US Army EN 5151 Engineer Course Design Forms For A Concrete Wall En5151


SUBCOURSE EDITION
EN5151 A
DESIGN FORMS FOR A CONCRETE WALL
DESIGN FORMS FOR A CONCRETE WALL
Subcourse EN5151
EDITION A
United States Army Engineer School
Fort Leonard Wood, Missouri 65473
5 Credit Hours
Edition Date: December 1995
SUBCOURSE OVERVIEW
This subcourse addresses the principles of designing wooden wall forms for concrete. One of the
carpenter's most important concerns is to ensure that all wooden concrete wall forms are designed for
strength and durability. In this subcourse you will be shown how to properly select the materials and
spacing of these materials to gain that desired strength. As a carpenter, you must be able to construct
these wall forms to support the concrete during placement and initial set period. This will be performed
in accordance with Field Manual (FM) 5-742.
There are no prerequisites for this subcourse.
The lessons in this subcourse reflect the doctrine which was current at the time it was prepared. In your
own work situation, always refer to the latest official publications.
Unless otherwise stated, the masculine gender of singular pronouns is used to refer to both men and
women.
TERMINAL LEARNING OBJECTIVE:
ACTION: You will describe procedures used to design and construct wooden forms for
concrete walls.
CONDITION: You will be given the material contained in this subcourse and an Army
Correspondence Course Program (ACCP) examination response sheet.
STANDARD: To demonstrate competency of this task, you must achieve a minimum of 70
percent the subcourse examination.
i EN5151
TABLE OF CONTENTS
Section Page
Subcourse Overview.......................................................................................................................................i
Lesson:
Part A: Math Review...................................................................................................................1-1
Part B: Select Materials for Wallforms.........................................................................................1-5
Part C: Complete Design Procedure............................................................................................1-8
Practice Exercise.............................................................................................................1-33
Answer Key and Feedback.............................................................................................1-44
Appendix A: List of Common Acronyms............................................................................................A-1
Appendix B: Recommended Reading List...........................................................................................B-1
EN5151 ii
LESSON
DESIGN FORMS FOR A CONCRETE WALL
Critical Task 051-199-4014
OVERVIEW
LESSON DESCRIPTION:
In this lesson you will learn what materials to select and the procedures necessary in designing a wooden
wall form for a concrete wall. The procedures must be performed in a step-by-step process and will be
presented in that manner in this lesson.
TERMINAL LEARNING OBJECTIVE:
ACTION You will deign a wooden form for concrete walls.
CONDITION You will be given subcourse booklet EN5151 and complete the review
exercise.
STANDARD: You must complete the lesson and the practical exercise.
REFERENCES: The material contained in this lesson was derived from FMs 5-34, 5-426, and 5-
742; and STPs 5-12B4-SM-TG; and 5-51B12-SM-TG.
INTRODUCTION
It is very important that you, as a carpenter, learn the processes involved with the designing of forms for
concrete walls. Your first step is to learn the different names of various components of wooden
concrete wallforms. This will enable you to determine what type and size of materials to use and where
to place these specific members. Your next step is to become an expert in determining the spacing of
each of these supporting members. This will enable you to design a concrete form that will successfully
handle concrete during the placing and setting up periods.
PART A: MATH REVIEW
Designing concrete forms, like other construction tasks, requires the use of a basic tool. If used
skillfully, the  tool -mathematics-will help you to complete this task.
1-1 EN5151
Before you start the subcourse lesson, you need to perform a short review of the various types of math
problems that you will encounter throughout. If you know how to add, subtract, multiply, divide, and
are familiar with the operation symbols, you will proceed through this lesson without any difficulty. On
the other hand, if you have trouble, be patient. Examples explaining each problem are included in this
lesson. Just follow the directions, keeping in mind that you learn best by actually working out the
solutions to the problems on paper.
MATH EXERCISE
Space has been provided below each question for you to work out your solution to each problem. After
completing the questions, turn to page 1-4 and check your solutions with the review exercise answers and
feedback sheet.
1. Convert 93 feet into inches.
2. How many 8-inch stakes can you cut from a piece of lumber that is 2 inches by 4 inches by 16 feet
long?
3. How many board feet are in a piece of lumber that is 2 inches by 6 inches by 12 feet long?
4. How many 28-inch-long stakes can you cut from a 7-foot stake that is a piece of a 2 by 4?
EN5151 1-2
5. How many square feet of plywood will you need to build a form for a small retaining wall that is 8
feet long and 24 inches high?
6. How many 3 foot lengths can you cut from three rolls of tie wire that are 500 feet long?
7. How many cubic yards of concrete will it take to fill a concrete form that is 40 feet long 34 inches
wide, and 6 inches deep?
