1LS, Nov 2008

Flare/Vent MeteringFlare/Vent MeteringIf you canIf you can’’t measure, you cant measure, you can’’t managet manage

Lex ScheersLex Scheerslex.scheers@shell.comlex.scheers@shell.com

Advanced Production Management

Prepared for Hydrocarbon Production Accounting workshopMoscow, 16-17 Dec 2008

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1. Introduction2. Flow regimes3. Fluid properties4. Flow measurement5. Composition measurement6. Design considerations7. Operational aspects

Content

3LS, Nov 2008

Introduction- The product balance

GAS

GAS

OIL

OIL

WATE

RW

ATE

R

RESERVOIRGA

SGA

S

WATE

RW

ATE

R

WATE

R W

ATE

R DIS

POSA

LDIS

POSA

L

SALES GASSALES GAS

SALES OILSALES OIL

FLARE GAS, FLARE GAS, OWN USEOWN USE $

$$

$$

$

$ $ $

PRODUCTION FACILITYfor each phase

Σin = Σout

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Flare en Vent yearly quantities

According to the Global Gas Flare Reduction (GGFR) programEstimate 150 - 170 * 109 Sm3/year

This equals 4 - 5% of the Global Gas Consumption

or 5 - 6% of the total “Groningen Gas Field”

Valuable energy resource wasted

Harms the environment (Green House Gasses)

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World Natural Gas Consumption2004 - 2030

(1012 cft ≈ 33 * 109 m3)

≈ 2,850 * 109 m3

Groningen gas field (GGF)≈ 2,850 x 109 Sm3≈ 8,500 x 1012 cft≈ 1014 MJ (1017 Btu)

100

165

1 GG

F

≈ 150 * 109 m3

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Oil Shrinkage and Gas Expansion

Separator

Q

Gas to Liquid

Liquid to Gas

ProductionProcess

Q

Q Q

V = 10,000 Sm3/dρ = 0.90 kg/m3

M = 9,000 kg

V = 12,094 Sm3/dρ = 0.85 kg/m3

M = 10,280 kg

V = 100 Sm3/dρ = 750 kg/m3

M = 75,000 kg

V = 97 Sm3/dρ = 760 kg/m3

M = 73,720 kg

Total Mass M = 84,000 kg M = 84,000 kg

S=0.97

E=1.2094

StockTank

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Conservation laws(no liquid <> gas transport)

Conservation of Mass (kg, tonnes)

Conservation of Standard Volume (Sm3, Scft)

Conservation of Actual Volume (Am3, cft)

Conservation of Energy (MJ, BTU, etc)

Conservation of Misery

Conservation of Mols (kmol)

??

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Continuous Flare and Vent measurement

Oil production facilities (associated gas)No gas infra-structure presentNo gas market presentNo economic benefit to re-inject the gas in the reservoirOften associated gas is considered as a by-product

Gas production facilitiesDisposal of waste streamsAcid gas from sweetening plantGlycol dehydration unitsInstrument vent gasProcess flash gas

In general flare and vent gas has various origins and therefore greatly varies in gas composition and quality

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Intermittent Flare and Vent measurement

Well testing

Well servicing

Depressurization (manual or controlled)

Compressor engine starts

Process upsets

Maintenance and inspection

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What is the ideal Gas Flare/Vent Meter ?

Tolerant to wet and dirty gas streams

Large turndownsmall waste streams during normal operations

large streams during blowdown and depressurization

Independent of fluid properties

Installation without a facility shut-down

Full bore measurements

Accuracy of a few percent

No upstream or downstream pipe requirements

Flow regime independent

Hence, the ideal Gas Flare/Vent meter does not exist !!!

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1. Introduction2. Flow regimes3. Fluid properties4. Flow measurement5. Composition measurement6. Design considerations7. Operational aspects

Content

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Velocity profile and velocity integration [1]

Path AveragingMulti-PointPoint

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Velocity profile and velocity integration [2]

Ref : API MPMS 14.10 [2007]

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1. Introduction2. Flow regimes3. Fluid properties4. Flow measurement5. Composition measurement6. Design considerations7. Operational aspects

Content

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Pressure room 405.3 kPa (4.053 bar)

1 Sm3 ? Sm3

Pressure room 101.3 kPa (1.013 bar)

How much gas is How much gas is present in the balloon ?present in the balloon ?

