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Introduction

GC3-Natural Gas Analysis User Guide: Drilling Safety Monitoring

Manual Information

Author(s):

C. Bennight

Reviewer(s):

L. Brandt, C. Neal, K. Marsaglia

Editor(s):

K. Graber, L. Peters

Management Approval (Name, Title, Date):

D.J. Houpt, Supervisor of Analytical Systems, 9/24/2010

Audience:

Scientists, Laboratory Technicians

Origination date:

5/12/2008

Current version:

Version 1.0 9/24/2010

Revised:


Domain:

Chemistry

System:

Gas Chromatography

Keywords:

Hydrocarbons, Natural Gas, Headspace

Changes to User Guide

Summarize requested modifications to this user guide in an e-mail and/or annotate the PDF file and e-mail change requests to techdoc@iodp.tamu.edu.

User Guide Contents

Topic

Introduction

Apparatus, Reagents, & Materials

Instrument Calibration/Calibration Verification

Sample Preparation & Analysis

Quality Assurance/Quality Control

LIMS Integration

Health, Safety, & Environment

Maintenance & Troubleshooting (HP6890GC)

Introduction

Overview

Natural gas analysis for hydrocarbons and hydrogen sulfide (H2S) is required to avoid natural gas and oil escaping from the hole and is part of the ship's standard drilling safety plan.
The absolute quantity of hydrocarbons is the primary safety risk during shipboard operations. Gas monitoring via gas chromatography is a means of quantifying the hydrocarbon risk. H2S is another significant risk factor for individuals working in the area. Emergency monitors on the drill floor provide early detection of H2S, while later quantification is performed on the natural gas analyzer (NGA).

Hydrocarbon Gases

Hydrocarbon generation in sediments is a result of thermal decomposition (maturation) of biogenic organic matter. Natural gas analysis for hydrocarbons and hydrogen sulfide (H2S) is required to avoid natural gas and oil escaping from the hole and is part of the ship's standard drilling safety plan.
The absolute quantity of hydrocarbons is the primary safety risk during shipboard operations. Gas monitoring via gas chromatography is a means of quantifying the hydrocarbon risk. H2S is another significant risk factor for individuals working in the area. Emergency monitors on the drill floor provide early detection of H2S, while later quantification is performed on the natural gas analyzer (NGA). A primary method of monitoring safety conditions is the concentration ratio of methane to ethane versus temperature (Figure 1). 

Image Added

Figure 1. Risk Assessment for Drilling Safety (IODP).

Hydrocarbon Generation

Hydrocarbon generation in sediments is a result of thermal decomposition (maturation) of biogenic organic matter. C1–C4 hydrocarbons may be generated in significant quantities in sediment via two processes:

  • Biogenic: biogenic hydrocarbons, typically characterized by methane, are produced in a sulfate-free environment via the reduction of dissolved bicarbonate.
  • Thermogenic: thermogenic hydrocarbons are produced in sediments in direct proportion to temperature. C5 and other heavier hydrocarbons are almost always the result of thermal generation of hydrogen-rich organic matter at temperatures typically ~100°C or greater.

The evolution of sedimentary biogenic organic matter under increasing burial depth and consequent temperature rise is divided into three stages:

  • Diagenesis
    • biological, physical, and chemical alteration of sedimentary organic matter that occurs at low temperature (<50°C) in relatively recently deposited sediments (Peters et al., 2005).
  • Catagenesis
    • principal zone of oil formation, refers to a temperature range of 50°C~150°C. Liquid and gaseous hydrocarbons together with organic compounds with heteroatoms (oxygen, sulfur, and nitrogen) are released from the kerogen (Figure 2), so the catagenesis stage is called the "oil window."
  • Metagenesis
    • Dry gases (mainly methane) are derived from liquid hydrocarbon accumulation in the crust (Figure 3). C1–C4 hydrocarbons may be generated in significant quantities in sediment via
two processes:
  • Biogenic: biogenic hydrocarbons, typically characterized by methane, are produced in a sulfate-free environment via the reduction of dissolved bicarbonate.
  • Thermogenic: thermogenic hydrocarbons are produced in sediments in direct proportion to temperature. C5 and other heavier hydrocarbons are almost always the result of thermal generation of hydrogen-rich organic matter at temperatures typically ~100°C or greater.

Hydrogen Sulfide

Sulfate-reducing bacteria produce hydrogen sulfide in euxinic sediments. This may occur in
    • biogenic and thermogenic processes.


Image Added
Figure 2. Hydrocarbon Formation Pathways in Geological Situations (Rullkotter, 1993).
Image Added
Figure 3. Hydrocarbon Generation Resulting from Burial of Organic Matter during Geologic Time.


Hydrogen Sulfide

Sulfate-reducing bacteria produce hydrogen sulfide in euxinic sediments. This may occur in a relatively shallow part of the sediment. Thermochemical sulfate reduction of sulfate by hydrocarbons in reservoirs occurs under high temperature (>127°C ~ 140°C).

Theory of Method

Two instruments monitor gases in core headspace and core void samples:

  • GC3: Agilent 6890 gas chromatograph (GC) with flame ionization detector (FID). This instrument measures C1–C3 hydrocarbons:
  • Methane (CH4)
  • Ethene (C2H4)
  • Ethane (C2H6)
  • Propene (C3H6)
  • Propane (C3H8)
  • NGA: Agilent 6890 GC with FID and thermal conductivity detector (TCD). This instrument measures C1–C7 hydrocarbons as well as some additional compounds:
  • Methane (CH4)
  • Ethene (C2H4)
  • Ethane (C2H6)
  • Propene (C3H6)
  • Popane (C3H8)
  • n-Butane (C4H10)
  • iso-Butane (

    Instruments

    The NGA systems are both based on an Agilent 7890 GCs. These systems were further customized with specialized gas injection inlets and various column, detector, and valving systems for gas monitoring

    Gases

    The GC requires that hydrogen and air are connected to the marked fittings on the back of the instrument. The type of makeup gas must be identified in the method file.

    • Air, compressed (Zero-Air +): >50 psi
    • Helium, compressed (99.9995% +): >50 psi
    • Hydrogen, compressed (99.9995% +): >50 psi


    Method


    Theory of method

    The NGA gas chromatograph is equipped with 2 detectors:

    • Flame ionization detector (FID)
    • Thermal conductivity detector (TCD)

    The TCD flow path travels through a 6 ft x 2.0 mm ID stainless steel (SS) column packed with Poropak T (50/80 mesh), a 3 ft x 2.0 mm ID SS column packed with molecular sieve 13x (60/80 mesh), and 6 ft x 2.0 mm ID SS column packed with 80/100 mesh HayeSep R (acid washed).
    The FID flow path traverses a 60 m x 0.25 mm ID capillary column with 0.25 µm DB-1 film.

