1 / 24

Drilling Engineering – PE 311 Chapter 2: Drilling Fluids Classification of Drilling Fluids

Drilling Engineering – PE 311 Chapter 2: Drilling Fluids Classification of Drilling Fluids. Classification of Drilling Fluids. WBMs. The following designations are normally used to classify water-base drilling fluid systems:

sukey
Download Presentation

Drilling Engineering – PE 311 Chapter 2: Drilling Fluids Classification of Drilling Fluids

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Drilling Engineering – PE 311 Chapter 2: Drilling Fluids Classification of Drilling Fluids

  2. Classification of Drilling Fluids WBMs The following designations are normally used to classify water-base drilling fluid systems: Nondispersed-noninhibited systems: spud muds, polymer/bentonite muds, extended bentonite muds ) Nondispersed-inhibited systems: salt muds, KCL-polymer muds Dispersed-noninhibited systems: lignite-lignosulfonate muds, phosphate-bentonite muds Dispersed-inhibited systems: lime muds, gyp-lignosulfonate muds, seawater-prehydrated bentonite muds.

  3. WBMs – Nondispersed-noninhibited fluids Nondispersed-noninhibited fluids The noninhibited-nondispersed fluids do not contain inhibiting ions such as chloride (Cl), calcium (Ca2+), or potassium (K+) in the continuous phase and do not utilize chemical thinners or dispersants to effect flow control. Nondispersed-inhibited fluids do contain inhibiting ions, but do not utilize chemical thinners or dispersants. Dispersed-noninhibited fluids utilize chemical thinners or dispersants, but do not contain inhibiting ions. Dispersed-inhibited fluids contain both chemical dispersants and inhibiting ions. When referring to a water-base mud system, the term nondispersed means that clay is free to find its own hydrous dispersed equilibrium in the aqueous solution. It also means that chemical acceleratives or dispersants have not been added to the system.The term noninhibited refers to the lack of specific ions such as potassium, calcium, or chloride that would inhibit the ability of the formation to absorb water. These systems use native waters; they do not use chemical thinners to affect the solids remaining in the system, or inhibitive ions to prevent the solids from swelling.

  4. WBMs – Nondispersed-noninhibited fluids Spud Muds Spud Muds are used during drilling to: clean the hole; prevent sloughing of the surface hole; provide a viscous sweep to clean gravel/sand from the borehole; and form a filter cake to prevent seepage to the formation. Formulation: Water: (Fresh, brackish, salt) Caustic: 8.5 to 10.5 pH in fresh-water muds 10.5 to 11.5 pH in salt-water muds Clay: 10 to 35 lb/bbl, depending on mud weight Fresh water-Sodium bentonite. Salt water-Attapulgite or prehydrated bentonite

  5. WBMs – Nondispersed-noninhibited fluids Polymer/Bentonite Muds Polymer/bentonite systems are used primarily in areas where the formations to be drilled contain low reactive solids. The systems can tolerate low concentrations of calcium. Water containing calcium in excess of 100 mg/L (ppm) should be pretreated with bicarbonate of soda to precipitate the calcium. Formulation: Water (Fresh, salty, light calcium) Sodium bentonite:    10 lb/bbl Polymer:   CMC (low viscosity):    0.5 to 1.5 lb/bbl   PAC (low viscosity):      0.5 to 1.5 lb/bbl   Corn or potato starch:  2.0 to 4.0 lb/bbl

  6. WBMs – Nondispersed-noninhibited fluids Extended Bentonite Muds Extended bentonite systems contain chemicals that extend the yield of bentonite and impart the desired properties to the mud while maintaining minimum solids content, which in turn improves penetration rates. Formulation: Water: (Treat out calcium with soda ash) Bentonite: 10 to 15 lb/bbl Polymers:   Polyacrylate: .04 percent by volume ( if the system is weighted, more is required)   Polyacrylamide: 0.5 to 3.0 lb/bbl Depending on the application, there are many other chemicals that can be used to impart viscosity and filtration control, such as polyanionic cellulose, xanthum gum, and potato or corn starch.