Difference between Sm3 and m3

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Equations of state- Ideal gases

p = absolute pressure N/m2

V = volume at p and T m3

n = amount of substance molR = universal gas constant 8.314 J/(mol.K) or (kPa.m3)/(kmol.K)T = absolute temperature K this is 273.15 + t (°C)

For ideal gases

TRnVp ... =

Note: 1 mol is the amount of substance which contains as many elementary entities (6.02 *1023) as there are atoms in 12 gram of Carbon-12

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Equations of state- Compressibility factor

),(..

. TpzTRn

Vp=

1.0

0.9

0.8

0.7

1.1

1.2

1.3

p (MPa)

0 10 20 30 40

Ideal gas

H2He

N2

Ar

z = 1 for 1) Ideal gases2) Low pressure gases

z is compressibility factor1) z is function of p and T2) z depends on composition

TRnzVp .... =

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1. Introduction2. Flow regimes3. Fluid properties4. Flow measurement5. Composition measurement6. Design considerations7. Operational aspects

Content

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Terms and definitions

Primary devicesFlow meter bodyPrimary sensing elementsTransmitters

Secondary devicesOther instruments measuring process conditionspressure, temperature and composition

Tertiary devicesCalculation devicesData loggersDCS, RTU, flow computers

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Single phase flowrate measurement- Operating range

Operating range: the range of flow rates within which thespecified accuracy can be obtained.

Turn-down: the ratio of maximum to minimum flowin the operating range.

Rangeability and Accuracy

Flow (arbitrary units)

Acc

urac

y (%

)

-40-30-20-10

010203040

0 10 20 30 40 50 60 70

Minimumat +/- 5%

Minimumat +/- 10%Max:Min

3:1 - limited range~ 10:1 - moderate range> 20:1 - good range

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Bernoulli’s Equation- Application to the Orifice/Venturi/Pitot devices

vv11, A, A11, P, P11 vv22, A, A22, P, P22Flow

v is fluid velocityA is areaP is pressure.

At the same height in the flow: 222

12

212

11 vPvP ρρ +=+

From continuity:

1

2

2

1

AA

vv

=

Combining:⎥⎦

⎤⎢⎣

⎡−=Δ 2

1

222

221 1

AAvP ρ

Need to knowthe density

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Venturi tube

Type of Measurement Δp (Bernoulli)Measurement point/path Cross Sectional AreaDiameter 2 to 48”Rangeability 10:1Straight pipe req’ments 6-20 D upstream, 2-40 D downstreamTotal pressure loss 10-20% of the ΔpP and T required ActVol = Yes, StdVol = Yes, Mass = YesUncertainty approx. 1-3% full scaleComposition dependent Yes, need densitySuitable in wet/dirty gas Yes, small amountsOther comments Eliminate pulsation

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Orifice plate

Type of Measurement Δp (Bernoulli)Measurement point/path Cross Sectional AreaDiameter 1 to 72”Rangeability 5:1Straight pipe req’ments 6-20 D upstream, 2-40 D downstreamTotal pressure loss HighP and T required ActVol = Yes, StdVol = Yes, Mass = YesUncertainty approx. 2-4% full scaleComposition dependent Yes, need densitySuitable in wet/dirty gas Yes, small amounts (drainhole)Other comments Pulsation

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(Averaging) Pitot tube

Type of Measurement Δp (Bernoulli)Measurement point/path Point or Multipoint averagingDiameter 1 to 72” (insertion) Rangeability 3:1Straight pipe req’ments 8-10 D upstream, 3 D downstreamTotal pressure loss Low, NilP and T required ActVol = Yes, StdVol = Yes, Mass = YesUncertainty approx. 1-5% full scaleComposition dependent Yes, need densitySuitable in wet/dirty gas LimitedOther comments Positioning critical, fouling, pulsation

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(Averaging) Pitot tube

Endress & HauserDP61D

Endress & HauserDP62D

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(Insertion) Turbine meter

Type of Measurement Velocity/VolumetricMeasurement point/path Point or Cross Sectional AreaDiameter 1 to 24” (insertion)Rangeability 20:1 to 100:1Straight pipe req’ments 10 D upstream, 5 D downstreamTotal pressure loss Design dependent (insertion low)P and T required ActVol = No, StdVol = Yes, Mass = YesUncertainty approx. 0.5% (insertion much higher)Composition dependent NoSuitable in wet/dirty gas LimitedOther comments Flow straightening, fouling

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Vortex flow meter

where,f = frequency of the vortices L = characteristic length of the bluff body V = velocity of the flow over the bluff body S = Strouhal number, which is essentially a constant

for a given body shape within its operating limits

LVSf .

