Difference between revisions of "Wellsite math"

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|+ {{table number|1}}Definitions of terms and abbreviations used in this chapter
 
|+ {{table number|1}}Definitions of terms and abbreviations used in this chapter
 
|-
 
|-
! Term
+
! Term || Definition || Unit
! Definition
 
! Unit
 
 
|-
 
|-
| P
+
| P || Hydrostatic pressure at depth d || psi
| Hydrostatic pressure at depth d
 
| psi
 
 
|-
 
|-
| MW
+
| MW || Mud weight || lb/gal
| Mud weight
 
| lb/gal
 
 
|-
 
|-
| D
+
| D || Vertical depth || ft
| Vertical depth
 
| ft
 
 
|-
 
|-
| V<sub>bpf</sub>
+
| V<sub>bpf</sub> || Volume || bbl/ft
| Volume
 
| bbl/ft
 
 
|-
 
|-
| <sup>D</sup><sub>1</sub>
+
| <sup>D</sup><sub>1</sub> || Larger diameter || in.
| Larger diameter
 
| in.
 
 
|-
 
|-
| <sup>D</sup> s
+
| <sup>D</sup> s || Smaller diameter || in.
| Smaller diameter
 
| in.
 
 
|-
 
|-
| V<sub>h</sub>
+
| V<sub>h</sub> || Hole volume; the volume of the open or cased hole || bbl/ft
| Hole volume; the volume of the open or cased hole
 
| bbl/ft
 
 
|-
 
|-
| V<sub>a</sub>
+
| V<sub>a</sub> || Annular volume; the volume of the annulus, the area between the outside of the drillpipe or collar and the open or cased hole || bbl/ft
| Annular volume; the volume of the annulus, the area between the outside of the drillpipe or collar and the open or cased hole
 
| bbl/ft
 
 
|-
 
|-
| V<sub>d</sub>
+
| V<sub>d</sub> || Displacement volume; the volume displaced by the steel volume of drillpipe or collar. Displacement is the volume between the outside diameter and inside diameter of a drillpipe or collar. || bbl/ft
| Displacement volume; the volume displaced by the steel volume of drillpipe or collar. Displacement is the volume between the outside diameter and inside diameter of a drillpipe or collar.
 
| bbl/ft
 
 
|-
 
|-
| V<sub>c</sub>
+
| V<sub>c</sub> || Capacity volume; the volume contained inside a drill pipe or collar || bbl/ft
| Capacity volume; the volume contained inside a drill pipe or collar
 
| bbl/ft
 
 
|-
 
|-
| W
+
| W || Weight of collars or casing || lb/ft
| Weight of collars or casing
 
| lb/ft
 
 
|-
 
|-
| od
+
| od || Outside diameter of pipe || in.
| Outside diameter of pipe
 
| in.
 
 
|-
 
|-
| id
+
| id || Inside diameter of pipe || in.
| Inside diameter of pipe
 
| in.
 
 
|-
 
|-
| D<sub>t</sub>
+
| D<sub>t</sub> || Triplex mud pump output || bbl/stroke
| Triplex mud pump output
 
| bbl/stroke
 
 
|-
 
|-
| D<sub>d</sub>
+
| D<sub>d</sub> || Duplex mud pump output || bbl/stroke
| Duplex mud pump output
 
| bbl/stroke
 
 
|-
 
|-
| L<sub>s</sub>
+
| L<sub>s</sub> || Length of pump stroke || in.
| Length of pump stroke
 
| in.
 
 
|-
 
|-
| D<sub>1</sub>
+
| D<sub>1</sub> || Diameter of pump liner || in.
| Diameter of pump liner
 
| in.
 
 
|-
 
|-
| D<sub>r</sub>
+
| D<sub>r</sub> || Diameter of pump rod (duplex only) || in.
| Diameter of pump rod (duplex only)
 
| in.
 
 
|-
 
|-
| AV
+
| AV || Annular velocity || ft/min
| Annular velocity
 
| ft/min
 
 
|-
 
|-
| GPM
+
| GPM || Mud pump output || gal/mi n
| Mud pump output
 
| gal/mi n
 
 
|-
 
|-
| Dh
+
| Dh || Hole diameter || in.
| Hole diameter
 
| in.
 
 
|-
 
|-
| An
+
| An || Jet nozzle area || in.<sup>2</sup>
| Jet nozzle area
 
| in.<sup>2</sup>
 
 
|-
 
|-
| J<sub>1</sub> … J<sub>n</sub>
+
| J<sub>1</sub> … J<sub>n</sub> || Size of jet nozzles, “32nd” omitted || 32nd in.
| Size of jet nozzles, “32nd” omitted
 
| 32nd in.
 
 
|-
 
|-
| JNV
+
| JNV || Jet nozzle velocity || ft/sec
| Jet nozzle velocity
 
| ft/sec
 
 
|-
 
|-
| THhp
+
| THhp || Total hydraulic horsepower || hp
| Total hydraulic horsepower
 
| hp
 
 
|-
 
|-
| Pp
+
| Pp || Mud pump pressure || psi
| Mud pump pressure
 
| psi
 
 
|-
 
|-
| JNPL
+
| JNPL || Jet nozzle pressure loss || psi
| Jet nozzle pressure loss
 
| psi
 
 
|-
 
|-
| % Hhpb
+
| % Hhpb || Percentage of total horsepower expended at bit || %
| Percentage of total horsepower expended at bit
 
| %
 
 
|-
 
|-
| BHhp
+
| BHhp || Hydraulic horsepower at the bit || hp
| Hydraulic horsepower at the bit
 
| hp
 
 
|-
 
|-
| Hhp/in.<sup>2</sup>
+
| Hhp/in.<sup>2</sup> || Hydraulic horsepower per square inch area of bit || hp/in.<sup>2</sup>
| Hydraulic horsepower per square inch area of bit
 
| hp/in.<sup>2</sup>
 
 
|-
 
|-
| Ob
+
| Ob || Bit diameter || in.
| Bit diameter
 
| in.
 