8. How many cubic yards of concrete do you need to place concrete in a sidewalk that is 4 feet wide, 35
feet long, and 4 inches thick? Add a 20 percent waste factor.
9. How many cubic yards of concrete do you need to place concrete in a footer that is 18 feet long, 12
inches wide, and 6 inches thick? Add a 10 percent waste factor.
10. How many cubic yards of concrete do you need to fill a column that is 18 inches square and 12 feet
high?
1-3 EN5151
REVIEW EXERCISE ANSWER KEY AND FEEDBACK
Item Correct Answer
1. 1,116 inches 93 x 12 = 1,116
2. 24 pieces 16 x 12= 192 ÷ 8 = 24
3. 12 board feet 2 x 6 x 2 = 144 ÷ 12 = 12
4 3 stakes 12 x 7 = 84 ÷ 28 = 3
5. 32 square feet 8 x 2 = 16 x 2 (sides) = 32
6. 500 500 x 3 = 1,500 ÷ 3 = 500
7. 2.1 cubic yards 40 x 34 ÷ 12 = 113.3 x 6 ÷ 12 = 56.67
40 x 34 = 1,360 x 0.5 = 680.0
680.0 ÷ 27 = 25.18
56.67 ÷ 27 = 2.1
8. 2.05 cubic yards 35 x 4 = 140 x 0.33 = 46.20
46.20 ÷ 27 = 1.71
1.71 x 0.20 = 0.3420
1.71 + 0.34 =2.05
9. 36 cubic yards 18 x 1 = 18 x 0.5 = 9.0
9.0 ÷ 27 = 0.33
0.33 x 0.10 = 0.0330
0.33 ÷ 0.03 = 0.36
10. 1 cubic yard 18 ÷ 12 x 18 ÷ 12 x 12 = 27
1.5 x 1.5 x 12 = 27
27 ÷ 27 = 1
EN5151 1-4
PART B: SELECT MATERIALS FOR WALL FORMS
Selecting the materials for wallforms is the first step in the process of designing a concrete wall. You
will cover the remaining steps in part C of this subcourse.
Step 1. Determine the materials to select for wall forms. To determine the materials to select for wall
forms, you will need to understand what materials are available and which to use. Material and sizes to
select from are-
Sheathing. Sheathing forms the vertical surfaces of a concrete wall. The materials to be used for
sheathing are normally 1- by 4-inch or 1- by 6-inch boards and 5/8- or 3/4-inch plywood.
You should select plywood whenever possible because of its ability to cover large areas with a single
sheet The ease of erection, economy, and strength are some of the reasons for selecting plywood. In
addition, you may select/use option of 1/2-inch or 1-inch plywood when/if available.
Sheathing can be 1 1/4, 1 1/2-, or 2-inch-thick boards of any width; however, these sizes are used only
on extra-large forms such as seawalls and dams. The type of sheathing selected will depend upon the
type available at the supply point, or on the materials available list.
Studs. Studs add vertical rigidity to the wall forms. Studs are made of 2- by 4-inch material; however,
they are available in sizes of 4 by 4 or 2 by 6. For economy, use 2 by 4s if possible.
NOTE: The larger the material, the greater the stud load.
Wales. Wales reinforce the studs when they extend upward more than 4 or 5 feet. Wales are
structured of the same materials as studs. Usually 2 by 4s are used because they are economical.
However, wales may also be made of 4 by 4 or 2 by 6s. Wales are always nailed together to make them
doubled, thereby increasing their strength. The exception to wales being nailed together is when you are
substituting heavier material; such as a single 4 by 4 for two 2 by 4s.
Bracing. Braces help stabilize the form. To prevent movement and maintain alignment, the form is
normally braced with 2- by 4-inch material. Bracing may be made of 4 by 4s or 2 by 6s. The choice
would depend upon the size of the form and the type of material available.
Tie wires. Tie wires secure the formwork against the lateral pressure of the plastic concrete. They
always have double strands. Tie wires are normally made of No. 8 or 9 gauge annealed (soft) wire, but
larger wire or barbed wire may also be used. The larger the wire number, the smaller the size of the
wire. Since barbed wire is doubled, you can use a smaller size wire.
1-5 EN5151
Work the following problems to see how well you understand the concepts covered in step 1. See page
1-31 for the solution to each problem.
Following each question is a list of materials to use for the function indicated. Select the best materials
for that function.
