Temperature Data Processing
ODP logging
contractor: LDEO-BRG
Hole: 845A
Leg: 138
Location: Guatemala Basin (tropical NE Pacific)
Latitude: 9° 34.950' N
Longitude: 94° 35.448 W
Logging date: May, 1991
Bottom felt: 3715.9 mbrf (used for depth shift to sea floor)
Total penetration: 291.6 mbsf
Total core recovered: 292.69 m (100.4 %)
Water Depth: 3704.2 mbsl
Temperature
Tool Used: LDEO-TLT
Depth versus time recording available: NO
Logging
Runs
Logging string 1: DIT/SDT/HLDT/NGT
Logging string 2: ACT/GST/NGT
Logging string 3: FMS/GPIT/NGT
Wireline heave compensator was used to counter ship heave.
The LDEO-TLT tool is a self-contained, high precision, low-temperature logging tool that is attached to the bottom of the Schlumberger tool strings. The tool provides two temperature measurements (in degree Celsius, recorded by a fast-response and a slow-response thermistor. The fast-response thermistor, though low in accuracy, is able to detect sudden, small temperature excursions caused by fluid flow between the formation and the borehole. The highly accurate, slow-response thermistor can be used to estimate heat flow. Pressure and the two temperature measurements are recorded as a function of time: conversion to depth can be based on the pressure reading (Legs 123-157) or, preferably, on simultaneous recording (by Schlumberger) of depth and time (Legs 159-181).
A linear relationship of pressure versus depth has been calculated from the pressure reading at the mudline and at the total logging depth for each logging run. The pressure at the mudline corresponds to the pressure recorded by the tool during the calibration stop (about 5 minutes), which takes place at the mudline on each logging run. The pressure readings are then converted to depth using a pressure/depth conversion that is linearly interpolated between the values determined at the mudline and total logging depth.
Depth = Pressure * x - WD
where
Depth = mbsf
Pressure = bars
x = pressure conversion coefficient (m/bars)
WD = mbsl
This procedure does not fully account for the vagaries of the pressure readings that result in lots of ups and downs in the generated depth channel. Further problems arise because of pumping during logging operations, which affects the pressure, especially when the Side Entry Sub is used. Also, whenever heavy pills of mud are used, the pressure-depth calculation is affected, resulting in a non-linear effect that is difficult to account for. If the pressure conversion coefficient is recalculated for the mudline, the resultant total depth is often wrong.
The following processing has been performed at Hole 845A:
Logging Run: DIT/SDT/HLDT/NGT
(downlog only)
Mudline (?) P=373 bars at 311 sec
x=WD/373=9.931
Pmax=396 bars at 1,414 sec
The pressure conversion factor has
been calculated from the average of pressure at mudline (10.011, 9.984) and
bottom of logged interval (9.991) in the GLT and FMS runs.
Logging Run: ACT/GST/NGT
Mudline P=370 bars at 295 sec
x=WD/370=10.011
Pmax = 400 bars at 1,074 sec
x=(WD+292)/400=9.991
The pressure conversion factor has
been calculated from the average of pressure at mudline (10.011, 9.984) and
bottom of logged interval (9.991) in the GLT and FMS runs.
The downlog and repeat pass uplog are of better quality.
Logging Run: FMS/GPIT/NGT
Slow-temperature thermistor not
working properly.
Mudline P=371 bars at 336 sec
x=WD/371=9.984
Pmax = 400 bars at 1,011 sec
x=(Wd+292)/400=9.991
The pressure conversion factor has
been calculated from the average of pressure at mudline (10.011, 9.984) and
bottom of logged interval (9.991) in the GLT and FMS runs.
Depth=Pressure * 9.994-3704.2
The downlog is of better quality.
Information about the temperature logging operations can be found in the Site Chapter (Operations, Downhole Measurements, and Heat Flow sections), ODP IR volume 138.
Cristina Broglia
Phone: 845-365-8343
Fax: 845-365-3182
E-mail: Cristina Broglia