can you draw a t-s diagram for this actual regenerative rankine cycle

Elements Of Electromagnetics
7th Edition
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Sadiku, Matthew N. O.
ChapterMA: Math Assessment
Section: Chapter Questions
Problem 1.1MA
icon
Related questions
Question

can you draw a t-s diagram for this actual regenerative rankine cycle

 

State 7s
P₁ = PL= 30 kPa
S75 = S6a
According to Table A5, when pressure of 30 kPa
Sf= 0.9441 kj/kg k
Sfg= 6.8234 kj/kg k
Sg- 7.7675 kj/kg k
hf=289.27 kj/kg
hfg=2335.3 kj/kg
hg=2624.6 kj/kg
Since S7s is less than Sg and larger than Sg at the pressure of 30 kPa, the status at 7s is saturated
mixture.
X7s =
= 7.8224 kJ/kg
X7a =
S7s-Sf 7.8224 0.9441
Sfg
y =
h7s = hf+X7shfg=289.27 +1.008x2335.3 = 2643.25
State 7a
6.8234
P₁ = PL= 30 kPa
hja
=h6a-(hoa-h7s)x nisen turb = 3707.45-(3707.45-2643.25)x0.86=2792.28 kJ/kg
Since h7a is less than hg and larger than hf at the pressure of 30 kPa, the stats at 7a is saturated mixture.
h7a-hf 2792.28 289.27
hfg
Wout=(
= 1.008
2335.3
h3-h₂a 908.47 291.50
h6а-h2а 3707.45 291.50
-=1.07
=0.180
Checking if Wnet=Qnet
Qin 2509.39 kJ/k
Qout = (1-y) ( h-a-h₁) = (1 − 0.180)( 2792.28-289.27) = 2052.46 kJ/kg
Win=(1-y)(
h₂a-h₁)+(h4a-h3)= (1-0.180) (291.50 -289.27)+(913.701-908.47)=7.059 kj/kg
h5-h6a)+(1 - y) (hoa-h7a)= (3423.1-3414.38 )+(1-0.80)(3707.45-2792.28)=759 kJ/kg
Qnet-lin-Qout-2509.39-2052.46-456.93
Transcribed Image Text:State 7s P₁ = PL= 30 kPa S75 = S6a According to Table A5, when pressure of 30 kPa Sf= 0.9441 kj/kg k Sfg= 6.8234 kj/kg k Sg- 7.7675 kj/kg k hf=289.27 kj/kg hfg=2335.3 kj/kg hg=2624.6 kj/kg Since S7s is less than Sg and larger than Sg at the pressure of 30 kPa, the status at 7s is saturated mixture. X7s = = 7.8224 kJ/kg X7a = S7s-Sf 7.8224 0.9441 Sfg y = h7s = hf+X7shfg=289.27 +1.008x2335.3 = 2643.25 State 7a 6.8234 P₁ = PL= 30 kPa hja =h6a-(hoa-h7s)x nisen turb = 3707.45-(3707.45-2643.25)x0.86=2792.28 kJ/kg Since h7a is less than hg and larger than hf at the pressure of 30 kPa, the stats at 7a is saturated mixture. h7a-hf 2792.28 289.27 hfg Wout=( = 1.008 2335.3 h3-h₂a 908.47 291.50 h6а-h2а 3707.45 291.50 -=1.07 =0.180 Checking if Wnet=Qnet Qin 2509.39 kJ/k Qout = (1-y) ( h-a-h₁) = (1 − 0.180)( 2792.28-289.27) = 2052.46 kJ/kg Win=(1-y)( h₂a-h₁)+(h4a-h3)= (1-0.180) (291.50 -289.27)+(913.701-908.47)=7.059 kj/kg h5-h6a)+(1 - y) (hoa-h7a)= (3423.1-3414.38 )+(1-0.80)(3707.45-2792.28)=759 kJ/kg Qnet-lin-Qout-2509.39-2052.46-456.93
CALCULATIONS
State 1:
Status: Saturated Liquid
P₁ = P₁= 30 kPa
L=
From Table A5 when P₁ = 30 kPa
v1=vf=0.001022 m³/kg
hl=hf=289.27 kJ/kg
State 2a:
Status: Compressed liquid
P2s PI=2000 kPa
h₂a=h₁+
State 3
State 4a
v_1 (p_2-p_1)
nisen pump
Status: Saturated liquid
P3-PI=2000 kpa
From Table A5, When P3= 2000 kPa and
h3=hf 908.47 kJ/kg
V3 vf 0.001177 m³/k
Pa = PH=6000kPa
hдa
=
= 289.27 +
h4a = h3 +
913.701 kPa
0.001022x (2000-30)
v3 (P4 - P3)
nisen pump
0.9
= 908.47 +
= 291.50 kJ/kg
0.001177x(6000 - 2000)
0.9
= 913.701
State 5
Status: Superheated Steam
P5 = P₁= 6000 kPa
Ts=Tr = 500
From Table A6 when P5 = 6000 kPa and T5 = 500 °C
h5
= 3423.1 kJ/kg
S5
6.8826 kJ/kg xk
Qin h5 -h4a=3423.1-913.701= 2509.39 kJ/Kg
=
=
State 6s
Pos= P₁= 2000 kPa
1=
$65 = S5 = 6.8826 kJ/kg
Since S6s is larger than Sf at the pressure of 2000 kPa, the status at S6s is superheated steam
By interpolation at S6s-6.8826 from table A6
hos
State 6a
(6.8826-6.7684)
(6.95883-6.7684)
Poa P₁= 2000 kPa
hoa
=
x(3137.7 – 3024.2) + 3024.2= 3092.45
(h5-h6s)x nisen pump =
3423.1+(3423.1-3092.45)x 0.86= 3707.45 kJ/kg
Since ha is larger than h at a preassure of 2000kpa, the status at háa is superheated
By interpolation at hoa = 3707.45 kJ/kg from table A6
S6a (3707.045-3693.9)/(3920.5-3693.9)x (8.0558-7.8101)+7.8101= 7.824 kJ/kg K
Transcribed Image Text:CALCULATIONS State 1: Status: Saturated Liquid P₁ = P₁= 30 kPa L= From Table A5 when P₁ = 30 kPa v1=vf=0.001022 m³/kg hl=hf=289.27 kJ/kg State 2a: Status: Compressed liquid P2s PI=2000 kPa h₂a=h₁+ State 3 State 4a v_1 (p_2-p_1) nisen pump Status: Saturated liquid P3-PI=2000 kpa From Table A5, When P3= 2000 kPa and h3=hf 908.47 kJ/kg V3 vf 0.001177 m³/k Pa = PH=6000kPa hдa = = 289.27 + h4a = h3 + 913.701 kPa 0.001022x (2000-30) v3 (P4 - P3) nisen pump 0.9 = 908.47 + = 291.50 kJ/kg 0.001177x(6000 - 2000) 0.9 = 913.701 State 5 Status: Superheated Steam P5 = P₁= 6000 kPa Ts=Tr = 500 From Table A6 when P5 = 6000 kPa and T5 = 500 °C h5 = 3423.1 kJ/kg S5 6.8826 kJ/kg xk Qin h5 -h4a=3423.1-913.701= 2509.39 kJ/Kg = = State 6s Pos= P₁= 2000 kPa 1= $65 = S5 = 6.8826 kJ/kg Since S6s is larger than Sf at the pressure of 2000 kPa, the status at S6s is superheated steam By interpolation at S6s-6.8826 from table A6 hos State 6a (6.8826-6.7684) (6.95883-6.7684) Poa P₁= 2000 kPa hoa = x(3137.7 – 3024.2) + 3024.2= 3092.45 (h5-h6s)x nisen pump = 3423.1+(3423.1-3092.45)x 0.86= 3707.45 kJ/kg Since ha is larger than h at a preassure of 2000kpa, the status at háa is superheated By interpolation at hoa = 3707.45 kJ/kg from table A6 S6a (3707.045-3693.9)/(3920.5-3693.9)x (8.0558-7.8101)+7.8101= 7.824 kJ/kg K
Expert Solution
steps