    This instrument measures C1–C7 hydrocarbons as well as some additional compounds:

    AnchorRTF36353035383a204669675469RTF36353035383a204669675469

    Instrument Calibration/Calibration Verification

    Overview
    • Methane (CH4)
    • Ethene (C2H4)
    • Ethane (C2H6)
    • Propene (C3H6)
    • Popane (C3H8)
    • n-Butane (C4H10)
    • iso-Butane (CH3-C3H7)
    • n-Pentane (C5H12)
    • iso-Pentane (CH3-C4H9)
    • n-Hexane (C6H14)
    • iso-Hexane (CH3-C5H11)
    • n-Heptane (C7H16)
    • iso-Heptane (CH3-C6H13)
    • Nitrogen (N2)
    • Oxygen (O2)

    The FID column on the NGA cannot separately quantify ethene/ethane and propene/propane, and they are reported as combined values. The TCD column does separate these components.

    AnchorRTF39353435363a203248656164RTF39353435363a203248656164Apparatus, Reagents, & Materials

    Instruments

    The GC3 and NGA systems are both based on an Agilent 6890 GCs. These systems were further customized with specialized gas injection inlets and various column, detector, and valving systems for gas monitoring.

    GC 3

    The GC3 system is equipped with a 1/6 inch VALCO union injector with 2 µm screen and an electronically switched 10 port VALCO valve. The column is an 80/100 mesh, 8 ft HayeSep "R" packed column (2.0 mm ID x 1/8 inch OD).
    The detector is an FID.

    NGA

    The NGA gas chromatograph is equipped with 2 detectors:

    • Flame ionization detector (FID)
    • Thermal conductivity detector (TCD)
    The TCD flow path travels through a 6 ft x 2.0 mm ID stainless steel (SS) column packed with Poropak T (50/80 mesh), a 3 ft x 2.0 mm ID SS column packed with molecular sieve 13x (60/80 mesh), and 6 ft x 2.0 mm ID SS column packed with 80/100 mesh HayeSep R (acid washed).
    The FID flow path traverses a 60 m x 0.25 mm ID capillary column with 0.25 µm DB-1 film.
    • Carbon dioxide (CO2)

    NGA Sample Flow Schematics

    Standby Mode

    He gas flow for standby mode (green lines).

    • Line 1: Aux-3—V1-4—V2-5—V2-3—capillary column—V2-4—V2-1—FID
    • Line 2: Aux-4—sample inlet—V1-2—V1-3—V1-6—V1-1—V3-3—V3-4—V3-1—V4-3—V4-2—V4-5—V4-4—Vent
    • Line 3: Front inlet—V3-5—V3-6—HaySep R column—V3-8—V3-7—V4-9—V4-8—TCD
    • Line 4: Back inlet—V4-6—V4-7—MolSieve column—V4-1—V4-10—Vent


    Image Added
    Figure 9. NGA in Standby Mode.


    Injection mode

    He carrier gas (green line) and sample gas (red line) flows in the NGA in injection mode. Sample gas fills the sample loops connected to V1 (25 µL), V3 (1 cm3), and V4 (0.5 cm3). He flushes the separation columns.
    He gas flow (green):

    • Line 1: Aux-3—V1-4—V1-5—V2-3—V2-2—capillary column—V2-4—V2-1—FID
    • Line 3: Front inlet—V3-5—V3-6—HaySep R column—V3-8—V3-7—V4-9—V4-8—TCD
    • Line 4: Back inlet—V4-6—V4-7—MolSieve column—V4-1—V4-10—Vent


    Sample gas flow (purge; red):

    • Sample inlet—V1-2—V1-3—V1-6—V1-1—V3-3—V3-4—V3-1—V3-2—V4-3—V4-2—V4-5—V4-4—Vent


    Image Added
    Figure 10. NGA in Injection Mode.


    Run Mode at 0.01 min (open Valve V4)

    He (green) and sample gas (red) flows in the NGA 0.01 min after start of run. Sample gas remains in the sample loop connected to V1 (25 µL) and V3 (1 cm3). After V4 opens, He returning from the back inlet pushes the sample gas out of the sample loop and into the molecular sieve column. Separated elements are detected by TCD.
    He gas flow:

    • Line 1: Aux-3—V1-4—V1-5—V2-3—V2-2—capillary column—V2-4—V2-1—FID
    • Line 2: Aux-4—V1-2
    • Line 3: Front inlet—V3-5—V3-6—HayeSep R column—V3-8—V3-7—V4-9—V4-10—Vent
    • Line 4: Back inlet—V4-6—V4-5


    Sample gas flow (purge):

    • V1-2—V1-3—V1-6—V1-1—V3-3—V3-4—V3-1—V3-2—V4-3—V4-4—out


    Sample gas flow with He:

    • V4-5—V4-2—V4-1—MolSieve column—V4-7—V4-8—TCD


    Image Added
    Figure 11. NGA in Run Mode: 0.01 min after starting run.


    Run Mode at 0.07 min (open Valves V1 and V2)

    He (green) and sample gas (red) flows in the NGA 0.07–1.79 min after start of run. Sample gas remains in the sample loop connected to V3 (1 cm3). After V1 and V2 open, He from Aux-3 pushes the sample gas out of the sample loop connected to V1 (25 µL) and into the capillary column (60 m) through V2, where it passes into the FID.
    He gas flow:

    • Line 1: Aux-3—V1-4
    • Line 2: Aux-4—V1-2
    • Line 3: Front inlet—V3-5—V3-6—HaySep R column—V3-8—V3-7—V4-9—V4-10—vent
    • Line 4: Back inlet—V4-6—V4-5—V4-2—V4-1—MolSieve column—V4-7—V4-8


    Sample gas flow (purge):

    • V3-4—V3-1—V3-2—V4-3—V4-4—out


    Sample gas flow with He:

    • V4-8—TCD
    • V1-3—V1-6—V1-5—V2-3—V2-4—capillary column—V2-2—V2-1—FID
    • V1-1—V3-3


    Image Added
    Figure 12. NGA in Run Mode: 0.07–1.79 min after starting run.


