Sect Sectio ion n5
Prima ri mary ry Cement mentin ing g Calcul lc ula ation ti ons s Table Table of Conte ont ents Introduction................................................................................................................................................5-3 Topic Area..............................................................................................................................................5-3 Learning Objectives .................. ................. .................. .................. .................. .................. ................... . 5-3 Unit A: Capacity Calculations ................ .................. .................. .................. .................. .................... ....... 5-3 Fill-Up Calculations .................. .................. .................. .................. .................. ................... .................. 5-4 Displacement..........................................................................................................................................5-5 Bull-Plugged Pipe ................ .................. .................. .................. .................. .................. .................. ...... 5-5 Open-Ended Pipe....................................................................................................................................5-5 Unit A Test:............................................................................................................................................5-7 Unit B: Annular Volume Calculations.......................................................................................................5-8 Unit B Test .................. .................. ................. .................. .................. .................. .................. .............. 5-11 Unit C: Slurry Weight and Volume Calculations .................. .................. .................. .................. ............ 5-12 Density .................. .................. .................. .................. .................. .................. ................. ................. ...5-12 ... 5-12 Specific Gravity....................................................................................................................................5-13 API Gravity ................. .................. .................. .................. .................. ................. .................. .............. 5-13 Absolute Density vs. Bulk Density .................. .................. ................... .................. ................... .......... 5-13 Absolute Volume..................................................................................................................................5-13 Unit C Quiz: ................ .................. .................. .................. .................. .................. ................. .............. 5-17 Unit D: Primary Cementing Calculations Example.................................................................................5-18 Given Information for Primary Cementing Calculations ................ ................. .................. ................. . 5-20 1 Calculations for Pressure Required to Lift Pipe.............. .................. ................... .................. .......... 5-20 2 Calculations for Amount of Cement ................. .................. .................. .................. .................. ....... 5-22 3 Sacks of Cement ................. .................. ................. .................. ................. .................. ................... ..5-25 .. 5-25 4 Calculations for Amount of Mixing Water ................ .................. .................. .................. ................ 5-25 5 Calculations for Amount of Fluid to Displace Top Plug ................. ................... .................. ........... 5-26 6 Calculations for Pressure to Land the Plug................ Plug ................ ................... .................. .................. ............... 5-27 7 Calculations for Resulting Force.................. .................. .................. .................. .................. ............ 5-28 Intermediate Casing Job One .................. ................. .................. ................. .................. ..................... ..5-33 .. 5-33 Unit D Quiz ................. .................. .................. .................. .................. .................. ................. .............. 5-36 Answers to Unit Quizzes ................. .................. .................. .................. .................. .................. .............. 5-37
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Use for Section Notes…
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Use for Section Notes…
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Introduction Primary cementing is the cementing operation performed immediately after the casing casing has been run downhole. The materials, tools, equipment, and techniques to be used vary depending on the hole conditions, depth of the well, and the people planning the the job. Successful primary cementing presents a constant challenge and requires up-to-date knowledge and technology.
C. Slurry Weight and Volume Calculations D. Primary Cementing Calculations Example
Learning Objectives Upon completion of this section, you should be familiar with:
Topic Ar ea The units in this section are: A. Capacity Calculations B. Annular Volume Calculations
How to calculate the amount of cement for a Primary job.
How to calculate the mixing water required for the cement.
How to calculate the pressure required to land the top plug
Unit A: Capacity Capacity Calculations Capacity is a term frequently used interchangeably with volume. As used in the oilfield, it is the volume that a certain length of pipe will hold. Knowing Knowing the shape of the pipe pipe is round, the volume can be calculated by hand.
It is recommended to caliper a number of joints of casing just inside the pin area. These are used to come up with an average ID for the casing being run. This ID should be used in the final calculations relating to casing capacity. The volume difference in can be significant.
In this unit, we will discuss fill-up and displacement calculations.
Unless a caliper value is given, this course will use the table values for ID as accurate.
Capacity calculations are one of the many types of mathematical problems that can be greatly simplified by using the Halliburton Cementing Cementing ). Section 210 lists capacity Tables ( Red Book ). factors for various sizes of drill pipe, tubing and casing. Currently, these are listed in terms of gallons per foot, barrels per foot, and cubic feet per foot. See Figure 5.1 for a sample of a capacity table for drill pipe.
To use the Capacity tables, locate the correct table for the type of pipe you’re dealing with: drill pipe, tubing, or casing. Next, locate the size and weight of pipe in the two left columns. (Note: For tubing, there are four columns.) Then find the volume units you want across the top. Read the capacity factor where the columns intersect.
The actual ID of a joint of casing is almost always larger than the value stated in the tables. This is due to the manufacturing process of seamless tubulars. The actual tolerances are identified in API specification 5CT.
Sample Problem What is the capacity, in gallons, of 1000 ft of 27/8 in., 10.4 lb/ft internal upset drill pipe? Use
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the sample of Section 210 shown in Figure 5.1 to aid your calculations.
Capacity Factor = 0.1888 gal/ft Capacity = 0.1888 gal/ft × 1000 ft = 188.8 gal
Solution Find the appropriate capacity factor (in gal/ft) in Figure 5.1. Then multiply by the length of the drill pipe.
Figure 5.1
Sample Problem
Fill-Up Calculation s
How many feet of 3-1/2 in., 15.50 lb/ft internal upset drill pipe will 25 barrels of oil fill? Use Figure 5.1 to aid in your calculations.
Fill-up of pipe is defined as the length of pipe a specified volume will fill. Fill-up factors are also listed in Section 210 of the Red Book .
Solution:
Fill-up Factor = 152.05 ft/bbl
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Sample Problem
Fill-up = 152.05 ft/bbl × 25 bbl = 3801.25 ft
What is the displacement, in barrels, for the string of bull-plugged pipe shown in Figure 5.2?
Displacement
Solution:
Displacement is defined as the volume of fluid displaced by an object when it is placed in that fluid. In the oilfield, the terms displacement and displace may be confused. The word displace often refers to pumping the fluid inside the pipe out of the pipe, as in displacing cement with fresh water. To do this, the volume of fluid pumped is usually equal to the capacity of the pipe. This is totally different from the definition of displacement as given in the first sentence of this paragraph.
3 in. = 0.25 ft Displacement = 0.7854 × 0.25 ft × 0.25 ft × 1000 ft = 49.09 ft3 Conversion factor = (located in section 240, page 85) 0.1781 bbl/ft 3 Displacement = 49.09 ft3 × 0.1781 bbl/ft 3 = 8.74 bbl
Bull -Plugg ed Pipe Open-Ended Pipe
Figure 5.2 illustrates the volume of fluid displaced when bull-plugged pipe is run in the hole. This volume is equal to the outside diameter’s flat surface area multiplied by the length of the pipe:
When the pipe is open-ended (that is, some opening permits the pipe to fill up on the inside as it is lowered into the well), it will displace less fluid than the bull-plugged string. As shown in Figure 5.3, open-ended pipe will displace a volume equal only to the volume of steel placed in fluid. This displacement can be calculated by multiplying the cross-sectional area by the length:
Displacement = OD Area × Length or Displacement = 0.7854 × OD × OD × Length
Displacement = Cross-sectional Area × Length
3 in. 1.5 in.
3 in. 1.5 in. Dry 1,000 ft
Bottom BullPlugged
Outside View
Dry
1,000 ft
Sectional View
Figure 5.2
Bottom Open Outside View
Sectional View
Figure 5.3
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Sample Problem
Displacement = 0.0368 ft2 × 1000 ft = 36.8 ft 3
What is the displacement, in barrels, for the open-ended pipe illustrated in Figure 5.3?
