FUNCTIONS AND PROPERTIES OF DRILLING FLUIDS


  • What is Drilling Fluid or Mud?
  • “It is a mixture of liquids and chemicals that allow the drilling and completion of a well”.
  • Drilling Fluid has to provide many functions in order that these objectives be achieved.
Primary Functions 
  • Lift and Carry Drilled Cuttings to Surface
  • Control Formation Pressures
  • Maintain a Stable “In Gauge” Hole
  • Cool and Lubricate the Bit
  • Lubricate the Drill String
  • Secure Hole Information
  • Power / Transmit signals from Downhole Tools
  • Prevent fluid from entering the formation
  • Permit separation of solids at surface
  • Form a thin low permeability filter cake  
Negative Functions
  • Not injure people or be damaging to the environment.
  • Not require unusual or expensive methods of completion
  • Non damaging to the fluid bearing formation
  • Not corrode or cause excessive wear of drilling equipment
  • Ridiculously expensive
  • The Drilling Fluid Company must be able to:
  • Provide cost effective solutions to the operators drilling problems
  • Maintain the mud properties
  • Provide an adequate supply of products on site and at the base
  • Provide adequate reporting
  • Engineer the fluid in widely differing conditions and locations
  • Provide back up testing facilities
  • Avoid damaging the reservoir  
Balancing Sub-Surface Pressures 
lThe pore pressure depends on:

The density of the overlying rock

The density of the interstitial fluid

Whether the rock is self supporting or is 
supported by the fluid.

Tectonic activity


Surface terrain
 

lIf the fluid hydrostatic pressure does not balance the 
pore pressure the following may occur:

Influxes of formation fluid into the wellbore

Lost circulation

Hole Instability

Stuck pipe
  1) Balancing Sub-Surface Pressures
lThe pressure balancing the formation pressure is composed from the hydrostatic pressure under static conditions:
nP = Depth (ft) x Density (ppg) x 0.052
lUnder circulating conditions the effective pressure is increased by the pumping pressure. This forms the Equivalent Circulating density (ECD):
 
2) Remove Cuttings From the Well Bore
The most important parameter is the Annular Velocity (A.V.)
Where possible the annular velocity should be 100 ft/min, higher in deviated holes.
In large hole sections the A.V. can be as low as 20 ft/min.
If the A.V. is insufficient to clean the hole the 
 viscosity must be increased
 
For top hole high viscosities must be used
Cuttings removal is harder in deviated and 
horizontal holes as the vertical component of the 
mud is reduced.
 3) Suspension of Solids
Whenever the pumps are switched off solids will start
 
 to settle. This can result in:
 
Bridging off of the wellbore
 
Stuck pipe
 
Hole fill
 
Loss of Hydrostatic
 
A gel structure is required to suspend the cuttings
 
under zero shear conditions:
 
The gel structure is caused by time dependant 
 
attractive forces which develop in the fluid. 
 
The longer the fluid is static the stronger these
 
 forces become
 
The gel structure should be easily broken
 
The gel properties are especially important for
 
 deviated and horizontal wells as the distance
 
solids have to settle is very small
 
4) Minimise Formation Damage
 
Damage to the formation while drilling to the 
 resevoir:
Formation swelling (Normally clay and 
 
Salt formations)
 
Washouts (Clay and Salt formations or 
any unconsolidated formation)
This can result in:
 
Difficult directional control
Poor zonal isolation
Excess mud and cement costs
Poor Hole Cleaning
Stuck Pipe
Difficult fishing jobs
 

 
 
Damage to the reservoir will result in loss of production or  the need for remedial treatment. This can result from:
Solids blocking reservoir pores
Emulsion droplets blocking reservoir pores
Swelling clays
Ions from the formation and drilling fluid forming insoluble salts
5) Isolate the Fluid From the Formation

The differential pressure forces fluid into the wellbore, resulting  in whole mud or filtrate entering the formation. Either, or both, of these is undesirable because:
The loss of whole mud into the wellbore is expensive and damaging
The loss of filtrate into the wellbore may cause formation damage
The flow of fluid is affected by the 
formation of a filter cake
The  filter cake  reduces the flow of fluid 
into the formation.
Special additives are added to improve 
the cake quality:
Bridging material
Plate like material
Plugging material
The filter cake should be thin with a low 
permeability
This avoids reducing the effective 
hole diameter
It also reduces the chance of 
differential sticking
   
6) Cooling and Lubrication
The drilling fluid removes heat from the bit
 which is then dispersed at the surface
Fluid formulations are not changed to
 improve this function
Very occasionally the temperature of 
the fluid exceeds the flash point. In this
 case it is necessary to improve surface
 cooling
Extra lubrication may be required between
 the drill string and the casing or wellbore, 
especially in directional wells
Liquid additives are used (IDLUBE), or 
Oil based mud
Solid additives are sometimes used 
such as glass beads or nut plug
Drill pipe rubbers are sometimes 
added to reduce wear between the 
casing and drill pipe
 7) Support Part of the Tubular Weight
lAids in supporting part of the weight
 of the drill string and casing
 
lThe degree of buoyancy is directly 
 
proportional to the density of the 
 
fluid.
The fluid density is never 
 
changed to increase the buoyancy
 8) Maximise Penetration Rates
The fluid properties greatly 
 
influence penetration rates by:
 
Removing cuttings from 
 
below the bit and wellbore
 
Reducing the cushioning 
 
effect of solids between the
 
 bit teeth and the formation
 
Reducing the hydrostatic
 
 differential
 
Increasing the jet velocity
 
 
  9) Control Corrosion
 
The fluid should be non corrosive to the:
Drill string
Casing
Surface equipment
Corrosion can lead to:
Wash outs
Twist offs
Pump failure
Surface Leaks
 
11) Other Functions
 
Power Down hole motors
Turbines to turn the bit or 
power MWD / LWD equipment
Transfer information from 
measurement equipment to the
 surface
This is done with a pressure
 pulse
 

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