  7. WBMs – Nondispersed-inhibited fluids Nondispersed - inhibited fluids The systems described below are classified as Nondispersed-Inhibited because prehydrated sodium bentonite finds its own equilibrium. Chemical dispersants (thinners) are not added to the systems. Included in these systems are certain muds containing salt ions (NaCl and KCl) that inhibit drilled formation solids from swelling and breaking into smaller particles as they are transported to the surface. This makes it easier for the solids-control equipment to remove these particles.

  8. WBMs – Nondispersed-inhibited fluids Attapulgite-Starch-Salt Muds Salt muds are used to improve borehole stability through the inhibiting effects of the salt(s) present in the makeup water, to minimize hole washout, and to prevent drilled solids from disintegrating as they are transported to the surface. Formulation: Seawater or natural brine Caustic soda: pH  9.0, by meter Attapulgite: 10 to 20 lb/bbl Potato or corn starch: 0.5 to 5.0 lb/bbl Polymer: 0.25 to 1.25 lb/bbl (Polyanionic cellulose, CMC, xanthum gum, guar gum) Attapulgite does not contribute to filtration control; instead, polymers and/or starches must be used for this purpose.

  9. WBMs – Nondispersed-inhibited fluids Saturated Salt Muds Saturated salt muds are used to prevent solution cavities from occurring in salt domes and stringers when they are penetrated by the bit, and to minimize hole washout in salt or carbonate beds. Formulation:  Saturated salt water: 189,500 mg/L NaCl Attapulgite: 10 to 25 lb/bbl Potato or corn starch: 0.5 to 2.5 lb/bbl Polymer:  0.25 to 1.5 lb/bbl   (Polyanionic cellulose, xanthum gum) Attapulgite should be used when filtration control is not required. When drilling other types of formations, sodium bentonite pre-mix (sodium bentonite prehydrated in fresh water) can be added to achieve a quality filter cake. To prevent the salt from dehydrating the sodium bentonite clay, a small amount of lignosulfonate can be added to the pre-mix solution prior to adding it to the mud system. However, this converts the system to a dispersed system.

  10. WBMs – Nondispersed-inhibited fluids Potassium Chloride-Polymer Muds Potassium chloride (KCl)-polymer muds inhibit clay swelling in thin, moderately active clay formations. A low percentage of K+ inhibits the swelling and disintegration of drilled solids, minimizes hole enlargement, and promotes borehole stability. Formulation:  KCl water (5 to 15% K+ ion):  l7.5 to 52.5 lb/bbl Caustic soda: Low pH (8.5) Prehydrated bentonite or attapulgite: 10 to 15 lb/bbl starch Polymer: 0.5 to 5.0 lb/bbl   (Potato or corn starch, polyanionic cellulose, xanthum gum, guar gum)

  11. WBMs –dispersed-Noninhibited fluids Lignite-Lignosulfonate Muds In dispersed-noninhibited systems, chemical thinners are added to encapsulate the sodium bentonite and reactive drilled solids. The systems do not contain inhibitive electrolytes; therefore, the cuttings are free to disperse as they are transported to the surface. Lignite-lignosulfonate muds are probably the most versatile exploratory drilling fluids in use today. Their rheological properties are easily controlled with chemical thinners, and this reduces the risk of detrimental effects of contaminants, such as salt, anhydrite, and cement, that may be encountered during drilling. Chemical thinners and filtration-control agents are used to control the high temperature/high-pressure fluid loss.

  12. WBMs –dispersed-Noninhibited fluids Lignite-Lignosulfonate Muds Formulation:  Water: Normally fresh Caustic soda:  pH 9.5 to 10,5 Sodium bentonite: 10 to 25 lb/bbl Lignite:   3 to 10 lb/bbl Lignosulfonate:    5 to 10 lb/bbl (A yield point of 10 to 16 lb/l00 sq. ft is recommended) Starches or polymers:   0.25 to 2.0 lb/bbl (Potato or corn starch, CMC, PAC) In general, the lignosulfonate system is very stable, but it shows severe thermal degradation at temperatures of 350� F and above. One common approach to this problem is the gradual decrease in the use of lignosulfonate as formation temperatures approach 350� F and conversion to a lignite-surfactant system.