PROBLEM 1
The best materials for sheathing on a wall form are-
A. 3/4-inch plywood and 1- by 6-inch material
B. 2- by 4- and 2- by 10-inch material
C. 3- by 6- and 2- by 6-inch material
D. 1- by 2- and 1- by 1-inch material
PROBLEM 2
The best materials for studs are-
A. 1- by 4- and 1- by 6-inch material
B. 2- by 2-inch material and 3/4-inch plywood
C. 2- by 6- and 2- by 4-inch material
D. 1- by 2- and 2- by 10-inch material
PROBLEM 3
The best materials for wales are-
A. 1- by 6- and 1- by l0-inch material
B. 2- by 10-inch material and 1/2-inch plywood
C. 3- by 6- and 2- by 2-inch material
D. 2- by 4- and 4 by 4-inch material
EN5151 1-6
PROBLEM 4
The best materials for the bracing on a wall form are-
A. 1- by 4- and 1- by 6-inch material
B. 2- by 10- and 1- by 2-inch material
C. 1- by 4- and 4- by 4-inch material
D. 4- by 4- and 2- by 4-inch material
PROBLEM 5
The best materials for tie wire on a wall form are:
A. 1/8-inch wire rope and No. 10 annealed wire
B. No. 10-barbed wire and No. 10 annealed wire
C. No. 8 and No. 9 annealed wire
D. No. 8 barbed wire and No. 4 hard-drawn wire
1-7 EN5151
PART C: COMPLETE DESIGN PROCEDURE
You completed step 1 of this process when you determined the materials needed to construct a concrete
form in part B. Now you are ready to begin the actual design of the form by completing steps 2
through 17.
You will continue this process by first determining the rate of placing or vertical fill rate per hour of the
form. This computation involves three parts. You will determine the mixer output (step 2), the plan
area (step 3), and the rate of placing (step 4). Each of these steps will be explained in the following
pages.
Step 2. Determine the mixer output. You determine the mixer output by dividing the mixer capacity
by the batch time. The unit measurement for mixer output is measured in cubic feet per hour. If you
use more than one mixer, multiply output by the number of mixers. Batch time includes loading all
ingredients, mixing, and unloading. Batch time is measured in minutes. To determine the mixer output
use this formula:
where-
cu ft = cubic feet cu/hr = cubic feet per hour, and min = minute
NOTE: If the answer contains a decimal, round up to the next whole number.
EXAMPLE:
Determine the mixer output, if the mixer's capacity is 16 cubic feet, the batching time is 7 minutes, and
the mixer operates for 1 hour.
Step 3. Determine the plan area. The plan area is the area enclosed by the form. You determine the
plan area by multiplying the length by width. It is measured in square feet. To determine the plan area,
use this formula:
Plan area (sq ft) = form L (ft) x W (ft)
where-
ft = feet, L = length, sq ft = square feet, and W = width
EN5151 1-8
EXAMPLE:
Determine the plan area for a concrete wall form that is 15 feet long by 2 feet wide by 6 feet high.
Plan area = 15 x 2= 30 sq ft
Step 4. Determine the rate of placing. Having determined the mixer output (step 2) and the plan area
(step 3), it is now time to compute the rate of placing. You determine the rate of placing of concrete in
the form by dividing the mixer output by the plan area. Rate of placing is measured in vertical feet per
hour. To determine the rate of placing, use this formula and the following procedures:
where-
ft/hr = feet per hour and R = rate of placing
" If the answer contains a decimal, round off to one decimal place. For example, for 1.41, use
1.4; for 1.57, use 1.6.
" The rates of placing should be kept below 5 feet/hour for economical design. Rate of placing
<5 feet/hour.
EXAMPLE:
Determine the rate of placing if the mixer output is 7 cubic yards per hour (189 cubic feet/hour) and the
plan area is 15 feet by 2 feet.
1-9 EN5151
Work the following problems to see how well you understand the concepts you just covered in steps 2,
3, and 4. See page 1-31 for the solution to each problem.
PROBLEM 6
Determine the plan area for a form that is 33 feet long by 7.5 feet high by 3 feet wide.
A. 30
B. 33
C. 66
D. 99
PROBLEM 7
Determine the total mixer output if the mixer capacity is 16 cubic feet and the batching time is 6
minutes with two mixers operating for 1 hour.
A. 290
B. 308
C. 320
D. 328
PROBLEM 8
Determine the rate of placing if the mixer output is 7 cubic yard per hour (189 cubic feet per hour) and
the plan area is 33 feet by 3 feet.
A. 0.8
B. 1.9
C. 2.3
D. 3.1
EN5151 1-10
Step 5. Determine the concrete placing temperature. You determine the concrete placing temperature
by making a reasonable estimate of the placing temperature of the concrete. During the seasons, you
will be considering the ambient (environmental) temperature. The optimum concrete temperatures are
55 degrees (°) to 73° Fahrenheit (F). If the temperature is too cold, heated aggregate and warm water
are used to bring the concrete temperature up to an acceptable level. If the temperature is too hot, ice
water may have to be used. The air temperature is normally 10° F above the concrete temperature.
