(a)
Interpretation:
The pressure at states 1, 2, 3, and 4 should be determined.
Concept Introduction:
As per the 2nd rule of
(b)
Interpretation:
The quality
Concept Introduction:
As per the 2nd rule of thermodynamics, work is needed to transfer heat from a cold region to a hot region. A refrigeration system transfers the heat from the heat source (icebox) to the surrounding (kitchen). The operating mechanism of a refrigeration cycle was mathematically illustrated by Carnot as a heat engine in the year 1824.
(c)
Interpretation:
The heat addition per kg of fluid should be determined.
Concept Introduction:
As per the 2nd rule of thermodynamics, work is needed to transfer heat from a cold region to a hot region. A refrigeration system transfers the heat from the heat source (icebox) to the surrounding (kitchen). The operating mechanism of a refrigeration cycle was mathematically illustrated by Carnot as a heat engine in the year 1824.
(d)
Interpretation:
The heat rejection per kg of fluid should be determined.
Concept Introduction:
As per the 2nd rule of thermodynamics, work is needed to transfer heat from a cold region to a hot region. A refrigeration system transfers the heat from the heat source (icebox) to the surrounding (kitchen). The operating mechanism of a refrigeration cycle was mathematically illustrated by Carnot as a heat engine in the year 1824.
(e)
Interpretation:
The
Concept Introduction:
As per the 2nd rule of thermodynamics, work is needed to transfer heat from a cold region to a hot region. A refrigeration system transfers the heat from the heat source (icebox) to the surrounding (kitchen). The operating mechanism of a refrigeration cycle was mathematically illustrated by Carnot as a heat engine in the year 1824.
(f)
Interpretation:
The coefficient of performance ? for the cycle should be determined.
Concept Introduction:
As per the 2nd rule of thermodynamics, work is needed to transfer heat from a cold region to a hot region. A refrigeration system transfers the heat from the heat source (icebox) to the surrounding (kitchen). The operating mechanism of a refrigeration cycle was mathematically illustrated by Carnot as a heat engine in the year 1824.
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Chapter 9 Solutions
Loose Leaf For Introduction To Chemical Engineering Thermodynamics
- Use this equation to solve it.arrow_forwardQ1: Consider the following transfer function G(s) 5e-s 15s +1 1. What is the study state gain 2. What is the time constant 3. What is the value of the output at the end if the input is a unit step 4. What is the output value if the input is an impulse function with amplitude equals to 3, at t=7 5. When the output will be 3.5 if the input is a unit steparrow_forwardgive me solution math not explinarrow_forward
- Example (6): An evaporator is concentrating F kg/h at 311K of a 20wt% solution of NaOH to 50wt %. The saturated steam used for heating is at 399.3K. The pressure in the vapor space of the evaporator is 13.3 KPa abs. The 5:48 O Transcribed Image Text: Example (7): Determine thearrow_forward14.9. A forward feed double-effect vertical evaporator, with equal heating areas in each effect, is fed with 5 kg/s of a liquor of specific heat capacity of 4.18 kJ/kg K. and with no boiling point rise, so that 50 per cent of the feed liquor is evaporated. The overall heat transfer coefficient in the second effect is 75 per cent of that in the first effect. Steam is fed at 395 K and the boiling point in the second effect is 373 K. The feed is heated by an external heater to the boiling point in the first effect. It is decided to bleed off 0.25 kg/s of vapour from the vapour line to the second effect for use in another process. If the feed is still heated to the boiling point of the first effect by external means, what will be the change in steam consumption of the evaporator unit? For the purpose of calculation, the latent heat of the vapours and of the steam may both be taken as 2230 kJ/kgarrow_forwardExample(3): It is desired to design a double effect evaporator for concentrating a certain caustic soda solution from 12.5wt% to 40wt%. The feed at 50°C enters the first evaporator at a rate of 2500kg/h. Steam at atmospheric pressure is being used for the said purpose. The second effect is operated under 600mmHg vacuum. If the overall heat transfer coefficients of the two stages are 1952 and 1220kcal/ m2.h.°C. respectively, determine the heat transfer area of each effect. The BPR will be considered and present for the both effect 5:49arrow_forward
- العنوان ose only Q Example (7): Determine the heating surface area 개 required for the production of 2.5kg/s of 50wt% NaOH solution from 15 wt% NaOH feed solution which entering at 100 oC to a single effect evaporator. The steam is available as saturated at 451.5K and the boiling point rise (boiling point evaluation) of 50wt% solution is 35K. the overall heat transfer coefficient is 2000 w/m²K. The pressure in the vapor space of the evaporator at atmospheric pressure. The solution has a specific heat of 4.18kJ/ kg.K. The enthalpy of vaporization under these condition is 2257kJ/kg Example (6): 5:48 An evaporator is concentrating F kg/h at 311K of a 20wt% solution of NaOH to 50wt %. The saturated steam used for heating is at 399.3K. The pressure in the vapor space of the evaporator is 13.3 KPa abs. The 5:48 1 J ۲/۱ ostrarrow_forwardExample 8: 900 Kg dry solid per hour is dried in a counter current continues dryer from 0.4 to 0.04 Kg H20/Kg wet solid moisture content. The wet solid enters the dryer at 25 °C and leaves at 55 °C. Fresh air at 25 °C and 0.01Kg vapor/Kg dry air is mixed with a part of the moist air leaving the dryer and heated to a temperature of 130 °C in a finned air heater and enters the dryer with 0.025 Kg/Kg alry air. Air leaving the dryer at 85 °C and have a humidity 0.055 Kg vaper/Kg dry air. At equilibrium the wet solid weight is 908 Kg solid per hour. *=0.0088 Calculate:- Heat loss from the dryer and the rate of fresh air. Take the specific heat of the solid and moisture are 980 and 4.18J/Kg.K respectively, A. =2500 KJ/Kg. Humid heat at 0.01 Kg vap/Kg dry=1.0238 KJ/Kg. "C. Humid heat at 0.055 Kg/Kg 1.1084 KJ/Kg. "C 5:42 Oarrow_forwardQ1: From the Figure below for (=0.2 find the following 1. Rise Time 2. Time of oscillation 3. Overshoot value 4. Maximum value 5. When 1.2 which case will be? 1.6 1.4 1.2 12 1.0 |=0.8- 0.6 0.4 0.8 0.2- 0.6 0.4 0.2 1.2 = 1.0 0 2 4 6 8 10 10 t/Tarrow_forward
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