 
|-
 
|-
| JIF
+
| JIF || Jet impact force || lb
| Jet impact force
 
| lb
 
 
|-
 
|-
| FFP
+
| FFP || Formation [[fracture]] pressure || psi
| Formation fracture pressure
 
| psi
 
 
|-
 
|-
| T% Hhpb
+
| T% Hhpb || Total percentage hydraulic horsepower at the bit || %
| Total percentage hydraulic horsepower at the bit
 
| %
 
 
|}
 
|}
  
Line 167: Line 97:
 
* The density of the liquid (mud weight)
 
* The density of the liquid (mud weight)
  
The total volume of liquid or shape of the hole have no influence on hydrostatic pressure, but the height of the liquid column (depth) must be measured in the same direction as the force due to gravity, that is, true vertical. This consideration is important in highly deviated and horizontal wellbores. The hydrostatic pressure (P) at any depth in a wellbore is calculated as follows:
+
The total volume of liquid or shape of the hole have no influence on hydrostatic pressure, but the height of the liquid column (depth) must be measured in the same direction as the force due to [[gravity]], that is, true vertical. This consideration is important in highly deviated and horizontal wellbores. The hydrostatic pressure (P) at any depth in a wellbore is calculated as follows:
  
 
:<math>\mbox{P} = 0.052 \times \mbox{MW} \times \mbox{D}</math>
 
:<math>\mbox{P} = 0.052 \times \mbox{MW} \times \mbox{D}</math>
Line 179: Line 109:
 
If the equation for hydrostatic pressure is solved for mud weight (MW), then the equivalent mud weight can be calculated, which has several important wellsite applications. Solving for MW, the equation becomes
 
If the equation for hydrostatic pressure is solved for mud weight (MW), then the equivalent mud weight can be calculated, which has several important wellsite applications. Solving for MW, the equation becomes
  
:<math>\mbox{MW} = \mbox{P}/(0.052 \times \mbox{D})</math>
+
:<math>\mbox{MW} = \frac{\mbox{P}}{(0.052 \times \mbox{D})}</math>
  
''Example'': Assume a formation at [[depth::10,000 ft]] has a known hydrostatic pressure of 6292 psi. The mud weight needed to drill this formation “balanced” (hydrostatic pressure equal to formation pressure) is calculated as follows:
+
'''''Example''''': Assume a formation at [[depth::10,000 ft]] has a known hydrostatic pressure of 6292 psi. The mud weight needed to drill this formation “balanced” (hydrostatic pressure equal to formation pressure) is calculated as follows:
  
:<math>\mbox{MW} = 6292/(0.052 \times 10{,}000) = 12.1 \mbox{ ppg}</math>
+
:<math>\mbox{MW} = \frac{6292}{(0.052 \times 10{,}000)} = 12.1 \mbox{ ppg}</math>
  
 
===Kill weight of mud===
 
===Kill weight of mud===
Line 191: Line 121:
 
'''''Example''''': Assume a well has taken a kick at [[depth::10,000 ft]] while drilling with 11.5-ppg mud. The well is shut-in, and the drill pipe pressure reads 312 psi. The excess in pounds per gallon mud weight equivalent is calculated as follows:
 
'''''Example''''': Assume a well has taken a kick at [[depth::10,000 ft]] while drilling with 11.5-ppg mud. The well is shut-in, and the drill pipe pressure reads 312 psi. The excess in pounds per gallon mud weight equivalent is calculated as follows:
  
:<math>\mbox{MW} = 312/(0.052 \times 10{,}000) = 0.6 \mbox{ ppg}</math>
+
:<math>\mbox{MW} = \frac{312}{(0.052 \times 10{,}000)} = 0.6 \mbox{ ppg}</math>
  
 
Adding the calculated excess of 0.6 ppg to the current mud weight of 11.5 ppg results in 12.1 ppg necessary to control the well. The mud weight is typically increased beyond the calculated kill weight to allow for the negative pressure (swab) exerted on the hole when tripping the drill string.
 
Adding the calculated excess of 0.6 ppg to the current mud weight of 11.5 ppg results in 12.1 ppg necessary to control the well. The mud weight is typically increased beyond the calculated kill weight to allow for the negative pressure (swab) exerted on the hole when tripping the drill string.
Line 201: Line 131:
 
'''''Example''''': Assume a leak-off test conducted in a 10,000-ft wellbore containing 11.5-ppg mud with a leak-off pressure of 1040 psi. The formation fracture pressure is estimated as
 
'''''Example''''': Assume a leak-off test conducted in a 10,000-ft wellbore containing 11.5-ppg mud with a leak-off pressure of 1040 psi. The formation fracture pressure is estimated as
  
:<math>\mbox{MW} = 1040/(0.052 \times 10{,}000 = 2.0 \mbox{ ppg}\end{align*}  $$</tex-math></disp-formula>
+
:<math>\mbox{MW} = \frac{1040}{(0.052 \times 10{,}000)} = 2.0 \mbox{ ppg}</math>
  
The formation fracture pressure is equivalent to an 11.5 + 2.0 = 13.5 ppg mud weight, or<disp-formula><tex-math notation="TeX">$$\begin{align*}\mbox{FFP} = 0.052 \times 13.5 \times 10{,}000 = 7020 \mbox{ psi}</math>
+
The formation fracture pressure is equivalent to an 11.5 + 2.0 = 13.5 ppg mud weight, or
 +
 
 +
:<math>\mbox{FFP} = 0.052 \times 13.5 \times 10{,}000 = 7020 \mbox{ psi}</math>
  
 
Therefore, loss of circulation may be a problem in this wellbore if mud weights exceed about 13.5 ppg. This procedure is sufficiently accurate for quick field calculations, but it slightly overestimates the formation fracture pressures because the effective compressibility of the drilling fluid and frictional pressure losses are not accounted for.
 
