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A. Preparing the Instrument

B. Instrument Calibration 

1. Double-click the ThermCON icon on the desktop (Figure 1) and login using ship credentials. ThermCON window will pop-up. Sample data will be added in this window.

2. Double-click the TK04 icon (Figure 1). TK04 window will open. Measurement parameters will be added in this window.

Image Added

Figure 1. ThermCON Icon (left). TK04 Icon (right).

B. Instrument Calibration 

The TK04 doesn't need to be calibrated. In order to verify that taken measurements The TK04 doesn't need to be calibrated. In order to verify that measurements taken are in the correct range of values, MACOR standards are measured at the start of each expedition.

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C. Set Measurement Parameters

Configuring Measurement Program

1. Load ThermCon software in offline mode. Ensure that the Text_ID field is blank.
   
2. Scan the core label using a scanner, then click Verify Sample.
   
3. If login is requested, enter UserName and Password and then click OK.
   
4. The folder path is shown on the screen. Do not close this window during measurement. 
   
5. Run TK04 program and choose Measuring > Configuration. 
   
6. Set configuration parameters as follows (see figure below):
   1. Probe Number: serial number of probe to be used in the measurement (Note: results may be wrong by several percent if the wrong serial number is entered or by a factor of ~2 if the wrong type of probe is entered),
   2. Root Name: six characters or less; suggest Core-Type-Section (no special characters in the root name).
   3. Serial Number: number of repeat measurements at each measurement point (1–99 single measurements).
   4. Folder: path for saving data results.
   5. Heating Power: for the VLQ (needle probe), set to twice the estimated thermal conductivity value of measured sediment. For example, 2–3 is good for sediment. (See the Appendix: TK04 Recommended Heating Power for power guidance.)
   6. Measuring Time: set to at least 80 s, or for mini HLQ 60 s.
   7. Click Expert Options to configure Drift Control and Pause in Minutes (see Step 7).
   8. Enter comments.

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1. Equilibrate core sections to room temperature for at least 4 hours in the core rack before bringing a target section to the thermal conductivity workstation.
2. Select measuring points in the core
   1. Intact core: middle of section; record offset in cm
   2. Cracked core: just above/below the middle (but in any case away from the crack); record offset in cm
3. Use the cordless drill to drill a ~2 mm hole into the core liner at the borderline between working and archive halves. If the sediment is unconsolidated, drill only through the core liner. If the sediment is semiconsolidated, drill a small hole in the sediment for the probe as well.
   Caution: it is very easy to bend the needle on the VLQ full space needles!
4. Optional - Apply thermal joint compound to the probe unless the sample is very soft and/or moist.
5. Carefully insert a clean full-space needle into the sediment. Avoid twisting the needle into the core. The needle must be completely inserted into the sample up to the handle. Do not attempt to force the needle into the sample if the resistance is too great; DO NOT BEND THE NEEDLE.

Figure 12. Thermal conductivity measurement on a soft-sediment section using full-space probe.

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1. Confirm configuration settings shown in the lower part of the TK04 screen, insert the probe into the hole drilled into the sample, and click Start Measuring. 
   
2. Drift control (DCL) repeats until the criterion for drift (set in the Expert Options window) is met. Each drift control measurement takes 0.5 min. For DCL = 40, drift control is <10 series (~5 min). For DCL = 10, drift control is <30 (~15 min).
   1. Counter: remaining number of measurements in the current drift series
   2. Recording: currently recorded time and temperature and drift series being recorded
   3. Drift: drift value from the last drift series; indicated in blue on the slider scale when acceptable
   4. Start signal light:
      1. Yellow: drift has reached the threshold; approximately half the drift time has passed
      2. Green: drift limit has been reached and measurement can begin
         
3. After satisfying drift control, sample heating and measuring begins, and temperature values are corrected automatically for the drift effect predicted from the last drift series. Elapsed measurement time is controlled by the value entered in Configuring Measurement Program > Step 6F.
   1. Recording: displays currently recorded time and temperature
   2. Data: lists recorded time/temperature values from the heating curve
   3. Heating diagram: continuously updated; can display as linear or logarithmic scale
      
4. Solutions calculated by the algorithm are shown on the screen. Note the result on the handwritten log.
   1. TC: thermal conductivity
   2. LET: logarithm of the extreme time (lower limit = 4); the measurement with the largest LET is used to calculate thermal conductivity
   3. CV: contact value
   4. PC: power control is shown on the plot in the lower part of the screen (recommended PC = 2–3. If PC is out of range, adjust the Heating Power (HP) in Configuring Measurement Program > Step 6E as follows: if PC > 3, decrease HP; if PC < 2, increase HP).
   5. Mean: mean thermal conductivity
   6. Count: number of measurements used to calculate thermal conductivity

F. Evaluating your Measurement

G. IMS Utilities

III. Uploading Data to LIMS

A. Data Upload Procedure

5. Upload data to LIMS and review if they appear on the data base (See next section).

Note: The "expanded" report shows all of the database parameters and may be confusing to a general user; use the "standard" report.

6. Once uploaded data are confirmed, clean the needle probe and place it in its styrofoam storage container.

7. Repeat sample measurement process with a new sample.

III. Uploading Data to LIMS

A. Data Upload Procedure

1. To upload results to LIMS, click Upload to LIMS. If upload is successful, a To upload results to LIMS, click Upload to LIMS. If upload is successful, a message like "Logged results for sample …" is shown. Close the ThermCon program.