=

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Vortex flow meter

Type of Measurement VelocityMeasurement point/path Cross Sectional AreaDiameter 1 to 24”Rangeability 30:1Straight pipe req’ments 10-20 D upstream, 5 D downstreamTotal pressure loss Design dependentP and T required ActVol = No, StdVol = Yes, Mass = YesUncertainty approx. 2% Composition dependent NoSuitable in wet/dirty gas LimitedOther comments Flow straightening, pulsation

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UltraSonic Gas Flow Measurement (transit time)

m

BAABm

mBA

mAB

vDQ

ttLv

vCLt

vCLt

.4.

11.)cos(.2

)cos(.

)cos(.

2π

ϕ

ϕ

ϕ

=

⎥⎦

⎤⎢⎣

⎡−=

−=

+=

C = Velocity of soundD = Pipe diameterL = Acoustic path length

LFlow D

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UltraSonic Gas Flow Measurement (transit time)

Type of Measurement VelocityMeasurement point/path Path or multi-pathDiameter > 3”Rangeability up to 2000:1Straight pipe req’ments 10-30 D upstream, 5-10 D downstreamTotal pressure loss NilP and T required ActVol = No, StdVol = Yes, Mass = YesUncertainty approx. 1-5% (no of paths) Composition dependent NoSuitable in wet/dirty gas Moderate (LVF < 0.5%)Other comments Elimination of swirl

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UltraSonic Gas Flow Measurement- Accuracy (1)

Ktt

ALQBAAB

⋅⎟⎟⎠

⎞⎜⎜⎝

⎛−⋅

⋅⋅=

11)cos(2 φ

Two uncertainty issues:

1) Travel time measurement (tAB, t BA)Instrument error

2) Installation parameters (L, A, φ)Geometry error

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GE Sensing GF 868 Flare Gas Meter

Downstream Transducers

Upstream Transducers

Pres

sure

Tra

nsm

itte

r

Temperature Transmitter

Preamplifier

Digital Analog and Alarm Output

FLOW

Spool piece• Best/Preferred solution• New build• Planned shutdownHot/ColdTap• Large Lines• Retrofit

Inside view of a bias 90 flare gas installation

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Fluenta FGM 160 Flare Gas Meter

Transducers

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Fluenta FGM 160 Flare Gas Meter

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Test facility NMI Delft

Master meter’s

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UltraSonic Gas Flow Measurement- Typical calibration curve

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Optical LaserTwoFocus

Type of Measurement VelocityMeasurement point/path PointDiameter Any (insertion)Rangeability up to 3000:1Straight pipe req’ments 10-30 D upstream, 5-10 D downstreamTotal pressure loss NilP and T required ActVol = No, StdVol = Yes, Mass = YesUncertainty approx. 3-7% Composition dependent NoSuitable in wet/dirty gas ModerateOther comments Elimination of swirl

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Optical Transit Time Velocimeters- LaserTwoFocus (L2F) Meters

Particle

Illuminating Optics

Detecting Optics

TSv

Δ=

Pro’s• High turn-down• High accuracy• Gas composition independent• Insertion typeCon’s• Point measurement

Photon Control L2B Optical Gas Flow Meter

39LS, Nov 2008

Thermal Mass Flow meter (Hot wire anemometer)

Type of Measurement VelocityMeasurement point/path PointDiameter Any (insertion)Rangeability 1000:1Straight pipe req’ments 8-10 D upstream, 3 D downstreamTotal pressure loss NilP and T required ActVol = Yes, StdVol = No, Mass = NoUncertainty approx. 1-3% Composition dependent Yes, need thermal conductivitySuitable in wet/dirty gas NoOther comments Positioning, fouling,

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Thermal Mass Flow meter (Anemometer)

Endress & Hausert-mass 65I

Size : 2.5-60”Turndown : 100:1Accuracy : 1%

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Technology Actual Volume Standard Volume Mass

UltraSonic (V) Output

Vortex Output

Optical Output

UltraSonic (M) Output

Thermal Output

Flowrate conversions Actual Conditions <> Standard Conditions

⎟⎟⎠

⎞⎜⎜⎝

⎛=

ffb

bbfvv ZTP

ZTPqQ

....

b

mv

qQρ

=b

vm

Qqρ

=

fvm qq ρ.=

fvm qq ρ.=

fvm qq ρ.=

⎟⎟⎠

⎞⎜⎜⎝

⎛=

ffb

bbfvv ZTP

ZTPqQ

....

