnish and Oxidation Management

Lubricant varnish — the formation of insoluble oxidation byproducts that deposit on internal machine surfaces — has become an increasingly significant reliability concern as lubricant formulations have shifted from Group I to Group II and Group III base stocks. Modern highly refined base oils have excellent oxidation resistance under normal conditions but can produce varnish deposits when exposed to thermal stress, micro-dieseling (pressure-induced thermal degradation in hydraulic systems), electrostatic discharge, or extended service life beyond the oil’s antioxidant capacity. Varnish deposits on servo valve spools cause sticking and erratic control. Deposits on bearing surfaces reduce heat transfer and can restrict oil flow to critical clearances. Deposits on filter media reduce filter life and effectiveness.

Our oil analysis program includes varnish potential testing — membrane patch colorimetry (MPC) per ASTM D7843 and ultra-centrifuge testing — for lubricant systems at risk. We establish MPC trending baselines and alert thresholds that provide early warning of varnish formation before deposits accumulate to the point of causing functional problems. When varnish risk is identified, we work with clients on mitigation strategies including electrostatic oil cleaning, balanced charge agglomeration filtration, lubricant formulation changes, and operating procedure modifications to reduce thermal stress.

Integration with Vibration Data

Oil analysis and vibration analysis are complementary technologies that together provide a more complete picture of machine health than either can alone. Vibration analysis excels at detecting dynamic mechanical faults — imbalance, misalignment, looseness, resonance — and at detecting bearing defects once they have progressed to the point of producing measurable vibration signatures (typically ISO stage 2 and beyond). Oil analysis detects the wear products generated by these same faults at earlier stages, often before vibration signatures become apparent, and also detects failure modes — lubricant degradation, contamination, chemical attack, adhesive wear from inadequate lubrication — that produce minimal vibration signature.

We cross-reference findings between technologies in every analysis cycle. A vibration report identifying a bearing defect on a gearbox drives a review of the most recent oil analysis for that unit — looking for elevated bearing metals (iron, chromium), increased particle counts, or wear particle morphology consistent with the vibration diagnosis. Conversely, an oil analysis showing a sudden increase in gear-related wear metals drives a detailed review of the vibration spectra for gear mesh frequency changes. This cross-correlation increases diagnostic confidence, reduces false positive rates, and occasionally catches conditions that one technology alone would miss.


What Equipment Is Typically Covered?

Industrial Gearboxes

Parallel shaft, helical, worm, bevel, and planetary gearboxes across all industrial applications. Gearboxes are one of the highest-value targets for oil analysis because their critical internal components — gear teeth, bearings, shafts, seals — are inaccessible for visual inspection and generate wear particles that oil analysis detects with high sensitivity. Spectrometric metals analysis tracks gear wear (iron), bearing wear (iron with copper and tin from bronze cages), and seal degradation. Analytical ferrography characterizes wear mode — distinguishing between normal benign wear, abrasive wear from contamination, fatigue spalling from overload or misalignment, and adhesive wear from lubrication failure. For large gearboxes with oil volumes exceeding 50 gallons, condition-based oil changes routinely extend drain intervals from annual to three-to-five year cycles.

Hydraulic Systems

All hydraulic system types — mobile, industrial, servo-controlled, proportional — benefit from oil analysis focused on contamination control. Particle counting is the primary monitoring parameter, with target cleanliness levels set based on the system’s most sensitive component. Water content monitoring is critical because water in hydraulic oil accelerates oxidation, promotes corrosion of ferrous components, and reduces lubricant film strength. For systems with bronze pumps or valve components, copper and zinc trending through spectrometric analysis provides early warning of accelerated wear that contamination may be driving.

Turbine Bearing Systems

Steam turbines, gas turbines, and associated generator bearing systems use high-quality turbine oils in circulation systems that may contain hundreds or thousands of gallons. These oils are expected to provide years of service when properly maintained — ISO VG 32 or 46 turbine oils with good antioxidant additive packages can last five to ten years in well-sealed, well-cooled systems. Oil analysis for turbine systems focuses on oxidation stability (RPVOT/RULER testing for remaining antioxidant life), varnish potential, water content, acid number, and particle count. Given the high replacement cost and the production impact of a turbine bearing failure, these systems justify comprehensive test slates and frequent sampling intervals.

