In an attempt to conserve water and to be awarded LEED (Leadership in Energy and
ID: 512246 • Letter: I
Question
In an attempt to conserve water and to be awarded LEED (Leadership in Energy and Environmental Design) certification, a 20.0 x 103 L cistern has been installed during construction of a new building. The cistern collects water from an HVAC (heating, ventilation and air-conditioning) system that is designed to provide 1.00 x 105 ft3/min air at 22.0°C and 40.0% relative humidity after converting it from ambient conditions (31.0°C, 86.0% relative humidity). The collected condensate serves as the source of water for lawn maintenance. Assume P = 1 atm. a. Estimate the intake of air at ambient conditions in cubic feet per minute. b.Estimate the hours of operation required to fill the cistern.
Explanation / Answer
#1. Given,
At 220C, the properties of conditioned air are-
Flowrate = 1.00 x 105 ft3/ min ; [1 ft3 = 28.3168 L]
= 1.00 x 105 x (28.3168L) / min
= 2.83168 x 106 L
#2. Let the intake at 310C = X liters/ min.
So, volume of air flowing per minutes = X liters
Moisture content = 86.0 % of X L = 0.86X L
Dry (some moisture removed) air content = X L – 0.86 X L = 0.14 L
#3. Volume of released air at 310C can be given by Charles’ law
(V1/ T1) = (V2/ T2) - equation 1
Where, V1 and T1 are for 310C (= 304.15 K); V2 and T2 are for 220C (295.15K).
Putting the values in equation 1-
(V1 / 304.15 K) = 1.00 x 105 ft3 / 295.15 K
Or, V1 = (1.00 x 105 ft3 / 295.15 K) x 304.15 K = 1.03049 x 105 ft3
That is, the volume of same exhaled air (1.0 x 105 ft3, per minute, at 220C) is equal to 1.03049 x 105 ft3 at 330C.
Now, during condensation, only water is removed. So, after removing water, the volume of dry gas and 40% RH is equal to 1.03727 x 105 ft3.
0.14X ft3 + 40% relative humidity of 0.14X ft3 = 1.03049 x 105 ft3
Or, 0.14 X ft3 + 0.056 X ft3 = 1.03049 x 105 ft3
Or, 0.196X ft3 = 1.03049 x 105 ft3
Or, X = (1.03049 x 105 ft3) / 0.196 = 5.26 x 105 ft3
Therefore, intake per minute at 310C = 5.26 x 105 ft3
#4. Volume of moisture removed =
Volume of intake air at 310C – Volume of exhausted air at 310C
= 5.26 x 105 ft3 – 1.03049 x 105 ft3
= 4.23 x 105 ft3
= 4.23 x 105 (28.3168 L)
= 1.21 x 107 L
Assuming moisture behave ideally at 310C, calculate the moles of water vapor condensed using ideal gas equation-
Using Ideal gas equation: PV = nRT - equation 2
Where, P = pressure in atm
V = volume in L
n = number of moles
R = universal gas constant= 0.0821 atm L mol-1K-1
T = absolute temperature (in K)
Putting the values for amount of moisture removed at 220C-
1.00 atm x 1.21 x 107 L = n x (0.0821 atm L mol-1K-1) x 304.15 K
Or, n = 1.21 x 107 L atm L / 24.970715 atm L mol-1
Or, n = 484567.62 mol
Thus, during conditioning, 484567.62 mol water is removed.
Mass of water removed = moles x molar mass
= 484567.62 mol mol x (18.0 g/ mol)
= 8722217.16 g
= 8722.22 kg
Assuming density of water to be 1.00 kg/ L at through the temperatures (310C to 220C), the volume of liquid water condensed in the cistern is given by-
Volume of water condensed = Mass of moisture removed x density of water
= 8722.22 kg x (1.00 kg/ L)
= 8722.22 L
Therefore, rate of water condensation in cistern = 8722.22 L/ min
Time required to fill the cistern = Capacity of cistern/ rate of water condensation
= 20000 L/ (8722.22 L/ min)
= 2.29 min
= 0.0381 hr
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