    Run Mode at 1.80 min (open Valve V3)

    He (green) and sample gas (red) flows in the NGA 1.80–1.82 min after start of run. After V3 opens, He from the front inlet pushes the sample gas out of the 1 cm3 sample loop into the HaySep column.
    He gas flow:

    • Line 1: Aux-3—V1-4—V1-3—V1-6—V1-5—V2-3—V2-4
    • Line 2: Aux-4—V1-2—V1-1—V3-3—V3-2—V4-3—V4-4—out
    • Line 3: Front inlet—V3-5—V3-4
    • Line 4: Back inlet—V4-6—V4-5—V4-2—V4-1—MolSieve column—V4-7—V4-8—TCD


    Sample gas flow with He:

    • Capillary column—V2-2—V2-1—FID
    • B3-4—V3-1—V3-8—HaySep R column—V3-6—V3-7


    Image Added
    Figure 13. NGA in Run Mode: 1.80–1.82 min after starting run.


    Run Mode at 1.83 min (close Valve V4)

    He (green) and sample gas (red) flows in the NGA 1.83–8.49 min after start of run. After V4 closes, He from the back inlet flushes the molecular sieve column (backflush). Gas samples separated by the HaySep column enter the TCD through V4.
    Helium gas flow:

    • Line 1: Aux-3—V1-4—V1-3—V1-6—V1-5—V2-3—V2-4—capillary column—V2-2—V2-1—FID
    • Line 2: Aux-4—V1-2—V1-1—V3-3—V3-2—V4-3—V4-2—V4-5—V4-4—out
    • Line 3: Front inlet—V3-5—V3-4—V3-1—V3-8


    Sample gas flow with He:

    • HaySep R column—V3-6—V3-7—V4-9—V4-8—TCD

    Backflush:

    • Line 4: Back inlet—V4-6—V4-7—MolSieve column—V4-1—V4-10—vent


    Image Added
    Figure 14. NGA in Run Mode: 1.83–8.49 min after starting run.


    Run Mode at 8.50 min (close Valve V3)

    He gas (green) and sample gas (red) flows in the NGA 8.50–9.09 min after start of run. After V3 closes, He from the front inlet flushes the HaySep column and the line leading to the TCD (backflush).
    He gas flow:

    • Line 1: Aux-3—V1-4—V1-3—V1-6—V1-5—V2-3—V2-4—capillary column—V2-2—V2-1—FID
    • Line 2: Aux-4—V1-2—V1-1—V3-3—V3-4—V3-1—V3-2—V4-3—V4-2—V4-5—V4-4—out
    • Line 3: Back inlet—V4-6—V4-7—MolSieve column—V4-1—V4-10—vent


    Backflush:

    • Line 3: Front inlet—V3-5—V3-6—HaySep R column—V3-8—V3-7—V4-9—V4-8—TCD


    Image Added
    Figure 15. NGA in Run Mode: 8.50–9.09 min after starting run.


    Run Mode at 10.0 min (close Valves V1 and V2)

    He (green) and sample gas (red) flows in the NGA 9.09–10.0 min after start of run. After V1 and V2 close, He flow returns to standby mode.
    He gas flow:

    • Line 1: Aux-3—V1-4—V1-5—V2-3—V2-2—capillary column—V2-4—V2-1—FID
    • Line 2: Aux-4—V1-2—V1-3—V1-6—V1-1—V3-3—V3-4—V3-1—V3-2—V4-3—V4-2—V4-5—V4-4—out
    • Line 3: Front inlet—V3-5—V3-6—HaySep R column—V3-8—V3-7—V4-9—V4-8—TCD
    • Line 4: Back inlet—V4-6—V4-7—MolSieve column—V4-1—V4-10—vent


    Image Added
    Figure 16. NGA in Run Mode: 9.09–10.0 min after starting run.



    NGA Startup

    The chromatography application ChemStation controls GC data acquisition and processing. It can be run either online or offline. Offline mode can be run without communication with the GCs, so it is useful for reintegrating or reprocessing chromatograms. Online mode requires communication with the GC.

    • Turn on the GC. WARNING: Before turning on the GC, make sure the gas lines are open.
      The 6890 GC performs a comprehensive self-evaluation and shows real-time diagnostics on the screen. Warning, Fault, or Bad Main Board & Fatal Error messages require troubleshooting before moving to the next step (see Maintenance & Troubleshooting (HP6890GC)).
    • Click the Agilent Control Panel, then select NGA1 or NGA2, then Launch to start ChemStation. The Method and Run Control window opens. At startup, ChemStation uses the method last used (shown on the main screen). In addition, the GC LCD shows the loaded settings from ChemStation. Settings changed on the GC using the GC control panel are also made to ChemStation, and parameter changes entered into ChemStation are made to the GC. ChemStation will prompt to save changes.
    • To load a different method in Chemstation:

      • Click Method > Load Method, select the method from the list, and press OK or
      • Click the Method tab on the left side of the window and select a method to load
    • The system automatically loads the new method selected in ChemStation to the appropriate GC. Oven and detector temperatures may increase immediately after a new method is loaded, and the FID will ignite when the detector temperature reaches 150°C. Sometimes, the GC beeps because the FID flame is out, especially after a long idle period. See Maintenance & Troubleshooting (HP6890GC).
    • If the GC has been turned off for longer than a week, then bake the column for 8 hr with gas flowing (manually set the oven temperature to 175°C for GC3 or 275°C for NGA).



    Instrument Operation


    Before unknown samples can be analyzed for headspace gases, each GC system must have a valid calibration curve and the calibration curve must have been verified using a calibration verification standard.

    1

    Create/refresh calibration curve (start at least 1 day before reaching site) (see Creating a Calibration Curve).

    2

    Verify calibration (Running a Calibration Verification Standard).

    3

    Perform a work flow test (Running a Gas Sample).

    Creating a Calibration Curve

    1

    Prepare 5–7 registered standard gases.

    2

    Activate GC3/NGA LIMS uploader located at Start > Program Files > IODP > MegaUploadaTron. The uploader must be activated before the calibration is run.

    3

    In the ChemStation Main menu, click Run Control > Sample Info.

    4

    Fill in the specific fields on the screen as follows:

    • Operator name: LIMS user account (your last name)
    • Sample name: name of the standard (e.g., STD_D) and the replicate number (STD_D-1, STD_D-2, etc.)
    • Comment: text ID of the standard (scan the label)
      Click OK to close screen.

    5

    Slowly inject 5000 µL of the first standard gas and observe the floating ball in the flow meter move upward.
    Keep the outflow rate on the flow meter <80 mL/min.

    6

    When the ball in the flow meter indicates flow has fallen to just above 0 (is about to hit 0), press the Start button on the control panel of the GC.

    7

    When the run has finished, open the Data Analysis screen in ChemStation and click Calibration.

    8

    On the Main ChemStation menu, select Calibration > Recalibrate.