Conversion Factor = 0.1781 bbl/ft 3 Displacement = 36.8 ft3 × 0.1781 bbl/ft 3 = 6.55 bbl
Solution:
OD = 3 in. = 0.25 ft
NOTE: In the above examples, it has been assumed that the tubular goods were flush joint; that is, no allowance was made for internal upsets, external upsets, or couplings. Section 130 of the Red Book contains factors that allow for upsets and couplings, as shown in Figure 5.4.
ID = 1.5 in. = 0.125 ft OD Area = 0.7854 × 0.25 ft × 0.25 ft = 0.0491 ft2 ID Area = 0.7854 × 0.125 ft × 0.125 ft = 0.0123 ft2 Cross-sectional Area = 0.0491 ft2 – 0.0123 ft2 = 0.0368 ft2
Figure 5.4 – Red Book data.
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Unit A Test: For items 1 and 2, fill in the blanks. For items 3 to 5, use your Red Book as a reference and find the solutions to check your progress in Unit A.
1. The volume that a certain length of pipe will hold is known as the pipe's ______________________. 2. ____________________________is defined as the volume of fluid displaced by an object when it is placed in that fluid. 3. What is the capacity, in barrels, of 10,000 ft of 7 in., 23.0 lb/ft casing?
4. The casing ID is callipered on location with an average ID measured of 6.50”. What is the recalculated capacity, in barrels, of 10,000 ft of 7 in., 23.0 lb/ft casing?
5. How many feet of 4-1/2 in., 16.6 lb/ft internal upset drill pipe will 25 barrels of oil fill?
6. What is the displacement, in barrels, for this open-ended pipe? OD = 4.5 in. ID = 2.0 in. Length = 2000 ft
Now, check your answers against the Answer Key at the back of this section.
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Unit B: An nular Volume Calculations Annular volume is the volume contained between the outside of the pipe and the open hole (Figure 5.5) or between the outside of the drill pipe or tubing and the inside of the casing (Figure 5.6). Annular volumes can be determined by calculating the cross-sectional area between the open hole or casing ID and the drill pipe OD and multiplying this by the length.
Figure 5.6
Note: Diameters and lengths must be in the same unit of measurement.
Rather than calculating cross-sectional areas to determine annular volumes, you can refer to the Red Book , which provides factors that you can multiply by the length of the annulus to more simply arrive at volumes. There are two sections in the Red Book that you should become familiar with regarding annular volumes:
Figure 5.5
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Section 122 is a set of tables of annular volume and annular fillup factors with tubular goods in various size holes. It also lists the factors for multiple strings of tubular goods in various hole sizes.
Section 221 lists factors for pipe strings inside other pipe. There are tables for tubing, drill pipe, and casing inside of larger casing. Like Section 122, there are also tables for multiple tubing strings inside casing.
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Figure 5.7
Annular Volume = 0.0479 bbl/ft × 1000 ft = 479 bbl
Sample Problem
You can also use these tables to determine the length that a given volume of fluid will fill.
Find the annular volume, in barrels, between 6000 ft of 2-3/8 in. (2.375 in.), 4.7 lb/ft tubing and a 6-1/8 in. hole. Use Section 122-A of the Red Book (see Figure 5.7).
Sample Problem
Solution:
How many feet of annular space between 4-1/2 in., 10.5 lb/ft casing and a 6 in. hole will 100 bbl of cement fill? Use Section 122 of the Red Book .
Annular Volume Factor = 0.0310 bbl/ft (from the Red Book ) Annular Volume = 0.0310 bbl/ft × 6000 ft = 186 bbl
Solution:
Sample Problem
Annular Fill-up = 65.3597 ft/bbl × 100 bbl = 6535.97 ft
What is the annular volume, in barrels, for 1000 ft of 5-1/2 in., 17 lb/ft casing inside 9-5/8 in., 36 lb/ft casing? Use Section 221 of the Red Book .
Another way of calculating annular volume between a string of casing and the ID of the hole is by using Section 210 of the Red Book. This contains the factors for different size cylinders or holes with a length of 1 foot. Annular volume can be calculated by subtracting the annular
Annular Fill-up Factor = 65.3597 ft/bbl
Solution:
Annular Volume Factor = 0.0479 bbl/ft
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volume factors for one foot of height and then multiplying by the desired annular height.
Solution:
Sample Problem
Volume Factor for 2-3/8 in. tubing = 0.0055 bbl/ft
Find the annular volume, in barrels, between 23/8 in., 4.7 lb/ft tubing and a 6-1/8 in. hole. Use Section 210 of the Red Book .
Annular Volume Factor = 0.0364 bbl/ft – 0.0055 bbl/ft = 0.0309 bbl/ft
Volume Factor for 6-1/8 in. hole = 0.0364 bbl/ft
Annular Volume = 6000 ft × 0.0309 bbl/ft = 185.4 bbl The differences between this way of determining annular volume and using Section 122 can be explained by the methods used when rounding off of decimals in establishing the tables.
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Unit B Test Calculate the answers for the following:
1. What is the annular volume, in gallons, between 5000 ft of 9-5/8 in., 53.50 lb/ft casing and 12-1/4 in. hole? Use the Red Book to find the appropriate factor.
2. What is the annular volume in cubic feet, for 7675 ft of 2-7/8 in., 6.5 lb/ft tubing inside 7 in., 26 lb/ft casing? Use the Red Book to find the appropriate factor.
Now, look up the suggested answers in the Answer Key at the back of this section.
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Unit C: Slurr y Weight and Volume Calculations The density of a base fluid is affected by the addition of additives. This density should be collected for additive concentration when determining hydrostatic pressure.
Density in 3 lb/ft Solids
Gold Mercury Lead Iron Aluminum Wood Ice
To help you with density calculations, this unit will introduce you to several terms. After completing this unit, you will be familiar with:
the relationships among density, weight, and volume
API gravity
specific gravity
absolute density vs. bulk density
absolute volume
slurry weight and volume calculations
Density in g/cc
1206.2 846.0 712.5 485.0 165.6 50.0 56.9
19.3 13.5 11.4 7.7 2.6 0.8 0.9
125.0 64.3 62.5 50.0 46.8
2.00 1.03 1.00 0.80 0.75
Liquids
Sulfuric Acid Sea Water Fresh Water Kerosene Gasoline Gases
Density
Air 0.075 Oxygen Nitrogen Carbon Monoxide Hydrogen
Density can be defined as the weight of a substance per unit volume. In the English system, one cubic foot is a unit of volume, and one pound is a unit of weight. In the metric system, a unit of volume is cubic centimeter (cc) and weight can be measured in grams (g). If you measured the weight of a specific volume of iron, wood, lead, and water, you would find they have widely different weights. Therefore, a term is needed to refer to the weight of a unit-volume of substance -- that term is density. For example, a cubic foot of water weighs 62.4 lb, so the density of water is 62.4 lb/ft 3.
0.0075 0.084 0.0737 0.0734 0.0053
0.0012 0.00134 0.00118 0.00117 0.000085
For practical purposes, the densities of gases are compared with air at atmospheric pressure instead of with water. Using air as a comparative reference, the vapor densities of the gases listed above are: Air Oxygen Nitrogen Carbon Monoxide Hydrogen
If you know the density and the volume of a material, you can calculate its weight: Weight = Density × Volume
1.00 1.120 0.983 0.979 2.004
Some densities of common materials are listed here for your reference.