Therefore, loss of circulation may be a problem in this wellbore if mud weights exceed about 13.5 ppg. This procedure is sufficiently accurate for quick field calculations, but it slightly overestimates the formation fracture pressures because the effective compressibility of the drilling fluid and frictional pressure losses are not accounted for.
Line 211: Line 143:
 
All important wellbore volumes are calculated with a single formula:
 
All important wellbore volumes are calculated with a single formula:
  
:<math>\mbox{V}_{\rm bpf} = (\mbox{D}_{\rm L}{}^{2} - \mbox{D}_{\rm S}{}^{2})/1029.4</math>
+
:<math>\mbox{V}_{\rm bpf} = \frac{(\mbox{D}_{\rm L}{}^{2} - \mbox{D}_{\rm S}{}^{2})}{1029.4}</math>
  
 
Volumes are reported in units of barrels and can be calculated for an in-gauge hole by using this equation to determine volume in barrels per foot, then multiplying that value by the length of the section of hole in feet. (Note: washouts and thick mud cake can substantially alter hole volume.)
 
Volumes are reported in units of barrels and can be calculated for an in-gauge hole by using this equation to determine volume in barrels per foot, then multiplying that value by the length of the section of hole in feet. (Note: washouts and thick mud cake can substantially alter hole volume.)
Line 218: Line 150:
  
 
:<math>\mbox{V}_{\rm h}  = [(8.0^{2})/1029.4] \times 10{,}000 = 621.7 \mbox{ bbl}</math>
 
:<math>\mbox{V}_{\rm h}  = [(8.0^{2})/1029.4] \times 10{,}000 = 621.7 \mbox{ bbl}</math>
:<math>&\\\mbox{V}_{\rm a} &= [(8.0^{2} - 5.0^{2})/1029.4] \times 10{,}000 = 378.9 \mbox{ bbl}\\&\\\mbox{V}_{\rm d} &= [(5.0^{2} - 4.0^{2})/1029.4] \times 10{,}000 = 87.4 \mbox{ bbl}\\&\\\mbox{V}_{\rm c} &= [(4.0^{2})/1029.4] \times 10{,}000 = 155.4 \mbox{ bbl}</math>
+
:<math>\mbox{V}_{\rm a} = [(8.0^{2} - 5.0^{2})/1029.4] \times 10{,}000 = 378.9 \mbox{ bbl}</math>
 +
:<math>\mbox{V}_{\rm d} = [(5.0^{2} - 4.0^{2})/1029.4] \times 10{,}000 = 87.4 \mbox{ bbl}</math>
 +
:<math>\mbox{V}_{\rm c} = [(4.0^{2})/1029.4] \times 10{,}000 = 155.4 \mbox{ bbl}</math>
  
 
Although this solution is correct mathematically (that is, the sum of annular volume, displacement, and capacity equals the hole volume), the basic formula results in an underestimate for displacement of drill pipe. Since drill pipe (not collars) has tool joints that are welded onto the pipe, calculation of drill pipe displacement involves an additional step to account for the additional volume displaced by the tool joints. For most calculations with commonly used sizes and weights of drill pipe (4.5 and 5 in.), the addition of the quantity 0.001 to the barrel per foot volume calculation for displacement accounts for the additional tool joint volume with sufficient accuracy. Using the data from the previous example, we obtain the following the displacement calculation:
 
Although this solution is correct mathematically (that is, the sum of annular volume, displacement, and capacity equals the hole volume), the basic formula results in an underestimate for displacement of drill pipe. Since drill pipe (not collars) has tool joints that are welded onto the pipe, calculation of drill pipe displacement involves an additional step to account for the additional volume displaced by the tool joints. For most calculations with commonly used sizes and weights of drill pipe (4.5 and 5 in.), the addition of the quantity 0.001 to the barrel per foot volume calculation for displacement accounts for the additional tool joint volume with sufficient accuracy. Using the data from the previous example, we obtain the following the displacement calculation:
  
 
:<math>\mbox{V}_{\rm d}  = ([5.0^{2} - 4.0^{2})/1029.4] + 0.001) \times 10{,}000</math>
 
:<math>\mbox{V}_{\rm d}  = ([5.0^{2} - 4.0^{2})/1029.4] + 0.001) \times 10{,}000</math>
:<math>&=97.4 \mbox{ bbl}</math>
+
:<math>=97.4 \mbox{ bbl}</math>
  
 
Notice that when drill pipe tool joints are considered, the displacement is 10.0 bbl greater. Again, this additional step is not necessary when calculating the displacement of collars since collars do not have welded-on tool joints.
 
Notice that when drill pipe tool joints are considered, the displacement is 10.0 bbl greater. Again, this additional step is not necessary when calculating the displacement of collars since collars do not have welded-on tool joints.
Line 248: Line 182:
  
 
:<math>\mbox{D}_{\rm t}  = (\mbox{L}_{\rm s} \times \mbox{D}_{l}{}^{2})/4118</math>
 
:<math>\mbox{D}_{\rm t}  = (\mbox{L}_{\rm s} \times \mbox{D}_{l}{}^{2})/4118</math>
:<math>\mbox{D}_{\rm d} &= \mbox{L}_{\rm s} \times [(2 \times \mbox{D}_{\rm l}{}^{2}) - \mbox{D}_{\rm r}{}^{2}]/6176</math>
+
:<math>\mbox{D}_{\rm d} = \mbox{L}_{\rm s} \times [(2 \times \mbox{D}_{\rm l}{}^{2}) - \mbox{D}_{\rm r}{}^{2}]/6176</math>
  
 
'''''Example''''': The output of a triplex mud pump with an 11-in. stroke length and 6-in. liners installed is
 