You will be performing this step as you proceed through step 6.
Step 6. Determine the maximum concrete pressure. You determine the maximum concrete pressure by
using Figure 1-1, page 1-12. Be as accurate as possible when using the graph. The use of a straight edge
is highly recommended. You must estimate the concrete temperature, (step 5) first. To determine the
maximum concrete pressure, use Figure 1-1, and the following procedures:
" Enter the bottom of the graph at the position where your rate of placing rate is located.
" Move vertically until you intersect the correct temperature curve. Estimate as closely to the
temperature range as possible.
" Move to the far left side of the graph and estimate as closely as possible to the correct
pressure number. This number is the maximum concrete pressure. It reads 100 pounds per
square feet.
EXAMPLE:
Determine the maximum concrete pressure if the rate of placing is 2.5 feet/hour and the concrete
temperature is 60° F.
500 pounds per square feet
1-11 EN5151
Figure 1-1. Maximum concrete pressure graph
For more accurate determination of maximum concrete pressure, use the following formula:
NOTE: This formula will be used in place of Figure 1-1 when determining maximum concrete
pressure throughout the subcourse and in the examination.
EN5151 1-12
EXAMPLE:
Determine the maximum concrete pressure if the rate of placing is 2.5 feet/hour and the concrete
temperature is 60° F.
525 pounds per square feet
Maximum concrete pressure =
where-
psf = pounds per square feet
Work the following problems to see how well you understand the concept you just reviewed in steps 5
and 6. See page 1-31 for the solution to each problem.
PROBLEM 9
Determine the maximum concrete pressure if the rate of placing is 1.6 feet per hour and the concrete
temperature is 70° F.
A. 205
B. 256
C. 300
D. 356
PROBLEM 10
Determine the maximum concrete pressure if the rate of placing is 19 feet per hour and the concrete
temperature is 50° F.
A. 400
B. 492
C. 500
D. 518
1-13 EN5151
Step 7. Determine the maximum stud spacing. Determining the maximum stud spacing depends on
the type of sheathing used-boards or plywood. Maximum stud spacing is found by using either Table 1-
1 for board sheathing or Table 1-2 for plywood sheathing. Be sure to use the correct one.
Table 1-1. Maximum stud or joist
spacing for support of board sheathing
To find the maximum stud spacing, use Table 1-1 or 1-2 and the following procedures:
" Find the Maximum concrete pressure in the left column. If the value is not listed, round the
load up to the next value on the table. For example, for 340 pounds per square feet, use 400
pounds per square feet
" Move across the row to the column headed by the sheathing thickness being used. The
intersecting number is the maximum stud spacing and is in inches.
EN5151 1-14
Table 1-2. Maximum stud or joist
spacing for support of plywood sheathing
NOTE: All plywood sheathing problems and practice exercises will be using the Strong Way column
in Table 1-2.
EXAMPLE:
Determine the maximum stud spacing, in inches, if the maximum concrete pressure is 320 pounds per
square feet and a sheathing thickness of 1-inch-boards is used.
18 inches
1-15 EN5151
Work the following problem to see how well you understand the concept you just reviewed in step 7.
See page 1-31 for the solution in this problem.
PROBLEM 11
Determine the maximum stud spacing, in inches, if the maximum concrete pressure is 700 pounds per
square feet and sheathing thickness of 1-inch boards is used.
A. 14
B. 15
C. 16
D. 21
EN5151 1-16
Step 8. Determine the uniform load on a stud. You determine the uniform load on a stud by
multiplying the maximum concrete pressure (step 6) by the stud spacing (step 7). Uniform load on a
stud is measured in pounds per linear feet. To determine uniform load on a stud, use this formula and
the following procedures:
where to-
in = inch, lb/lin ft = pounds per linear feet, lb/sq ft = pounds per square feet and ULS =
uniform load on a stud
" Use the actual concrete pressure, not the rounded up figure that was used to obtain the stud
spacing in step 7.
" Carry out the answer two decimal places.
EXAMPLE:
Determine the uniform load on a stud if the maximum concrete pressure is 410 pounds per square feet
and the maximum stud spacing is 18 inches.
Work the following problem to see how well you understand the concept you just reviewed in step 8.
See page 1-31 for the solution to this problem.
PROBLEM-12
Determine the uniform load on a stud if maximum concrete pressure is 350 pounds per square feet and
the maximum stud spacing is 20 inches.
