Directions:Read the passages and choose the best answer to each question.PassageNear the end of the 19th century, British engineer Osborne Reynolds ran a set of experiments to observe and predict the transition between laminar (steady) and turbulent and#64258;ow of a liquid through a pipe. In Reynoldsandrsquo; experiments, dye was forced through a liquid to show visually when the and#64258;ow changed from laminar to turbulent. Laminar and#64258;ow is common only in cases in which the and#64258;ow channel is relatively small, the and#64258;uid is moving slowly, and its viscosity (the degree to which a and#64258;uid resists and#64258;ow under an applied force) is relatively high. In turbulent and#64258;ow, the speed of the and#64258;uid at any given point is continuously undergoing changes in both magnitude and direction. Reynolds demonstrated that the transition from laminar to turbulent and#64258;ow in a pipe depends upon the value of a mathematical quantity equal to the velocity of and#64258;ow (V ) times the diameter of the tube (D) times the mass density (andrho;) of the and#64258;uid divided by its absolute viscosity (andmicro;). The andldquo;Reynolds number,andrdquo; as it is called, is determined by the following equation:Several students designed similar experiments to observe and#64258;ow rates of different liquids. To conduct the experiments, the students were given the following apparatus: Liquid supply tank with clear test section tube and andlsquo;bell mouthandrsquo; entrance 1 Rotameter to measure the velocity of and#64258;ow (and#64258;ow rate) Tap water andbull; Motor oil 4, 10-ft long smooth pipes of various diameters: 0.25-inch, 0.50-inch, 0.75-inch, 1.0-inchFigure 1 illustrates an approximation of the set-up of each experiment.Figure 2 shows approximate viscosities of the water and motor oils used in the experiments.Experiment 1In Experiment 1, students began with a pipe of diameter 0.25 inches. The pipe was set first at a 15anddeg; angle and tap water was released steadily from the tank into the pipe. The velocity of flow (V) was measured. The pipe was then set at a 30anddeg; angle, a 45anddeg; angle, and a 60anddeg; angle, water was released steadily from the tank into the pipe, and the velocity of flow was measured. The process was then repeated for each diameter of pipe using the same amount of water each time. All data were recorded in Table 1. Temperature of the water was held constant at 20anddeg;C.Experiment 2In the second experiment, the tap water was replaced by Motor Oil A and the processes were repeated. The results are given in Table 2.Experiment 3In a third experiment, the tap water was replaced by Motor Oil B and the processes were repeated.Q.Which of the following conclusions is best supported by information in the passage? As viscosity increases:a)laminar and#64258;ow decreases.b)velocity of and#64258;ow increases.c)velocity of and#64258;ow decreases.d)laminar and#64258;ow cannot be measured.Correct answer is option 'C'. Can you explain this answer?

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Directions: Read the passages and choose the best answer to each question.

Passage
Near the end of the 19th century, British engineer Osborne Reynolds ran a set of experiments to observe and predict the transition between laminar (steady) and turbulent ﬂow of a liquid through a pipe. In Reynolds’ experiments, dye was forced through a liquid to show visually when the ﬂow changed from laminar to turbulent. Laminar ﬂow is common only in cases in which the ﬂow channel is relatively small, the ﬂuid is moving slowly, and its viscosity (the degree to which a ﬂuid resists ﬂow under an applied force) is relatively high. In turbulent ﬂow, the speed of the ﬂuid at any given point is continuously undergoing changes in both magnitude and direction. Reynolds demonstrated that the transition from laminar to turbulent ﬂow in a pipe depends upon the value of a mathematical quantity equal to the velocity of ﬂow (V ) times the diameter of the tube (D) times the mass density (ρ) of the ﬂuid divided by its absolute viscosity (µ). The “Reynolds number,” as it is called, is determined by the following equation:

Several students designed similar experiments to observe ﬂow rates of different liquids. To conduct the experiments, the students were given the following apparatus:

Liquid supply tank with clear test section tube and ‘bell mouth’ entrance
1 Rotameter to measure the velocity of ﬂow (ﬂow rate)
Tap water • Motor oil
4, 10-ft long smooth pipes of various diameters: 0.25-inch, 0.50-inch, 0.75-inch, 1.0-inch

Figure 1 illustrates an approximation of the set-up of each experiment.

Figure 2 shows approximate viscosities of the water and motor oils used in the experiments.

Experiment 1
In Experiment 1, students began with a pipe of diameter 0.25 inches. The pipe was set first at a 15° angle and tap water was released steadily from the tank into the pipe. The velocity of flow (V) was measured. The pipe was then set at a 30° angle, a 45° angle, and a 60° angle, water was released steadily from the tank into the pipe, and the velocity of flow was measured. The process was then repeated for each diameter of pipe using the same amount of water each time. All data were recorded in Table 1. Temperature of the water was held constant at 20°C.

Experiment 2
In the second experiment, the tap water was replaced by Motor Oil A and the processes were repeated. The results are given in Table 2.

Experiment 3
In a third experiment, the tap water was replaced by Motor Oil B and the processes were repeated.

Q. Which of the following conclusions is best supported by information in the passage? As viscosity increases:

a)
laminar ﬂow decreases.
b)
velocity of ﬂow increases.
c)
velocity of ﬂow decreases.
d)
laminar ﬂow cannot be measured.

Correct answer is option 'C'. Can you explain this answer?

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Directions:Read the passages and choose the best answer to each questi...

