Turbine oil monitoring.pdf

Innovative Lubricating Solution For Gas Turbines Gas Turbine Users Forum Sydney November 25 2015 Warren Scott- Lubricants Specialist

4/01/2016

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TODAY’S TURBINES HAVE TO WORK HARDER THAN EVER BEFORE Environmental legislation continuously driving towards lower emission levels

Greater demand for less downtime, extended oildrain intervals and efficiency improvements

Turbine sump volumes are shrinking in size while handling the same or increased power

Cyclic operating conditions are placing more stresses on turbines

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Affects the turbine oil

Increased operating temperatures drive requirements for greater component protection

Increased pressure on gearboxes

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OIL STRESS HAS INCREASED BY 400% AND OPERATING TEMPERATURES ARE HIGHER Increasing oil stress and operating temperatures* 12

80 70 60

8

50 40

6

30

4

20 2

Oil temperature, °C

Oil stress index, MW m-3

10

10 0

0 8C

GE fr 5

Oil stress index, MW m-3

GE fr 6A

GE fr 6B

GE fr 9E

Oil temperature, °C *Shell calculation based on publically available data

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Why the lubricant is important – reliability •

Turbine reliability requires – Prevention of metal-to-metal contact in hydrodynamic lubrication regime and control valve sticking both during start up and shut down and across the range of operating temperatures – Cooling to prevent rapid oil degradation and the formation of bearing deposits – Corrosion protection for the main bearings and system components

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Shell Turbo

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WHY THE LUBRICANT IS IMPORTANT – EFFICIENCY Deposit build-up on metal surfaces

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Why the lubricant is important – efficiency • Turbine system efficiency is affected by Deposit build-up on metal surfaces

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Excessive foam in the turbine reservoir

Shell Turbo

The formation of emulsions

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TYPICAL TURBINE OIL COMPOSITION Base Oil 98-99% Antioxidants R&O Additive System < 1-2%

Rust Inhibitor Corrosion Inhibitor Others *

Turbine oil additive system

* Defoamer, demulsifier, AW/EP additives (where required)

Group

Typical Process Route

Sulphur (Wt %)

Saturates (Vol %)

Viscosity Index

I

Solvent refining

> 0.03 &/or

<90

≥ 80 – < 120

II

All-Hydro-processing

≤ 0.03 &

≥ 90

≥ 80 – < 120

III

All-Hydro-processing

≤ 0.03 &

≥ 90

≥ 120

IV

Synthetic

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Poly-Alpha-Olefins (PAO) Other Base Oils Not Group I, II, III or IV 7

GAS-TO-LIQUIDS (GTL) BASE OIL TECHNOLOGY •Catalytic process converting gas to oil products

GTL base oil API group III+ base oil Primarily iso-paraffinic, no impurities, excellent antioxidant response, surface properties, narrow molecular distribution

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INNOVATIVE TURBINE OILS BASED ON GTL TECHNOLOGY •High performance turbine oils to: – Meet the demands of the latest highefficiency turbine systems – Offer outstanding, long-term performance under the most severe operating conditions – Help to minimise deposit formation, even under cyclic peak loading. The use of GTL technology enables performance enhancements in the area of: – High viscosity index – Rapid air release – Foaming resistance – High flash point – Rapid water separation

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DEPOSIT FORMATION TENDENCY – ASTM D7873 DRY TURBINE OIL STABILITY TEST (DRY TOST) •1,008 hour Dry TOST (ASTM D7873) 



Oxidation of the fluid is promoted by heat, in the presence of oxygen and metals (copper and steel coils), no water Measure RPVOT and oxidation products (sludge) after 1,008 hours

Test Conditions • Temperature 120ºC (248ºF) • Copper and steel catalyst • Evaluate the sample at 1008 hrs

Assesses the sludge tendency by measuring insoluble oxidation products and RPVOT retention Copyright of Shell Lubricants

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DEPOSIT FORMATION TENDENCY – ASTM D7873 DRY TURBINE OIL STABILITY TEST (DRY TOST)

Dry TOST Evaluation at 1008 hrs (D7873)

1000 5000

Better Performance

Sludge, mg/kg

800 4000

600

400

200

0

Turbo S4 GtL-based Oil

Oil A

Oil B

Oil C

Oil D

Oil E

Testing based on commercially obtained samples

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OXIDATION STABILITY AND DEPOSIT CONTROL MAN-LTAT (LUBRICANT TEMPERATURE AGING TEST) AT 180°C Static Oven = 180ºC (356ºF) Test Time = 48 hours Air Flow = None Metal Catalysts = None

Measurable: – Sludge, mg/kg – Volatility of base oil and formulation This thermal stability test assesses the oil’s short term deposit resistance when exposed to very high temperatures. The test result indicates the oil’s resistance against sludge formation and is key to obtaining MAN Turbo approval. The lower the sludge levels in the oil at the end of test the better the performance. 4/01/2016