  13. WBMs –dispersed-Noninhibited fluids Phosphate-Bentonite Muds Phosphate-treated muds with mud weights less than 12 lb/gal are used to drill shallow wells in which bottomhole temperatures will not exceed 150�F. The phosphates normally used in these systems have specific limitations; therefore, the system should not be exposed to chlorides in excess of 5000 mg/L or calcium in excess of 100 mg/L. The calcium can be controlled with soda ash or bicarbonate of soda. Formulation:  Water  SAPP: 0.5 to 3.0 lb/bbl (per addition) Sodium bentonite: 20 lb/bbl CMC: 0.5 to 3.0 lb/bbl for fluid-loss control Flocculation may occur at temperatures above 150� F due to phosphate reversion; therefore, the system should be used for shallow-hole drilling only.

  14. WBMs –Dispersed-inhibited Fluids Dispersed-inhibited Fluids Dispersed-inhibited systems contain chemical dispersants to disperse clays and drilled solids, along with inhibiting ions to prevent the hydration and the dispersion of formation materials. The fluids do not contribute to the hydration and dispersion of formation clays, and the cuttings are held together for removal at the surface. Drilled solids have a minimal effect on rheological properties in inhibited systems due to the presence of inhibiting electrolytes (Ca2+, K+, CaSO4, surfactants). These electrolytes suppress the ability of clays to subdivide into numerous interacting particles, making it easy to maintain the fluid's rheological properties with low treatment concentrations.

  15. WBMs –Dispersed-inhibited Fluids Lime Muds In general, inhibited systems have lower viscosities and low gel strengths. These fluids are used principally in the drilling of shales or clay formations. Formulation: Water (Fresh or salty) Sodium bentonite: Not to exceed 15 lb/bbl Caustic soda: 11.5 pH Lignite: 2 to 6 lb/bbl (used at breakover and not in highly weighted systems) Lime: 2 to 3 lb/bbl excess in high-density fluids; 6 to 8 lb/bbl excess in low-density fluids Lignosulfonate: 1 to 10 lb/bbl Starch or polymers: 0.75 to 3.0 lb/bbl    (Potato or corn starch, polyanionic cellulose, CMC)

  16. WBMs –Dispersed-inhibited Fluids Lime Muds Lime muds perform well up to bottomhole temperatures of 250� F, at which point the fluid loss becomes difficult to control. This leads to dehydration of the system, and solidification can occur. In most cases the calcium-inhibited system is made from the native mud used to drill the surface hole. Downhole temperatures aid in converting the system to an inhibited (calcium-bentonite) system. This procedure is called a breakover. Normally, there is a short period of time during the breakover when the viscosity may become very high. This is the hump, which is caused by the clay flocculating and converting to a calcium clay.

  17. WBMs –Dispersed-inhibited Fluids Gyp-Lignosulfonate Muds Gyp muds function as inhibited systems at lower alkalinities than lime muds, and they contain more soluble calcium (700 mg/L) than lime muds. Therefore, gyp muds are more inhibitive. Gyp muds are also generally more tolerant of contamination than lime muds, and they have a slightly higher temperature stability (2750 F) Formulation: Water:   (Fresh or salty) Sodium bentonite:   15 lb/bbl maximum Caustic soda:   9.5 pH Lignosulfonate:   6 lb/bbl Gypsum:    2 to 6 lb/bbl excess Starch or polymer:    As required    (Polyanionic cellulose-LV, CMC, potato starch)

  18. WBMs –Dispersed-inhibited Fluids Seawater-Prehydrated Bentonite Muds The primary advantage of a seawater-prehydrated bentonite system is the easy availability of it’s source water. Another advantage is that the moderate amount of soluble salts in seawater inhibits the hydration and dispersion of clays. Formulation: Seawater MBT: 12 to 18 lb/bbl Prehydrated sodium bentonite to raise MBTCaustic soda: 0.5 lb/bbl Sodium bentonite: 30 to 50 lb/bbl Lignosulfonate: 4 lb/bbl Caustic soda: 10.5 to 11.5 pH Lignite, starch or polymer:  0.25 to 6 lb/bbl   Defoamer Aluminum stearate and nontoxic oil