    9

    On the Recalibration screen, select Level # and Replace (or Average) as applicable for that level.

    10

    Repeat Steps 5–9 for 3 replicate standards (CH4: A 25%, B = 50%, C 75%, D = 99%).

    11

    Click OK to change the calibration value. For NGA calibration, the same standard can be applied to both the appropriate TCD and FID level; you do not need separate standards for TCD and FID.

    Running a Calibration Verification Standard

    1

    Ensure the uploader is activated and the CV standard is registered in LIMS.

    2

    Click Run Control in the main menu of ChemStation and select Sample Info.

    3

    Fill in the specific section on the window as follows:

  • Operator name: LIMS user account (your last name)
  • Sample name: common name for standard (e.g., STD_D-1)
  • Comment: text ID of the standard

    must have been verified using a calibration verification standard.

    Creating a Calibration Curve

    1

    Prepare 5–7 registered standard gases.

    2

    Activate NGA LIMS uploader located at Start > Program Files > IODP > MegaUploadaTron. The uploader must be activated before the calibration is run.

    3

    In the ChemStation Main menu, click Run Control > Sample Info.

    4

    Fill in the specific fields on the screen as follows:

    • Operator name: LIMS user account (your last name)
    • Sample name: name of the standard (e.g., STD_D) and the replicate number (STD_D-1, STD_D-2, etc.)
    • Comment: text ID of the standard (scan the label)
      Click OK to close screen.

    5

    Slowly inject 5000 µL of the first standard gas and observe the floating ball in the flow meter move upward.
    Keep the outflow rate on the flow meter <80 mL/min.

    6

    When the ball in the flow meter indicates flow has fallen to just above 0 (is about to hit 0), press the Start button on the control panel of the GC.

    7

    When the run has finished, open the Data Analysis screen in ChemStation and click Calibration.

    8

    On the Main ChemStation menu, select Calibration > Recalibrate.

    9

    On the Recalibration screen, select Level # and Replace (or Average) as applicable for that level.

    10

    Repeat Steps 5–9 for 3 replicate standards (CH4: A 25%, B = 50%, C 75%, D = 99%).

    11

    Click OK to change the calibration value. For NGA calibration, the same standard can be applied to both the appropriate TCD and FID level; you do not need separate standards for TCD and FID.

    Running a Calibration Verification Standard

    1

    Ensure the uploader is activated and the CV standard is registered in LIMS.

    2

    Click Run Control in the main menu of ChemStation and select Sample Info.

    3

    Fill in the specific section on the window as follows:

    • Operator name: LIMS user account (your last name)
    • Sample name: common name for standard (e.g., STD_D-1)
    • Comment: text ID of the standard (scan the label)
      Click OK to close the sample info screen.

    4

    Prepare the CV standard at approximately the mid-point concentration of the curve.

    5

    Slowly inject 5000 µL of the standard gas, keeping the outflow rate <80 mL/min.

    6

    Press Start on the GC control panel when the flow meter is just above 0.

    7

    When the run is finished, the report will automatically display the values. Click Upload in the uploader to submit the data to LIMS.

    Running a Blank

    1

    To run a blank, in the Main menu click RunControl > Sample Info.

    2

    Fill in the following fields:

    • Operator name: your last name
    • Sample name: "BLANK"
    • Comment: text ID of the blank (scan the label)
      Click OK to close the sample info screenwindow and save information.

    43

    Prepare the CV standard at approximately the mid-point concentration of the curve.

    5

    Slowly inject 5000 µL of the standard gas, keeping the outflow rate <80 mL/min.

    6

    Press Start laboratory air (5000 µL) and inject it into the GC in the same fashion as the standards above when the ChemStation software shows Ready.

    4

    Press the Start button on the GC control panel when the flow meter is just above 0to start the run.

    7

    When the run is finished, the report will automatically display the values. Click Upload in the uploader to submit the data to LIMS5

    Confirm the chromatogram on the screen shows no peaks. If peaks are present, the system contamination must be found (injector, detector, sample loop, etc.).

    Running a

    Blank

    Gas Sample

    1To

    run a blank, in the Main menu click RunControl > Ensure the uploader has been activated.

    2

    Click Run Control in the main menu of ChemStation and select Sample Info.

    23

    Fill in the following fieldsspecific section on the window as follows:

    • Operator name: LIMS user account (your last name)
    • Sample name: "BLANK"Exp/site/hole/core/coretype/section/interval (e.g., 324-U1351A 5H4 32-35)
    • Comment: text ID of the blank sample (scan the label)
      Click OK to close window and save information.

    3

    Prepare laboratory air (5000 µL) and inject it into the GC in the same fashion as the standards above when the ChemStation software shows Ready.

    4

    Press the Start button on the GC control panel to start the run.

    5

    Confirm the chromatogram on the screen shows no peaks. If peaks are present, the system contamination must be found (injector, detector, sample loop, etc.).

    Running a Gas Sample

    1

    Ensure the uploader has been activated.

    2

    Click Run Control in the main menu of ChemStation and select Sample Info.

    3

    Fill in the specific section on the window as follows:

    • Operator name: LIMS user account (your last name)
    • Sample name: Exp/site/hole/core/coretype/section/interval (e.g., 324-U1351A 5H4 32-35)
    • Comment: text ID of sample (scan label)
      Click OK to close sample info screen.

    4

    Prepare a headspace or void gas sample.

    5

    Slowly inject 5000 µL of the gas sample, keeping the maximum gas outflow <80 mL/min.

    6

    Press Start on the GC control panel when the ball on the flow meter is just above 0.

    Sample Preparation & Analysis

    Overview

    There are two primary sample types used for natural gas analysis.

    • Headspace gas, which is obtained from core samples by heating a sample to ~70°C.
    • Void gas collected with a vacuum vial.

    Occasionally, cores that come on deck have voids with large amounts of free gas. Free gas must be sampled using a sampling device that penetrates the liner and provides a channel for the gas to be drawn into a gas-tight syringe, vacuum vial, or gas sampling bag.

    Sampling Tools

    • Sample coring tool (metal cylinder)
    • Sample coring plunger
    • Puncture tool (to penetrate plastic liner)
    • Headspace vial
    • Headspace gasket with crimp top
    • Crimping tool
    • Permanent marker for labeling

    Sampling Procedure and Gas Sample Preparation

    Headspace Gas

    Collect samples from a freshly cut core section at a position within 0.5 inch of the inner side of the core liner (where sample has not been disturbed by contact with drilling fluid or core liner). In addition, the sample must be taken prior to the use of acetone or any other organic solvent in the catwalk area.
    The curator authorizes the sampling plan before coring; therefore, the chemistry specialist must know the catwalk sampling plan before taking samples.