'''''Example''''': The output of a triplex mud pump with an 11-in. stroke length and 6-in. liners installed is
Line 259: Line 193:
  
 
:<math> \mbox{Bbl/min} = \mbox{Bbls/stroke} \times \mbox{Strokes/min}</math>
 
:<math> \mbox{Bbl/min} = \mbox{Bbls/stroke} \times \mbox{Strokes/min}</math>
:<math>&\\&\mbox{Gal/stroke} = \mbox{Bbls/stroke} \times 42\\&\\&\mbox{Gal/min} = \mbox{Gal/stroke} \times \mbox{Strokes/min}</math>
+
:<math> \mbox{Gal/stroke} = \mbox{Bbls/stroke} \times 42</math>
 +
:<math> \mbox{Gal/min} = \mbox{Gal/stroke} \times \mbox{Strokes/min}</math>
  
 
'''''Example''''': If the triplex pump previously discussed was operating at 95% volumetric efficiency at 98 strokes/min, the following calculations can be made:
 
'''''Example''''': If the triplex pump previously discussed was operating at 95% volumetric efficiency at 98 strokes/min, the following calculations can be made:
  
 
:<math> \mbox{Bbl/stroke} = 0.0962 \times 0.95 = 0.0914 \mbox{ bbl/stroke}</math>
 
:<math> \mbox{Bbl/stroke} = 0.0962 \times 0.95 = 0.0914 \mbox{ bbl/stroke}</math>
:<math>&\\&\mbox{Bbl/min} = 0.9814 \times 98 = 8.96 \mbox{ bbl/min}\\&\\&\mbox{Gal/stroke} = 0.0914 \times 42 = 3.84 \mbox{ gal/stroke}\\&\\&\mbox{Gal/min} = 3.84 \times 98 = 376 \mbox{ gal/min}</math>
+
:<math> \mbox{Bbl/min} = 0.9814 \times 98 = 8.96 \mbox{ bbl/min}</math>
 +
:<math> \mbox{Gal/stroke} = 0.0914 \times 42 = 3.84 \mbox{ gal/stroke}</math>
 +
:<math> \mbox{Gal/min} = 3.84 \times 98 = 376 \mbox{ gal/min}</math>
  
 
==Circulation or lag time==
 
==Circulation or lag time==
Line 270: Line 207:
 
Bottoms-up circulation, or ''lag time'', is the time for samples or gas created at the bit to arrive at the surface (via the drilling fluid) for examination. This calculation is dependent on the volume and rate.
 
Bottoms-up circulation, or ''lag time'', is the time for samples or gas created at the bit to arrive at the surface (via the drilling fluid) for examination. This calculation is dependent on the volume and rate.
  
After calculating wellbore volumes and mud pump output, several parameters for the circulating time of the drilling fluid can be estimated. The most routinely used of these parameters are
+
After calculating wellbore volumes and mud pump output, several parameters for the circulating time of the [[drilling fluid]] can be estimated. The most routinely used of these parameters are
  
 
* surface-to-bit pump strokes,
 
* surface-to-bit pump strokes,
Line 279: Line 216:
 
Because drilling fluid is pumped down the inside of the drill string to the bit, surface-to-bit (s-to-b) calculations are made as follows:
 
Because drilling fluid is pumped down the inside of the drill string to the bit, surface-to-bit (s-to-b) calculations are made as follows:
  
:<math>\mbox{S-to-b strokes}  = (\mbox{Total capacity in bbl})/(\mbox{pump output in}</math>
+
:<math>\mbox{S-to-b strokes}  = \frac{\mbox{Total capacity in bbl}}{\mbox{pump output in bbl/stroke}}</math>
:<math>&\quad \ \mbox{bbl/stroke})</math>
 
  
 
[[Drilling fluid]] is then pumped back up the hole to the surface via the annulus, therefore bit-to-surface (b-to-s) or lag calculations are made as follows:
 
[[Drilling fluid]] is then pumped back up the hole to the surface via the annulus, therefore bit-to-surface (b-to-s) or lag calculations are made as follows:
  
:<math>\mbox{B-to-s strokes}  = (\mbox{Total annular volume in bbl})/(\mbox{pump}</math>
+
:<math>\mbox{B-to-s strokes}  = \frac{\mbox{Total annular volume in bbl}}{\mbox{pump output in bbl/stroke}}</math>
:<math>&\quad \ \mbox{output in bbl/stroke})\\&\\\mbox{B-to-s min} &= (\mbox{B-to-s strokes})/(\mbox{pump rate in strokes/min})</math>
+
:<math>\mbox{B-to-s min} = \frac{\mbox{B-to-s strokes}}{\mbox{pump rate in strokes/min}}</math>
  
 
'''''Example''''': Using the previously calculated data, we can calculate circulating time as follows:
 
'''''Example''''': Using the previously calculated data, we can calculate circulating time as follows:
  
:<math>\mbox{S-to-b strokes}  = (155.4 \mbox{ bbl})/(\mbox{0.914-in. bbl/stroke})</math>
+
:<math>\mbox{S-to-b strokes}  = \frac{155.4 \mbox{ bbl}}{\mbox{0.914-in. bbl/stroke}} = 1700 \mbox{ strokes}</math>
:<math> &= 1700 \mbox{ strokes}\\&\\\mbox{S-to-b min} &= (1700 \mbox{ strokes})/(98 \mbox{ strokes/min}) = 17.35 \mbox{ min}\\&\\\mbox{B-to-s strokes} &= (378.9 \mbox{ bbl})/(\mbox{0.0914-in. bbl/stroke})\\&= 4146 \mbox{ strokes}\\&\\\mbox{B-to-s min} &= (4146 \mbox{ strokes})/(98 \mbox{ strokes/min}) = 42.30 \mbox{ min}</math>
+
:<math>\mbox{S-to-b min} = \frac{1700 \mbox{ strokes}}{98 \mbox{ strokes/min}} = 17.35 \mbox{ min}</math>
 +
:<math>\mbox{B-to-s strokes} = \frac{378.9 \mbox{ bbl}}{\mbox{0.0914-in. bbl/stroke}} = 4146 \mbox{ strokes}</math>
 +
:<math>\mbox{B-to-s min} = \frac{4146 \mbox{ strokes}}{98 \mbox{ strokes/min}} = 42.30 \mbox{ min}</math>
  
