Show evaluation

A gas show is a recorded increase in gases above a baseline amount indicative of the hydrocarbon potential of the formation. This increase is assumed to be independent of any borehole drilling or circulation process. Table 1 summarizes the nomenclature of gas that can result from the drilling process. The presence of these gases should not be confused with a “show.”

The analysis of a gas show begins with the detection of hydrocarbon gases that are the result of drilling a specific interval. The amounts and compositions of these gases are recorded on gas detection and chromatograph equipment. The simplest and most widely utilized gas detection device is the hot wire. This type of detector can provide readings of the total gas present (in units or percentage) as long as the gas concentrations are low enough that the equipment does not become “saturated” (on most hot wire equipment, gas percentages must be below a certain maximum for accurate readings).

Flame ionization gas detector (FID) equipment operates on a different principle and does not saturate. An FID detector can also provide chromatographic analysis of the gases. Chromatograph recordings normally distinguish the amounts of methane (C1), ethane (C2), propane (C3), isobutane (IC4), normal butane (NC4), isopentane (IC5), and normal pentane (NC5). The greater the amount and percentage of a gas show represented by the heavier hydrocarbons (particularly C4 and C5), the greater the potential for oil production from that zone^[1]. However, the presence of anomalous, noncombustible gases such as nitrogen or carbon dioxide can attenuate hydrocarbon gas curves.

Ratios of the different gases are often used to do the following:

• Support show identification
• Cross-check lag time calculations
• Discriminate among different show zones
• Indicate possible “richness trends”
• Identify fluid content
• Provide stratigraphic correlation

Various gas ratios can be used depending on the data available. The most common gas ratios used are those with the most separation (C5/C1) and those with the heaviest composition (C4/C1 or C5/C1). Because gas ratio analysis is empirical in nature, it can sometimes prove inconclusive. However, the following “rules of thumb” can be useful^[2]:

• Zones with a high C1 value may represent dry gas, coal, biogenic gas, or a water wet zone.
• Wet gas zones commonly have a C1 /C3 ratio that is higher than the C1 /C4 ratio.
• Nonproductive zones tend to have a ratio trend where subsequent values are lower than preceding values.

Factors affecting gas detection

Factors that affect the quality or presence of gas shows include mud weight and wellbore flushing, operation of the surface mud system, and accuracy of calculated lag time (see chapter on “Mudlogging: Gas Extraction and Monitoring”).

Mud weight and wellbore flushing

Near wellbore flushing occurs when the pressure or weight of the mud column exceeds the fluid entry pressure of the formation (for information on calculating mud weight, see chapter on Wellsite math in Part 3). This flushing by mud filtrate occurs above and ahead of the bit and is a function of time. If the mud system is overbalanced, gas shows can be reduced or totally suppressed. Even in a carefully balanced mud system where the fluid loss is minimized and the radius of wellbore flushing is small, problems can still occur in evaluating gas show quality if the rock's petrophysical properties are not considered. In zones of low effective porosity, even relatively small volumes of filtrate loss may result in deep invasion profiles. This causes a zone with a good gas show when drilled to recover only mud filtrate or to appear water saturated when later tested or electric logged. In zones of high effective porosity and permeability, the rocks will initially be flushed, then return to their native state soon after drilling, with little or no gas liberated. This causes a zone with minimal gas show when drilled to appear productive on electric logs or when later tested. Low permeability overpressured zones will not flush and will give high gas readings.

Information that can aid in the interpretation of flushed anomalies includes the following:^[2]

• Pump pressure
• Jet nozzle size(s) of the bit
• Mud rheology (plastic viscosity and yield point)
• Mud weight and effective circulation density
• Formation balance gradient (mud weight required to equalize formation pressure)
• Mud filtrate (water loss) amount
• Lithology descriptions of
  • visual porosity (absolute, effective)
  • porosity description (type, size, distribution)
  • cementation (type, degree, mineralogy)

Surface mud system

Flowline

A high degree of degassing takes place in the conductor pipe and flowline. Loss of gas from the mud to the atmosphere also occurs extensively in the flowline^[2], particularly when

• The flowline is not filled with mud
• Changes in flowline slope promote turbulence
• Sections of flowline are open to the atmosphere
• The flowline enters the possum belly above mud level

In extreme situations, the amount of gas lost from the mud system prior to analysis can be so great that any resultant shows are significantly biased.

Gas trap and agitator

This equipment is usually in or around where the flowline enters the possum belly. If the equipment is not operational (plugged orifices or lines, not powered-up, etc.), insufficient gas may reach gas analysis equipment to allow for an accurate analysis (see Mudlogging: gas extraction and monitoring).

Gas analysis system

If the detection and analytical equipment are not properly and constantly maintained and calibrated, inaccurate gas detection and analyses can result. Because there are numerous ways that the drilling, the gas-gathering system, and equipment wear can affect this analytical equipment, a complete system check and calibration is recommended on each tour.