    Collecting a Headspace Gas Sample

    1

    Locate a freshly sectioned core (consult with the curator).

    2

    Gently push the sample coring tool into the core section slightly inward of the edge.

    3

    Gently pull out the tool. If the sample recovery (% of coring tool with sample) is >80% (~5–7 cm3), proceed; otherwise repeat Steps 1 and 2.

    4

    Place the open end of the sample coring tool over a clean headspace gas vial and use the plunger to push the sediment into the vial.

    5

    Immediately place a gasket with a crimp top over the vial and crimp shut.

    6

    After sealing the vial, immediately write down the sampling interval, location, and any other information for the sample that was just taken. Generate a proper label and apply it to the vial as soon as possible.

    7

    Place the vial with the sample in a 70°C oven for 30 min to degas the sediment (use timer).

    8

    Inject extracted gas sample into the GC using syringe (see
    Running a Sample).

    Collecting a Void Gas Sample

    1

    Use the puncture tool to make a hole in the core liner to make a channel for the gas.

    2

    Quickly collect a free gas sample from the small hole with a syringe.

    3

    Immediately introduce the gas sample into the GC instruments in the same manner as the headspace samples.

    Running a Sample

    1

    Start GC and operation system at least 1 day before reaching site (the system should be fully calibrated and ready for analysis) (see Advanced User Guide).

    2

    Ensure LIMS uploader is running.

    3

    Inject 5 mL of headspace gas after the sample has heated in the oven for 30 min.

    4

    Click Upload if the uploader is not in automatic mode.

    Quality Assurance/Quality Control

    Overview

    QA/QC for GC3/NGA analysis consists of instrument calibration and continuing calibration verification using check standards, instrument blanks, and replicate samples.

    Analytical Batch

    An analytical batch is a method-defined number of samples with which QC samples including calibration verification, blank, and replicate samples are run. Samples are implicitly grouped into batches based on the spacing between CV samples.

    QC Samples

    Blank

    • The blank determines the level of contamination originating from the laboratory environment (air) and sample path in the GC (injection port with screen, sample loop, and separation column).
    • Run a blank with each batch of samples by injecting 5 mL of ambient laboratory air into the GC using the same syringe used to inject headspace gas samples.
    • All calibrated values other than O2 and N2 should be nondetectable in the blank. If aberrant peaks appear, bake the column for 8 hr and repeat the blank analysis.

    Calibration Sample

    • Five to seven levels of calibration samples (standard gases) are used to create a calibration curve, which is saved with the measurement data (see Instrument Calibration/Calibration Verification).
    • Correlation coefficient values for calibration curves should be 0.99 or better, except O2 and N2, which should be 0.95 or better.

    Calibration Verification (CV) Sample

    • Select one of the 5–7 calibration samples from the calibration curve for the calibration verification sample.
    • Run a CV sample at least every shift that samples are taken (see Instrument Calibration/Calibration Verification).
    • The CV should fall within 3% of the calibrated value; O2 and N2 should be within 10% of the calibrated value.

    Control Limits

    For a system to be considered in control, all QA/QC samples (blank and calibration verification) must be in control.

    In Control

    A QA/QC sample is in control when the sample analysis result is within a certain tolerance of acceptable limits (see above). Calibration verification samples should be within acceptable limits of the actual value calculated against the calibration curve (see Calibration Verification (CV) Sample) and blanks should be within acceptable limits of background levels of headspace hydrocarbons and gases (see Blank). When the system is in control, as indicated by acceptable results on QA/QC samples, analytical results for unknown samples are considered to be reliable.

    Out of Control

    If the control limits are exceeded, the instrument system is considered out of control and all samples in the current analytical batch are invalid and must be rerun after the system is proved to be in control.

    LIMS Integration

    LIMS Components

    Analysis

    Component

    Unit

    Description

    GC3

    dat
    • sample info screen.

    4

    Prepare a headspace or void gas sample.

    5

    Slowly inject 5000 µL of the gas sample, keeping the maximum gas outflow <80 mL/min.

    6

    Press Start on the GC control panel when the ball on the flow meter is just above 0.


    Sample Preparation 


    There are two primary sample types used for natural gas analysis.

    • Headspace gas, which is obtained from core samples by heating a sample to ~70°C.

    • Void gas collected with a vacuum vial.

    Occasionally, cores that come on deck have voids with large amounts of free gas. Free gas must be sampled using a sampling device that penetrates the liner and provides a channel for the gas to be drawn into a gas-tight syringe, vacuum vial, or gas sampling bag.

    Headspace Gas

    Collect samples from a freshly cut core section at a position within 0.5 inch of the inner side of the core liner (where sample has not been disturbed by contact with drilling fluid or core liner). In addition, the sample must be taken prior to the use of acetone or any other organic solvent in the catwalk area.
    The curator authorizes the sampling plan before coring; therefore, the chemistry specialist must know the catwalk sampling plan before taking samples.

    1

    Locate a freshly sectioned core (consult with the curator).

    2

    Gently push the sample coring tool into the core section slightly inward of the edge.

    3

    Gently pull out the tool. If the sample recovery (% of coring tool with sample) is >80% (~5–7 cm3), proceed; otherwise repeat Steps 1 and 2.

    4

    Place the open end of the sample coring tool over a clean headspace gas vial and use the plunger to push the sediment into the vial.

    5

    Immediately place a gasket with a crimp top over the vial and crimp shut.

    6

    After sealing the vial, immediately write down the sampling interval, location, and any other information for the sample that was just taken. Generate a proper label and apply it to the vial as soon as possible.

    7

    Place the vial with the sample in a 70°C oven for 30 min to degas the sediment (use timer).

    8

    Inject extracted gas sample into the GC using syringe (see
    Running a Sample).


    Collecting a Void Gas Sample

    1

    Use the puncture tool to make a hole in the core liner to make a channel for the gas.

    2

    Quickly collect a free gas sample from the small hole with a syringe.

    3

    Immediately introduce the gas sample into the GC instruments in the same manner as the headspace samples.

    Data Upload


    Data is uploaded from the NGA via a multi-step process:

    1. When the run is complete, a macro (NGA_MUT.MAC) is automatically called, as configured in the method file. The macro copies information from the method directory to C:\LIMS\NGA\data
    2. An in-house program called MegaUploadaTron (MUT) monitors the data folder locations and when a file is copied in initiates the next steps of the upload process.
    • The file is opened and read, and data points are uploaded to LIMS
    • The data files are compressed (zipped) and uploaded as well
    • LIMS analysis codes are NGAFID, and NGATCD
    1. After the upload to LIMS is complete, MUT moves the data files to an archive directory at C:\DATA\GC3\archive or C:\DATA\NGA\archive.
    2. If an upload error occurs, the files are not archived and MUT will report the error in the main window (only).