 
Lag time can also be measured at the wellsite by placing calcium carbide in the pipe when a connection is made. The carbide reacts with the water in the mud and forms acetylene gas that is readily detected by the chromatograph. The stroke counter is reset when the carbide is “dropped” down the pipe, and the number of strokes needed for the acetylene return is noted. The actual and calculated lags are then compared, and an interpretation is made.
 
Lag time can also be measured at the wellsite by placing calcium carbide in the pipe when a connection is made. The carbide reacts with the water in the mud and forms acetylene gas that is readily detected by the chromatograph. The stroke counter is reset when the carbide is “dropped” down the pipe, and the number of strokes needed for the acetylene return is noted. The actual and calculated lags are then compared, and an interpretation is made.
Line 304: Line 242:
 
''Annular velocity'' is the average speed at which the drilling fluid is moving back up the annular space as the well is circulated. Although the mud pump output remains constant, annular velocities vary at different points in the wellbore due to changes in pipe, collar, and hole sizes. Annular velocity (AV) can be calculated as
 
''Annular velocity'' is the average speed at which the drilling fluid is moving back up the annular space as the well is circulated. Although the mud pump output remains constant, annular velocities vary at different points in the wellbore due to changes in pipe, collar, and hole sizes. Annular velocity (AV) can be calculated as
  
:<math>\mbox{AV} = (24.5 \times \mbox{GPM})/(\mbox{Dh}^{2} - \mbox{od}^{2})</math>
+
:<math>\mbox{AV} = \frac{24.5 \times \mbox{GPM}}{\mbox{Dh}^{2} - \mbox{od}^2}</math>
  
 
'''''Example''''': If mud is circulated at 400 gal/min in an 8.5-in. hole containing a 4.5-in. drill pipe and 6.5-in. collars, the annular velocities are
 
'''''Example''''': If mud is circulated at 400 gal/min in an 8.5-in. hole containing a 4.5-in. drill pipe and 6.5-in. collars, the annular velocities are
  
:<math>\mbox{Drill pipe: AV} = (24.5 \times 400)/(8.5^{2} - 4.5^{2})</math>
+
:<math>\mbox{Drill pipe: AV} = \frac{24.5 \times 400}{8.5^2 - 4.5^2} = 188.5\mbox{ ft/min}</math>
:<math>&= 188.5 \mbox{ ft/min}\\&\\\mbox{Collars: AV} &= (24.5 \times 400)/(8.5^{2} - 6.5^{2})\\&= 326.7 \mbox{ ft/min}</math>
+
:<math>\mbox{Collars: AV} = \frac{24.5 \times 400}{8.5^2 - 6.5^2} = 326.7 \mbox{ ft/min}</math>
  
 
===Jet nozzle area===
 
===Jet nozzle area===
Line 325: Line 263:
 
Jet nozzle velocity (JNV) is the velocity of the mud exiting the jet nozzles of the bit and is estimated as
 
Jet nozzle velocity (JNV) is the velocity of the mud exiting the jet nozzles of the bit and is estimated as
  
:<math>\mbox{JNV} = (0.32086 \times \mbox{GPM})/\mbox{An}</math>
+
:<math>\mbox{JNV} = \frac{0.32086 \times \mbox{GPM}}{\mbox{An}}</math>
  
 
''Example'': The jet nozzle velocity for a bit with three 13's jets installed and a circulation rate of 400 GPM is
 
''Example'': The jet nozzle velocity for a bit with three 13's jets installed and a circulation rate of 400 GPM is
  
:<math>\mbox{JNV} = (0.32086 \times 400)/0.3889 = 330 \mbox{ ft/sec}</math>
+
:<math>\mbox{JNV} = \frac{0.32086 \times 400}{0.3889} = 330 \mbox{ ft/sec}</math>
  
 
====Total hydraulic horsepower====
 
====Total hydraulic horsepower====
Line 335: Line 273:
 
The total hydraulic horsepower (THhp) available for drilling hydraulics is defined by the circulation rate and pressure of the mud pump. Total hydraulic horsepower is calculated as
 
The total hydraulic horsepower (THhp) available for drilling hydraulics is defined by the circulation rate and pressure of the mud pump. Total hydraulic horsepower is calculated as
  
:<math>\mbox{THhp} = (\mbox{Pp} \times \mbox{GPM})/1714</math>
+
:<math>\mbox{THhp} = \frac{\mbox{Pp} \times \mbox{GPM}}{1714}</math>
  
 
'''''Example''''': The total hydraulic horsepower available if circulating at 400 gal/min with a pump pressure of 2000 psi is
 
'''''Example''''': The total hydraulic horsepower available if circulating at 400 gal/min with a pump pressure of 2000 psi is
  
:<math>\mbox{THhp} = (2000 \times 400)/1714 = 467 \mbox{ hp}</math>
+
:<math>\mbox{THhp} = \frac{2000 \times 400}{1714} = 467 \mbox{ hp}</math>
  
 
===Jet nozzle pressure loss===
 
===Jet nozzle pressure loss===
Line 345: Line 283:
 
Pump pressure is the total pressure expended throughout the circulating system's surface equipment (such as the standpipe, kelly hose, and kelly), drill string bore, jet nozzles, and annulus. Only the pressure expended through the jet nozzles accomplishes useful work for drilling. The remaining pressure losses are referred to as ''parasitic pressure losses''. Jet nozzle pressure loss is estimated as follows:
 