Compressors

Rotary screw, reciprocating, and centrifugal compressors each have distinct oil analysis requirements. Rotary screw compressors operate with the oil in direct contact with the compressed gas, exposing the lubricant to elevated temperatures, moisture from gas cooling, and process gas contaminants. Acid number and oxidation trending are critical monitoring parameters. Reciprocating compressors generate wear particles from piston rings, cylinder liners, and crosshead components that spectrometric and ferrographic analysis can characterize. Centrifugal compressor oil systems resemble turbine bearing systems and follow similar monitoring protocols with emphasis on cleanliness and lubricant condition.

Large Electric Motors with Sleeve Bearings

Large motors (typically 500 HP and above) equipped with sleeve bearings rather than rolling element bearings use oil lubrication systems where analysis tracks bearing wear (babbitt metals — tin, lead, copper), oil degradation, and contamination. These motors often drive critical process equipment, and a sleeve bearing failure can be catastrophic. Oil analysis trending of babbitt wear metals provides early detection of bearing distress that vibration analysis may not capture until the condition has progressed to measurable changes in shaft position or vibration signature.


What Results Do Companies Typically See?

A well-executed oil analysis program delivers measurable returns across multiple dimensions of maintenance and operations performance. The following outcome ranges reflect consistent results across our client base.

Gearbox and bearing failure cost avoidance of $50,000-$250,000 per year for typical medium-to-large industrial facilities.

  • Lubricant life extension of 30-60% by replacing time-based drain intervals with condition-based changes — the actual extension depends on the starting interval, operating environment, and contamination control practices, with the largest gains realized on systems that were being changed too frequently under the old schedule
  • Contamination-related failure reduction of 40-60% as particle counting drives contamination control improvements (breather upgrades, seal replacements, filtration enhancements, handling procedure changes) that address the root cause of the most common lubrication failure mode
  • Early wear detection on an average of 8-15 assets per year (for a facility monitoring 100-200 machines) — catching active wear conditions weeks to months before they would progress to functional failure or produce detectable vibration signatures
  • Lubricant procurement cost reduction of 15-30% from extended drain intervals and reduced lubricant waste, partially offset by the cost of the analysis program itself — net savings are typically positive within the first year for facilities with moderate to large oil inventories
  • Hydraulic system reliability improvement of 25-40% as contamination control discipline drives particle counts to target cleanliness levels and maintains them there through ongoing monitoring and corrective action
  • Cross-contamination event detection — our programs routinely catch misapplied lubricants through viscosity and additive element anomalies, preventing the accelerated wear and component damage that wrong-lubricant conditions produce
  • Gearbox and bearing failure cost avoidance of $50,000-$250,000 per year for typical medium-to-large industrial facilities — calculated from confirmed saves where oil analysis detected conditions that would have progressed to failure without intervention

Over a three-to-five year horizon, the compounding effect of improved lubrication practices typically produces reliability improvements that exceed the direct value of individual fault detections by a substantial margin.

The relationship between oil analysis and overall equipment reliability is cumulative and self-reinforcing. As the program identifies and drives correction of contamination sources, lubricant selection errors, and degradation patterns, the baseline condition of the lubricant environment improves. Cleaner, properly selected, properly maintained lubricants reduce wear rates, which extends component life, which reduces maintenance costs and unplanned downtime. Over a three-to-five year horizon, the compounding effect of improved lubrication practices — enabled and sustained by ongoing oil analysis — typically produces reliability improvements that exceed the direct value of the individual fault detections by a substantial margin. Our team provides the sampling infrastructure, laboratory analysis, diagnostic expertise, and contamination control guidance to build and sustain that trajectory for your operation.

Why it matters

Why Companies Choose Our Oil & Lubrication Analysis Program

Detect Hidden Wear Patterns

Spectrometric analysis reveals wear metal concentrations that indicate exactly which internal components are degrading, months before vibration signatures change.

Extend Oil Drain Intervals

Condition-based oil changes replace calendar-based intervals, extending drain periods by 30-50% while ensuring lubricant condition stays within specification.

Prevent Lubrication-Related Failures

Over 40% of bearing and gearbox failures originate from lubrication issues. Oil analysis catches contamination and degradation before mechanical damage begins.