    Quality Assurance/Quality Control


    QA/QC for GC3/NGA analysis consists of instrument calibration and continuing calibration verification using check standards, instrument blanks, and replicate samples.

    Analytical Batch

    An analytical batch is a method-defined number of samples with which QC samples including calibration verification, blank, and replicate samples are run. Samples are implicitly grouped into batches based on the spacing between CV samples.

    QC Samples

    Blank

    • The blank determines the level of contamination originating from the laboratory environment (air) and sample path in the GC (injection port with screen, sample loop, and separation column).
    • Run a blank with each batch of samples by injecting 5 mL of ambient laboratory air into the GC using the same syringe used to inject headspace gas samples.
    • All calibrated values other than O2 and N2 should be nondetectable in the blank. If aberrant peaks appear, bake the column for 8 hr and repeat the blank analysis.


    Calibration Sample

    • Five to seven levels of calibration samples (standard gases) are used to create a calibration curve, which is saved with the measurement data (see Instrument Calibration/Calibration Verification).
    • Correlation coefficient values for calibration curves should be 0.99 or better, except O2 and N2, which should be 0.95 or better.

    Calibration Verification (CV) Sample

    • Select one of the 5–7 calibration samples from the calibration curve for the calibration verification sample.
    • Run a CV sample at least every shift that samples are taken (see Instrument Calibration/Calibration Verification).
    • The CV should fall within 3% of the calibrated value; O2 and N2 should be within 10% of the calibrated value.

    Control Limits

    For a system to be considered in control, all QA/QC samples (blank and calibration verification) must be in control.

    In Control

    A QA/QC sample is in control when the sample analysis result is within a certain tolerance of acceptable limits (see above). Calibration verification samples should be within acceptable limits of the actual value calculated against the calibration curve (see Calibration Verification (CV) Sample) and blanks should be within acceptable limits of background levels of headspace hydrocarbons and gases (see Blank). When the system is in control, as indicated by acceptable results on QA/QC samples, analytical results for unknown samples are considered to be reliable.

    Out of Control

    If the control limits are exceeded, the instrument system is considered out of control and all samples in the current analytical batch are invalid and must be rerun after the system is proved to be in control.

    LIMS Integration


    LIMS Components

    Analysis

    Component

    Unit

    Description

    GC3

    dat_asman_id

    Serial number of chromatographic data file in digital asset management database (ASMAN)


    dat_filename

    File name of chromatographic data file containing measurements


    run_test

    Test number of related calibration or QA/QC test


    propene

    ppmv

    Relative concentration of propene in the sample


    propane

    ppmv

    Relative concentration of propane in the sample


    ethene

    ppmv

    Relative concentration of ethene in the sample


    ethane

    ppmv

    Relative concentration of ethane in the sample


    methane

    ppmv

    Relative concentration of methane in the sample

    GC3_QAQC

    dat_asman_id

    Serial number of chromatographic data file in ASMAN


    dat_filename

    File name of chromatographic data file containing measurements


    run_test

    Test number of related calibration or QA/QC test


    propene

    ppmv

    Relative concentration of propene in the sample


    propane

    ppmv

    Relative concentration of propane in the sample


    ethene

    ppmv

    Relative concentration of ethene in the sample


    ethane

    ppmv

    Relative concentration of ethane in the sample


    methane

    ppmv

    Relative concentration of methane in the sample

    GC3_QCAL

    mtd_asman_id

    Serial number of chromatographic data file in digital asset management database (ASMAN)datmethod in ASMAN