Pump pressure is the total pressure expended throughout the circulating system's surface equipment (such as the standpipe, kelly hose, and kelly), drill string bore, jet nozzles, and annulus. Only the pressure expended through the jet nozzles accomplishes useful work for drilling. The remaining pressure losses are referred to as ''parasitic pressure losses''. Jet nozzle pressure loss is estimated as follows:
  
:<math>\mbox{JNPL} = (\mbox{MW} \times \mbox{GPM}^{2})/(10{,}858 \times \mbox{An}^{2})</math>
+
:<math>\mbox{JNPL} = \frac{\mbox{MW} \times \mbox{GPM}^2}{10{,}858 \times \mbox{An}^2}</math>
  
 
'''''Example''''': The pressure lost through three 13′s jet nozzles while circulating a 12.0-ppg mud at 400 gal/min is
 
'''''Example''''': The pressure lost through three 13′s jet nozzles while circulating a 12.0-ppg mud at 400 gal/min is
  
:<math>\mbox{JNPL} = (12 \times 400^{2})/(10{,}858 \times 0.3889^{2}) = 1169 \mbox{ psi}</math>
+
:<math>\mbox{JNPL} = \frac{12 \times 400^2}{10{,}858 \times 0.3889^2} = 1169 \mbox{ psi}</math>
  
 
===Hydraulic horsepower at the bit===
 
===Hydraulic horsepower at the bit===
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The hydraulic horsepower at the bit (BHhp) is calculated as for total hydraulic horsepower (THhp), but the mud pump pressure (Pp) is replaced by the jet nozzle pressure loss (JNPL):
 
The hydraulic horsepower at the bit (BHhp) is calculated as for total hydraulic horsepower (THhp), but the mud pump pressure (Pp) is replaced by the jet nozzle pressure loss (JNPL):
  
:<math>\mbox{BHhp} = (1169 \times 400)/1714 = 273 \mbox{ hp}</math>
+
:<math>\mbox{BHhp} = \frac{1169 \times 400}{1714} = 273 \mbox{ hp}</math>
  
 
The ''percentage'' of the total hydraulic horsepower expended at the bit is an important parameter to determine and is calculated in two ways:
 
The ''percentage'' of the total hydraulic horsepower expended at the bit is an important parameter to determine and is calculated in two ways:
  
:<math>\% \mbox{ Hhpb} = (\mbox{BHhp/THhp}) \times 100</math>
+
:<math>\% \mbox{ Hhpb} = \frac{\mbox{BHhp}}{\text{THhp}} \times 100</math>
  
 
or
 
or
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==See also==
 
==See also==
* [[Drilling problems]]
 
* [[Mudlogging: Drill cuttings analysis]]
 
 
* [[Introduction to wellsite methods]]
 
* [[Introduction to wellsite methods]]
 
* [[Wellbore trajectory]]
 
* [[Wellbore trajectory]]
* [[Conventional coring]]
 
* [[Drilling fluid]]
 
* [[Land rigs]]
 
* [[Rig personnel]]
 
* [[Core handling]]
 
* [[Mudlogging: Equipment, services, and personnel]]
 
* [[Core alteration and preservation]]
 
* [[Wellsite safety]]
 
* [[Sidewall coring]]
 
* [[Show evaluation]]
 
 
* [[Rate of penetration]]
 
* [[Rate of penetration]]
* [[Mudlogging: The mudlog]]
 
* [[Well planning]]
 
 
* [[Pressure detection]]
 
* [[Pressure detection]]
 
* [[Drill stem testing]]
 
* [[Drill stem testing]]
* [[Measurement while drilling]]
 
* [[Offshore rigs]]
 
* [[Fishing]]
 
* [[Core orientation]]
 
* [[Mudlogging: Gas extraction and monitoring]]
 
  
 
==References==
 
==References==
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[[Category:Wellsite methods]] [[Category:Pages with unformatted equations]]
 
[[Category:Wellsite methods]] [[Category:Pages with unformatted equations]]
 +
[[Category:Methods in Exploration 10]]

Latest revision as of 15:10, 24 January 2022

A few simple mathematical formulas are used to make key calculations during the drilling of a well. The results from these calculations increase knowledge of well behavior and facilitate communication with drilling personnel. Definitions of the mathematical variables and abbreviations used in this chapter are given in Table 1.

Table 1 Definitions of terms and abbreviations used in this chapter
Term Definition Unit
P Hydrostatic pressure at depth d psi
MW Mud weight lb/gal
D Vertical depth ft
Vbpf Volume bbl/ft
D1 Larger diameter in.
D s Smaller diameter in.
Vh Hole volume; the volume of the open or cased hole bbl/ft
Va Annular volume; the volume of the annulus, the area between the outside of the drillpipe or collar and the open or cased hole bbl/ft
Vd Displacement volume; the volume displaced by the steel volume of drillpipe or collar. Displacement is the volume between the outside diameter and inside diameter of a drillpipe or collar. bbl/ft
Vc Capacity volume; the volume contained inside a drill pipe or collar bbl/ft
W Weight of collars or casing lb/ft
od Outside diameter of pipe in.
id Inside diameter of pipe in.
Dt Triplex mud pump output bbl/stroke
Dd Duplex mud pump output bbl/stroke
Ls Length of pump stroke in.
D1 Diameter of pump liner in.
Dr Diameter of pump rod (duplex only) in.
AV Annular velocity ft/min
GPM Mud pump output gal/mi n
Dh Hole diameter in.
An Jet nozzle area in.2
J1 … Jn Size of jet nozzles, “32nd” omitted 32nd in.
JNV Jet nozzle velocity ft/sec
THhp Total hydraulic horsepower hp
Pp Mud pump pressure psi
JNPL Jet nozzle pressure loss psi
% Hhpb Percentage of total horsepower expended at bit %
BHhp Hydraulic horsepower at the bit hp
Hhp/in.2 Hydraulic horsepower per square inch area of bit hp/in.2
Ob Bit diameter in.
JIF Jet impact force lb
FFP Formation fracture pressure psi
T% Hhpb Total percentage hydraulic horsepower at the bit %