B. View and Verify Data

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Data Available in LIVE

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Run LIVE from the ship application page to check thermal conductivity data:

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The data measured on each instrument can be viewed in real time on the LIMS information viewer (LIVE).

Choose the appropriate template (Ex: PHYS_PROPS_Summary

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Retrieving Data from LIMS REPORTs

1. Go to LIMS Reports at http://webserv.ship.iodp.tamu.edu:8080/UWQ/.
2. Under Select Report, choose Physical Properties > Thermal Conductivity (TCON).

Note: The "expanded" report shows all of the database parameters and may be confusing to a general user; use the "standard" report.

3. Under Select Sample Range, specify Expedition, Site, Hole, and Section image(s) to retrieve.

4. Click View data or Download data file to view results or download a CSV file.

After Verifying Data Upload

1. Once uploaded data are confirmed, clean the needle probe and place it in its styrofoam storage container.
2. Repeat sample measurement process with a new sample.

Data Management

Once all sections for the Expedition have been sent through the track, all data needs to be placed in the appropriate folders on data1 (S:\data1).
1. Copy files from archive and place them in the 5.1 Petrophysics TCON thermcon folder. Confirm relocation. Delete all files off the local drive.

LIMS Component descriptions

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Analysis

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Component

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Unit

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Definition

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TCON

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Bottom_depth

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m

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Location of bottom of measurement, measured from the top of the hole

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Comment

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None

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Comment about the run

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Contact_value

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None

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Measure of contact quality between probe and sample

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End_time

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s

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Elapsed time for end of analysis window

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Heating_power

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W/m

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Power applied to needle during heating

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Length_of_time

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s

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Elapsed time, start to finish, of analysis

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Log_extreme_time

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s

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LET, used in calculation algorithm

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Method

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None

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Data reduction method: SAM or TCON

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Needle_name

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None

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Full-space or half-space

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Number_of_solutions

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None

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Number of solutions found by the software

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Offset

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cm

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Location of measurement from top of section

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Start_time

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s

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Elapsed time into experiment for start of analysis window

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Therm_con_average

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W/(m·K)

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Mean thermal conductivity result

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Therm_con_number

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None

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Number of measurements in the population

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Therm_con_result

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W/(m·K)

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Individual thermal conductivity result

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Therm_con_stdev

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W/(m·K)

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Standard deviation (n-1) of measurement population

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Top_depth

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m

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Location of top of measurement from top of hole

), Expedition, Site, Hole or the needed restrictions and click View Data. The requested data will be displayed. You can travel in them by clicking on each of each core or section, which will enlarge the image.

Data Available in LORE

Each data set from the Thermoconductivity Station is written to a file by section. These reports are found under the Physical Properties heading. The expanded reports include the linked original data files and more detailed information regarding the measurement.

C. Retrieve Data from LIMS

Expedition data can be downloaded from the database using the instrument Expanded Report on Download LIMS core data (LORE).

IV. Appendix

A.1 Health, Safety & Environment

Safety

C. Retrieve Data from LIMS

IV. Important Notes

V. Appendix

A.1 Health, Safety & Environment

Safety

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This analytical system does not require personal protective equipment.

Pollution Prevention

This procedure does not generate heat or gases and requires no containment equipment.

A.2 Maintenance and Troubleshooting

Troubleshooting

Drift phase takes too long:

• Ambient temperature is not stable: allow sample more time to equilibrate
• Probe and sample are not in equilibrium with ambient temperature: place sample/probe in insulated case
• If necessary, force measurements by choosing a weaker drift limit

Variation of measurement series is too high:

• Ambient temperature is not stable enough
• Heating power too low to produce sufficient temperature increase: increase heating power
• Start time maximum value is too high: set to 40 s
• Interval length minimum value is too low: set to >25–30 s
• Contact values vary strongly: omit outliers from evaluation

Evaluation returns few or no solutions:

• Wet sample may cause convection effects: reduce heating power
• Poor contact between probe and sample: use contact fluid
• Interval length minimum value too high: set <30 s
• Start time maximum value too low: set to 40 s
• Variations in ambient temperature: insulate sample and/or probe
• Heat transport into the sample is not distributed: smooth sample surface and apply contact fluid
• Issue with the probe: Run test on Macor Standard to see if you get expected results

LET values too low:

• Poor contact between probe and sample
• Unstable ambient temperature
• Interval length or start time minimum values too high

Evaluation intervals start later than ~35 s:

• Poor contact between probe and sample
• Heating power too high
• Boundary effects caused by finite probe length

Descending trend in thermal conductivity values:

• Water-saturated samples drying out: keep sample wet during analysis

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V. Credits

This document originated from 2009, TK04 UG v.,V378P | 372 (Revised: 372|V371T|no change 03/18  ), that had contributions from the authors Hastedt, Y.-G. Kim, M.A. Kominz, and the reviewers David Houpt, T. Gorgas, M. Vasilyev, R. Wilkens, K. Milliken, H. Barnes, S. Hermann; T. Cobb. Credits for subsequent changes to this document are given in the page history.

All improvements to the Quick Start Guides and User Guides are a communal effort, with honorable mention to the group of LOs, ALOs, and technicians who have helped.

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VI. Archived Versions

• TK04 User Guide 2020 (*.pdf)
• TK04 User Guide 2021 (*.pdf)