Step by step

Solved in 3 steps with 3 images

Blurred answer
Follow-up Questions
Read through expert solutions to related follow-up questions below.
Follow-up Question

can you provided with a schematic of this cycle with data provided 

Solution
Bartleby Expert
SEE SOLUTION
Knowledge Booster
Power Plant Engineering
Learn more about
Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, mechanical-engineering and related others by exploring similar questions and additional content below.
Recommended textbooks for you
Elements Of Electromagnetics
Elements Of Electromagnetics
Mechanical Engineering
ISBN:
9780190698614
Author:
Sadiku, Matthew N. O.
Publisher:
Oxford University Press
Mechanics of Materials (10th Edition)
Mechanics of Materials (10th Edition)
Mechanical Engineering
ISBN:
9780134319650
Author:
Russell C. Hibbeler
Publisher:
PEARSON
Thermodynamics: An Engineering Approach
Thermodynamics: An Engineering Approach
Mechanical Engineering
ISBN:
9781259822674
Author:
Yunus A. Cengel Dr., Michael A. Boles
Publisher:
McGraw-Hill Education
Control Systems Engineering
Control Systems Engineering
Mechanical Engineering
ISBN:
9781118170519
Author:
Norman S. Nise
Publisher:
WILEY
Mechanics of Materials (MindTap Course List)
Mechanics of Materials (MindTap Course List)
Mechanical Engineering
ISBN:
9781337093347
Author:
Barry J. Goodno, James M. Gere
Publisher:
Cengage Learning
Engineering Mechanics: Statics
Engineering Mechanics: Statics
Mechanical Engineering
ISBN:
9781118807330
Author:
James L. Meriam, L. G. Kraige, J. N. Bolton
Publisher:
WILEY