Hydrostatic pressure in liquid columns[edit]

Mud weight is the key pressure gauge used in drilling since it responds directly to formation pressure. The hydrostatic pressure at any point in a wellbore filled with liquid drilling fluid (mud) under static conditions (that is, not circulating and/or not moving the drill string up or down) is a function of only two variables:

  • The height of the liquid column (depth)
  • The density of the liquid (mud weight)

The total volume of liquid or shape of the hole have no influence on hydrostatic pressure, but the height of the liquid column (depth) must be measured in the same direction as the force due to gravity, that is, true vertical. This consideration is important in highly deviated and horizontal wellbores. The hydrostatic pressure (P) at any depth in a wellbore is calculated as follows:

Example: If a 10,000-ft-deep hole contains drilling fluid with a weight of 11.5 ppg (pounds per gallon), the hydrostatic pressure at the bottom of the hole is

Mud weight[edit]

If the equation for hydrostatic pressure is solved for mud weight (MW), then the equivalent mud weight can be calculated, which has several important wellsite applications. Solving for MW, the equation becomes

Example: Assume a formation at depth::10,000 ft has a known hydrostatic pressure of 6292 psi. The mud weight needed to drill this formation “balanced” (hydrostatic pressure equal to formation pressure) is calculated as follows:

Kill weight of mud[edit]

In a well control situation after a kick has been taken, it is necessary to increase the mud weight to balance the formation pressure. The kill weight of the mud can be calculated by observing the stabilized shut-in drill pipe pressure. The shut-in drill pipe pressure records the excess formation pressure over the hydrostatic pressure of the drilling fluid in the hole. Shut-in drill pipe pressure is converted to an equivalent mud weight. This weight is added to the mud weight currently in the hole to obtain the kill weight needed. The kill weight of the mud can also be converted back to pounds per square inch to obtain an estimation of the formation pressure.

Example: Assume a well has taken a kick at depth::10,000 ft while drilling with 11.5-ppg mud. The well is shut-in, and the drill pipe pressure reads 312 psi. The excess in pounds per gallon mud weight equivalent is calculated as follows:

Adding the calculated excess of 0.6 ppg to the current mud weight of 11.5 ppg results in 12.1 ppg necessary to control the well. The mud weight is typically increased beyond the calculated kill weight to allow for the negative pressure (swab) exerted on the hole when tripping the drill string.

Formation fracture pressure[edit]

The formation fracture pressure (FTP) can be determined by the use of a leak-off or formation integrity test. In this test, the well is shut-in and drilling fluid is pumped slowly into the well. Wellbore pressure increases linearly up to the point where the formation starts to take drilling fluid. The pressure at this point is the leak-off pressure and is used to estimate formation fracture pressure. Like shut-in drill pipe pressure, leak-off pressure is added to the pressure of the mud in the hole.

Example: Assume a leak-off test conducted in a 10,000-ft wellbore containing 11.5-ppg mud with a leak-off pressure of 1040 psi. The formation fracture pressure is estimated as

The formation fracture pressure is equivalent to an 11.5 + 2.0 = 13.5 ppg mud weight, or

Therefore, loss of circulation may be a problem in this wellbore if mud weights exceed about 13.5 ppg. This procedure is sufficiently accurate for quick field calculations, but it slightly overestimates the formation fracture pressures because the effective compressibility of the drilling fluid and frictional pressure losses are not accounted for.

Wellbore volumes[edit]

All important wellbore volumes are calculated with a single formula:

Volumes are reported in units of barrels and can be calculated for an in-gauge hole by using this equation to determine volume in barrels per foot, then multiplying that value by the length of the section of hole in feet. (Note: washouts and thick mud cake can substantially alter hole volume.)

Example: If a 10,000-ft-deep hole with an 8.0-in.-diameter contained pipe with an outside diameter of length::5.0 in. and an inside diameter of length::4.0 in., the volume calculations are as follows:

Although this solution is correct mathematically (that is, the sum of annular volume, displacement, and capacity equals the hole volume), the basic formula results in an underestimate for displacement of drill pipe. Since drill pipe (not collars) has tool joints that are welded onto the pipe, calculation of drill pipe displacement involves an additional step to account for the additional volume displaced by the tool joints. For most calculations with commonly used sizes and weights of drill pipe (4.5 and 5 in.), the addition of the quantity 0.001 to the barrel per foot volume calculation for displacement accounts for the additional tool joint volume with sufficient accuracy. Using the data from the previous example, we obtain the following the displacement calculation:

Notice that when drill pipe tool joints are considered, the displacement is 10.0 bbl greater. Again, this additional step is not necessary when calculating the displacement of collars since collars do not have welded-on tool joints.

When volume calculations are made at the wellsite, it is important to identify each hole geometry in the wellbore. This is best accomplished by drawing a schematic diagram of the wellbore and identifying all casing, open hole, drill pipe, and collar dimensions. Several handbooks have extensive tables listing pipe and collar dimensions[1]. Calculations must then be made for each annular displacement capacity and hole volume and then summed for a total.