Monitor Contamination Sources

Water ingress, fuel dilution, silicon from air leaks, and process fluid contamination are identified and traced to their source for permanent correction.

What we solve

Challenges We Solve

Sampling Consistency

Oil sample quality depends on consistent draw points, equipment operating temperature, and time since last oil change. Inconsistent sampling produces unreliable trend data.

Interpreting Trend Breaks

A single abnormal result may indicate a real problem or a sampling error. Distinguishing between the two requires experience and knowledge of equipment operating context.

Contamination vs. Normal Wear

New oil additions, filter changes, and top-offs create data discontinuities that must be accounted for when interpreting results.

The Process

How Our Oil & Lubrication Analysis Process Works

Our oil analysis programs are designed to integrate with your existing maintenance routines and deliver clear, actionable results.

  1. 01

    Sampling Program Design

    We define sample points, frequencies, and procedures for each lubricated asset based on criticality, lubricant type, and operating environment.

  2. 02

    Baseline Establishment

    Initial samples establish normal wear metal concentrations, viscosity ranges, and contamination levels specific to each piece of equipment.

  3. 03

    Routine Sampling and Analysis

    Samples are collected on schedule, analyzed for 20+ parameters, and compared against equipment-specific baselines and industry limits.

  4. 04

    Trend Reporting and Recommendations

    Quarterly trend reports highlight developing issues, recommend corrective actions, and track the effectiveness of previous interventions.

By Industry

Industries We Serve

Industry

Oil & Lubrication Analysis for Automotive Manufacturing Plants

Oil analysis for automotive plants monitors press hydraulic systems, robotic gearbox oils, and conveyor reducer lubricants across JIT production lines where...

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Industry

Oil & Lubrication Analysis for Cement and Aggregates Plants

Oil analysis for cement plants tracks extreme particulate contamination and thermal degradation in kiln drive gearboxes, mill bearings, and ID fan...

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Industry

Oil & Lubrication Analysis for Chemical Processing Plants

Oil analysis for chemical plants detects process fluid contamination, corrosive wear, and lubricant degradation in pumps, compressors, and agitators...

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Industry

Oil & Lubrication Analysis for Food and Beverage Plants

Oil analysis for food and beverage plants monitors food-grade lubricant condition and contamination in an environment where lubricant selection is...

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Industry

Oil & Lubrication Analysis for Industrial Refrigeration

Oil analysis for industrial refrigeration monitors compressor oils where refrigerant dilution, moisture, and acid formation degrade lubricants and...

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Industry

Oil & Lubrication Analysis for Logistics and Distribution Centers

Oil analysis for distribution centers monitors conveyor gearbox oils and dock equipment hydraulics to maximize equipment availability before and during peak...

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Industry

Oil & Lubrication Analysis for Manufacturing Facilities

Oil analysis for manufacturing tracks wear metals, contamination, and lubricant condition across gearboxes, hydraulic systems, and CNC spindle bearings to...

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Industry

Oil & Lubrication Analysis for Metals and Steel Facilities

Oil analysis for metals and steel monitors gearbox, hydraulic, and bearing oils operating in extreme heat and contamination environments where thermal...

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Industry

Oil & Lubrication Analysis for Mining and Minerals Operations

Oil analysis for mining monitors crusher, mill, and haul truck lubricants where abrasive contamination and extreme loads accelerate wear far beyond standard...

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Industry

Oil & Lubrication Analysis for Oil and Gas Facilities

Oil analysis for oil and gas monitors compressor oils, turbine lubricants, and engine oils across remote facilities where lubricant condition directly...

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Industry

Oil & Lubrication Analysis for Pharmaceutical Facilities

Oil analysis for pharmaceutical plants monitors lubricant condition in GMP environments where lubricant changes require change control documentation and...

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Industry

Oil & Lubrication Analysis for Plastics and Rubber Manufacturing

Oil analysis for plastics and rubber monitors extruder gearbox oils and injection molding hydraulics where thermal stress and contamination cause quality...

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Industry

Oil & Lubrication Analysis for Power Generation Facilities

Oil analysis for power plants monitors turbine oils, generator hydrogen seal oils, and auxiliary system lubricants where oil condition directly affects unit...

