The results of a laboratory experiment to evaluate the effects of a plasticizerare shown below.a. Calculate the water-cement ratio in each of the three cases.b. Using water reducer, how can we increase the compressive strength ofconcrete without changing workability? Refer to the appropriate case inTable P6.32.c. Using water reducer, how can we improve workability without changingthe compressive strength? Refer to the appropriate case in the table.TABLE P6.32With Water ReducerWithout Water ReducerCase 1 Case 2 Case 3Cement content, kg/m³815815815734Water content,* kg/m³446446355402Slump, mm501005050Compressive strength, MPa37.838.04637.9*Assume that the water content is above the saturated surface-dry (SSD) condition of the aggregate.d. Using water reducer, how can we reduce cost without changing work-ability or strength? (Assume that the cost of the small amount of waterreducer added is less than the cost of cement.) Refer to the appropriatecase in the table.e. Summarize all possible effects of water reducers on concrete.

a)The water content ratio: water/cement=water content/cement content water/cement=446/815…

Answered: The results of a laboratory experiment…

Structural Analysis

6th Edition

ISBN:9781337630931

Author:KASSIMALI, Aslam.

Publisher:KASSIMALI, Aslam.

Chapter2: Loads On Structures

Section: Chapter Questions

Problem 1P

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Using Figure a. Determine the ultimate stress at each water–cement ratio.b. Determine the secant modulus at 40% of the ultimate stress at each water–cement ratio.c. Plot the relationship between the secant moduli and the ultimate stresses.d. Plot the relationship between the moduli and the ultimate stresses on the same graph of part (c), using the relation of the ACI Building Code.e. Compare the two relations in questions c and d and comment on any discrepancies.f. Determine the toughness at each water–cement ratio and comment on the effect of increasing water–cement ratio on the toughness of concrete.
Using Figure 7.34,a. Determine the ultimate stress at each water–cement ratio.b. Determine the secant modulus at 40% of the ultimate stress at eachwater–cement ratio.c. Plot the relationship between the secant moduli and the ultimate stresses.d. Plot the relationship between the moduli and the ultimate stresses onthe same graph of part (c), using the relation of the ACI Building Code(Equation 7.3).e. Compare the two relations in questions c and d and comment on anydiscrepancies.f. Determine the toughness at each water–cement ratio and comment on theeffect of increasing water–cement ratio on the toughness of concrete.
Using Figure 7.34, d. Plot the relationship between the moduli and the ultimate stresses on the same graph of part (c), using the relation of the ACI Building Code (Equation 7.3). e. Compare the two relations in questions c and d and comment on any discrepancies f. Determine the toughness at each water-cement ratio and comment on the effect of increasing water-cement ratio on the toughness of concrete.
Design the concrete mix according to the following conditions:Design EnvironmentBuilding frameRequired design strength = 27.6 MPaMinimum dimension = 150 mmMinimum space between rebar = 40 mmMinimum cover over rebar = 40 mmStatistical data indicate a standard deviation of compressive strength of2.1 MPa is expected (more than 30 samples).Only air entrainer is allowed.Available MaterialsAir entrainer: Manufacture specification 6.3 mL/1% air/100 kg cement.Coarse aggregate: 19 mm nominal maximum size, river gravel (rounded)Bulk oven-dry specific gravity = 2.55, absorption = 3.6,Oven-dry rodded density = 1761 kg/m3Moisture content = 2.5,Fine aggregate: Natural sandBulk oven-dry specific gravity = 2.659, absorption = 0.5,Moisture content = 2,Fineness modulus = 2.47
The results of a laboratory experiment to evaluate the effects of a plasticizer are shown.a. Calculate the water/cement in each of the three cases. b. Choose an appropriate case that - by using water reducer, how can we increase the compressive strength of concrete without changing workability? (Refer to the appropriate case in the table) c. Choose an appropriate case that - by using a water reducer, how can we improve workability without changingthe compressive strength? (Refer to the appropriate case in the table)d. Choose an appropriate case that - by using water reducer, how can we reduce cost without changing workability or strength? (Refer to the appropriate case in the table)
What is the effect of water–cement ratio on the permeability of hardened concrete? How does permeability affect the durability of the concrete structure?Using Figure 7.33, what is the approximate percent increase in the coefficientof permeability if the water–cement ratio increases from 0.5 to 0.6? Using thesame figure, what is the approximate percent increase in the coefficient ofpermeability if the water–cement ratio increases from 0.5 to 0.7?
Design the concrete mix according to the following conditions:Design Environment• Building beamo Required design strength = 27.6 MPao Minimum dimension = 150 mmo Minimum space between rebar = 40 mmo Minimum cover over rebar = 40 mmo Statistical data indicate a standard deviation of compressive strengthof 2.1 MPa is expected (more than 30 samples).• Only air entrainer is allowed.• Moderate Sulphate exposure.• Available Materialso Air entrainer:▪ Manufacture specification 6.3 mL/1% air/100 kg cement.o Coarse aggregate:▪ 19 mm nominal maximum size▪ River gravel (rounded)▪ Bulk oven-dry specific gravity = 2.55▪ Absorption = 3.6▪ Oven-dry rodded density = 1761 kg/m3▪ Moisture content = 2.5o Fine aggregate:▪ Natural sand▪ Bulk oven-dry specific gravity = 2.659▪ Absorption = 0.5▪ Moisture content = 2▪ Fineness modulus = 2.47o Cement▪ Type II (Moderate Sulphate Resistant)▪ Specific Gravity = 3.15Based on this information, find the following and summarize the findings in a table d) The amount…
Design the concrete mix according to the following conditions:Design Environment• Building beamo Required design strength = 27.6 MPao Minimum dimension = 150 mmo Minimum space between rebar = 40 mmo Minimum cover over rebar = 40 mmo Statistical data indicate a standard deviation of compressive strengthof 2.1 MPa is expected (more than 30 samples).• Only air entrainer is allowed.• Moderate Sulphate exposure.• Available Materialso Air entrainer:▪ Manufacture specification 6.3 mL/1% air/100 kg cement.o Coarse aggregate:▪ 19 mm nominal maximum size▪ River gravel (rounded)▪ Bulk oven-dry specific gravity = 2.55▪ Absorption = 3.6▪ Oven-dry rodded density = 1761 kg/m3▪ Moisture content = 2.5o Fine aggregate:▪ Natural sand▪ Bulk oven-dry specific gravity = 2.659▪ Absorption = 0.5▪ Moisture content = 2▪ Fineness modulus = 2.47o Cement▪ Type II (Moderate Sulphate Resistant)▪ Specific Gravity = 3.15Based on this information, find the following and summarize the findings in a table.a) Required…
If the compressive strength is 30.68 MPa, water - cement ratio is 0.45, and coarse aggregate is 992 kg/m3, determine Air content, in percent Water content, kg/m3 Cement, in kg/m3
2. Data for calculating compressive strength: Ø Tested material – cement paste Ø Force destroying the specimen (first half of the beam), Fc1 – 25900 N Ø Force destroying the specimen (first half of the beam), Fc2 – 26300 N Calculate compressive strength
In the normal consistency of paste cement, If I get 30 percent normal consistency, what does it imply? What is result of the concrete if I use this product. explain explicitly
Give the different behavior and manipulation of resin cements, give atleast 1 description of each.

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