    mtd_filename

    File name of the chromatographic data method file containing measurements


    runethene_testcorr2

    Test number of related calibration or QA/QC test

    propene

    ppmv

    Relative concentration of propene in the sample

    propane

    ppmv

    Relative concentration of propane in the sample

    ethene

    ppmv

    Relative concentration of ethene in the sample

    ethane

    ppmv

    Relative concentration of ethane in the sample

    methane

    ppmv

    Relative concentration of methane in the sample

    GC3_QAQC

    dat_asman_id

    Serial number of chromatographic data file in ASMAN

    dat_filename

    File name of chromatographic data file containing measurements

    run_test

    Test number of related calibration or QA/QC test

    propene

    ppmv

    Relative concentration of propene in the sample

    propane

    ppmv

    Relative concentration of propane in the sample

    ethene

    ppmv

    Relative concentration of ethene in the sample

    ethane

    ppmv

    Relative concentration of ethane in the sample

    methane

    ppmv

    Relative concentration of methane in the sample

    GC3_QCAL

    mtdR2

    Ethene calibration coefficient


    ethene_intercept

    Intercept of ethene calibration curve


    ethene_slope

    Slope of ethene calibration curve


    ethane_corr2

    R2

    Ethane calibration coefficient


    ethane_intercept

    Intercept of ethane calibration curve


    ethane_slope

    Slope of ethane calibration curve


    propene_corr2

    R2

    Propene calibration coefficient


    propene_intercept

    Intercept of propene calibration curve


    propene_slope

    Slope of propene calibration curve


    propane_corr2

    R2

    Propane calibration coefficient


    propane_intercept

    Intercept of propane calibration curve


    propane_slope

    Slope of propene calibration curve


    methane_corr2

    R2

    Methane calibration coefficient


    methane_intercept

    Intercept of methane calibration curve


    methane_slope

    Slope of methane calibration curve

    NGAFID

    dat_asman_id

    Serial number of chromatographic method data file in ASMAN


    mtddat_filename

    File name of the chromatographic method data file containing measurements


    ethene_corr2

    R2

    Ethene calibration coefficient

    ethene_interceptrun_test

    Intercept Test number of ethene calibration curve

    ethene_slope

    Slope of ethene calibration curve

    ethane_corr2

    R2

    Ethane calibration coefficient

    ethane_intercept

    Intercept of ethane calibration curve

    ethane_slope

    Slope of ethane calibration curve

    propene_corr2

    R2

    Propene calibration coefficient

    propene_intercept

    Intercept of propene calibration curve

    propene_slope

    Slope of propene calibration curve

    propane_corr2

    R2

    Propane calibration coefficient

    propane_intercept

    Intercept of propane calibration curve

    propane_slope

    Slope of propene calibration curve

    methane_corr2

    R2

    Methane calibration coefficient

    methane_intercept

    Intercept of methane calibration curve

    methane_slope

    Slope of methane calibration curve

    NGAFIDrelated calibration or QA/QC test


    iso_butane

    ppmv

    Concentration of iso_butane in a sample


    iso_heptane

    ppmv

    Concentration of iso_heptane in a sample


    iso_hexane

    ppmv

    Concentration of iso_hexane in a sample


    iso_pentane

    ppmv

    Concentration of iso_pentane in a sample


    n_butane

    ppmv

    Concentration of n_butane in a sample


    n_heptane

    ppmv

    Concentration of n_heptane in a sample


    n_hexane

    ppmv

    Concentration of n_hexane in a sample


    n_pentane

    ppmv

    Concentration of n_pentane in a sample


    ethane_ethene

    ppmv

    Concentration of ethane + ethene in a sample


    propane_propene

    ppmv

    Concentration of propane + propene in a sample


    methane

    ppmv

    Concentration of methane in a sample

    NGAFID_QA

    dat_asman_id

    Serial number of chromatographic data file in ASMAN


    dat_filename

    File name of chromatographic data file containing measurements


    run_test

    Test number of related calibration or QA/QC test


    iso_butane

    ppmv

    Concentration of iso_butane in a sample


    iso_heptane

    ppmv

    Concentration of iso_heptane in a sample


    iso_hexane

    ppmv

    Concentration of iso_hexane in a sample


    iso_pentane

    ppmv

    Concentration of iso_pentane in a sample


    n_butane

    ppmv

    Concentration of n_butane in a sample


    n_heptane

    ppmv

    Concentration of n_heptane in a sample


    n_hexane

    ppmv

    Concentration of n_hexane in a sample


    n_pentane

    ppmv

    Concentration of n_pentane in a sample


    ethane_ethene

    ppmv

    Concentration of ethane + ethene in a sample


    propane_propene

    ppmv

    Concentration of propane + propene in a sample


    methane

    ppmv

    Concentration of methane in a sample

    NGAFID_QAQC

    datmtd_asman_id

    Serial number of chromatographic data file method in ASMAN


    datmtd_filename

    File name of the chromatographic data method file containing measurements

    run_test

    Test number of related calibration or QA/QC test


    iso_butane

    ppmv

    Concentration of iso_butane in a sample

    iso_heptane

    ppmv

    Concentration of iso_heptane in a sample

    iso_hexane

    ppmv

    Concentration of iso_hexane in a sample

    iso_pentane

    ppmv

    Concentration of iso_pentane in a sample

    n_butane

    ppmv

    Concentration of n_butane in a sample

    n_heptane

    ppmv

    Concentration of n_heptane in a sample

    n_hexane

    ppmv

    Concentration of n_hexane in a sample

    n_pentane

    ppmv

    Concentration of n_pentane in a sample

    ethane_ethene

    ppmv

    Concentration of ethane + ethene in a sample

    propane_propene

    ppmv

    Concentration of propane + propene in a sample

    methane

    ppmv

    Concentration of methane in a sample

    NGAFID_QC

    mtd_asman_id

    Serial number of chromatographic method in ASMAN

    mtd_filename

    File name of the chromatographic method file containing measurements

    iso_butane_corr2

    R2

    Iso-butane calibration coefficient


    iso_butane_intercept

    Intercept of iso-butane calibration curve


    iso_butane_slope

    Slope of iso-butane calibration curve


    iso_heptane_corr2

    R2

    Iso-heptane calibration coefficient


    iso_heptane_intercept

    Intercept of iso-heptane calibration curve


    iso_heptane_slope

    Slope of iso-heptane calibration curve


    iso_hexane_corr2

    R2

    Iso-hexane calibration coefficient


    iso_hexane_intercept

    Intercept of iso-hexane calibration curve


    iso_hexane_slope

    Slope of iso-hexane calibration curve


    iso_pentane_corr2

    R2

    Iso-butane pentane calibration coefficient


    iso_butanepentane_intercept

    Intercept of iso-butane pentane calibration curve


    iso_butanepentane_slope

    Slope of iso-butane pentane calibration curve


    ison_heptanebutane_corr2

    R2

    Ison-heptane butane calibration coefficient


    ison_heptanebutane_intercept

    Intercept of ison-heptane butane calibration curve


    ison_heptanebutane_slope

    Slope of ison-heptane butane calibration curve


    ison_hexaneheptane_corr2

    R2

    Ison-hexane heptane calibration coefficient


    ison_hexaneheptane_intercept

    Intercept of ison-hexane heptane calibration curve


    ison_hexaneheptane_slope

    Slope of ison-hexane heptane calibration curve


    ison_pentanehexane_corr2

    R2

    Ison-pentane hexane calibration coefficient


    ison_pentanehexane_intercept

    Intercept of ison-pentane hexane calibration curve


    ison_pentanehexane_slope

    Slope of ison-pentane hexane calibration curve


    n_butanepentane_corr2

    R2

    n-butane pentane calibration coefficient


    n_butanepentane_intercept

    Intercept of n-butane pentane calibration curve


    n_butanepentane_slope

    Slope of n-butane pentane calibration curve


    nethane_heptaneethene_corr2

    R2

    n-heptane Ethane + ethene calibration coefficient


    nethane_heptaneethene_intercept

    Intercept of n-heptane ethane + ethene calibration curve


    nethane_heptaneethene_slope

    Slope of n-heptane ethane + ethene calibration curve


    npropane_hexanepropene_corr2

    R2

    n-hexane Propane + propene calibration coefficient


    npropane_hexanepropene_intercept

    Intercept of n-hexane propane + propene calibration curve


    npropane_hexanepropene_slope

    Slope of n-hexane propane + propene calibration curve

    nNGAFID_pentaneQC

    methane_corr2

    R2

    n-pentane Methane calibration coefficient


    n_pentanemethane_intercept

    Intercept of n-pentane methane calibration curve


    n_pentanemethane_slope

    Slope of n-pentane methane calibration curve

    ethaneNGATCD

    dat_etheneasman_corr2id

    R2

    Ethane + ethene calibration coefficient

    ethane_ethene_intercept

    Serial number of chromatographic data file in ASMAN


    dat_filename

    Intercept of ethane + ethene calibration curve

    ethane_ethene_slopeFile name of chromatographic data file containing measurements