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Industry

Oil & Lubrication Analysis for Pulp and Paper Mills

Oil analysis for pulp and paper monitors gearbox, bearing, and hydraulic oils in wet, corrosive environments where water contamination and paper fiber...

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Industry

Oil & Lubrication Analysis for Water and Wastewater Plants

Oil analysis for water and wastewater monitors blower, pump, and gearbox lubricants with small maintenance staff using simple sampling protocols and...

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By Equipment

Equipment We Support

Equipment

Oil & Lubrication Analysis for Air Compressors

Oil & Lubrication Analysis programs for Air Compressors, targeting common failure modes and degradation mechanisms.

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Equipment

Oil & Lubrication Analysis for Bearing Systems

Oil & Lubrication Analysis programs for Bearing Systems, targeting common failure modes and degradation mechanisms.

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Equipment

Oil & Lubrication Analysis for Boilers

Oil & Lubrication Analysis programs for Boilers, targeting common failure modes and degradation mechanisms.

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Equipment

Oil & Lubrication Analysis for Chillers & Cooling Systems

Oil & Lubrication Analysis programs for Chillers & Cooling Systems, targeting common failure modes and degradation mechanisms.

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Equipment

Oil & Lubrication Analysis for Cooling Towers

Oil & Lubrication Analysis programs for Cooling Towers, targeting common failure modes and degradation mechanisms.

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Equipment

Oil & Lubrication Analysis for Crushers & Mills

Oil & Lubrication Analysis programs for Crushers & Mills, targeting common failure modes and degradation mechanisms.

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Equipment

Oil & Lubrication Analysis for Dust Collection Systems

Oil & Lubrication Analysis programs for Dust Collection Systems, targeting common failure modes and degradation mechanisms.

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Equipment

Oil & Lubrication Analysis for Extruders

Oil & Lubrication Analysis programs for Extruders, targeting common failure modes and degradation mechanisms.

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Equipment

Oil & Lubrication Analysis for HVAC Systems

Oil & Lubrication Analysis programs for HVAC Systems, targeting common failure modes and degradation mechanisms.

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Equipment

Oil & Lubrication Analysis for Industrial Ovens & Furnaces

Oil & Lubrication Analysis programs for Industrial Ovens & Furnaces, targeting common failure modes and degradation mechanisms.

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Equipment

Oil & Lubrication Analysis for Industrial Refrigeration Systems

Oil & Lubrication Analysis programs for Industrial Refrigeration Systems, targeting common failure modes and degradation mechanisms.

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Equipment

Oil & Lubrication Analysis for Industrial Robots

Oil & Lubrication Analysis programs for Industrial Robots, targeting common failure modes and degradation mechanisms.

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Equipment

Oil & Lubrication Analysis for Injection Molding Machines

Oil & Lubrication Analysis programs for Injection Molding Machines, targeting common failure modes and degradation mechanisms.

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Equipment

Oil & Lubrication Analysis for Mixers & Agitators

Oil & Lubrication Analysis programs for Mixers & Agitators, targeting common failure modes and degradation mechanisms.

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Equipment

Oil & Lubrication Analysis for Packaging Equipment

Oil & Lubrication Analysis programs for Packaging Equipment, targeting common failure modes and degradation mechanisms.

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Equipment

Oil & Lubrication Analysis for Water Treatment Equipment

Oil & Lubrication Analysis programs for Water Treatment Equipment, targeting common failure modes and degradation mechanisms.

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Equipment

Oil Analysis for Belt Conveyors

We analyze gearbox and bearing lubricants on belt conveyor drives to detect gear wear, bearing fatigue, and contamination from harsh operating sites.

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Equipment

Oil Analysis for Centrifugal Compressors

Our oil analysis monitors journal bearing wear, seal oil contamination, and lube oil system cleanliness in centrifugal compressors per API 614 standards.

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Equipment

Oil Analysis for Centrifugal Fans

We analyze centrifugal fan bearing lubricants for contamination, wear metals, and grease breakdown to optimize relubrication and prevent failures.

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Equipment

Oil Analysis for Centrifugal Pumps

Our oil analysis programs detect bearing wear metals, seal contamination, and lubricant degradation in centrifugal pumps to extend bearing service life.

