This paper presents an evaluation process efficiency based on the consumption of primary energy for all types of practical desalination methods available hitherto. The conventional performance ratio has, thus far, been defined with respect to the consumption of derived energy, such as the electricity or steam, which are susceptible to the conversion losses of power plants and boilers that burned the input primary fuels. As derived energies are usually expressed by the units, either kWh or Joules, these units cannot differentiate the grade of energy supplied to the processes accurately. In this paper, the specific energy consumption is revisited for the efficacy of all large-scale desalination plants. In today's combined production of electricity and desalinated water, accomplished with advanced cogeneration concept, the input exergy of fuels is utilized optimally and efficiently in a temperature cascaded manner. By discerning the exergy destruction successively in the turbines and desalination processes, the relative contribution of primary energy to the processes can be accurately apportioned to the input primary energy. Although efficiency is not a law of thermodynamics, however, a common platform for expressing the figures of merit explicit to the efficacy of desalination processes can be developed meaningfully that has the thermodynamic rigor up to the ideal or thermodynamic limit of seawater desalination for all scientists and engineers to aspire to.

1.
M. A. K.
Al-Sofi
,
Desalination
126
,
61
(
1999
).
2.
J. E.
Miller
, SAND Report No. 0800,
2003
.
3.
5.
M. A.
Eltawil
,
Z.
Zhengming
, and
L.
Yuan
, in
Twelfth International Water Technology Conference, IWTC12 2008 Alexandria, Egypt
(
2008
).
6.
A. N.
Mabrouk
and
H. E. S.
Fath
,
Desalination
371
,
115
(
2015
).
7.
R. S.
Silver
,
Proc. Inst. Mech. Eng.
179
,
135
(
1964
).
8.
H. C.
Simpson
and
R. S.
Silver
,
National Academy of Sciences
(
National Research Council Publication
,
1963
), Vol.
942
, p.
387
.
9.
Y.
Cerci
,
Y.
Cengel
,
B.
Wood
,
N.
Kahraman
, and
E. S.
Karakas
, “
Desalination and water purification research and development program final report no. 78
,” Agreement No. 99-FC-81-0183, US Department of Interior, Bureau of Reclamation,
2003
.
10.
M.
Elimelech
and
W. A.
Phillip
,
Science
333
,
712
(
2011
).
11.
S.
Mrayed
,
D.
Maccioni
, and
G.
Leslie
,
Int. J. Chem., Mol., Nucl., Mater. Metall. Eng.
7
,
991
(
2013
).
12.
A.
Al-Karaghouli
and
L. L.
Kazmerski
,
Renewable Sustainable Energy Rev.
24
,
343
(
2013
).
13.
M. M.
Alhazmy
,
Desalination
214
,
102
(
2007
).
14.
K. H.
Mistry
and
J. H.
Lienhard
,
Entropy
15
,
2046
(
2013
).
15.
K. C.
Smith
and
R.
Dmello
,
J. Electrochem. Soc.
163
,
A530
(
2016
).
16.
Y.
Cerci
,
Y. A.
Cengel
, and
B.
Wood
,
ASME AES
39
,
545
(
1999
).
17.
R.
Kempton
,
D.
Maccioni
,
S. M.
Mrayed
, and
G.
Leslie
,
Water Sci. Technol.: Water Supply
10
,
416
(
2010
).
18.
D. S.
Sholl
and
R. P.
Lively
,
Nature
532
,
435
(
2016
).
19.
K. S.
Spiegler
and
Y. M.
El-Sayedb
,
Desalination
134
,
109
(
2001
).
20.
N. L.
Le
and
S. P.
Nunes
,
Sustainable Mater. Technol.
7
,
1
(
2016
).
21.
M. A.
Darwish
and
A. A.
El-Hadik
,
Desalination
60
,
251
(
1986
).
22.
H.
El-Dessoukey
,
H. I.
shaban
, and
H.
Al-Ramadan
,
Desalination
103
,
271
(
1995
).
23.
O. A.
Hamed
and
S.
Aly
,
Desalination
80
,
1
(
1991
).
24.
C. D.
Honburg
and
B. M.
Walson
,
Desalination
92
,
331
(
1993
).
25.
26.
27.
H.
El-Dessoukey
,
H. I.
Shaban
, and
H.
Al-Ramadan
,
Desalination
103
,
253
(
1995
).
28.
F.
Kafi
,
V.
Renaudin
,
D.
Alonso
, and
J. M.
Hornut
,
Desalination
166
,
53
(
2004
).
30.
31.
S. C.
Kaushika
,
V.
Siva Reddya
, and
S. K.
Tyagi
,
Renewable Sustainable Energy Rev.
15
,
1857
(
2011
).
33.
Y.
Wang
and
N.
Lior
,
Desalination
196
,
84
(
2006
).
34.
35.
M. A.
Darwish
,
H. K.
Abdulrahim
, and
A. B.
Amer
,
Energy
33
,
571
(
2008
).
36.
M. A.
Darwish
and
A. B.
Amer
,
Energy
14
,
275
(
2014
).
37.
M. W.
Shahzad
,
M.
Burhan
,
L.
Ang
, and
K. C.
Ng
,
Desalination
413
,
52
(
2017
).
39.