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API readings are standardized at a temperature of 60°F. If taken at any other temperature, readings must be converted to 60°F to be accurate. Tables for this conversion and for conversion of API gravity to specific gravity can be found in the API Standard 2500 bulletin and in various engineering handbooks.
Specific Gravity Specific gravity (abbreviated Sp Gr) is the weight of a volume of material divided by the weight of the same volume of material taken as a standard. For solids and liquids, the standard is water; for gases, the standard is air. Another definition of specific gravity is the ratio of the density of a substance to the density of water or air. The density of water is 8.33 lb/gal. It is a simple matter to convert density to specific gravity (or vice versa).
Formulas for conversion are: Degrees API Gravity =
Specific Gravity =
Sample Problem
Solution
Sp Gr =
Sp Gr
- 131.5
141.5 API 131.5
Abso lute Den si ty vs. B ulk Density
What is the specific gravity of a 10 lb/gal brine?
Sp Gr =
141.5
Absolute density is the mass per unit volume. Absolute density considers only the actual volume occupied by a material. Bulk density is mass per unit bulk volume -- which includes the actual volume of the material plus the volume of trapped “air.”
density of substance density of standard
10 lb/gal 8.33 lb/gal
Sp Gr = 1.2
Abso lute Vo lume
If you were given the specific gravity of a liquid as 1.2, the density can be calculated:
Absolute volume is the volume per unit mass. Here is an example of absolute volume. Let's assume we have a container (Figure 5.8) that measures one cubic foot (1 ft high, 1 ft deep, 1 ft wide). This container is filled with golf balls. There are void spaces between the golf balls filled with trapped air. We want to know the volume in gallons that is occupied by the golf balls only.
1.2 × 8.33 lb/gal = 10 lb/gal
API Gravi ty Baume’s gravity is a scale that uses salt water as a reference rather than fresh water. It is used in refineries to determine the gravity of acids and alkalis only. API gravity is used in most other instances in the oil field. Water is used as the standard. Water's API gravity is 10 degrees.
As the specific gravity increases, the API gravity decreases. Crude oil with a 42° API gravity has an actual specific gravity of 0.82. American crude is commonly run from 0.768 to 0.966 specific gravity, which would range from 52.6 to 10.5° on the API gravity scale.
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The volume occupied by the golf balls can best be determined by first calculating the volume occupied by the void spaces. For this, we could add water to the container and measure it. After obtaining the number of gallons of water needed to fill the void spaces, we can subtract from 7.4805 gal/ft3 to determine the volume occupied by the golf balls alone.
One cubic foot 7.4805 gal. 1 ft
1 ft 1 ft
The volume of golf balls determined in this way is called the absolute volume. While this example is exaggerated, it does help explain the concept. We work with sand, cement, etc. rather than golf balls, but the balls can be seen as a magnification of sand or cement particles. Void spaces exist in sand; the volume we add to fracturing fluids is actually the absolute volume of the sand.
This container below is filled with golf balls.
1 ft
1 ft 1 ft
Figure 5.8 – The volume of golf balls is less than the total volume because of the spaces between them.
Calculating absolute volume for sand or cement can be simplified by using the tables for "Physical Properties of Cementing Materials and Admixtures" provided in the Technical Data section of the Halliburton Cementing Tables (Figure 5.9).
Figure 5.9 – Red Book data.
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Total lb Total abs gal = lb/gal
The left-hand column lists the material, the second column gives the bulk weight in lb per ft3. The third column gives the specific gravity, and the fourth column provides absolute volume in gal/lb.
12.33 lb 1.1824 gal = 10.427943 lb/gal
Sample Problem What is the absolute volume (gallons) and weight (lb per gallon) of this slurry?
Note: When using fluids in absolute volume calculations, you will not find a gal/lb factor in the Red Book . However, you can calculate this factor if you know the fluid density in lb/gal. Simply divide 1 by the fluid density. For example, water is 8.33 lb/gal, so:
Base Fluid is water @ 8.33 lb/gal
Additive is 3% KC1
4 lb of sand is added
Solution
gal/lb = 1 8.33 lb/gal = 0.12 gal/lb
ABSOLUTE
Sample Problem
MATERIAL
FACTOR
VOLUME
MATERIALS
(lb)
(gal/lb)
(gallons)
What is the absolute volume (gallons) and weight (lb per gallon) of this slurry?
Water
8.33
×
0.1200
=
1.0
0.2499
×
0.0443
=
0.0110705
Base Fluid is water @ 8.33 lb/gal
Sand
4.0
×
0.0456
=
0.1824
4 lb of sand is added.
TOTALS
3% KC1
1.1934705 gal
Total lb Total abs gal = lb/gal
Solution
12.5799 lb 1.1934705 gal = 10.5 lb/gal
We will use the chart below to help in our calculation of absolute volume. First, list the materials and their weights in the first two columns. Then, using the Red Book table, list the absolute volume factors (gal/lb) in the third column.
Note: Generally, when working with sand and water (or base fluid) slurries, the calculations are based on 1 gallon of base fluid and the weight of that 1 gallon of fluid.
Sample Problem
ABSOLUTE MATERIAL
FACTOR
VOLUME
MATERIALS
(lb)
(gal/lb)
(gallons)
Water
8.33
0.1200
Sand
4
0.0456
What is the absolute volume (gallons) and weight (lb per gallon) of this slurry?
TOTALS
Multiply the materials (lb) by the factor (gal/lb) to obtain the absolute volume and add these values to the table. For the totals, add the materials (lb) together and add the absolute volumes together: MATERIAL
FACTOR
VOLUME
MATERIALS
(lb)
(gal/lb)
(gallons)
Water
8.33
×
0.1200
=
1.0
Sand
4.0
×
0.0456
=
0.1824
12.33 lb
Class H Cement
Water @ 8.33 lb/gal
Solution
For this cementing problem, we will add a column to the chart for mixing water requirements. Proceed as in the last two sample problems until you need to fill in the mixing water requirements for the Class H cement. This quantity you can find in the Technical Data section of the Red Book in the table for “Water Requirements.” For Class H cement, the requirements are 4.3 gal/sk. Enter this under the appropriate column:
ABSOLUTE
TOTALS
12.579 lb
1.1824 gal
Find the weight of the mixed slurry using this formula:
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ABSOLUTE
MIXING
MATERIAL FACTOR VOLUME MATERIALS
(lb)
Cement
94
Water
(gal/lb)
×
0.0382
=
ABSOLUTE
WATER
(gallons)
(gallons)
3.6
4.3
MATERIAL FACTOR VOLUME MATERIALS
Cement
8.33
Water
TOTALS
TOTALS
Enter 5.2 gal for the absolute volume for water. Divide the water factor by the absolute volume to determine the materials (lb) for water. Then calculate the totals:
MIXING
(lb)
(gal/lb)
(gallons)
(gallons)
4.3
94
×
0.0382
=
3.6
35.82
=
8.33
4.3
129.82 lb
WATER
7.9 gal
Total lb Total abs gal = lb/gal 129.82 lb 7.9 gal = 16.4 lb/gal Find the yield of cement (ft 3 per sack) by using this formula: Total abs gal 7.4805 gal/ft 3 = ft3/sk 7.9 gal/sk* 7.4805 gal/ft 3 = 1.06 ft 3/sk * NOTE: When working with cement slurries, the calculations are usually based on one sack of cement and the weight of that sack.
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Unit C Quiz: For items 1 3, fill in the blanks. For items 4 and 5, calculate the answer.