According to the passage, Motor Oil B has the highest viscosity, followed by Motor Oil A, followed by tap water. The tables indicate that Motor Oil B has the slowest ﬂow rates, Motor Oil A has slightly faster ﬂow rates, and tap water has the fastest ﬂow rates, overall. This information best supports answer choice C.

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Directions:Read the passages and choose the best answer to each question.PassageNear the end of the 19th century, British engineer Osborne Reynolds ran a set of experiments to observe and predict the transition between laminar (steady) and turbulent ﬂow of a liquid through a pipe. In Reynolds’ experiments, dye was forced through a liquid to show visually when the ﬂow changed from laminar to turbulent. Laminar ﬂow is common only in cases in which the ﬂow channel is relatively small, the ﬂuid is moving slowly, and its viscosity (the degree to which a ﬂuid resists ﬂow under an applied forc e) is relatively high. In turbulent ﬂow, the speed of the ﬂuid at any given point is continuously undergoing changes in both magnitude and direction. Reynolds demonstrated that the transition from laminar to turbulent ﬂow in a pipe depends upon the value of a mathematical quantity equal to the velocity of ﬂow (V ) times the diameter of the tube (D) times the mass density (ρ) of the ﬂuid divided by its absolute viscosity (µ). The “Reynolds number,” as it is called, is determined by the following equation:Several students designed similar experiments to observe ﬂow rates of different liquids. To conduct the experiments, the students were given the following apparatus: Liquid supply tank with clear test section tube and ‘bell mouth’ entrance 1 Rotameter to measure the velocity of ﬂow (ﬂow rate) Tap water • Motor oil 4, 10-ft long smooth pipes of various diameters: 0.25-inch, 0.50-inch, 0.75-inch, 1.0-inchFigure 1 illustrates an approximation of the set-up of each experiment.Figure 2 shows approximate viscosities of the water and motor oils used in the experiments.Experiment 1In Experiment 1, students began with a pipe of diameter 0.25 inches. The pipe was set first at a 15° angle and tap water was released steadily from the tank into the pipe. The velocity of flow (V) was measured. The pipe was then set at a 30° angle, a 45° angle, and a 60° angle, water was released steadily from the tank into the pipe, and the velocity of flow was measured. The process was then repeated for each diameter of pipe using the same amount of water each time. All data were recorded in Table 1. Temperature of the water was held constant at 20°C.Experiment 2In the second experiment, the tap water was replaced by Motor Oil A and the processes were repeated. The results are given in Table 2.Experiment 3In a third experiment, the tap water was replaced by Motor Oil B and the processes were repeated.Q.Based on Experiment 1, the relationship between the angle of the pipe and the velocity of ﬂow

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Directions:Read the passages and choose the best answer to each question.PassageNear the end of the 19th century, British engineer Osborne Reynolds ran a set of experiments to observe and predict the transition between laminar (steady) and turbulent ﬂow of a liquid through a pipe. In Reynolds’ experiments, dye was forced through a liquid to show visually when the ﬂow changed from laminar to turbulent. Laminar ﬂow is common only in cases in which the ﬂow channel is relatively small, the ﬂuid is moving slowly, and its viscosity (the degree to which a ﬂuid resists ﬂow under an applied forc e) is relatively high. In turbulent ﬂow, the speed of the ﬂuid at any given point is continuously undergoing changes in both magnitude and direction. Reynolds demonstrated that the transition from laminar to turbulent ﬂow in a pipe depends upon the value of a mathematical quantity equal to the velocity of ﬂow (V ) times the diameter of the tube (D) times the mass density (ρ) of the ﬂuid divided by its absolute viscosity (µ). The “Reynolds number,” as it is called, is determined by the following equation:Several students designed similar experiments to observe ﬂow rates of different liquids. To conduct the experiments, the students were given the following apparatus: Liquid supply tank with clear test section tube and ‘bell mouth’ entrance 1 Rotameter to measure the velocity of ﬂow (ﬂow rate) Tap water • Motor oil 4, 10-ft long smooth pipes of various diameters: 0.25-inch, 0.50-inch, 0.75-inch, 1.0-inchFigure 1 illustrates an approximation of the set-up of each experiment.Figure 2 shows approximate viscosities of the water and motor oils used in the experiments.Experiment 1In Experiment 1, students began with a pipe of diameter 0.25 inches. The pipe was set first at a 15° angle and tap water was released steadily from the tank into the pipe. The velocity of flow (V) was measured. The pipe was then set at a 30° angle, a 45° angle, and a 60° angle, water was released steadily from the tank into the pipe, and the velocity of flow was measured. The process was then repeated for each diameter of pipe using the same amount of water each time. All data were recorded in Table 1. Temperature of the water was held constant at 20°C.Experiment 2In the second experiment, the tap water was replaced by Motor Oil A and the processes were repeated. The results are given in Table 2.Experiment 3In a third experiment, the tap water was replaced by Motor Oil B and the processes were repeated.Q.According to the passage, laminar ﬂow was most likely to be observed under which of the following conditions?

