Question 10 of 50

What is the fundamental relationship that defines the square of the speed of sound, c, in terms of the rate of change of pressure (P) with respect to density (ρ)?

For a perfect gas, what is the correct formula for the speed of sound, c, given the ratio of specific heats (k), the specific gas constant (R), and the absolute temperature (T)?

In the context of a two-phase medium, such as gas with dust particles, how does the addition of the second phase (particles) affect the speed of sound compared to that of the pure gas?

For calculating the speed of sound in liquids, the formula c = sqrt(B/ρ) is used. What does the term 'B' represent?

Calculate the speed of sound in air at a temperature of 300 Kelvin. Assume air is a perfect gas with a ratio of specific heats (k) of 1.4 and a specific gas constant (R) of 287 J/(kg·K).

The equation of state for a real gas can be expressed as P = zρRT. What does the compressibility factor, 'z', represent?

According to the text, how does the speed of sound in solids generally compare to the speed of sound in liquids and gases?

The derivation of the speed of sound from a pressure pulse (Figure 3.1) assumes the flow process is of what nature?

In a two-phase mixture of gas and solid particles, the effective ratio of specific heats, γ, is given by the formula (Cp + mC) / (Cv + mC). What does the term 'm' represent in this context?

What physical property of a solid is used in the formula c = sqrt(E/ρ) to represent its elastic properties for calculating the speed of sound?

Calculate the speed of sound in a solid structural steel with a Young's Modulus (E) of 160 x 10^9 N/m^2 and a density (ρ) of 7860 Kg/m^3.

The derivation for the speed of sound c^2 = dP/dρ can be obtained from the energy equation. What other fundamental equation can also be used to derive the same result?

When calculating the speed of sound in a real gas, the coefficient 'n' is used in the relation P/ρ^n = constant. The text defines n as k * [(z + T(∂z/∂T)ρ) / (z + T(∂z/∂T)P)]. Under what condition does 'n' approach the value of 'k'?

Why is it important for engineers to understand the speed of sound in non-pure substances, such as air with particles, as highlighted in the Motivation section of the chapter?

Which of the following substances listed in Table 3.3 has the highest speed of sound?

The speed of sound in a real gas can be calculated as c = sqrt(znRT). An engineer is working with air at 30 degrees Celsius and atmospheric pressure, for which k=1.407, z=0.995, and n=1.403, with R=287 J/kg/K. What is the approximate speed of sound?

In a mixture of gas with a small amount of liquid droplets, the mixture isentropic relationship is given as P * T^((1-γ)/γ) = constant. How is the effective gamma (γ) for the mixture defined?

What is the average bulk modulus of water given as an example in the text?

When analyzing a two-phase mixture, the text assumes that the two materials are homogeneously mixed and that two other transport phenomena do NOT occur between the particles. What are these two phenomena?

Which liquid listed in Table 3.2 has the lowest speed of sound?

In the derivation of the speed of sound, a control volume is attached to a pressure pulse. What is the velocity of the gas entering the control volume from the right, relative to the control volume itself?

The speed of sound in a perfect gas is given by c = sqrt(kRT). If the temperature of the gas is quadrupled, how does the new speed of sound compare to the old one?

What is the primary reason that a correction factor 'z' (compressibility factor) is needed for real gases but not for ideal gases?

The speed of sound is generally defined in physical terms as the square root of the ratio of two properties of the medium. What are these two properties?

Which of the following materials listed in Table 3.3 has a speed of sound closest to 5100 m/s?

What is the main reason provided in the text for the limited discussion about the speed of sound outside of ideal gases in traditional compressible flow classes?

In the analysis of a two-phase medium, what does the approximation ρ/ρ_a = 1 + m apply to?

What happens to the correction factor in Example 3.3 for the time it takes sound to travel through a linearly varying temperature field as the temperature difference between points A and B approaches zero (TB -> TA)?

In summary, the text states that the speed of sound in liquids is about how many times relative to the speed of sound in gases?

When analyzing the speed of sound for a real gas, which thermodynamic function is used to begin the derivation that relates enthalpy, entropy, and pressure (Tds = dh - dP/ρ)?

What is the speed of sound in rubber as listed in Table 3.3?

In Example 3.2, the speed of sound in water vapor at 20 bar and 350 degrees C is calculated. The ideal gas assumption yields a result of 771.5 m/sec. How does this compare to the value estimated from the steam tables?

For a two-phase mixture of gas and solid particles, the effective gas constant for the mixture, R_mix, is implicitly defined by the equation P/ρ = R_mix * T. How does R_mix relate to the gas constant of the pure gas, R?

What is the general trend for the speed of sound in fresh water as the temperature increases from 0 degrees Celsius to 34 degrees Celsius?

What is the key assumption made about the pressure pulse in the derivation of the speed of sound?

The text mentions Wilson's empirical formula for the speed of sound in sea water, c(S, T, P). What three parameters does this formula depend on?

According to the analysis in Section 3.4, a change in which property can have a 'dramatical change' on the speed of sound for a real gas, especially at moderate pressure but low temperature?

In the analysis of a two-phase medium like gas with dust, the equation P/ρ_a^k = constant is used. What does ρ_a represent?

What is the primary physical reason the situation with sound speed in solids is 'considerably more complicated' than in liquids or gases?

Which of the following materials from Table 3.3 has a speed of sound value for its longitudinal wave of 5790 m/s?

For an ideal gas, the pressure can be expressed as P = constant * ρ^k. What does this relationship describe?

What is the speed of sound in Mercury as listed in Table 3.2?

At what condition does the compressibility factor 'z' in Figure 3.3 equal 1?

Why does the text state that 'one language is not enough today' in a footnote in the motivation section?

What is the speed of sound in Glycerol as listed in Table 3.2?

The text states that the speed of sound in a solid is dependent on geometry and can have different values for transverse and longitudinal waves. For steel, what is the speed of the transverse shear wave listed in Table 3.3?

In the analysis of sound speed in a two-phase medium, what does the variable ξ (xi) represent?

Calculate the speed of sound in a liquid with a bulk modulus (B) of 2.2 x 10^9 N/m^2 and a density (ρ) of 1000 kg/m^3.

In the derivation of the speed of sound from a moving piston, what term is neglected in Equation (3.3) to arrive at Equation (3.4)?