A. 350.38
B. 560.70
C. 583.33
D. 593.35
1-17 EN5151
STEP 9. Determine the maximum wale spacing. Determine the maximum wale spacing by using Table
1-3 the following procedures:
" Find the uniform load in the left-hand column. If the value you have for this load is not
listed in the table, round up to the nearest value given. For example, for 840 pounds per
linear feet, use 900 pounds per linear feet.
" Move across this row to the column headed by the correct size of the stud being used. The
intersecting number is the maximum wale spacing and is given in inches.
Table 1-3. Maximum wale spacing.
EN5151 1-18
EXAMPLE:
Find the maximum wale spacing if the uniform load is 1,560 pounds per linear feet and the studs are 2
by 6 inches.
23 inches
Work the following problem to see how well you understand the concept you just reviewed in step 9.
See page 1-31 for the solution to this problem.
PROBLEM 13
Find the maximum wale spacing if the uniform load is 581 pounds per linear feet and the studs are 2 by
4 inches.
A. 19
B. 22
C. 24
D. 27
1-19 EN5151
Step 10. Determine the uniform load on a wale. You determine the uniform load on a wale by
multiplying the maximum concrete pressure (step 6) by the maximum wale spacing (step 9). Uniform
load on a wale is measured in pounds per linear foot. To determine the uniform load on a wale, use
this formula and the following procedures:
ULW (lb/lin ft) =
maximum concrete pressure (psf) x maximum wale spacing (in)
12 (in/ft)
where-
ULW = uniform load on a wale
" Use the actual concrete pressure, not the rounded off figure that you used to obtain the wale
spacing (step 9).
" Carry out your answer two decimal places.
EXAMPLE:
Determine the uniform load on a wale if the maximum concrete pressure is 550 pounds per square feet
and the maximum wale spacing is 20 inches.
Work the following problem to see how well you understand the concept you just reviewed in step 10.
See page 1-31 for the solution to this problem.
PROBLEM 14
Determine the uniform load on a wale if the maximum concrete pressure is 350 pounds per square feet
and the maximum wale spacing is 26 inches.
A. 350.83
B. 758.33
C. 780.53
D. 810.66
EN5151 1-20
To determine the tie wire spacing, you will need to perform the steps sequentially. First, compute tie
wire spacing based on wale size (step 11). Next, you will need to compute the tie wire spacing based on
tie wire strength (step 12). Last, compare the two to select the maximum allowable tie wire spacing (step
13). The following pages will cover each of these steps.
Step 11. Determine tie wire spacing based on wale size. Tie wire spacing based on wale size is found
by using Table 1-4. The sizes at the top of the table refer to the wale material being used. The table is
divided into two halves, single-wale members located on the left, and double-wale members on the right.
Table 1-4. Maximum spacing of supporting members
(wales, ties, stringers, and 4- by 4-inch and larger shores)
1-21 EN5151
To find the tie-wire spacing, use Table 1-4, page 1-21 and the following procedures:
" Find the uniform load on a wale in the left-hand column of the table. If the value you have
for this load is not listed in the table, round up to the nearest value given. For example, for
1,250 pounds per linear feet, use 1,400 ponds per linear feet.
" Move across this row to either the single- or double-wale members section. Then locate the
wale size that you will be using. The intersecting number is the tie-wire spacing, in inches,
based on wale size.
EXAMPLE:
Determine the tie-wire spacing in inches, if the uniform load on a wale is 125 pounds per linear feet and
4- by 4-single wales are used.
82 inches
Work the following problem to see how well you understand the concept you just reviewed in step 11.
See page 1-31 for the solution to this problem.
PROBLEM 15
Determine the tie wire spacing, in inches, if the uniform load is 756 pounds per linear feet and 2- by 4-
double wales are used.
A. 30
B. 43
C. 46
D. 72
EN5151 1-22
Step 12: Determine wire spacing based on tie-wire strength. You determine wire spacing based on tie-
wire strength by dividing the tie breaking strength (step 12) by the uniform load on a wale (step 10). To
determine wire spacing based on tie-wire strength, use this formula and the following procedures:
where-
ULW = uniform load on a wale
" If you do not know the strength of the tie wire, the minimum breaking load for a double
strand of wire is given in Table 1-5.
" If the tie-wire spacing is not a whole number of inches, round the value down to the next
lower whole number of inches. For example, for 11.4, use 11; for 12.7, use 12.
Table 1-5. Average breaking load of tie material (lb).
1-23 EN5151
EXAMPLE:
Determine the tie-wire spacing, in inches, if the uniform load on a wale is 1,250 pounds per linear feet
and you are using a No. 9-gauge steel tie-wire.