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Directions:Read the passages and choose the best answer to each question.PassageNear the end of the 19th century, British engineer Osborne Reynolds ran a set of experiments to observe and predict the transition between laminar (steady) and turbulent ﬂow of a liquid through a pipe. In Reynolds’ experiments, dye was forced through a liquid to show visually when the ﬂow changed from laminar to turbulent. Laminar ﬂow is common only in cases in which the ﬂow channel is relatively small, the ﬂuid is moving slowly, and its viscosity (the degree to which a ﬂuid resists ﬂow under an applied forc e) is relatively high. In turbulent ﬂow, the speed of the ﬂuid at any given point is continuously undergoing changes in both magnitude and direction. Reynolds demonstrated that the transition from laminar to turbulent ﬂow in a pipe depends upon the value of a mathematical quantity equal to the velocity of ﬂow (V ) times the diameter of the tube (D) times the mass density (ρ) of the ﬂuid divided by its absolute viscosity (µ). The “Reynolds number,” as it is called, is determined by the following equation:Several students designed similar experiments to observe ﬂow rates of different liquids. To conduct the experiments, the students were given the following apparatus: Liquid supply tank with clear test section tube and ‘bell mouth’ entrance 1 Rotameter to measure the velocity of ﬂow (ﬂow rate) Tap water • Motor oil 4, 10-ft long smooth pipes of various diameters: 0.25-inch, 0.50-inch, 0.75-inch, 1.0-inchFigure 1 illustrates an approximation of the set-up of each experiment.Figure 2 shows approximate viscosities of the water and motor oils used in the experiments.Experiment 1In Experiment 1, students began with a pipe of diameter 0.25 inches. The pipe was set first at a 15° angle and tap water was released steadily from the tank into the pipe. The velocity of flow (V) was measured. The pipe was then set at a 30° angle, a 45° angle, and a 60° angle, water was released steadily from the tank into the pipe, and the velocity of flow was measured. The process was then repeated for each diameter of pipe using the same amount of water each time. All data were recorded in Table 1. Temperature of the water was held constant at 20°C.Experiment 2In the second experiment, the tap water was replaced by Motor Oil A and the processes were repeated. The results are given in Table 2.Experiment 3In a third experiment, the tap water was replaced by Motor Oil B and the processes were repeated.Q.Information in the passage and the results of the experiments indicate which of the following? Compared to tap water, Motor Oil A

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Directions:Read the passages and choose the best answer to each question.PassageNear the end of the 19th century, British engineer Osborne Reynolds ran a set of experiments to observe and predict the transition between laminar (steady) and turbulent ﬂow of a liquid through a pipe. In Reynolds’ experiments, dye was forced through a liquid to show visually when the ﬂow changed from laminar to turbulent. Laminar ﬂow is common only in cases in which the ﬂow channel is relatively small, the ﬂuid is moving slowly, and its viscosity (the degree to which a ﬂuid resists ﬂow under an applied forc e) is relatively high. In turbulent ﬂow, the speed of the ﬂuid at any given point is continuously undergoing changes in both magnitude and direction. Reynolds demonstrated that the transition from laminar to turbulent ﬂow in a pipe depends upon the value of a mathematical quantity equal to the velocity of ﬂow (V ) times the diameter of the tube (D) times the mass density (ρ) of the ﬂuid divided by its absolute viscosity (µ). The “Reynolds number,” as it is called, is determined by the following equation:Several students designed similar experiments to observe ﬂow rates of different liquids. To conduct the experiments, the students were given the following apparatus: Liquid supply tank with clear test section tube and ‘bell mouth’ entrance 1 Rotameter to measure the velocity of ﬂow (ﬂow rate) Tap water • Motor oil 4, 10-ft long smooth pipes of various diameters: 0.25-inch, 0.50-inch, 0.75-inch, 1.0-inchFigure 1 illustrates an approximation of the set-up of each experiment.Figure 2 shows approximate viscosities of the water and motor oils used in the experiments.Experiment 1In Experiment 1, students began with a pipe of diameter 0.25 inches. The pipe was set first at a 15° angle and tap water was released steadily from the tank into the pipe. The velocity of flow (V) was measured. The pipe was then set at a 30° angle, a 45° angle, and a 60° angle, water was released steadily from the tank into the pipe, and the velocity of flow was measured. The process was then repeated for each diameter of pipe using the same amount of water each time. All data were recorded in Table 1. Temperature of the water was held constant at 20°C.Experiment 2In the second experiment, the tap water was replaced by Motor Oil A and the processes were repeated. The results are given in Table 2.Experiment 3In a third experiment, the tap water was replaced by Motor Oil B and the processes were repeated.Q.All of the experimental factors were identical EXCEPT

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Directions:Read the passages and choose the best answer to each question.PassageNear the end of the 19th century, British engineer Osborne Reynolds ran a set of experiments to observe and predict the transition between laminar (steady) and turbulent ﬂow of a liquid through a pipe. In Reynolds’ experiments, dye was forced through a liquid to show visually when the ﬂow changed from laminar to turbulent. Laminar ﬂow is common only in cases in which the ﬂow channel is relatively small, the ﬂuid is moving slowly, and its viscosity (the degree to which a ﬂuid resists ﬂow under an applied forc e) is relatively high. In turbulent ﬂow, the speed of the ﬂuid at any given point is continuously undergoing changes in both magnitude and direction. Reynolds demonstrated that the transition from laminar to turbulent ﬂow in a pipe depends upon the value of a mathematical quantity equal to the velocity of ﬂow (V ) times the diameter of the tube (D) times the mass density (ρ) of the ﬂuid divided by its absolute viscosity (µ). The “Reynolds number,” as it is called, is determined by the following equation:Several students designed similar experiments to observe ﬂow rates of different liquids. To conduct the experiments, the students were given the following apparatus: Liquid supply tank with clear test section tube and ‘bell mouth’ entrance 1 Rotameter to measure the velocity of ﬂow (ﬂow rate) Tap water • Motor oil 4, 10-ft long smooth pipes of various diameters: 0.25-inch, 0.50-inch, 0.75-inch, 1.0-inchFigure 1 illustrates an approximation of the set-up of each experiment.Figure 2 shows approximate viscosities of the water and motor oils used in the experiments.Experiment 1In Experiment 1, students began with a pipe of diameter 0.25 inches. The pipe was set first at a 15° angle and tap water was released steadily from the tank into the pipe. The velocity of flow (V) was measured. The pipe was then set at a 30° angle, a 45° angle, and a 60° angle, water was released steadily from the tank into the pipe, and the velocity of flow was measured. The process was then repeated for each diameter of pipe using the same amount of water each time. All data were recorded in Table 1. Temperature of the water was held constant at 20°C.Experiment 2In the second experiment, the tap water was replaced by Motor Oil A and the processes were repeated. The results are given in Table 2.Experiment 3In a third experiment, the tap water was replaced by Motor Oil B and the processes were repeated.Q. In Experiment 1, at a 30° angle, flow rate would most likely have been approximately 6.0 ft/s for which new pipe diameter?

