Required information $($Just Answer the one that is wrong$)$

Problem $03\mathrm{.}093-$ Carbon dioxide gas

Carbon dioxide gas enters a pipe at $3$ MPa and $500$ K at a rate of $2\mathrm{.}000k\frac{g}{s}.C{O}_2$ is cooled at

constant pressure as it flows in the pipe, and the temperature of the $C{O}_2$ drops to $450$ K at the

exit. The gas constant, the critical pressure, and the critical temperature of $C{O}_2$ are

$R=0\mathrm{.}1889$kPa$*\frac{m^3}{k}g*K,T_{cr}=304\mathrm{.}2K,$ and $P_{cr}=7\mathrm{.}39$MPa. Use data from the tables.

roblem $03\mathrm{.}093.$c $-$ Percent errors for carbon dioxide flow

etermine the error involved in the first case. $($Round the final answer to three decimal places.$)$

percentage error for volume flow rate at the inlet is

$\%.$

percentage error for density at the inlet is

$\%.$

e percentage error for volume flow rate at the outlet is Problem $03\mathrm{.}093.$b $-$ Carbon dioxide flow using Z

Determine the volume flow rate and the density of carbon dioxide at the inlet and the volume flow rate at the exit of the

pipe using the compressibility charts.

The volume flow rate at the inlet is

The density of carbon dioxide at the inlet is

The volume flow rate at the outlet is

$\frac{m^3}{s}.($Round the final answer to three decimal places.$)$

$o.k\frac{g}{m^3}.$

$\frac{m^3}{s}.($Round the final answer to three decimal places.$)$ Required information

Problem $03\mathrm{.}093-$ Carbon dioxide gas

Carbon dioxide gas enters a pipe at $3$ MPa and $500$ K at a rate of $2\mathrm{.}000k\frac{g}{s}.C{O}_2$ is cooled at

constant pressure as it flows in the pipe, and the temperature of the $C{O}_2$ drops to $450$ K at the

exit. The gas constant, the critical pressure, and the critical temperature of $C{O}_2$ are

$R=0\mathrm{.}1889$kPa$*\frac{m^3}{k}g*K,T_{cr}=304\mathrm{.}2K,$ and $P_{cr}=7\mathrm{.}39$MPa. Use data from the tables.

Problem $03\mathrm{.}093.$a $-$ Carbon dioxide flow

Determine the volume flow rate and the density of carbon dioxide at the inlet and the volume flow rate at the exit of the

pipe using the ideal$-$gas equation.

The volume flow rate at the inlet is

The density of carbon dioxide at the inlet is

The volume flow rate at the outlet is