Work the following problem to see how well you understand the concept you just reviewed in step 12.
See page 1-31 for the solution to this problem.
PROBLEM 16
Determine the tie-wire spacing, in inches, if the uniform load on the wale is 1,200 pounds per linear feet
and and you will using a No. 8-gauge steel tie-wire.
A. 14
B. 16
C. 17
D. 18
EN5151 1-24
Step 13. Determine the maximum tie-wire spacing. You determine the maximum tie-wire spacing by
comparing the results from steps 11 and 12, then use the smaller of the two tie-wire spacings as the
maximum tie wire spacing.
EXAMPLE:
Determine the maximum tie-wire spacing value by comparing the following measurement:
" Tie-wire spacing based on wale size = 24 inches
" Tie-wire spacing based on wire strength = 20 inches
Use the smaller tie wire spacing (20 inches).
PROBLEM 17
Work the following problem to see how well you understand the concept you just reviewed in step 13.
See page 1-32 for the solution to this problem.
Determine the maximum tie-wire spacing value by comparing the following measurement:
" 16 inches (based on wire strength)
" 26 inches (based on wale size)
1-25 EN5151
STEP 14. Determine the location of the ties. Now that you have obtained the maximum stud spacing
(step 7) and the maximum tie wire spacing (step 13), it is time to compare the two. The correct location
(spacing) of your ties must be determined to ensure that the form design has the proper strength.
NOTE: This step is performed only when using wires. If you use snap ties, the spacing was found in
step 13.
Determining the location of the ties requires consideration of two factors when comparing stud spacing
and tie wire spacing:
" If the maximum tie spacing is less than the maximum stud spacing, reduce the maximum
stud spacing to equal the maximum tie-wire spacing and install the tie at the intersections of
the studs and wales or get a stronger wire.
" If the maximum tie spacing is greater than or equal to the maximum stud spacing, use the
size for the maximum stud spacing and install the tie at the intersections of the studs and
wales.
EXAMPLE:
Determine where the ties will be made if the maximum stud spacing is 28 inches and the maximum tie
wire spacing is 24 inches.
" 28 inches (expand stud spacing)
" 24 inches (reduce stud spacing)
Reduce the stud spacing to 24 inches and install the tie at the intersections of the studs and wales.
Work the following problem to see how well you understand the concept you just reviewed in step 14.
See page 1-32 for the solution to this problem.
PROBLEM 18
Determine where the ties will be made if the maximum stud spacing is 14 inches and the maximum tie
wire spacing is 20 inches.
" 14 inches (reduce stud spacing)
" 20 inches (expand stud spacing)
EN5151 1-26
Step 15. Determine the number of studs for one side. You determine the number of studs for one
side of a form by dividing the form length by the maximum stud spacing (step 7 or step 14 if stud
spacing has been reduced). Add one to this number, and round up to the next value if your answer
contains decimal. Your first and last studs must be placed at the ends of the form, even though the
spacing between the last two studs may be less than the maximum allowable spacing. To determine the
number of studs for one side of the form, use this formula and the following procedures:
" If your answer contains a decimal, round up to the next whole number.
" The spacing between the last two studs may be less than the maximum allowable spacing.
EXAMPLE:
Determine how many studs are required for one side of the form if the stud spacing is 24 inches and
the form length is 28 feet.
Work the following problem to see how well you understand the concept you just reviewed, in step 15.
See page 1-32 for the solution to this problem.
PROBLEM 19
Determine how many studs are required for one side of the form if the stud spacing is 14 inches and
the form length is 24 feet.
A. 19
B. 20
C. 21
D. 22
1-27 EN5151
Step 16. Determine the number of double wales for one side. You determine the number of double
wales for one side of a form by dividing the form height by the maximum wale spacing (step 9). Wall
studs over 4 feet require double walls. To determine the number of double wales for one side, use this
formula and the following procedures:
" If the answer that you get is not a whole number, round up to the next whole number. For
example, for 11.4, use 12; for 12.7, use 13.
" You must place the first wale one-half the maximum wale spacing up from the bottom. The
remaining wales are placed at the maximum wale spacings that you previously determined
(see Figure 1-2).
Figure 1-2. Double wales on a 8-foot wall form
EN5151 1-28
EXAMPLE:
Determine how many wales are required for one side of the form if the wale spacing is 32 inches and a
form height of 8 feet is used.
Work the following problems to see how well you understand the concept you just reviewed in step 16.
See page 1-32 for the solution to this problem.
PROBLEM 20
Determine how many wales are required for one side of the form if the wale spacing is 30 inches and
the form height is 8 feet.