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Directions:Read the passages and choose the best answer to each question.PassageNear the end of the 19th century, British engineer Osborne Reynolds ran a set of experiments to observe and predict the transition between laminar (steady) and turbulent ﬂow of a liquid through a pipe. In Reynolds’ experiments, dye was forced through a liquid to show visually when the ﬂow changed from laminar to turbulent. Laminar ﬂow is common only in cases in which the ﬂow channel is relatively small, the ﬂuid is moving slowly, and its viscosity (the degree to which a ﬂuid resists ﬂow under an applied force) is relatively high. In turbulent ﬂow, the speed of the ﬂuid at any given point is continuously undergoing changes in both magnitude and direction. Reynolds demonstrated that the transition from laminar to turbulent ﬂow in a pipe depends upon the value of a mathematical quantity equal to the velocity of ﬂow (V ) times the diameter of the tube (D) times the mass density (ρ) of the ﬂuid divided by its absolute viscosity (µ). The “Reynolds number,” as it is called, is determined by the following equation:Several students designed similar experiments to observe ﬂow rates of different liquids. To conduct the experiments, the students were given the following apparatus: Liquid supply tank with clear test section tube and ‘bell mouth’ entrance 1 Rotameter to measure the velocity of ﬂow (ﬂow rate) Tap water • Motor oil 4, 10-ft long smooth pipes of various diameters: 0.25-inch, 0.50-inch, 0.75-inch, 1.0-inchFigure 1 illustrates an approximation of the set-up of each experiment.Figure 2 shows approximate viscosities of the water and motor oils used in the experiments.Experiment 1In Experiment 1, students began with a pipe of diameter 0.25 inches. The pipe was set first at a 15° angle and tap water was released steadily from the tank into the pipe. The velocity of flow (V) was measured. The pipe was then set at a 30° angle, a 45° angle, and a 60° angle, water was released steadily from the tank into the pipe, and the velocity of flow was measured. The process was then repeated for each diameter of pipe using the same amount of water each time. All data were recorded in Table 1. Temperature of the water was held constant at 20°C.Experiment 2In the second experiment, the tap water was replaced by Motor Oil A and the processes were repeated. The results are given in Table 2.Experiment 3In a third experiment, the tap water was replaced by Motor Oil B and the processes were repeated.Q.Which of the following conclusions is best supported by information in the passage? As viscosity increases:a)laminar ﬂow decreases.b)velocity of ﬂow increases.c)velocity of ﬂow decreases.d)laminar ﬂow cannot be measured.Correct answer is option 'C'. Can you explain this answer?