1. In dealing with specific gravity, the weight of a volume of a material is ________________________ by the weight of the same volume of a material taken as a_______. 2. Absolute density considers only the___________ ____________ occupied by the material. 3. Volume per unit mass defines ______________ _______________. 4. Calculate the weight (lb/gal) of the following slurry:
base fluid is 10 lb/gal brine
sand at 10 lb/gal (0.0456 gal/lb)
5. Using Class H cement (94 lb/sk) and 4.3 gallons mixing water, what is the cement slurry density (lb/ gal) and yield (ft 3/sk)?
Now, look up the suggested answers in the Answer Key at the back of this section.
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Unit D: Primary Cementing Calculations Example Before a primary cementing job can begin, several calculations must be done. In this unit, you will learn these calculations:
Primary Cementing Calculations 7 critical calculations that need to be made with every surface casing job
Also included is a new slurry weight and yield worksheet.
1
7
1
Critical Circulating Pressure – Pressure required to lift (pump) the casing out of the h ole
2
Cement volume – The volume of cement required to fill the required footage of the annulus plus the shoe track capacity.
3
Sacks of Cement – Converting the required volume of cement into sacks.
4
Mixing water required for given slurries.
5
Displacement fluid required to the top plug from surface to the top of the shoe track.
6
Pressure to land the plug – Differential pressure required to pump the plug to the top of the shoe track.
7
Resulting Force – The calculated hook load at the t op of the casing once the plug has landed.
F
Well Parameters
A
A B C D E F G
B 5
C
2
3
Pipe Size Well Fluid Hole Size Pipe Depth Shoe Track Length Required Cement fill-up Excess volume required (percent)
Calculation Guidelines
4 6
Do not apply any decimal places for pressure or sacks
Apply one decimal place for lb/gal Apply 2 decimal places for psi/bbl cubic feet pounds feet area gallons barrels
For psi/ft use same number of decimal places as in Red Book “Hydrostatic Pressure And Fluid Weight Conversion Tables”
Show one decimal place for bbl/min
Rounding numbers – if the last number is to be dropped, round up if 5, down if < 5.
E
D
Figure 5.10 – Primary Cementing Setup
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Worksheet for Slurry Weight and Volume Calcul ations MATERIAL NAME
Material (lb)
.
Water
Ab so lu te Volume (gal)
Factor (gal/lb)
Mix in g Water Requirements (gal)
X
=
X
=
+
X
=
+
X
=
+
X
=
+
X
=
+
=
lb/gal
gal
TOTALS ==>
gal
Total mixing water must be entered under absolute gallons b efore totaling. Find the weight of the mixed cement by using this fo rmula: Total Pounds/Total Absolute gallons = lb/gal Find the cement yield in c ubic feet per sack by using this fo rmula: 3 3 Total Absolute gallons / 7.4805 gal/ft (constant) = ft /sack The mixing w ater per sack is the sum of t he gallons in the far right co lumn
lb/gal
Cement Density (lb/gal) ==> 3
3
Cement Yield (ft /sk) ===> Mixing Water required ===>
ft /sk gal/sk
Figure 5.11 – Absolute Volume Worksheet
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Primary Cementing Calculations 7 critical calculations that need to be made with every surface casing job
1
Critical Circulating Pressure – Pressure required to lift (pump) the casing out of the h ole
2
Cement volume – The volume of cement required to fill the required footage of the annulus plus the shoe track capacity.
3
Sacks of Cement – Converting the required volume of cement into sacks.
4
Mixing water required for given slurries.
5
Displacement fluid required to the top plug from surface to the top of the shoe track.
6
Pressure to land the plug – Differential pressure required to pump the plug to the top of the shoe track.
7
Resulting Force – The calculated hook load at the t op of the casing once the plug has landed.
In the Essential Red Book course, you were introduced to the basic calculations and concepts needed in preparing for a primary cementing job. In this unit you will be shown the steps for calculating a surface casing cement job. Later, you’ll be asked to actually make the calculations for a similar job on your own.
Given Information for Primary Cementing Calculation s Refer to the well parameter information as you work through the calculations for the surface casing cementing job.
Figure 5.12 – Surface Casing Cementing Job
1 Calcul ations for Pressure Requi red to Lif t Pipe
Surface Casing Job One When pipe is run into a hole, the result in a ram effect. This ram effect increases as the running speed and the diameter of the pipe increases. In some cases, the ram effect will break down low pressure zones. Sand may slough off and bridge the annulus. If the casing is stuck in the hole, you cannot pull it out without parting it.
This casing job consists of a single slurry, which is to be circulated from total depth to surface.
Well Parameters Pipe Size
9 5/8 in 36 lb/ft
Well Fluid
8.7 lb/gal
Hole Size
12.25 in
Pipe Depth
300 ft
Shoe Track Length
40 ft
Required Cement Fill-Up
To surface
Excess Volume Required (percent)
100%
These calculations are performed as a precaution. They are done before mixing any cement. Just in case the annulus has bridged, you need to know how much pressure would be required to lift the pipe. This pressure could
5 • 20
Cementing 1
Primary Cementing Calculations
possibly lift the pipe out of the hole, so you need to chain the pipe down during the operations.
d) The buoyancy factor (Step 2a) multiplied by the weight per foot of casing (Step 2b) times the length of the casing (Step 2c) equals the weight of the pipe hanging in fluid:
1. First, the area of the casing must be found. a) In the “Calculations and Formulae” section of the Red Book (see also Figure 5.13), look up the formula for the area of a circle.
0.8671 BF × 36 lb/ft × 300 ft = 9364.68 lb (The arrow indicates the direction of this force.)
Area = 0.7854 × D 2
3. Now you have enough information to calculate the amount of pressure to apply to the casing at the surface, pumping downward through the casing below the casing shoe, to start the lift (or to balance the pipe). The larger the diameter of the pipe the less pressure is required to lift the string. This is why you need to chain down large diameter casing during the pumping operation (chain it to the substructure or a leg of the derrick, but not to the rotary table).
Figure 5.13
The downward force of the pipe (step 2d) divided by the area of the pipe (step 1b) is the pressure needed to start the lift:
b) Plug the diameter (9 5/8 in.) into the formula for area of a circle (area of the casing):
9364.68 lb 72.76 in. = 129 psi
9.625 in. × 9.625 in. × 0.7854 = 72.76 in. 2
When applying pressure to start circulation, caution should be taken to prevent the pipe from blowing out of the hole and causing damage. The casing should be chained down and all personnel except the operator, should be cleared off the rig floor.
2. The next step is to calculate the weight of the pipe when it is hanging in fluid (the downward force of the pipe in the wellbore.) a) First, look up the buoyancy factor for the wellbore fluid you are working with. Keep in mind that this buoyancy factor relates to the fact that open-ended pipe weighs less in a fluid than it does in air. The weight of this fluid is 8.7 lb/gal. Referring to the “Displacement” section of the Red Book (see also Figure 5.14), you will see that the buoyancy factor is 0.8671 for a fluid of that weight. b) You also need to know how much your casing weights in air. From the casing stamp, you can find that this casing weigh 36 lb/ft. c) Since it is not known at what depth the annulus might become bridged, use the overall length of your casing (300 ft) for these calculations.