  19. Oil Based System Oil Based Drilling Fluids The inclusion of water in oil muds is beneficial for the following reasons: Economy:  Water is cheaper than oil; the substitution of water for oil usually reduces mud costs. Viscosity and Gelation:  Because water acts as a solid in invert emulsions, it helps to increase mud viscosity. Moreover, the presence of water helps disperse the organophilic clays that are routinely used to provide gelation properties. Filtration Control:   Again, because the water droplets act as small suspended solids in these systems, their presence helps to reduce mud filtration. Stabilization:   The inclusion of water in the systems allows us to dissolve salts in the water phase to aid in stabilizing reactive clays and shales. Safety:  The presence of water in an oil mud increases the flash and fire points of the fluid. When high temperatures on surface are encountered, the water begins to evaporate from the system, thereby helping to insulate the system from oxygen.

  20. Oil Based System Oil Based Drilling Fluids The most common base oils used have been diesel and kerosene. They have an acceptable viscosity, low flammability, and a low solvency for any rubber in the drilling system. Diesel, however, is relatively toxic, making the environmental impact of diesel-base muds generally higher than those of water-base muds. Mineral oils have replaced diesel oil and kerosene in environmentally sensitive areas of the world. Mineral oils contain a much smaller percentage of aromatics than diesel or kerosene, and thus are less toxic to marine life. There is a wide range in aromatic content in mineral oils marketed today. Crude oil can be used in oil muds; however, it has some drawbacks. For example, crude oil usually has a significant fraction of light ends, and thus exhibits low flash and fire points. Crude oil may need to be weathered prior to use. Also, crudes often contain significant amounts of asphaltenes that may present problems during drilling or completion operations, and may affect the performance of invert emulsion additives.

  21. Oil Based System Oil Based Drilling Fluids Water present in an oil mud is in the form of an emulsion. A chemical emulsifier must be added to prevent the water droplets from coalescing and settling out of the emulsion. The emulsifier also permits water originally present in the rock destroyed by the bit to emulsify easily. A chemical wettability reversal agent is added to make the solids in the mud preferentially wet by oil rather than water. Otherwise, the solids will by absorbed by the water droplets and cause high viscosities and eventually settling of barite. The emulsified water of an oil mud tends to increase the viscosity of the mud in the same manner as inert solids. It also causes a slight increase in fluid density. Since the water is much less expensive than oil, it also decreases the total cost of an oil mud.

  22. Oil Based System Emulsifiers The calcium or magnesium fatty acid soap frequently is used as an emulsifier for oil muds. Fatty acids are organic asids present in naturally occurring fats and oils that have a structure: CH3 – CH2 – (CH2)n –COOH While the fatty acid soaps are the most common type of emulsifier used in oil muds, almost any type of oil soluble soap can be used. Calcium naphthenic acid soaps and soaps made from rosin (pipe tree sap) also are common organic acid type soaps.

  23. Oil Based System Wettability Control When a drop of liquid is placed on the surface of a solid, it may spread to cover the solid surface or it may remain as a stable drop. The shape that the drop assumes depends upon the strength of the adhesive forces between molecules of the liquid and solid phases. The wettability of a given solid surface to a given liquid is defined in terms of the contact angle q. A liquid that exhibits a small contact angle has a strong wetting tendency. If q = 1800, the liquid is said to be completely nonwetting

  24. Oil Based System Wettability Control Most natural minerals are preferentially wet by water. When water-wet solids are introduced to a water-in-oil emulsion, the solids tend to agglomerate with the water, causing high viscosities and settling. To overcome this problem, wettability control agents are added to the oil phase of the mud. The wetting agents are surfactants similar to the emulsifiers. This effectively changes the solids from being preferentially wet by water to preferentially wet by oil. The soaps added to serve as emulsifiers also function to some extent as wetting agents. However, they usually do not act fast enough to handle a large influx of water-wet solids during fast drilling or mud weighting operations.

More Related