Weight of collars or casing[edit]

The weight (W) of collars or casing, in pounds per foot, is estimated by

Often the outside diameter (od) and the weight of the collars are the only dimensions known. In this case, the previous equation can be solved for the inside diameter (id) of the collars:

Example: To estimate the inside diameter of drill collars having an outside diameter of length::6.5 in. and weighing 96 lb/ft, the following calculation is made:

Mud pump output[edit]

The theoretical pump outputs for triplex and duplex type pumps are calculated by the following formulas:

Example: The output of a triplex mud pump with an 11-in. stroke length and 6-in. liners installed is

This is a theoretical calculation based on the pump working at 100% efficiency. Mud pumps are rarely 100% efficient, and this calculation is multiplied by some volumetric efficiency factor, typically 0.90 to 0.99 for triplex pumps and 0.80 to 0.90 for duplex pumps. The actual efficiency of a pump is determined by measuring the suction pit, isolating the suction pit so that mud is pumped out of that pit only for a certain number of pump strokes, then calculating the volume pumped out of the pit and dividing by the total number of pump strokes.

In addition to barrels per stroke, mud pump output can also be expressed in gallons per stroke, barrels per minute, or gallons per minute. Once barrel per stroke is determined, the remaining parameters are easily calculated as follows:

Example: If the triplex pump previously discussed was operating at 95% volumetric efficiency at 98 strokes/min, the following calculations can be made:

Circulation or lag time[edit]

Bottoms-up circulation, or lag time, is the time for samples or gas created at the bit to arrive at the surface (via the drilling fluid) for examination. This calculation is dependent on the volume and rate.

After calculating wellbore volumes and mud pump output, several parameters for the circulating time of the drilling fluid can be estimated. The most routinely used of these parameters are

  • surface-to-bit pump strokes,
  • surface-to-bit time,
  • bit-to-surface pump strokes (lag strokes), and
  • bit-to-surface time (lag time).

Because drilling fluid is pumped down the inside of the drill string to the bit, surface-to-bit (s-to-b) calculations are made as follows:

Drilling fluid is then pumped back up the hole to the surface via the annulus, therefore bit-to-surface (b-to-s) or lag calculations are made as follows:

Example: Using the previously calculated data, we can calculate circulating time as follows:

Lag time can also be measured at the wellsite by placing calcium carbide in the pipe when a connection is made. The carbide reacts with the water in the mud and forms acetylene gas that is readily detected by the chromatograph. The stroke counter is reset when the carbide is “dropped” down the pipe, and the number of strokes needed for the acetylene return is noted. The actual and calculated lags are then compared, and an interpretation is made.

Comparison of measured and calculated lag time and a knowledge of volume and mud pump calculations have several other problem-solving applications at the wellsite. These include the location of a washout (crack or hole) in the drill string, where to spot oil when the drill string is stuck, and the density of the intruding kick fluid.

Bit hydraulics[edit]

Hydraulics is a branch of science that deals with practical applications of fluids in motion. Bit hydraulics is important because hole cleaning and drilling efficency are directly affected by horsepower expended at the bit.

Annular velocity[edit]

Annular velocity is the average speed at which the drilling fluid is moving back up the annular space as the well is circulated. Although the mud pump output remains constant, annular velocities vary at different points in the wellbore due to changes in pipe, collar, and hole sizes. Annular velocity (AV) can be calculated as

Example: If mud is circulated at 400 gal/min in an 8.5-in. hole containing a 4.5-in. drill pipe and 6.5-in. collars, the annular velocities are

Jet nozzle area[edit]

A conventional rotary drilling bit typically has two to four jet nozzles installed to impart a jetting action on the mud to clean the bottom of the hole. Nozzle size is variable and is measured in 32nds of an inch. Note that when jet nozzle sizes are given, the “32nd” is usually omitted. Thus, a bit with “three 13′s” installed means the bit has three 13/32-in. nozzles installed. The total area (An) of the jet nozzles is calculated as

Example: The area of jet nozzles for a bit with three 13/32-in. nozzles installed is

Jet nozzle velocity[edit]

Jet nozzle velocity (JNV) is the velocity of the mud exiting the jet nozzles of the bit and is estimated as

Example: The jet nozzle velocity for a bit with three 13's jets installed and a circulation rate of 400 GPM is

Total hydraulic horsepower[edit]

The total hydraulic horsepower (THhp) available for drilling hydraulics is defined by the circulation rate and pressure of the mud pump. Total hydraulic horsepower is calculated as

Example: The total hydraulic horsepower available if circulating at 400 gal/min with a pump pressure of 2000 psi is

Jet nozzle pressure loss[edit]

Pump pressure is the total pressure expended throughout the circulating system's surface equipment (such as the standpipe, kelly hose, and kelly), drill string bore, jet nozzles, and annulus. Only the pressure expended through the jet nozzles accomplishes useful work for drilling. The remaining pressure losses are referred to as parasitic pressure losses. Jet nozzle pressure loss is estimated as follows:

Example: The pressure lost through three 13′s jet nozzles while circulating a 12.0-ppg mud at 400 gal/min is

Hydraulic horsepower at the bit[edit]

The hydraulic horsepower at the bit (BHhp) is calculated as for total hydraulic horsepower (THhp), but the mud pump pressure (Pp) is replaced by the jet nozzle pressure loss (JNPL):

The percentage of the total hydraulic horsepower expended at the bit is an important parameter to determine and is calculated in two ways:

or

Example: Using the data from the previous examples, we can calculate the percentage hydraulic horsepower at the bit as follows:

or

Another key hydraulic parameter that indicates the magnitude of power expended at the bit is hydraulic horsepower per square inch of bit area. It is calculated by

Example: Using the previous data with an 8.5-in. bit, we can calculate the hydraulic horsepower per square inch of bit area as

Jet impact force[edit]

One of the theories of “optimum” drilling hydraulics holds that the cleaning action of the bit on the hole bottom is maximized by maximizing the jet impact force. Jet impact force (JIF) is estimated by

Example: Using the previous data, we can calculate the jet impact force as follows:

See also[edit]

References[edit]

  1. Baker Service Tools, 1985, Technical information for the oil & gas specialist.

External links[edit]

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Wellsite math
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