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Equipment

Oil Analysis for DC Motors

Our oil analysis detects armature bearing wear, commutator carbon contamination, and lubricant breakdown in DC motors operating under variable-speed loads.

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Equipment

Oil Analysis for Gas Turbines

We monitor gas turbine lube oil for varnish formation, bearing wear metals, and thermal degradation products to protect bearings and extend oil life.

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Equipment

Oil Analysis for Gearboxes

Our gearbox oil analysis identifies gear tooth wear morphology, EP additive depletion, and bearing fatigue particles via ferrography and ISO codes.

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Equipment

Oil Analysis for Generators

Our oil analysis monitors generator bearing babbitt wear, hydrogen seal oil contamination, and lube system varnish to prevent bearing-related faults.

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Equipment

Oil Analysis for Hydraulic Cylinders

We analyze hydraulic fluid for cylinder seal wear debris, rod contamination ingress, and fluid degradation to predict rebuild timing and prevent drift.

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Equipment

Oil Analysis for Hydraulic Systems

Our hydraulic fluid analysis tracks pump wear, contamination levels, and fluid degradation to maintain ISO 4406 cleanliness and extend component life.

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Equipment

Oil Analysis for Induction Motors

Our oil analysis programs detect bearing wear metals, contamination, and grease degradation in induction motors to prevent bearing-related failures.

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Equipment

Oil Analysis for Industrial Blowers

Our oil analysis programs detect timing gear wear, rotor bearing degradation, and oil oxidation in industrial blowers to prevent rotor contact and seizure.

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Equipment

Oil Analysis for Lubrication Systems

Our team applies oil analysis programs to lubrication systems, targeting pump wear, filter element clogging, and related degradation mechanisms before they...

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Equipment

Oil Analysis for Plate Heat Exchangers

We test lubricants and thermal fluids in plate heat exchanger circuits for cross-contamination from gasket failures and heat transfer oil degradation.

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Equipment

Oil Analysis for Positive Displacement Pumps

We analyze lubricants in positive displacement pumps to identify gear wear, plunger packing debris, and process fluid contamination from seal leakage.

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Equipment

Oil Analysis for Reciprocating Compressors

We analyze crankcase and cylinder lubricants in reciprocating compressors to detect crosshead wear, bearing distress, and gas-induced oil degradation.

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Equipment

Oil Analysis for Screw Compressors

We analyze screw compressor lubricants for rotor wear metals, fluid breakdown products, and moisture contamination to optimize oil change intervals.

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Equipment

Oil Analysis for Screw Conveyors

Our oil analysis detects hanger bearing wear, gearbox degradation, and process contamination in screw conveyor drive lubricants and grease systems.

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Equipment

Oil Analysis for Shell & Tube Heat Exchangers

Our oil analysis detects lubricant cross-contamination through heat exchanger tube leaks and verifies thermal fluid condition in oil-cooled systems.

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Equipment

Oil Analysis for Steam Turbines

Our turbine oil analysis programs track varnish precursors, bearing babbitt wear, and water contamination per ASTM D4378 for steam turbine systems.

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Equipment

Oil Analysis for Submersible Pumps

Our oil analysis programs monitor submersible pump motor oil for moisture ingress, bearing metals, and dielectric fluid breakdown to prevent motor burnout.

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Equipment

Oil Analysis for Synchronous Motors

We monitor synchronous motor bearing oil for babbitt wear, hydrogen seal oil purity, and lubricant degradation to protect high-value motor investments.

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Equipment

Oil Analysis for Variable Speed Drives

We analyze lubricants in VFD-driven equipment for electrical discharge machining damage particles, bearing wear, and lubricant conductivity degradation.

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Equipment

Oil Analysis for Vibration Monitoring Equipment

Our team applies oil analysis programs to vibration monitoring equipment, targeting sensor degradation, cable faults, and related degradation mechanisms...

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Common Questions

FAQ

A comprehensive oil analysis tests for wear metals (iron, copper, chromium, lead, tin), contamination (water, silicon, fuel, glycol), lubricant condition (viscosity, TAN/TBN, oxidation), and particle counts per ISO 4406. Each parameter tells a different part of the equipment health story.

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