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Directions:Read the passages and choose the best answer to each question.PassageNear the end of the 19th century, British engineer Osborne Reynolds ran a set of experiments to observe and predict the transition between laminar (steady) and turbulent ﬂow of a liquid through a pipe. In Reynolds’ experiments, dye was forced through a liquid to show visually when the ﬂow changed from laminar to turbulent. Laminar ﬂow is common only in cases in which the ﬂow channel is relatively small, the ﬂuid is moving slowly, and its viscosity (the degree to which a ﬂuid resists ﬂow under an applied force) is relatively high. In turbulent ﬂow, the speed of the ﬂuid at any given point is continuously undergoing changes in both magnitude and direction. Reynolds demonstrated that the transition from laminar to turbulent ﬂow in a pipe depends upon the value of a mathematical quantity equal to the velocity of ﬂow (V ) times the diameter of the tube (D) times the mass density (ρ) of the ﬂuid divided by its absolute viscosity (µ). The “Reynolds number,” as it is called, is determined by the following equation:Several students designed similar experiments to observe ﬂow rates of different liquids. To conduct the experiments, the students were given the following apparatus: Liquid supply tank with clear test section tube and ‘bell mouth’ entrance 1 Rotameter to measure the velocity of ﬂow (ﬂow rate) Tap water • Motor oil 4, 10-ft long smooth pipes of various diameters: 0.25-inch, 0.50-inch, 0.75-inch, 1.0-inchFigure 1 illustrates an approximation of the set-up of each experiment.Figure 2 shows approximate viscosities of the water and motor oils used in the experiments.Experiment 1In Experiment 1, students began with a pipe of diameter 0.25 inches. The pipe was set first at a 15° angle and tap water was released steadily from the tank into the pipe. The velocity of flow (V) was measured. The pipe was then set at a 30° angle, a 45° angle, and a 60° angle, water was released steadily from the tank into the pipe, and the velocity of flow was measured. The process was then repeated for each diameter of pipe using the same amount of water each time. All data were recorded in Table 1. Temperature of the water was held constant at 20°C.Experiment 2In the second experiment, the tap water was replaced by Motor Oil A and the processes were repeated. The results are given in Table 2.Experiment 3In a third experiment, the tap water was replaced by Motor Oil B and the processes were repeated.Q.Which of the following conclusions is best supported by information in the passage? As viscosity increases:a)laminar ﬂow decreases.b)velocity of ﬂow increases.c)velocity of ﬂow decreases.d)laminar ﬂow cannot be measured.Correct answer is option 'C'. Can you explain this answer? for ACT 2025 is part of ACT preparation. The Question and answers have been prepared according to the ACT exam syllabus. Information about Directions:Read the passages and choose the best answer to each question.PassageNear the end of the 19th century, British engineer Osborne Reynolds ran a set of experiments to observe and predict the transition between laminar (steady) and turbulent ﬂow of a liquid through a pipe. In Reynolds’ experiments, dye was forced through a liquid to show visually when the ﬂow changed from laminar to turbulent. Laminar ﬂow is common only in cases in which the ﬂow channel is relatively small, the ﬂuid is moving slowly, and its viscosity (the degree to which a ﬂuid resists ﬂow under an applied force) is relatively high. In turbulent ﬂow, the speed of the ﬂuid at any given point is continuously undergoing changes in both magnitude and direction. Reynolds demonstrated that the transition from laminar to turbulent ﬂow in a pipe depends upon the value of a mathematical quantity equal to the velocity of ﬂow (V ) times the diameter of the tube (D) times the mass density (ρ) of the ﬂuid divided by its absolute viscosity (µ). The “Reynolds number,” as it is called, is determined by the following equation:Several students designed similar experiments to observe ﬂow rates of different liquids. To conduct the experiments, the students were given the following apparatus: Liquid supply tank with clear test section tube and ‘bell mouth’ entrance 1 Rotameter to measure the velocity of ﬂow (ﬂow rate) Tap water • Motor oil 4, 10-ft long smooth pipes of various diameters: 0.25-inch, 0.50-inch, 0.75-inch, 1.0-inchFigure 1 illustrates an approximation of the set-up of each experiment.Figure 2 shows approximate viscosities of the water and motor oils used in the experiments.Experiment 1In Experiment 1, students began with a pipe of diameter 0.25 inches. The pipe was set first at a 15° angle and tap water was released steadily from the tank into the pipe. The velocity of flow (V) was measured. The pipe was then set at a 30° angle, a 45° angle, and a 60° angle, water was released steadily from the tank into the pipe, and the velocity of flow was measured. The process was then repeated for each diameter of pipe using the same amount of water each time. All data were recorded in Table 1. Temperature of the water was held constant at 20°C.Experiment 2In the second experiment, the tap water was replaced by Motor Oil A and the processes were repeated. The results are given in Table 2.Experiment 3In a third experiment, the tap water was replaced by Motor Oil B and the processes were repeated.Q.Which of the following conclusions is best supported by information in the passage? As viscosity increases:a)laminar ﬂow decreases.b)velocity of ﬂow increases.c)velocity of ﬂow decreases.d)laminar ﬂow cannot be measured.Correct answer is option 'C'. Can you explain this answer? covers all topics & solutions for ACT 2025 Exam. Find important definitions, questions, meanings, examples, exercises and tests below for Directions:Read the passages and choose the best answer to each question.PassageNear the end of the 19th century, British engineer Osborne Reynolds ran a set of experiments to observe and predict the transition between laminar (steady) and turbulent ﬂow of a liquid through a pipe. In Reynolds’ experiments, dye was forced through a liquid to show visually when the ﬂow changed from laminar to turbulent. Laminar ﬂow is common only in cases in which the ﬂow channel is relatively small, the ﬂuid is moving slowly, and its viscosity (the degree to which a ﬂuid resists ﬂow under an applied force) is relatively high. In turbulent ﬂow, the speed of the ﬂuid at any given point is continuously undergoing changes in both magnitude and direction. Reynolds demonstrated that the transition from laminar to turbulent ﬂow in a pipe depends upon the value of a mathematical quantity equal to the velocity of ﬂow (V ) times the diameter of the tube (D) times the mass density (ρ) of the ﬂuid divided by its absolute viscosity (µ). The “Reynolds number,” as it is called, is determined by the following equation:Several students designed similar experiments to observe ﬂow rates of different liquids. To conduct the experiments, the students were given the following apparatus: Liquid supply tank with clear test section tube and ‘bell mouth’ entrance 1 Rotameter to measure the velocity of ﬂow (ﬂow rate) Tap water • Motor oil 4, 10-ft long smooth pipes of various diameters: 0.25-inch, 0.50-inch, 0.75-inch, 1.0-inchFigure 1 illustrates an approximation of the set-up of each experiment.Figure 2 shows approximate viscosities of the water and motor oils used in the experiments.Experiment 1In Experiment 1, students began with a pipe of diameter 0.25 inches. The pipe was set first at a 15° angle and tap water was released steadily from the tank into the pipe. The velocity of flow (V) was measured. The pipe was then set at a 30° angle, a 45° angle, and a 60° angle, water was released steadily from the tank into the pipe, and the velocity of flow was measured. The process was then repeated for each diameter of pipe using the same amount of water each time. All data were recorded in Table 1. Temperature of the water was held constant at 20°C.Experiment 2In the second experiment, the tap water was replaced by Motor Oil A and the processes were repeated. The results are given in Table 2.Experiment 3In a third experiment, the tap water was replaced by Motor Oil B and the processes were repeated.Q.Which of the following conclusions is best supported by information in the passage? As viscosity increases:a)laminar ﬂow decreases.b)velocity of ﬂow increases.c)velocity of ﬂow decreases.d)laminar ﬂow cannot be measured.Correct answer is option 'C'. Can you explain this answer?.