5 • 21
Cementing 1
Primary Cementing Calculations
You will find Class G slurry properties on page 3 of the Class G Section in the Technical Data Section of the Red Book . We will work through the absolute volume calculations as an example. Refer to the gray pages in the “Technical Data: section of your Red Book (see also Figure 5.9). You will see that the table labeled “Physical Properties of Cementing Materials and Admixtures” contains much of the information needed to calculate the slurry’s absolute volume (as well as its weight that will be calculated later). To aid in these calculations, the Worksheet for Slurry Weight and Volume Calculations has been developed (Figure 5.11). This worksheet will be completed as the following calculations are worked out. 1. First, find the bulk weight of API cements listed in Figure 5.9 – 94 lb/ft 3. The factor for absolute volume of API cements is 0.0382 gal/lb. 2. Then calculate the correct figures for each of the additives and the water being used. a) Calculate how much the calcium chloride will weigh by multiplying the weight of cement by 2%: 0.02 × 94 lb = 1.88 lb b) Look up the factor for absolute volume of Calcium Chloride, which is 0.0612 lb/gal.
Figure 5.14
c) Look up the absolute volume factor for Flocele, which is 0.0845 gal/lb. 3. To find the absolute volumes of the ce ment, Calcium Chloride and Flocele, multiply the numbers in the materials column by the numbers in the factor column:
2 Calculations for Amount of Cement
94 lb × 0.0382 gal/lb = 3.6 gal 1.88 lb × 0.0612 gal/lb = 0.12 gal. 0.25 lb × 0.0845 gal/lb = 0.02 gal
To find the amount (sacks) of cement needed for this surface casing cementing job, you need to know the type of cement, its weight and its yield. Class G cement with 2% calcium chloride and ¼ lb/sk Flocele has been chosen for this surface casing job. Using this information, you can perform the calculations necessary to eventually find out how much cement you will need.
5 • 22
Cementing 1
Primary Cementing Calculations
Worksheet f or Slurry Volumes Worksheet for Slurry Weight and Volume Calculatio ns Casing Job One API Cement Weig ht = 94 l b/sac k 1 sack = 1 cubic foot Material Name
Material (lb)
Class G Cement
Figure 5.15 – Class G data from Red Book
4. To find the mixing water requirements for a sack of cement with its additives, refer to the gray pages in the “Technical Data” section of your handbook (see also Figure 5.15). These requirements are 5.0 gal., 0 gal and 0 gal for the cement, Calcium Chloride and Flocele respectively. Add these figures together for the water’s absolute volume:
Factor (gal/lb)
Absolute Mixing Volume Water (gal) Required (gal)
94 ×
0.0382 =
3.5908
2% Calcium Chloride
1.88 ×
0 .0612 =
0.11506
.25lb Flocele
0.25 ×
0.845 =
0.02113
×
=
41.65 ×
8.33 =
Water Totals
5.00
5.00
137.78
8.7270
5.00
Total mixing water must be entered under absolute gallons before totaling. Find the weight of the mixed cement by using this formula: Total Pounds ÷ Total Absolute gallons = lb/gal Find the cement yield in cubic feet per sack by using this formula: 3
3
Total Absolute gal ÷ 7.4805 gal/ft (constant) = ft /sk
5 gal + 0 + 0 gal = 5 gal
The mixing water per sack is the sum of the gallons in the far right column
5. To obtain the weight of the water required, multiply the weight per gallon of water by the volume of water (step 4): 8.33 gal/lb × 5 gal = 41.65 lb
Cement Densit y
137.78 ÷
8. 7270 =
15.8
lb/gal
Cement Yield
8.7270 ÷
7.4805 =
1.17
ft /sk
5.00
gal/sk
Mixing Water Required
3
6. Total the materials and absolute volume columns:
5 • 23
Cementing 1
Primary Cementing Calculations
8. Then find the yield by dividing the total absolute volume in gallons (Step 6) by the constant which can be found in the table “Conversion Constants” (Figure 5.16) – 7.4805 gal/ft 3 8.7270 gal 7.4805 gal/ft 3 = 1.17 ft3/sk Now assume that you have circulated through the surface casing down to a depth of 300 ft and that you have a well-conditioned hole. It is necessary to calculate the volume of slurry needed for the job. This is a combination of the slurry needed to fill annular space and to fill the shoe joint. 9. To determine how much slurry is needed to fill the annulus, the ft 3/ft for the annulus is multiplied by the length of the annulus. a) First, refer to the “Volume and Height Between Tubing, Casing, Drill Pipe, and Hole” section in the handbook. (To use this table, you need to find the table with the correct number of strings. For example, see the four different tables for tubing with an OD of 3 ½ in). Look on the table for 9 5/8 in (see also Figure 5.17). The ft 3/ft for this annulus is 0.3132. b) You know that the length of the annulus is 300 ft. Multiplying this by the ft 3/ft value found in Step 9a results in the volume needed to fill the annular space. 300 ft × 0.3132 ft 3/ft = 93.96 ft 3. c) Excess cement – knowing we need 100% excess (double the calculation volume) we calculate the following:
Figure 5.16
93.96 ft3 × 2 = 187.92 ft 3
7. To find the weight of the cement slurry in pounds per gallon, divide the total pounds by the total absolute volume in gallons: 137.78 8.7270 gal = 15.8 lb/gal
5 • 24
Cementing 1
Primary Cementing Calculations
Figure 5.17
10. Now, the amount of slurry in the shoe joint (or track) needs to be calculated in the last step, to determine how much slurry is in the shoe joint, the capacity factor of the joint is multiplied by its length.
3 Sacks of Cement 1. Now that you know the cubic feet needed (Step 11), you use the yield (Step 8) to calculate the number of sacks needed:
a) To find this capacity factor, turn to the “Capacity” section of the Cementing Table (See also Figure 5.18) You need to know the OD (9 5/8 in.) and the weight (36 lb/ft) of your casing. The capacity factor is 0.4340 ft 3/ft.
205.28 ft3 1.17 ft3/sk = 175 sk
4 Calculations for Amount of Mixing Water
b) The length of the shoe track was given as 40 ft.
After you know the number of sacks of cement needed, you need to calculate the volume of water required on location to mix the slurry. This water should always be fresh water (unless slurry is designed for salt or seawater).
c) Multiply the capacity factor for the shoe joint (10a) by the length of the shoe joint (10b) for the capacity for the shoe joint: 0.4340 ft3/ft × 40 ft = 17.36 ft 3
Your worksheet shows that you will need 5 gal of water per sack of cement. This is multiplied by the number of sacks in order to obtain the total number of gallons of mixing water needed. This unit of measurement needs to be converted to barrels since tanks on trucks are marked off in barrels.
11. Add the volume of slurry to fill the annulus (step 9c) to the volume of slurry to fill the shoe joint (step10c) to determine the total numbers of barrels of cement that you need: 187.92 ft3 + 17.36 ft 3 = 205.28 ft 3
5 • 25
Cementing 1
Primary Cementing Calculations
Figure 5.18 First, find out how much mixing water you need in gallons:
When all of the cement has been mixed, the top plug will be pumped down to a depth of 260 ft. The number of barrels needed to do this is the same as the capacity of the casing to the float collar.
5 gal/sk × 175 sk = 875 gal 1. Since there are 42 gal in a barrel, convert to barrels:
0.0773 bbl/ft × 260 ft = 20.1 bbl
875 gal 42 gal/bbl = 20.83 bbl
In this example we have used the Redbook value which is based on the stated ID of this particular casing OD and weight. The actual ID of a joint of casing is almost always larger than the value stated in the tables. This is due to the manufacturing process of seamless tubulars. The actual tolerances are identified in API specification 5CT.
Therefore, it will take this amount of water to mix your cement. You will need more water on location, considering the water used for cleanup, spacer, etc.
5 Calculations for Amount of Fluid to Displace Top Plug
It is recommended to caliper a number of joints of casing just inside the pin area. These are used to come up with an average ID for the casing being run.