A. 1
B. 2
C. 3
D. 4
1-29 EN5151
Step 17: Determine the time required to place the concrete. You determine the time required to place
the concrete by dividing the height of the form by the rate of placing (step 4). To determine the time
required to place the concrete, use the following formula:
NOTE: Round all answers up to the next hour. For example, for 3.6, use 4 hours; for 5.8, use 6
hours; for 2.1, use 3 hours.
EXAMPLE:
Determine how long it will take to place concrete if a form, height is 20 feet and the rate of placing is
1.2 feet per hour.
Work the following problem to determine how well you understand the concept you just reviewed in
step 17. See page 1-32 for the solution to this problem.
PROBLEM 21
Determine, in hours, how long it will take to place concrete if the form height is 12 feet and the rate of
placing is 1.6 feet per hour.
A. 6.3
B. 7.5
C. 8.0
D. 8.4
EN5151 1-30
PROBLEMS ANSWER KEY AND FEEDBACK
Problem Correct Answer
1. A. 3/4-inch plywood and 1- by 6-inch material (page 1-5)
2. C. 2- by 6-inch and 2- by 4-inch material (page 1-5)
3. D. 2- by 4-inch and 4- by 4-inch material (page 1-5)
4. D. 4- by 4-inch and 2- by 4-inch material (page 1-5)
5. C. No. 8 and No. 9 annealed wire (page 1-5)
6. D. 99. Plan area = 33 x 3 = 99 square feet (page 1-8)
7.
8.
9.
10.
11. A. 14 inches (page 1-14)
12.
13. C. 24 inches (page 1-18)
14.
15. A. 30 inches (page 1-21)
16.
1-31 EN5151
PROBLEMS ANSWER KEY AND FEEDBACK CONT.
Problem Correct Answer
17. 16 inches. Use the smallest tie-wire spacing. (page 1-25)
18. Reduce tie stud spacing to 14 inches. (page 1-26)
19.
20.
21.
EN5151 1-32
PRACTICE EXERCISE
The following items will test your grasp of the material covered in this lesson. There is only one correct
answer for each item. When you have completed the exercise, check your answers with the key that
follows. If you answer any item incorrectly, study again that part which contain the portion involved.
There are two problems for this exercise. You will be performing them step by step as you did during
the lesson. Step 1, materials to be selected, has been completed for you and appears in each of the
problem statements.
Problem 1. You will be designing a form work for a concrete wall that is to be 5 feet high, 140 feet
long, and 18 inches thick. You will have three 16-S mixers with a 16 cubic foot capacity to use for
concrete mixing. Each has a batch cycle of 3 minutes. The concrete temperature expected to be 80° F.
Materials available are: 1-by 12-inch-boards, 2-by 4-inch studs, 2-by 4-inch doubled wales, and 3,000-
pound snap ties.
1. Determine, in cubic feet per hour, the total mixer output if the mixer capacity is 16 cubic feet,
batching time is 3 minutes, and the 3 mixers will be operating for 1 hour.
A. 960
B. 840
C. 3,200
D. 7,400
2. Determine the plan area for a concrete wall form that is 140 feet long, 5 feet high and 18 inches
thick.