⎟⎟⎠

⎞⎜⎜⎝

⎛=

ffb

bbfvv ZTP

ZTPqQ

....

b

vm

Qqρ

= bvm Qq ρ.=

42LS, Nov 2008

1. Introduction2. Flow regimes3. Fluid properties4. Flow measurement5. Composition measurement6. Design considerations7. Operational aspects

Content

43LS, Nov 2008

Composition Monitoring

Some FlowMeters are composition dependente.g. Δp type of metersIs relationship composition <>correction knownIs sensitivity to composition high or low

Convert volumetric flowrate to mass or energy flowrate (or vv)Determine heating value of the gas Emission measurement, e.g. H2S, SO2 or GHG reporting

Two ways to monitor composition:

1) Sampling and analyses

2) Continuous on-line analyzers

44LS, Nov 2008

Composition Monitoring1) Sampling and analyses

Manual sample or auto sampler

Laboratory analyses

Low cost

Representativeness in wet gas streams Not suitable for LVF or GVF measurement

Suitable for separate liquid composition and gas composition

Flow proportionality

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Composition Monitoring2) Continuous on-line analyzers

Only applicable for clean/processed gas

Need for conditioning units (sample train)

Higher maintenance

Higher costs

Not often used

Daniel® Model 500Gas Chromatographs

46LS, Nov 2008

1. Introduction2. Flow regimes3. Fluid properties4. Flow measurement5. Composition measurement6. Design considerations7. Operational aspects

Content

47LS, Nov 2008

SafetyStaffEquipment

LocationKnock-out drums neededAccessibility Single or Multiple meters

PipingFlow profileStraight runs up- and downstreamFlow conditionersSampling arrangements

Process conditions P and T measurementComposition measurement

Requirements AccuracyAvailabilityContinuous measurement

Flare Gas Meter Min/Max flowrateMin/Max gas velocityRate of changeTypical gas composition Change of gas compositionEffect of foulingPressure rangeTemperature rangeAmbient temperatureSensitivity to liquidsGas density (z-factor)Gas flowrate calculationsMeter outputDiagnostics softwareSignal processing

CompetenceService of vendorTraining own staff

Design considerations

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Flare Meter Datasheet- Ref MPMS API 14.10

49LS, Nov 2008

Flare Meter Datasheet- Ref MPMS API 14.10

50LS, Nov 2008

Flare Meter Datasheet- Ref MPMS API 14.10

51LS, Nov 2008

1. Introduction2. Flow regimes3. Fluid properties4. Flow measurement5. Composition measurement6. Design considerations7. Operational aspects

Content

52LS, Nov 2008

Methods for spot checks

No shut down requiredPersonnel operating in flare area >>

Need for strict procedures and policies Safety

Need for sampling and injection pointsAlso for verification of primary measurements

Four ways to execute spot checks:

1) Insertion flow meters

2) End-of-pipe measurements

3) Tracer dilution technology

4) Pulse velocity technique

53LS, Nov 2008

Methods for spot checks1) Insertion flow meters

Insertion point needs 20 D upstream straight length5D downstream straight length

Thermal anemometer (thermal mass flow meter)Great sensitivityNo wet or dirty gas applicationsSubject to fouling

Pitot tubeMechanically more complexSubject to fouling

54LS, Nov 2008

Methods for spot checks2) Tracer dilution technology

Injection of tracer (with known injection rate) upstreamAfter sufficient mixing sampling of the gas Analyses for the tracer Perform mass balance to determine the total gas flowrateor in other words:the dilution of tracer is a measure for the total gas flowrateSufficient mixing of tracer is requiredSampling at least 20 D from injection tracer point Background correction

Sample without tracer injection to find out backgroundTracer requirements:

Stable or inert substanceReasonable priceEasy onside analyses Example is SF6

55LS, Nov 2008

Methods for spot checks2) Tracer dilution technology

ci = Tracer concentration in the injected solution [mol/m3]cp = Tracer concentration in the pipeline [mol/m3]Qi = Injection flow rate of tracer solution [m3/s]Qp = Liquid flow rate in pipeline [m3/s]

Provided Qp >> Qi, the concentration of tracer in the pipe is:

CiCp

x Injection flow rateGas flow rate =

Tracer mass balance:

Mixing distanceGas sample

Tracer supplybottle

Meteringpump

Ci

Wet gasflow

Cp

56LS, Nov 2008

Methods for spot checks3) Pulse velocity technique

Radioactive tracer injection upstream

Detection of passing the first pulse

Detection of passing of second pulse

Velocity is distance detectors (ΔS) over (ΔT) time delay

57LS, Nov 2008

Continuous flare and vent measurement- Conclusion

Ultrasonic is the preferred choiceLiquid content should be < 0.5% by volume

(if >0.5% use liquid knock out vessel)

Excellent rangeability

Good accuracy

No frequent calibration required

Independent of gas composition or density