The first step in the cementing process is to run a bottom plug to wipe the casing clean of mud buildup. The cement following the bottom plug will rupture the plug’s diaphragm. Then it will move through the center of the plug, out the bottom of the shoe, and up the annulus. If a bottom plug is not run, the top plug will wipe down the walls and mud will collect in the shoe joint between the top plug and the cement slurry.
The caliper ID should be used in the final calculations relating to casing capacity such as shoe track volume and fluid to displace the top plug. The volume difference in displacing the top plug can be significant.
5 • 26
Cementing 1
Primary Cementing Calculations
6 Calcul ations for Pressur e to Land the Plug Calculations for pressure to land the plug should be made on each job. You need to know the pressure required to put the cement in place. Any pressure buildup in excess of this pressure might indicate channeling or bridging in the annulus. A loss of pressure could mean a loss of cement into the formation. Figure 5.12 shows a balanced section of hole. The shoe is at 300 feet and the plug landing point is 260 feet. The shoe joint and the annular space opposite it are full of the same weight cement. Therefore that part of the well is balanced and no calculations are required. You do need to make a few calculations concerning the unbalanced portion of the hole indicated in Figure 5.12. The annular space from 260 ft back to surface is filled with 15.8 lb/gal cement (this density was determined during the amount of cement calculations, Step 7 in Calculations for Amount of Cement). Also, you have displaced the plug with 8.7 lb/gal fluid in the casing. Because the fluids have different densities, a differential pressure results. You must convert the lb/gal of the cement and displacement fluid to psi/ft in order to make the calculation (Figure 5.19).
Figure 5.19
1. Refer to the Hydrostatic Pressure and Fluid Weight Conversion tables in the “Calculations and Formulae” section of your Red Book (see also Figure 5.19). To find the psi/ft for the weight of the cement (15.8 lb/gal), To minimize errors, here is the most accurate way to make this calculation: Working form the bottom of the casing up to the surface, calculate the hydrostatic pressure outside, then calculate the hydrostatic pressure inside. Remember, work from the bottom up, for the entire casing string.
5 • 27
Cementing 1
Primary Cementing Calculations
calculations – Step 1) for a fluid weighing 15.8 lbs/gal.
Hydrostatic Outside Cement 300 ft × 0.8208 psi/ft
=
Total: 300 ft
The hydrostatic pressure in a casing job is the pressure in the annular space. The plug will close off the pressure in the casing when it lands on a float collar. If you do not land the plug or run a float collar or back pressure valve, but only stop the plug in the casing, then you will close in the cementing head and the pressure to land the plug will remain on the casing until the cement has set.
246 psi 246 psi
Hydrostatic Inside Cement 40 ft × 0.8208 psi/ft Well Fluid 260 ft × 0.4519 psi/ft Total 300 ft
=
33 psi
=
117 psi 150 psi
To calculate the hydrostatic pressure at a given depth, multiply that depth by the psi/ft of the fluid in the annulus – in this case, cement slurry:
Differential Pressure (At top of shoe) = 246 psi – 150 psi = 96 psi
Always re-total the depth. If you don’t end up with the same depth then something is wrong.
300 ft × 0.8203 psi/ft = 246 psi
NOTE: You must slow the pump rate down to a half-barrel per minute to read this on a chart or gauge because high rates create friction pressure (which can give you a false pressure reading).
7 Calcul ations for Result ing Force Precautions must be taken before pumping the plug down when you are working on the surface casing. You need to find out if the casing will remain still, or if the plug landing pressure will pump the casing out of the hole – if so, you will need to chain the pipe down (in addition to chaining the head to the elevators).
When the plug has been pumped to its landing position and 96 psi is readable on the gauge, this job has been done successfully. Remember that you will not be able to correctly read the pressure to land a plug on all jobs. Losing cement into the formation or developing channels in the cement will alter the pressure reading. Release the pressure when the plug lands; this will prevent a microannulus. Keep in mind that most companies will require more pressure than what is required to land the plug in order to test the plug’s seal. Depending on the situation, some customers will pressure test casing after the plug lands.
As you did in Calculation 1, you will calculate the difference between the upward force on the pipe and the downward force on the pipe. 1. You have calculated the area of the surface casing (Step 1b - Pressure to Lift the Pipe Calculations) to be 72.76 in. 2. In addition, you know the pressure to land the plug is 96 psi (Step 6 – Pressure to Land the Plug Calculations). Multiplying the two values will give you the amount of upward f orce in pounds.
Calculatio ns for Hydros tatic Pressure at a Given Depth You need to be able to calculate the hydrostatic pressure at any depth. For the purpose of this problem, you will determine the hydrostatic psi at 260 ft. Will this formation support the amount of pressure exerted by the column of cement down the annulus to the given point?
72.76 in2 × 96 psi = 6984.96 lb 2. In a previous problem, you looked up the buoyancy factor for the 8.7 lb/gal displacement fluid (Step 2a – Pressure to Lift the Pipe Calculations). Referring to the “Displacement” section again, look up the buoyancy factor for the cement used (see also Figure 5.14) The weight of cement is 15.8 lb/gal as determined in Step 7 of the amount of cement calculations. To find the
In this example problem, you will have only one hydrostatic pressure to work with since you have cement from the top to the bottom of the well. That pressure is 0.8208 psi/ft, which you determined earlier (Pressure to Land the Plug
5 • 28
Cementing 1
Primary Cementing Calculations
buoyancy factor for this weight, you must look up 15.8.
3. In the same way, calculate the downward force contributed by the cement:
Now the length and weight of the piece of pipe in question are needed. Cement is inside the pipe in the shoe joint (40 ft) and displacement fluid is inside the pipe above the float collar (260 ft). The weight of the pipe is 36 lb/gal.
40 ft × 0.7586 BF × 36 lb/ft = 1092.38 lb 4. Adding these two downward forces together (Step 2 and 3) will give you the total downward force: 8116.06 lb + 1092.38 lb = 9208.44 lb
Using the formula for downward force, determine the downward force contributed by the displacement fluid:
5. Subtract the upward force (Step 1) from the downward force (Step 4) to obtain the resulting force:
Length of pipe × buoyancy factor for the displacement fluid inside the pipe × pipe weight per foot = pounds of downward force
9208.44 lb - 6984.96 lb = 2223.96 lb Although this is considered a downward force, it will be necessary to chain down the casing as a precautionary measure.
260 ft × 0.8671 BF × 36 lb/ft = 8116.06 lb
5 • 29
Cementing 1
Primary Cementing Calculations
Surface Casing Jo b Two This casing job consists of LEAD and TAIL slurries in which cement is to be circulated from tot al depth to surface.
Well Parameters
13 3/8-in. Casi ng
17 1/2-in. Hol e
Pipe Size
13 3/8 in., 68 lb/ft
Well Fluid
8.5 lb/gal
Hole Size
17.5 in.