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PREVENTING CRITICAL COMPONENT FAILURE & UNPLANNED SHUTDOWNS •

The long-term resistance to formation of sludge and varnish deposits of GtLbased turbine oil helps reduce the risk of bearing temperature issues and control valve positioning problems, which can upset running stability and cause turbine trips. MAN-LTAT oxidation test (beaker test) at 180°C*

Better Performance

2,000

Sludge, mg

1,500

1,000

500

GtL-based oil performs much better than other oils tested in the MAN-LTAT oxidation test (beaker test)

0 GtL-based Oil Shell Turbo S4

Oil A

Oil B

Oil C

Oil D

Oil E *Source: Shell test data

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Shell Turbo

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EFFICIENCY BENEFITS OF API GRP iii BASED TURBINE OILS •

•

Turbine oil formulated with GTL base oil provide a higher inherent viscosity index and lower friction coefficient relative to turbine oils formulated with API Grp I or Grp II base oils Provides a thicker lubricating film at higher operating temperatures versus conventional GP I/II (lower VI) based oils of the same ISO grade

--- GTL Based Turbine Oil --- Converntional API Grp II Turbine Oil

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EFFICIENCY BENEFITS OF GTL BASED TURBINE OILS AIR RELEASE AND FOAMING •Turbine oil reservoirs are circulating oil system and entrainment of air and foaming is possible •Important to consider residence time of oil in tank to help settle contaminants (including air, water) •Turbine oils formulated with GTL base oils can significantly improve air release times and reduce foaming potential

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EFFICIENCY BENEFITS OF GTL BASED TURBINE OILS AIR RELEASE AND FOAMING – Poor air separation properties leads to: 

Adiabatic compression within the oil (micro-dieseling), acidic contaminants, rapid decrease of the antioxidant system and an increase in oil insoluble material

– Operational difficulties due to poor air separation include: 

Cavitation, loss of oil pressure, reduced oil flow, poor response in high pressure servos, filter blocking

– Use of turbine oils formulated with GtL base oils show an outstanding air separation properties leading to: 

Reduced maintenance cost, increased turbine reliability, extended oil life, higher return on investment, peace of mind

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PROACTIVE TURBINE OIL MONITORING – Turbine oil condition monitoring is critical – Important to use an oil analysis testing programme that includes targets, warning limits and frequency, with diagnosis and recommended actions

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Shell Turbo

04 January 2016

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Summary – Turbine oils play a critical role in the availability and reliability of turbines used in the power generation, oil & gas and heavy industry sectors – In response to field issues, OEMs and industry bodies are developing increasingly differentiated turbine oil requirements with a focus on longer life and reduced deposit forming tendencies

 Innovation in turbine oil technology such as the use of Gtl technology based oils in Shells new Turbo S4 X/GX range allows operator needs to be met

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SHELL TURBO S4 SERIES: FIELD EXPERIENCE TO DATE

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Current Usage of Turbo S4 X 32 & S4 X46 Shell Turbo S4 X 32

Location

Equipment

Start

Shell Technology Centre Houston

USA

Solar Taurus C 60 GT

Since 2012

Dominion Energy

USA

GE Frame 7 FA GT

Since 2013

Shell Canada Scotford Shell Canada Scotford Spectra Energy Empire District Energy

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Notes Drain and fill Replace Texaco GT 32 – drain and fill

Since 2014

Replace Turbo SG 32 – drain and fill

Sundyne Compressor x2

Since 2014

Replace Turbo SG 32 – drain and fill

USA

Solar Centaur GT

Since 2015

New start-up

USA

Siemens-Westinghouse 1426RT2 Steam Turbine

Since 2015

Conversion from Mobil DTE 732

Canada Canada

Elliott PAP Compressors x 5

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Current Usage of Turbo S4 GX 32/46 Shell Turbo S4 GX

Location

Equipment

Start

Notes

Stadtwerke Rostock

Germany

ABB V32A Steam Turbine

Since 2015

Stadtwerke Rostock

Germany

Siemens SGT 600 GT

Since 2015

Drain and fill

Vattenfall

Germany

Siemens GT

Since 2015

Top off – Shell Turbo CC 46

Drain and fill

EDF

France

GE Frame 9FHA

Since 2015

Initial fill new combined cycle

EDF

France

GE D14 Steam Turbine

Since 2015

Initial fill new combined cycle

Samsung (EPC)

SaudiArabia

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MAN TurboCompressor

Since 2015

Initial fill new project

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Dominion Energy First field trial candidate selected in US

Heavy duty gas turbine GE frame 7 FA Power Generation service Product: Shell TURBO S4 X 32 Field trial started mid April 2013 In service > 2 year with Shell Turbo S4 X 32 • Peaking Power Plant - low operational hours (~2,628) • Peaking and cylic duty is more severe on lubricant performance than base load - Starts= 279

– Overall oil condition very good • No filterability or servo valve varnish issues •

Good foaming & water separation characteristics

•

Air release < 2 minutes

•

MPC < 10; RPVOT retention >95% (1426 minutes)

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