Complete the following table for refrigerant-134a. If the quality is not defined for a current phase (for example, comp...
Complete the following table for refrigerant-134a: P psia 70 h Btu/lbmm 64 TOF Phase description 20 10 0.7 70 180 128.8 110 1.0
Complete the following table for refrigerant-134a; TF Ppsia h Btu/Ibm 64 Phase Description 70 0.7 70 180 128.77 110
ROBLEM 2: 3–26 Complete this table for refrigerant-134a: TOC P, kPa & m²/kg Phase description saturated 0.007644 liquid 320 (x=0) super heated 10 0.0065 (x2.11725) 850 0.02LOGI Saturated vapor 600 - 4 ५५.४१ 33:45 Oxco 90
1. (48 pts) Complete this table for water. Input 'not applicable' in the quality 'x' column if water is not at saturated state. Possible phases for the 'phase description' column are 'compressed iquid', 'saturated liquid', saturated mixture, ‘saturated vapor, and ‘superheated vapor, TC C) P (kPa) h(kJ/kg) Phase description 90 0.A 100 0.7 105 275 200 60,000 200 100 200 1823 200 2803.0
Question 1 Complete the following table for R-134a T. °C P, kPa 34 v, m2 /kg 0.019 x % Phase description Saturated mixture 280 110 700 1 Saturated vapor Superheated
Complete the following table for Refrigerant-134a. Use data from the steam tables. T,°C P, kPa u kJ/kg 20 95 -12 Phase description (Click to select) Saturated liquid (Click to select) (Click to select) 300 400 600 8
if the sufficient data are provided complete the blank cells in the following table Problem 2: Complete this table for H2O: T,°C P, kPa h, kJ/kg Phase description 200 950 800 0.7 140 1800 0.0 80 500 3162.2 Problem 3: If sufficient data are provided, complete the blank cells in the following table of properties of water. In the last column describe the condition of water as compressed liquid, saturated mixture, superheated vapor, or insufficient information; and if applicable give...
A vapor compression refrigeration cycle utilizes R-134a as the working fluid. The refrigerant flow rate is 50 g/s. Vapor at 150 kPa and -10 °C enters the compressor and leaves at 1.2 MPa and 75 °C. The power input to the non-adiabatic compressor is measured and found to be 2.4 kW. The refrigerant enters the expansion valve at 1.15 MPa and 40 °C and leaves the evaporator at 160 kPa and -15 °C. Determine the entropy generation in the compression...