Solutions for Directions:Read the passages and choose the best answer to each question.PassageNear the end of the 19th century, British engineer Osborne Reynolds ran a set of experiments to observe and predict the transition between laminar (steady) and turbulent ﬂow of a liquid through a pipe. In Reynolds’ experiments, dye was forced through a liquid to show visually when the ﬂow changed from laminar to turbulent. Laminar ﬂow is common only in cases in which the ﬂow channel is relatively small, the ﬂuid is moving slowly, and its viscosity (the degree to which a ﬂuid resists ﬂow under an applied force) is relatively high. In turbulent ﬂow, the speed of the ﬂuid at any given point is continuously undergoing changes in both magnitude and direction. Reynolds demonstrated that the transition from laminar to turbulent ﬂow in a pipe depends upon the value of a mathematical quantity equal to the velocity of ﬂow (V ) times the diameter of the tube (D) times the mass density (ρ) of the ﬂuid divided by its absolute viscosity (µ). The “Reynolds number,” as it is called, is determined by the following equation:Several students designed similar experiments to observe ﬂow rates of different liquids. To conduct the experiments, the students were given the following apparatus: Liquid supply tank with clear test section tube and ‘bell mouth’ entrance 1 Rotameter to measure the velocity of ﬂow (ﬂow rate) Tap water • Motor oil 4, 10-ft long smooth pipes of various diameters: 0.25-inch, 0.50-inch, 0.75-inch, 1.0-inchFigure 1 illustrates an approximation of the set-up of each experiment.Figure 2 shows approximate viscosities of the water and motor oils used in the experiments.Experiment 1In Experiment 1, students began with a pipe of diameter 0.25 inches. The pipe was set first at a 15° angle and tap water was released steadily from the tank into the pipe. The velocity of flow (V) was measured. The pipe was then set at a 30° angle, a 45° angle, and a 60° angle, water was released steadily from the tank into the pipe, and the velocity of flow was measured. The process was then repeated for each diameter of pipe using the same amount of water each time. All data were recorded in Table 1. Temperature of the water was held constant at 20°C.Experiment 2In the second experiment, the tap water was replaced by Motor Oil A and the processes were repeated. The results are given in Table 2.Experiment 3In a third experiment, the tap water was replaced by Motor Oil B and the processes were repeated.Q.Which of the following conclusions is best supported by information in the passage? As viscosity increases:a)laminar ﬂow decreases.b)velocity of ﬂow increases.c)velocity of ﬂow decreases.d)laminar ﬂow cannot be measured.Correct answer is option 'C'. Can you explain this answer? in English & in Hindi are available as part of our courses for ACT. Download more important topics, notes, lectures and mock test series for ACT Exam by signing up for free.

