Record yourself doing the following using Engineering Equation Solver $($EES$)$ software:

$1..$

Determine the following properties given the information below using the thermophysical properties functions. You must show the steps to calculations $(\backslash ($ i $\backslash ).$ Show the functions being created and then calculated$)$:

a$.$ Specific enthalpy $(\backslash (\backslash$mathrm$\{$kJ$\}/\backslash$mathrm$\{$kg$\}\backslash ))$ of $\backslash (\backslash$mathrm$\{$R$\}-134\backslash )$ a refrigerant at $\backslash (\backslash$mathrm$\{$T$\}=65^\{\backslash$circ$\}\backslash$mathrm$\{$C$\}\backslash )$ and $\backslash (\backslash$mathrm$\{$P$\}=200\backslash$mathrm$\{$kPa$\}\backslash )$

b$.$ Specific entropy $(\backslash (\backslash$mathrm$\{$kJ$\}/\backslash$mathrm$\{$kg$\}-\backslash$mathrm$\{$K$\}\backslash ))$ of water at $\backslash (\backslash$mathrm$\{$T$\}=350^\{\backslash$circ$\}\backslash$mathrm$\{$C$\}\backslash )$ and $\backslash (\backslash$mathrm$\{$x$\}=0\mathrm{.}85\backslash )$

c$.$ Phase of Ammonia at $\backslash (\backslash$mathrm$\{$P$\}=4000\backslash$mathrm$\{$kPa$\}\backslash )$ and $\backslash (220^\{\backslash$circ$\}\backslash$mathrm$\{$C$\}\backslash )$

$2.$

Plot the following power cycle on the T$-$s diagram of water and show the plot. Use the "Overlay plot function" on the "Property Plot" of water. $($The steps to creating an overlay plot are in the "EES demo" on Moodle$).$ For this exercise, you can begin recording after you create the lookup table of your Temperature and entropy values. You do not need to record all the initial calculations to determine entropy values.

a$.1-2$ Water is moved through an isentropic $($constant entropy$)$ pump where it begins as a saturated liquid at $10$ kPa and exits the pump at a pressure of $3$ MPa $.$

b$.2-3$ The water is boiled in a constant pressure process at $3$ MPa until it reaches a temperature of $\backslash (350^\{\backslash$circ$\}\backslash$mathrm$\{$C$\}\backslash ).$

c$.3-4$ The steam is expanded through an isentropic$($constant entropy$)$ turbine where it exits at a pressure of $10$ kPa $.$

d$.4-1$ The mixture is then cooled at constant pressure back to the conditions at state $1.$