a) Write Bernoulli´s equation in terms of: Energy, heat and pressure for streamline flow. b) Write...

Discuss all the different heads (including losses) in Bernoulli energy equation defining all terms with their...

Discuss all the different heads (including losses) in Bernoulli energy equation defining all terms with their units?

The Bernoulli equation is a consequence of A) Conservation of energy B) Conservation of momentum C)...

The Bernoulli equation is a consequence of A) Conservation of energy B) Conservation of momentum C) Conservation of mass D) Conservation of charge

1) An isentropic flow: a) has no heat transfer, b) does not allow temperature to change,...

1) An isentropic flow: a) has no heat transfer, b) does not allow temperature to change, c) can occur in a real physical problem, d) can only occur when the fluid is at rest. 2) Based on the first law of thermodynamics (assuming no chemical reactions, i.e. just a simple gas like air or helium): a) changing the flow velocity can heat the flow, b) moving a solid body through a fluid can heat the fluid, c) compressing a perfectly...

Observe a fluid flow to which conservation of mass, energy equations, and/or Bernoulli’s equation may be...

Observe a fluid flow to which conservation of mass, energy equations, and/or Bernoulli’s equation may be applied. Use that observation to write and solve your own “homework-style” problem that analyzes a flow or designs something that flows. I recommend you choose something that you can observe and estimate sizes, mass or volume flow rates, velocities, etc. Use tools in chapter 5, including conservation of mass, energy equations, and/or Bernoulli equation.

Write down the conservation of energy equation for heat when a mass of aluminium (Al), at...

Write down the conservation of energy equation for heat when a mass of aluminium (Al), at a temperature of 100℃ (T1), is added to a copper (Cu) container holding some cool water, at a temperature (T2). Underneath each term indicate the process involved, e.g. aluminium block cools (Q1), cool water warms (Q2) and copper container warms (Q3). Your equation must contain all these variables mwater,mCu, mAl cwater, cCu and cAl; the initial temperatures T1 and T2; and the final equilibrium...

Saturated steam at a gauge pressure of 3.00 bar is to be used to heat a...

Saturated steam at a gauge pressure of 3.00 bar is to be used to heat a stream of ethane. The ethane enters a heat exchanger at 16°C and 1.5 bar gauge pressure at a rate of 895 m3/min and is heated at constant pressure to 93°C. The steam condenses and leaves the exchanger as a liquid at 24.0°C. The specific enthalpy of ethane at the given pressure is 941 kJ/kg at 16°C and 1073 kJ/kg at 93°C.   You may take...

For each case below, list the assumptions that are applicable. Indicate which of (a) continuity equation,...

For each case below, list the assumptions that are applicable. Indicate which of (a) continuity equation, (b) Euler’s equation, (c) Bernoulli’s equation, (d) energy equation, (e) isentropic relations, and/or (f) equation of state would be most appropriate to use to find the discharge velocity (more than one may apply). Defend your choice(s) by explaining how each equation fits the assumptions stated and how each would be used to solve the problem. Only include the information requested—do not attempt to solve...

(a)What equation gives the wavelength of a particle? (b) What equation gives the energy of the...

(a)What equation gives the wavelength of a particle? (b) What equation gives the energy of the n=4 level of the hydrogen atom? In your equation write RH as RH. (c) What is the equation for the frequency of light when the Hydrogen atom makes a transition from n=4 to n=2? Evaluate everything but RH and h. Thank you so much!

When doing an adiabatic flash calculation for a continuous flow process where a liquid at high...

When doing an adiabatic flash calculation for a continuous flow process where a liquid at high pressure is “flashed” to lower pressure to produce a mixture of gas and liquid you know: Inlet: Temperature (T1), Pressure (P1), molar flowrate (F) and mole fractions (zi). Outlet: Pressure (P2) For this adiabatic flash: a) Draw a picture and clearly label the unknown variables b) Write down the equations (in terms of the above variables) that you would have to solve in order...

(a) Write a balanced chemical equation that shows dissolving AgCl(s) in water. (b) Write K expression...

(a) Write a balanced chemical equation that shows dissolving AgCl(s) in water. (b) Write K expression for (a). Note this K is also called Ksp AgCl(s)!!! (c) AgCl according to solubility rule is insoluble. Knowing this, do you expect Ksp to be large or small? Explain. (d) Draw an ICE table for the equation you have for (a). Assume you have “some” AgCl(s), fill in the ICE table, and show how it relates to Ksp. Do not solve for anything....