Here you can find the meaning of Directions:Read the passages and choose the best answer to each question.PassageNear the end of the 19th century, British engineer Osborne Reynolds ran a set of experiments to observe and predict the transition between laminar (steady) and turbulent ﬂow of a liquid through a pipe. In Reynolds’ experiments, dye was forced through a liquid to show visually when the ﬂow changed from laminar to turbulent. Laminar ﬂow is common only in cases in which the ﬂow channel is relatively small, the ﬂuid is moving slowly, and its viscosity (the degree to which a ﬂuid resists ﬂow under an applied force) is relatively high. In turbulent ﬂow, the speed of the ﬂuid at any given point is continuously undergoing changes in both magnitude and direction. Reynolds demonstrated that the transition from laminar to turbulent ﬂow in a pipe depends upon the value of a mathematical quantity equal to the velocity of ﬂow (V ) times the diameter of the tube (D) times the mass density (ρ) of the ﬂuid divided by its absolute viscosity (µ). The “Reynolds number,” as it is called, is determined by the following equation:Several students designed similar experiments to observe ﬂow rates of different liquids. To conduct the experiments, the students were given the following apparatus: Liquid supply tank with clear test section tube and ‘bell mouth’ entrance 1 Rotameter to measure the velocity of ﬂow (ﬂow rate) Tap water • Motor oil 4, 10-ft long smooth pipes of various diameters: 0.25-inch, 0.50-inch, 0.75-inch, 1.0-inchFigure 1 illustrates an approximation of the set-up of each experiment.Figure 2 shows approximate viscosities of the water and motor oils used in the experiments.Experiment 1In Experiment 1, students began with a pipe of diameter 0.25 inches. The pipe was set first at a 15° angle and tap water was released steadily from the tank into the pipe. The velocity of flow (V) was measured. The pipe was then set at a 30° angle, a 45° angle, and a 60° angle, water was released steadily from the tank into the pipe, and the velocity of flow was measured. The process was then repeated for each diameter of pipe using the same amount of water each time. All data were recorded in Table 1. Temperature of the water was held constant at 20°C.Experiment 2In the second experiment, the tap water was replaced by Motor Oil A and the processes were repeated. The results are given in Table 2.Experiment 3In a third experiment, the tap water was replaced by Motor Oil B and the processes were repeated.Q.Which of the following conclusions is best supported by information in the passage? As viscosity increases:a)laminar ﬂow decreases.b)velocity of ﬂow increases.c)velocity of ﬂow decreases.d)laminar ﬂow cannot be measured.Correct answer is option 'C'. Can you explain this answer? defined & explained in the simplest way possible. Besides giving the explanation of Directions:Read the passages and choose the best answer to each question.PassageNear the end of the 19th century, British engineer Osborne Reynolds ran a set of experiments to observe and predict the transition between laminar (steady) and turbulent ﬂow of a liquid through a pipe. In Reynolds’ experiments, dye was forced through a liquid to show visually when the ﬂow changed from laminar to turbulent. Laminar ﬂow is common only in cases in which the ﬂow channel is relatively small, the ﬂuid is moving slowly, and its viscosity (the degree to which a ﬂuid resists ﬂow under an applied force) is relatively high. In turbulent ﬂow, the speed of the ﬂuid at any given point is continuously undergoing changes in both magnitude and direction. Reynolds demonstrated that the transition from laminar to turbulent ﬂow in a pipe depends upon the value of a mathematical quantity equal to the velocity of ﬂow (V ) times the diameter of the tube (D) times the mass density (ρ) of the ﬂuid divided by its absolute viscosity (µ). The “Reynolds number,” as it is called, is determined by the following equation:Several students designed similar experiments to observe ﬂow rates of different liquids. To conduct the experiments, the students were given the following apparatus: Liquid supply tank with clear test section tube and ‘bell mouth’ entrance 1 Rotameter to measure the velocity of ﬂow (ﬂow rate) Tap water • Motor oil 4, 10-ft long smooth pipes of various diameters: 0.25-inch, 0.50-inch, 0.75-inch, 1.0-inchFigure 1 illustrates an approximation of the set-up of each experiment.Figure 2 shows approximate viscosities of the water and motor oils used in the experiments.Experiment 1In Experiment 1, students began with a pipe of diameter 0.25 inches. The pipe was set first at a 15° angle and tap water was released steadily from the tank into the pipe. The velocity of flow (V) was measured. The pipe was then set at a 30° angle, a 45° angle, and a 60° angle, water was released steadily from the tank into the pipe, and the velocity of flow was measured. The process was then repeated for each diameter of pipe using the same amount of water each time. All data were recorded in Table 1. Temperature of the water was held constant at 20°C.Experiment 2In the second experiment, the tap water was replaced by Motor Oil A and the processes were repeated. The results are given in Table 2.Experiment 3In a third experiment, the tap water was replaced by Motor Oil B and the processes were repeated.Q.Which of the following conclusions is best supported by information in the passage? As viscosity increases:a)laminar ﬂow decreases.b)velocity of ﬂow increases.c)velocity of ﬂow decreases.d)laminar ﬂow cannot be measured.Correct answer is option 'C'. Can you explain this answer?, a detailed solution for Directions:Read the passages and choose the best answer to each question.PassageNear the end of the 19th century, British engineer Osborne Reynolds ran a set of experiments to observe and predict the transition between laminar (steady) and turbulent ﬂow of a liquid through a pipe. In Reynolds’ experiments, dye was forced through a liquid to show visually when the ﬂow changed from laminar to turbulent. Laminar ﬂow is common only in cases in which the ﬂow channel is relatively small, the ﬂuid is moving slowly, and its viscosity (the degree to which a ﬂuid resists ﬂow under an applied force) is relatively high. In turbulent ﬂow, the speed of the ﬂuid at any given point is continuously undergoing changes in both magnitude and direction. Reynolds demonstrated that the transition from laminar to turbulent ﬂow in a pipe depends upon the value of a mathematical quantity equal to the velocity of ﬂow (V ) times the diameter of the tube (D) times the mass density (ρ) of the ﬂuid divided by its absolute viscosity (µ). The “Reynolds number,” as it is called, is determined by the following equation:Several students designed similar experiments to observe ﬂow rates of different liquids. To conduct the experiments, the students were given the following apparatus: Liquid supply tank with clear test section tube and ‘bell mouth’ entrance 1 Rotameter to measure the velocity of ﬂow (ﬂow rate) Tap water • Motor oil 