Pipe Depth
2400 ft
Shoe Track Length
80 ft
Required Cement Fill-Up (TAIL)
400 ft
Required Cement Fill-Up (LEAD)
2000 ft
Excess Volume Required (percent)
120%
1
Critic al Circul ating Pressure
Area Of Pip e 2 13.375 in × 13.375 in × 0. 7854 = 140.50 in. (Section 240 Page 85)
2,000 ft
Hook Load 2,400 ft × 68 lb/ft × 0.8701 = 142,000.32/lbs (Section 130 Table 132 Buoyancy Factor) Pressure to lift (pump) pipe out of the hole 2 142,000.32 lb 140.50 in. = 1010 psi
2,320 ft
2 Lead Tail Displacement
2,400 ft
Figure 5.20
Cement Volume
Lead Slurry Composition Halliburton Light Cement 2% Calcium Chloride 1/4 lb/sk Flocele
Given Sl. Wt 13.6 lb/gal 3 Sl. Vol. 1.55 ft /sk Water 7.62 gal/sk
Tail Slurry Composition Class H Premium 1% Calcium 1/4 lb/sk Flocele
Given Sl Wt 16.4 lb/gal 3 Sl. Vol 1.07 ft /sk Water 4.3 gal/sk
Tail 3 400 ft (openhole) × 0.6946 ft /ft
3
=
277.84 ft
277.84 ft × 2.2 (excess) 3 80 ft (shoes) × 0.8406 ft /ft
= =
611.25 ft 3 67.25 ft 3 678.50 ft (tail)
Lead 3 2000 ft (openhole) × 0.6946 ft /ft
=
1389.20 ft
=
3056.24 ft (lead)
3
3
1389.20 ft × 2.2 (excess)
3
3
3
NOTE: We are required to pump 120% excess cement on this job; 120% excess is equal to multiplying the perfect hole volume by 2.2.
5 • 30
Cementing 1
Primary Cementing Calculations
Surface Casin g Two L ead Cement
Surface Casing Two Tail Cement
Worksheet for Slurry Weight and Volume Calculations
Worksheet for Slurry Weight and Volume Calculations
Material Name
Material (lb)
65% Class H Cement
61.1 ×
Absolute Mixing Volume Water (gal) Required (gal) 0.0382 = 2.33402 2.75
35% Poz
25.9 × 5.22 ×
0.0488 = 0.0453 =
1.26392
1.27
0.23647
2% Calcium Chloride
1.74 ×
0.0612 =
0.10649
.25lb Flocele
0.25
6% Bentonite
Water
Factor (gal/lb)
63.47 = Totals
0.0845
0.02113
8.33 ×
157.68
Material Name
Material (lb)
Class H Cement
Factor (gal/lb)
94 ×
Absolute Mixing Volume Water (gal) Required (gal) 0.0382 = 3.5908 4.30
0.94 ×
0.0612 =
0.05753
3.60
1% Calcium Chloride
0.00
.25lb Flocele
0.25 ×
0.0845 =
0.02113
×
=
35.819 =
8.33 ×
0.00
7.62
Water
11.5820
7.62
4.30
Totals 131.009
7.9695
4.30
Total mixing water must be entered under absolute gallons before totaling.
Total mixing water must be entered under absolute gallons before totaling.
Find the weight of the mixed cement by using this formula:
Find the weight of the mixed cement by using this formula:
Total Pounds ÷ Total Absolute gallons = lb/gal
Total Pounds ÷ Total Absolute gallons = lb/gal
Find the cement yield in cubic f eet per sack by usin g this formula:
Find the cement yield in cubic f eet per sack by usin g this formula:
3
3
3
3
Total Absolute gal ÷ 7.4805 gal/ft (constant) = ft /sk
Total Absolute gal ÷ 7.4805 gal/ft (constant) = ft /sk
The mixing water per sack is the sum of the gallons in the far right column
The mixing water per sack is the sum of the gallons in the far right column
Cement Density Cement Yield Mixing Water Required
157.68 ÷ 11.5820 ÷
11.5820 = 7.4805 =
13.6
lb/gal 3
Cement Density
1.55
ft /sk
Cement Yield
7.62
gal/sk
Mixing Water Required
5 • 31
131.009 ÷
7.9695 =
16.4
lb/gal
7.9695 ÷
7.4805 =
1.07
ft /sk
4.3
gal/sk
3
Cementing 1
Primary Cementing Calculations
3
7
Sacks of Cement
Resulting Force
Force Down
Tail 3 3 678.50 ft 1.07 ft /sk
=
634 sk
Lead 3 3 3056.24 ft 1.55 ft /sk
=
1972 sk
2320 ft × 68 lb/ft × 0.8701 BF 80 ft × 68 lb/ft × 0.7494 BF 2400 ft Total Down
2
Mixing Water Requir ed
Tail 634 sk × 4.3 gal/sk
Lead 1972 sk × 7.62 gal/sk
= =
2726.2 gal 64.91 bbl
= =
15026.64 gal 42 gal/bbl 357.78 bbl
42
137266.98 lb 4,076.74 lb 141343.72 lb
Force Up 140.50 in × 661 psi
4
= =
Hook Load
gal/bbl
=
92870.50 lb 141343.72 lb 92870.50 lb 48473.22 lb Downward Force When Plug Lands
Total 422.69 bbl
5
Displacement Fluid Volume
2400 ft (Total Pipe) - 80 ft (Shoe Track) = 2320 ft (Top of Shoe) 2320 ft × 0.1497 bbl/ft = 347.30 bbl
6
Pressure To Land The Plug ** Working From The Bottom Up**
Hydrostatic Outside Tail 400 ft × 0.8519 psi/ft Lead 2000 ft × 0.7065 psi/ft
=
341 psi
=
1413 psi
Total: 2400 ft
1754 psi
Hydrostatic Inside Tail 80 ft × 0.8519 psi/ft Well Fluid 2320 ft × 0.4416 psi/ft Total 2400 ft
=
68 psi
=
1025 psi 1093 psi
Differential Pressure (At top of shoe) 1754 psi – 1093 psi = 661 psi
Hint: Always re-total the lengths to make sure both outside and inside pipe segments are calculated. If the lengths are not the same then the calculations will be incorrect.
5 • 32
Cementing 1
Primary Cementing Calculations
Intermediate Casing Job One This casing job consists of a single tail slurry with 500 ft fill.
Well Parameters
Well f luid Spacer Cement
Pipe Size
7 in. 32 lb/ft
Well Fluid
10.4 lb WBM
Hole Size
8 ¾ in.
Pipe Depth
9700 ft
Shoe track length
80 ft
Required cement fill-up (TAIL)
500 ft
Excess volume required (percent)
25%
GIVEN: Cement through casing as follows 30 bbl spacer @ 11.4 lb/gal
TOS (t op of spacer)
Followed by: Premium Class G Cement containing 0.5% CFR-3 + 0.1% HR-5. Displace plug with 10.4 lb/gal WBM.
TOC (t op of cement) 9,200 ft
Due to drillout and deepening displace with mud instead of water.