    run_test

    Slope of ethane + ethene calibration curve

    propane_propene_corr2

    R2

    Propane + propene calibration coefficient

    propane_propene_intercept

    Intercept of propane + propene calibration curve

    propane_propene_slope

    Slope of propane + propene calibration curve

    NGAFID_QC

    methane_corr2

    R2

    Methane calibration coefficient

    methane_intercept

    Intercept of methane calibration curve

    methane_slope

    Slope of methane calibration curve

    NGATCD

    dat_asman_id

    Serial number of chromatographic data file in ASMAN

    dat_filename

    File name of chromatographic data file containing measurements

    run_test

    Test number of related calibration or QA/QC test

    carbon_dioxide

    ppmv

    Concentration of carbon dioxide in a sample

    ethane

    ppmv

    Concentration of ethane in a sample

    ethene

    ppmv

    Concentration of ethene in a sample

    hydrogen_sulfide

    ppmv

    Concentration of hydrogen sulfide in a sample

    methane

    ppmv

    Concentration of methane in a sample

    nitrogen

    ppmv

    Concentration of nitrogen in a sample

    oxygen

    ppmv

    Concentration of oxygen in a sample

    propane

    ppmv

    Concentration of propane in a sample

    propene

    ppmv

    Concentration of propene in a sample

    Uploading Data to LIMS

    Data are uploaded to LIMS automatically using a process explained in the GC3-NGA Advanced User Guide. If the data do not upload to LIMS, contact the laboratory technician.

    Health, Safety & Environment

    Safety

    • The following parts are dangerously hot. Avoid touching these areas and cool completely to room temperature before servicing them:
    • Inlets
    • Oven
    • Detectors
    • Column nuts
    • Be careful when working behind the instrument; during cooldown cycle the oven emits hot exhaust that can cause burns.
    • Do not place temperature-sensitive items (e.g., gas cylinders, chemicals, regulators, and plastic tubing) in the path of the heated exhaust.
    • Insulation around inlets, detectors, and valve box contains refractory ceramic fibers. Avoid inhaling particles and wear personal protective equipment including gloves, safety glasses, and dust/mist respirator when working in these areas.
    • Do not leave flammable gas flows on if GC will be unmonitored for long periods of time (however, leave carrier gas on for column flow).
    • Always operate the instrument with the cover properly installed.

    Maintenance & Troubleshooting (HP6890GC)

    Troubleshooting

    Faults

  • Beeping instrument (cancel beep by pressing Clear on the instrument keyboard)
  • One beep: instrument fault, warning, or shutdown
  • Series of beeps: gas flow cannot reach setpoint and flow will be shut down after 1–2 min
  • Continuous beep: thermal shutdown
  • Blinking setpoint on GC display
  • Control table setpoint blinking: gas flow, valve, or oven shutdown
  • Detector On/Off line blinking: pneumatics or detector failure
  • Instrument screen messages (press Clear to remove message)
  • Caution: configuration problems
  • Error: setpoint out of range or incorrect hardware
  • Popup: shutdown, fault, or warning (see error table)
  • FID will not stay lit
  • Make sure the dessicant in the hydrogen generator is not saturated with water (replace/recharge as necessary).
  • Check water level in hydrogen generator

    Test number of related calibration or QA/QC test


    carbon_dioxide

    ppmv

    Concentration of carbon dioxide in a sample


    ethane

    ppmv

    Concentration of ethane in a sample


    ethene

    ppmv

    Concentration of ethene in a sample


    hydrogen_sulfide

    ppmv

    Concentration of hydrogen sulfide in a sample


    methane

    ppmv

    Concentration of methane in a sample


    nitrogen

    ppmv

    Concentration of nitrogen in a sample


    oxygen

    ppmv

    Concentration of oxygen in a sample


    propane

    ppmv

    Concentration of propane in a sample


    propene

    ppmv

    Concentration of propene in a sample


    Health, Safety & Environment


    Safety

    • The following parts are dangerously hot. Avoid touching these areas and cool completely to room temperature before servicing them:
    • Inlets
    • Oven
    • Detectors
    • Column nuts
    • Be careful when working behind the instrument; during cooldown cycle the oven emits hot exhaust that can cause burns.
    • Do not place temperature-sensitive items (e.g., gas cylinders, chemicals, regulators, and plastic tubing) in the path of the heated exhaust.
    • Insulation around inlets, detectors, and valve box contains refractory ceramic fibers. Avoid inhaling particles and wear personal protective equipment including gloves, safety glasses, and dust/mist respirator when working in these areas.
    • Do not leave flammable gas flows on if GC will be unmonitored for long periods of time (however, leave carrier gas on for column flow).
    • Always operate the instrument with the cover properly installed.

    Maintenance & Troubleshooting (HP6890GC)


    Use the Status and Info keys on the GC keypad as a first check when something goes wrong.

    Troubleshooting

    Faults

    • Beeping instrument (cancel beep by pressing Clear on the instrument keyboard)
    • One beep: instrument fault, warning, or shutdown
    • Series of beeps: gas flow cannot reach setpoint and flow will be shut down after 1–2 min
    • Continuous beep: thermal shutdown
    • Blinking setpoint on GC display
    • Control table setpoint blinking: gas flow, valve, or oven shutdown
    • Detector On/Off line blinking: pneumatics or detector failure
    • Instrument screen messages (press Clear to remove message)
    • Caution: configuration problems
    • Error: setpoint out of range or incorrect hardware
    • Popup: shutdown, fault, or warning (see error table)
    • FID will not stay lit
    • Make sure the dessicant in the hydrogen generator is not saturated with water (replace/recharge as necessary).
    • Check water level in hydrogen generator

    Leak Checking

    When checking for leaks, check both parts of the system:

    • External leaks: gas cylinders, gas purifiers/traps, regulator fittings, supply shutoff valves, GC supply fittings.
    • GC leaks: inlets, purge vents; column connections to inlets, detectors, valves, splitters, adapters, and unions.


    For safe leak-checking and flow measurement:

    • Purge flowmeters with inert gas after measuring a flammable gas (such as hydrogen).
    • Measure gases individually.
    • Turn off detectors while measuring gas flows.

    Column Size and Carrier Gas Flow Rate

    Column type

    Column ID

    Carrier gas flow rate (mL/min)

     



    Hydrogen

    Helium

    Packed

    1/8 inch


    30


    1/4 inch


    60

    Capillary

    50 µm

    0.5

    0.4


    100 µm

    1.0

    0.8


    200 µm

    2.0

    1.6


    250 µm

    2.5

    2.0


    320 µm

    3.2

    2.6


    530 µm

    5.3

    4.2

    These flow rates at normal temperature and pressure (25°C and 1 atm) are recommended for all column temperatures.
    For capillary columns, flow rates are proportional to column diameter and are 20% lower for helium than for hydrogen.




    Archive Version

    LMUG-GC3-NGAUG2011-230220-1904-144.pdf