4, 10-ft long smooth pipes of various diameters: 0.25-inch, 0.50-inch, 0.75-inch, 1.0-inchFigure 1 illustrates an approximation of the set-up of each experiment.Figure 2 shows approximate viscosities of the water and motor oils used in the experiments.Experiment 1In Experiment 1, students began with a pipe of diameter 0.25 inches. The pipe was set first at a 15° angle and tap water was released steadily from the tank into the pipe. The velocity of flow (V) was measured. The pipe was then set at a 30° angle, a 45° angle, and a 60° angle, water was released steadily from the tank into the pipe, and the velocity of flow was measured. The process was then repeated for each diameter of pipe using the same amount of water each time. All data were recorded in Table 1. Temperature of the water was held constant at 20°C.Experiment 2In the second experiment, the tap water was replaced by Motor Oil A and the processes were repeated. The results are given in Table 2.Experiment 3In a third experiment, the tap water was replaced by Motor Oil B and the processes were repeated.Q.Which of the following conclusions is best supported by information in the passage? As viscosity increases:a)laminar ﬂow decreases.b)velocity of ﬂow increases.c)velocity of ﬂow decreases.d)laminar ﬂow cannot be measured.Correct answer is option 'C'. Can you explain this answer? has been provided alongside types of Directions:Read the passages and choose the best answer to each question.PassageNear the end of the 19th century, British engineer Osborne Reynolds ran a set of experiments to observe and predict the transition between laminar (steady) and turbulent ﬂow of a liquid through a pipe. In Reynolds’ experiments, dye was forced through a liquid to show visually when the ﬂow changed from laminar to turbulent. Laminar ﬂow is common only in cases in which the ﬂow channel is relatively small, the ﬂuid is moving slowly, and its viscosity (the degree to which a ﬂuid resists ﬂow under an applied force) is relatively high. In turbulent ﬂow, the speed of the ﬂuid at any given point is continuously undergoing changes in both magnitude and direction. Reynolds demonstrated that the transition from laminar to turbulent ﬂow in a pipe depends upon the value of a mathematical quantity equal to the velocity of ﬂow (V ) times the diameter of the tube (D) times the mass density (ρ) of the ﬂuid divided by its absolute viscosity (µ). The “Reynolds number,” as it is called, is determined by the following equation:Several students designed similar experiments to observe ﬂow rates of different liquids. To conduct the experiments, the students were given the following apparatus: Liquid supply tank with clear test section tube and ‘bell mouth’ entrance 1 Rotameter to measure the velocity of ﬂow (ﬂow rate) Tap water • Motor oil 4, 10-ft long smooth pipes of various diameters: 0.25-inch, 0.50-inch, 0.75-inch, 1.0-inchFigure 1 illustrates an approximation of the set-up of each experiment.Figure 2 shows approximate viscosities of the water and motor oils used in the experiments.Experiment 1In Experiment 1, students began with a pipe of diameter 0.25 inches. The pipe was set first at a 15° angle and tap water was released steadily from the tank into the pipe. The velocity of flow (V) was measured. The pipe was then set at a 30° angle, a 45° angle, and a 60° angle, water was released steadily from the tank into the pipe, and the velocity of flow was measured. The process was then repeated for each diameter of pipe using the same amount of water each time. All data were recorded in Table 1. Temperature of the water was held constant at 20°C.Experiment 2In the second experiment, the tap water was replaced by Motor Oil A and the processes were repeated. The results are given in Table 2.Experiment 3In a third experiment, the tap water was replaced by Motor Oil B and the processes were repeated.Q.Which of the following conclusions is best supported by information in the passage? As viscosity increases:a)laminar ﬂow decreases.b)velocity of ﬂow increases.c)velocity of ﬂow decreases.d)laminar ﬂow cannot be measured.Correct answer is option 'C'. Can you explain this answer? theory, EduRev gives you an ample number of questions to practice Directions:Read the passages and choose the best answer to each question.PassageNear the end of the 19th century, British engineer Osborne Reynolds ran a set of experiments to observe and predict the transition between laminar (steady) and turbulent ﬂow of a liquid through a pipe. In Reynolds’ experiments, dye was forced through a liquid to show visually when the ﬂow changed from laminar to turbulent. Laminar ﬂow is common only in cases in which the ﬂow channel is relatively small, the ﬂuid is moving slowly, and its viscosity (the degree to which a ﬂuid resists ﬂow under an applied force) is relatively high. In turbulent ﬂow, the speed of the ﬂuid at any given point is continuously undergoing changes in both magnitude and direction. Reynolds demonstrated that the transition from laminar to turbulent ﬂow in a pipe depends upon the value of a mathematical quantity equal to the velocity of ﬂow (V ) times the diameter of the tube (D) times the mass density (ρ) of the ﬂuid divided by its absolute viscosity (µ). The “Reynolds number,” as it is called, is determined by the following equation:Several students designed similar experiments to observe ﬂow rates of different liquids. To conduct the experiments, the students were given the following apparatus: Liquid supply tank with clear test section tube and ‘bell mouth’ entrance 1 Rotameter to measure the velocity of ﬂow (ﬂow rate) Tap water • Motor oil 4, 10-ft long smooth pipes of various diameters: 0.25-inch, 0.50-inch, 0.75-inch, 1.0-inchFigure 1 illustrates an approximation of the set-up of each experiment.Figure 2 shows approximate viscosities of the water and motor oils used in the experiments.Experiment 1In Experiment 1, students began with a pipe of diameter 0.25 inches. The pipe was set first at a 15° angle and tap water was released steadily from the tank into the pipe. The velocity of flow (V) was measured. The pipe was then set at a 30° angle, a 45° angle, and a 60° angle, water was released steadily from the tank into the pipe, and the velocity of flow was measured. The process was then repeated for each diameter of pipe using the same amount of water each time. All data were recorded in Table 1. Temperature of the water was held constant at 20°C.Experiment 2In the second experiment, the tap water was replaced by Motor Oil A and the processes were repeated. The results are given in Table 2.Experiment 3In a third experiment, the tap water was replaced by Motor Oil B and the processes were repeated.Q.Which of the following conclusions is best supported by information in the passage? As viscosity increases:a)laminar ﬂow decreases.b)velocity of ﬂow increases.c)velocity of ﬂow decreases.d)laminar ﬂow cannot be measured.Correct answer is option 'C'. Can you explain this answer? tests, examples and also practice ACT tests.

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