9,620 ft
9,700 f t
Figure 5.21 – Intermediate Casing Job
5 • 33
Cementing 1
Primary Cementing Calculations
Worksheet for Slurry Weight and Volume Calcul ations MATERIAL NAME Class G Cement 0.05% CFR-3 (dispersant) 0.1% HR-5 (retarder)
Water
Material (lb) 94 X
=
Mix in g Water Requirements (gal) 5.00
0.47
X
0.0938
=
0.04409
+
0.094
X
0.0750
=
0.00705
+
X
=
+
X
=
+
X
=
+
41.65 =
TOTALS ==>
Factor (gal/lb) 0.0382
Ab so lu te Volume (gal) 3.5908
8.33
136.214
X
5.00
gal
8.6419
5.00 gal
Total mixing water must be entered under absolute gallons b efore totaling. Find the weight of the mixed cement by using this fo rmula: Total Pounds/Total Absolute gallons = pounds/gallons Find the cement yield in cu bic feet per sack by using th is formu la: 3 3 Total Absolute gallons / 7.4805 gal/ ft (constant) = ft ./sack The mixing water per sack is the sum o f the gallons in the far right c olumn
Cement Density (lb/gal) ==> 3
Cement Yield (ft /sk) ===> Mixing Water required ===>
136.214 /
8.6419 =
15.8
lb/gal
8.6419 /
7.4805 =
1.16
ft /sk
5.00
3
gal/sk
5 • 34
Cementing 1
Primary Cementing Calculations
1
Cement Volume 3
Open Hole: 500 ft × 0.1503 ft /ft 3 25% Excess: 75.15 ft × 25% 3/ Shoe Track: 80 ft × 0.2025 ft /ft Total:
2
3
1.16
3
ft /sk
95 sks
= =
475 gal 11.31 bbl
Displacement Fluid Volume
9660 ft × 0.0360 bbl/ft
5
=
Mixing Water Required
95 sk × 5 gal/sk 475 gal 42 gal/bbl
4
75.15 ft 3 18.79 ft 3 16.2 ft 3 110.14 ft
Sacks of Cement
110.14 ft
3
3
= = =
=
347.76 bbl
Pressure to Land The Plug
Unknown – Height of Spacer (for “worst case”) Height of Cement (for “worst case”) Discussion: In calculating the pressure to land the plug, we want to anticipate “worst case” which would be an increased pressure over plan. We planned our cement volume based upon hole washout (in this case 25%). We need to calculate the height of cement & spacer (Which are heavier than the mud) in a perfect hole situation which will give us a taller column & higher differential pressure. Height Of Cement 3
Open Hole Volume 25% Excess Volume
= =
75.15 ft (From 1) 3 18.79 ft 3 93.94 ft
Perfect Hole Fill-up Factor (7 in OD × 8 3/4 in hole)
=
6.652 ft/ft
=
624.89 ft cement
=
1120.45 ft spacer
=
7954.66 ft
3
3
93.94 ft x 6.652 ft/ft
3
Height Of Spacer 30 bbl spacer (given) 30 bbl × 37.3484 ft/bbl ** Working from the bottom up** Height Of Mud 9700 ft - 624.89 ft - 1120.45 ft Hydrostatic Outside Cement: 624.89 ft × 0.8208 psi/ft Spacer: 1120.45 ft × 0.5922 psi/ft WBM: 7954.66 ft × 0.5403 psi/ft
= = =
Total: 9700 ft
513 psi 664 psi 4298 psi 5475 psi
Hydrostatic Inside Cement (in shoe): 40 ft × 0.8208 psi/ft WBM: 9660 ft × 0.5403 psi/ft
= =
Total: 9700 ft Differential Pressure (at top of shoe) 5475 psi - 5252 psi
33 psi 5219 psi 5252 psi
=
223 psi
5 • 35
Cementing 1
Primary Cementing Calculations
Unit D Quiz Fill in the blank with one or more words to check your progress in Unit D.
1. When using the Worksheet for Slurry Weight and Volume Calculations, the first thing you need to know is what ___________ of cement is being used. Then you can look up the ingredient’s ______________ and _____________ volume factors. 2. An absolute volume for each material is calculated by multiplying its _____ by its ___________. 3. To obtain the density of the cement mixture, divide the ________________ of the materials by the ________________________________________ of the materials. 4. To find the yield, the total absolute volume in gallons is divided by the constant, ___________ gal/ft³. 5. To calculate the total volume of slurry needed for this job, add the slurry needed to fill the _________________ and the slurry needed to fill the ____________________. Your unit of measure will be ___________ which needs to be converted to __________. 6. To calculate the number of sacks needed for this job, divide the amount of slurry in _____________ by the _______________________________ in cubic feet per sack. 7. To obtain the total amount of mixing water you will need, multiply the number of ______/sk water by the number of __________.Then convert to the unit of measurement used in tanks, ___________, by dividing gallons by _______gal/bbl. 8. You need to calculate the pressure needed to land the plug, since a pressure build up might indicate_________ and a loss of pressure may mean ______________________________________________. 9. For the pressure to land the plug, you will need to use the ____________ ___________________________________ conversion tables in the “Calculations and Formulas” section of you handbook. You will look up the _____/ft of the fluids (extrapolating, if necessary), then multiply these by the depth of the float collar (or the length of the _____________ part of the hole).
Now, look up the suggested answers in the Answer Key at the back of this section.
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Answers to Unit Quizzes Items fro m Unit A Quiz
Refer to Page
1. capacity 2. Displacement 3.
Turn to Section 210 Pages 21 0.0393 bbl/ft × 10,000 ft = 393 bbl
4.
ID × 3.14159/4/144 = 0.230438cft/ft 0.230438 / 5.6146 cft/bbl = 0.041043 bbl/ft
2
0.041043 bbl/ft × 10,000 ft = 410.43 bbl 5.
Turn to Section 210, Table 212B, Page 9 25 bbl × 70.32 ft/bbl = 1758 ft
6.
OD = 4.5 in. = 0.375 ft ID = 2.0 in. = 0.167 ft OD Area = 0.7854 × 0.375 ft × 0.375 ft = 2 0.1104 ft ID Area = 0.7854 × 0.167 ft × 0.167 ft = 2 0.0219 ft Cross-sectional Area = 2 2 2 0.1104 ft - 0.0219 ft = 0.0885 ft Displacement = 2 3 0.0885 ft × 2000 ft = 117 ft Conversion Factor = 0.1781 bbl/ft
3
Displacement = 3 3 117 ft × 0.1781 bbl/ft = 31.52 bbl
Items fro m Unit B Quiz 1.
Turn to Section 122-B 3 3 0.3132 ft /ft × 5000 ft = 1566 ft 3 3 1566 ft × 7.4805 gal/ft = 11714 gal
2.
Turn to Section 221-B, Page 73 3 3 0.1697 ft /ft × 7675 ft = 1302.45 ft
Refer to Page
Refer to Page
Items from Unit C Quiz 1.
Divided, standard
2.
Actual volume
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Cementing 1
Primary Cementing Calculations
3.
Absolute volume
4. ABSOLUTE MATERIAL
FACTOR
VOLUME
MATERIALS
(lb)
(gal/lb)
(gal)
Brine Water
10
Sand
10
TOTALS
×
0.0456
=
1.0
=
0.456
20 lbs
1.456 gal
Slurry Weight = 20 lbs ÷ 1.456 gal = 13.74 lbs/gal
5.
Worksheet for Slurry Weight and Volume Calculations
API Cement weight = 94 lb/sack 1 sack = 1 cubic foot Abs ol ut e MATERIAL
Material
Factor
Volum e
(lb)
(gal/lb)
(gal)
NAME
94 X
Class H Cement
35.819 =
Water TOTALS ==>
0.0382 =
3.5908
8.33 lb/gal
129.819
Mixing Water Requiremen ts (gal) 4.30
4.30 gal 7.8908
4.30 gal
Find the weight of the mixed cement by using this formula: Total Pounds/ Total Absolute gallons = pounds/gallon. Find the cement yield in cubic feet per sack by using this formula: 3 3 Total Absolute gallons / 7.4805 gal / ft (constant) = ft /sack The mixing water per sack is the sum of the gallons in the far right column.
Cement Density (lb/gal) ==> 3
Cement Yield (ft /sk) ===>
129.819 /
7.8908 =
16.5
7.8908 /
7.4805 =
1.05
4.30
Mixing Water req (gal/sk)===>
Refer to Page
Items from Unit D Quiz 1.
type, water requirement, absolute
2.
gal/lb, weight
3.
weight, gallons
4.
7.4805
5.
annulus, shoe joint, ft , sk
6.
ft , yield
7.
gal, sk, bbl, 42
3
3
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Cementing 1