Lag time

It is of the utmost importance to know the exact depth that all drill cuttings samples and gas are coming from within the borehole (for information on calculating lag time, see Wellsite math).

In many wells, drill cuttings collected may represent the only subsurface data available for geological interpretation. After a detailed lithology description, cuttings are analyzed for hydrocarbon indications (see Mudlogging: drill cuttings analysis). Traces of gas and oil in the cuttings represent formation hydrocarbons that have not been flushed by the drilling fluid. Gas in cuttings is analyzed by grinding a measured amount (approximately 100 mg) of unwashed cuttings in a blender, with any liberated gases analyzed by the standard gas detection system. This analysis is often divided into two components: total gas, comprising all combustible gasses; and petroleum vapors, comprising C2 through C5. This type of analysis can indicate the amount and composition of gases in the formation, even if the larger rock pores are flushed.

Evaluation of oil in cuttings is performed on unwashed and washed bulk cuttings and on individual grains. Evaluation includes visual inspection and analysis using a microscope and ultraviolet (UV) box. Oil shows are described by their physical properties of visual stain, fluorescence, cut, and odor. Care must be taken always to evaluate hydrocarbon shows in cuttings with respect to their petrophysical properties (see review by ^[3].

Visual stain

Staining of the drill cuttings by oil is an indication that hydrocarbons have been in the formation at some point in time. The lack of sample staining, however, does not prove that a reservoir lacks producible hydrocarbons. The amount and distribution of staining is a function of the reservoir porosity and permeability. Stain color can be related to oil gravity, with darker staining indicating heavier hydrocarbons. If a stained sample does not fluoresce or cut, then this indicator is classified as thermally “dead oil” and is not considered a show. Staining is described in terms of its color, distribution, percentage of sample stained, and fluorescence (if any).

Fluorescence

Fluorescence refers to the color of the drill cuttings under UV light of various wavelengths. A lack of fluorescence, however, does not prove the absence of hydrocarbons in the zone of interest. Care must be taken to distinguish hydrocarbon fluorescence from natural minerals or artificial materials (Table 2). Fluorescence is described in terms of its color, intensity, distribution, and percentage of sample fluorescing.

^a_{Samples of oil-based mud and other petroleum products used around the wellsite should be routinely sampled and examined under UV light to avoid potential confusion with hydrocarbon shows from the rocks.}

Cut fluorescence

A cut is the oil liberated from drill cuttings when a solvent is added. A common solvent used for inducing cuts is chlorothene; others include acetone, petroleum ether, alcohol, hot water, and acid. Note that because of its toxicity, carbon tetrachloride should not be used. Most solvents are flammable, and great care must be taken to handle these materials safely. A cut is performed while viewing the rock samples under both normal and UV light. Solvent cuts allow deductions to be made regarding oil mobility and reservoir permeability. A cut is described in terms of its natural color, fluorescence color, “liberation” rate and intensity, and residue. All suspected hydrocarbon-bearing intervals should be tested for cut fluorescence. This is because there may be a positive cut fluorescence test when other hydrocarbon detection methods fail.

Odor

The odor of hydrocarbons may be present even in the absence of any other hydrocarbon indicators. This condition is most noticeable during the sample drying process, when lighter hydrocarbons are driven off. Odor is described as faint, fair, or strong (indicative of heavier hydrocarbons). Keep in mind that methane through butane have no odor.

Factors affecting cuttings evaluation

Attention to differential pressure (over- or underbalanced), ROP, hole size and condition, contaminants, recycling, etc. is necessary for proper cuttings evaluation. Also, as there is no substitute for representative cuttings samples that are correctly correlated to depth, the importance of an accurate lag time cannot be overemphasized.

Wellsite evaluation of hydrocarbon shows requires clear and constant communication with vendor and drilling company personnel.

Drilling activities that represent shows include

• Flaring gas
• Oil in the pits, tanks, or mud system

Activities that may not represent a show include

• A drilling break or increase in the ROP (see Rate of penetration)
• An increase in the mud tank level

Activities that are not a show but can be mistaken for a show include

• Rig maintenance (lubrication, washing diesel into the mud pits)
• Mud additives
• Lowering mud weight

Activities that can lead to overlooked shows include

• Drilling with a constant ROP (controlled drilling)
• Overbalanced mud system
• High mud filtrate loss
• Losing circulation
• Bypassing the shaker
• Electrical power fluctuations

• Drilling problems
• Mudlogging: drill cuttings analysis
• Introduction to wellsite methods
• Wellbore trajectory
• Conventional coring
• Drilling fluid
• Land rigs
• Rig personnel
• Wellsite math
• Core handling
• Mudlogging: equipment, services, and personnel
• Core alteration and preservation
• Wellsite safety
• Sidewall coring
• Rate of penetration
• Mudlogging: the mudlog
• Well planning
• Pressure detection
• Drill stem testing
• Measurement while drilling
• Offshore rigs
• Fishing
• Core orientation
• Mudlogging: gas extraction and monitoring

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