A. 140
B. 180
C. 210
D. 250
1-33 EN5151
3. Determine the rate of placing, in feet per hour.
A. 3.8
B. 4.6
C. 5.0
D. 5.6
4. Determine the concrete temperature.
A. 60
B. 70
C. 80
D. 90
5. Determine the maximum concrete pressure, in pounds per square feet.
A. 600.3
B. 630.6
C. 667.5
D. 750.5
6. Determine the maximum stud spacing, in pounds per square feet.
A. 13
B. 14
C. 15
D. 16
EN5151 1-34
7. Determine the uniform load on a stud, in pounds per linear feet.
A. 678.3
B. 738.5
C. 778.7
D. 828.5
8. Determine the maximum wale spacing, in inches.
A. 20
B. 21
C. 22
D. 24
9. Determine the uniform load on a wale, in pounds per linear feet.
A. 1,168.13
B. 1,268.25
C. 1,325.35
D. 1,362.73
10. Determine the tie-wire spacing, based on wale size.
A. 21
B. 23
C. 25
D. 35
1-35 EN5151
11. Determine the tie-wire spacing, based on tie wire strength.
A. 26
B. 28
C. 32
D. 30
12. Determine the maximum tie-wire spacing, in inches.
A. 21
B. 25
C. 23
D. 26
13. Determine the adjusted tie-wire/stud spacing.
A. 18
B. 20
C. 25
D. Does not apply for snap ties
14. Determine how many studs are required for one side of the form.
A. 121
B. 122
C. 126
D. 131
EN5151 1-36
15. Determine how many double wales will be required for one side.
A. 2
B. 3
C. 4
D. 5
16. Determine the time required to place the concrete, in hours.
A. 0.5
B. 1.0
C. 1.5
D. 2.0
1-37 EN5151
Problem 2. You will be designing a form work for a concrete wall that is to be 6.5 feet high, 92 feet
long, and 12 inches thick. You will have one M919 mobile mixer with 27-cubic-foot capacity to use for
concrete mixing. It has a 1-cubic-yard batch cycle for every four minutes. The concrete temperature is
expected to be 50° F. Materials available are: 5/8-inch-plywood sheathing, 2- by 4-inch lumber for
studs, 4- by 4-inch lumber for wales, and No. 9 wire for ties.
17. Determine the total mixer output in cubic feet per hour, if the mixer capacity is 27 cubic feet (1
cubic yard) with batching time of four minutes and you have one mixer operating for an hour.
A. 310
B. 405
C. 435
D. 450
18. Determine the plan area, in square feet, for a concrete wall form that is 92 feet long, 6.5 feet high,
and 12 inches thick.
A. 46
B. 92
C. 112
D. 598
EN5151 1-38
19. Determine the rate of placing, in feet per hour.
A. 3.8
B. 4.4
C. 4.6
D. 5.6
20. Determine the concrete temperature.
A. 50
B. 60
C. 70
D. 80
21. Determine the maximum concrete pressure, in pounds per square feet.
A. 667
B. 750
C. 842
D. 942
1-39 E5151
22. Determine the maximum stud spacing, in pounds per square feet.
A. 6
B. 7
C. 8
D. 9
23. Determine the uniform load on a stud, in pounds per linear feet.
A. 678.5
B. 706.5
C. 738.5
D. 828.5
24. Determine the maximum wale spacing, in inches.
A. 20
B. 21
C. 22
D. 24
EN5151 1-40
25. Determine the uniform load on the wale, pounds per linear feet.
A. 1,325.5
B. 1,468.5
C. 1,568.5
D. 1,648.5
26. Determine the tie-wire spacing, based on wale size.
A. 21
B. 22
C. 23
D. 25
27. Determine the tie-wire spacing, based on tie-wire strength.
A. 8
B. 10
C. 12
D. 14
1-41 EN5151
28. Determine the maximum tie-wire spacing, in inches.
A. 8
B. 9
C. 10
D. 11
29. Determine the adjusted tie-wire/stud spacing, in inches.
A. 6
B. 8
C. 9
D. 10
30. Determine how many studs are required for one side of the form.
A. 120
B. 121
C. 124
D. 126
EN5151 1-42
31. Determine how many double wales will be required for one side.
A. 2
B. 3
C. 4
D. 5
32. Determine the time required to place the concrete, in hours.
A. 0.5
B. 1.0
C. 1.5
D. 2.0
1-43 EN5151
PRACTICE EXERCISE
ANSWER KEY AND FEEDBACK
Problem 1
Item Correct Answer
1. A. 960 (page 1-8)
2. C. 210 (pages 1-8, and 9)
3. B. 4.6 (page 1-9)
4. C. 80 (problem statement, page 1-33 and step 5, page 1-11)
5. C. 667.5 (page 1-12)
6. B. 14 (page 1-14)
7. C. 778.7 (page 1-17)
8. B. 21 (page 1-18)
9. A. 1,168.13 (page 1-20)
10. C. 25 (pages 1-21, and 22)
11. D. 30 (pages 1-23, and 24)
12. B. 25 (page 1-25)
13. D. Does not apply for snap ties (page 1-26)
14. A. 121 (page 1-27)
15. B. 3 (pages 1-28, and 29)
16. C. 1.5 (page 1-30)
EN5151 1-44
Problem 2
Item Correct Answer
17. B. 405 (page 1-8)
18. B. 92 (pages 1-8, and 9)
19. B. 4.4 (page 1-9)
20. A. 50 (problem statement page 1-38 and step 5, page 1-11)
21. D. 942 (page 1-12)
22. D. 9 (page 1-15)
23. B. 706 (page 1-17)
24. B. 21 (page 1-18)
25. D. 1,648.5 (page 1-20)
26. B. 22 (pages 1-21, and 22)
27. B. 10 (pages 1-23, and 24)
28. C. 10 (page 1-25)
29. C. 9 (page 1-26)
30. C. 124 (page 1-27)
31. C. 4 (pages 1-28, and 29)
32. D. 2.0 (page 1-30)
1-45 EN5151
THIS PAGE IS INTENTIONALLY LEFT BLANK
EN5151 1-46


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