A.
Hussain
,
A.
Woldai
,
A.
Al-Radif
,
A.
Kesou
,
R.
Borsani
,
H.
Sultan
, and
P. B.
Deshpandey
,
Desalination
97
,
555
(
1994
).
40.
A. M.
Helal
,
M. S.
Medani
, and
M. A.
Soliman
,
Comput. Chem. Eng.
10
,
327
(
1986
).
41.
M.
Rasso
,
A.
Beltramini
,
M.
Mazzotti
, and
M.
Morbidelli
,
Desalination
108
,
335
(
1996
).
43.
R.
Rautenbach
and
B.
Arzt
,
Desalination
52
,
105
(
1985
).
44.
N.
Kahraman
and
Y. A.
Cengel
,
Energy Convers. Manage.
46
,
2625
(
2005
).
45.
J.
Ji
,
R.
Wang
,
L.
Li
, and
H.
Ni
,
Chem. Eng. Technol.
30
,
1633
(
2007
).
46.
M. A.
Sanz
, WEX,
2012
.
47.
M.
Al-Shammiri
and
M.
Safar
,
Desalination
126
,
45
(
1999
).
48.
J.
Tonner
,
Desalination and Water Purification Research and Development Program Report
(
US Department of the Interior
,
2008
).
49.
Economic and Social Commission for West Asia
,
Water Desalination Technologies in the ESCWA Member Countries
(
ESCWA
,
UN
,
2001
).
51.
R.
Borsani
and
S.
Rebagliati
,
Desalination
182
,
29
(
2005
).
52.
J. E.
Blank
,
G. F.
Tusel
, and
S.
Nisan
,
Desalination
205
,
298
(
2007
).
53.
IRENA
. “
Water desalination using renewable energy
,” IEA-ETSAP and IRENA Technology Brief, Report No. 112,
2012
.
54.
K. C.
Ng
and
M. W.
Shahzad
, in
International Conference on Sustainable Energy Technology
(
2016
).
55.
S.
Ihm
,
O. Y.
Najdi
,
O. A.
Hamed
,
G.
Jun
, and
H.
Chung
,
Desalination
397
,
116
(
2016
).
56.
R.
Lemes
,
J.
Talavera
,
R.
Falcon
,
R.
Arocha
,
J.
Curbelo
,
V.
Platas
,
L.
Lorenzo
, and
D.
Zarzo
, in
IDA World Congress
(
2011
).
57.
A.
Farooque
,
A.
Jamaluddin
,
A.
Al-Reweli
,
P.
Jalaluddin
,
S.
Al-Marwani
,
A.
Mobayed
, and
A.
Qasim
,
Desalination
219
,
137
(
2008
).
58.
N. Y.
Yip
,
A.
Tiraferri
,
W. A.
Phillip
,
J. D.
Schiffman
, and
M.
Elimelech
,
Environ. Sci. Technol.
44
,
3812
(
2010
).
59.
W. J.
Lau
,
S.
Gray
,
T.
Matsuura
,
D.
Emadzadeh
,
J. P.
Chen
, and
A. F.
Ismail
,
Water Res.
80
,
306
(
2015
).
60.
H.
Cooley
and
M.
Heberger
,
The World's Water
, Chap. 6 (
Pacific Institute
,
2013
).
61.
A.
Almutairi
,
P.
Pilidis
,
N.
Al-Mutawa
, and
M.
Al-Weshahi
,
Appl. Therm. Eng.
103
,
77
(
2016
).
62.
M. W.
Shahzad
and
K. C.
Ng
,
Nat. Middle East
(
2016
).
63.
A.
Li
,
K.
Thu
,
A.
Bin Ismail
,
M. W.
Shahzad
, and
K. C.
Ng
,
Int. J. Heat Mass Transfer
92
,
149
(
2016
).
64.
M. W.
Shahzad
,
K.
Thu
, and
K. C.
Ng
,
Environ. Sci.: Water Res. Technol.
2
,
206
(
2016
).
65.
B. B.
Saha
,
I. I.
El-Sharkawy
,
M. W.
Shahzad
,
K.
Thu
,
A.
Li
, and
K. C.
Ng
,
Appl. Therm. Eng.
97
,
68
(
2016
).
66.
M. W.
Shahzad
,
K.
Thu
,
Y. D.
Kim
, and
K. C.
Ng
,
Appl. Energy
148
,
273
(
2015
).
67.
M. W.
Shahzad
,
K.
Thu
,
K. C.
Ng
, and
W. G.
Chun
,
Desalin. Water Treat.
57
,
7396
(
2016
).
68.
M. W.
Shahzad
,
A.
Myat
,
W. G.
Chun
, and
K. C.
Ng
,
Appl. Therm. Eng.
50
,
670
(
2013
).
69.
K. C.
Ng
,
K.
Thu
,
S. J.
Oh
,
A.
Li
,
M. W.
Shahzad
, and
A. B.
Ismail
,
Desalination
356
,
255
(
2015
).
70.
M. W.
Shahzad
,
K. C.
Ng
,
K.
Thu
,
B. B.
Saha
, and
W. G.
Chun
,
Appl. Therm. Eng.
72
,
289
(
2014
).
71.
K. C.
Ng
,
K.
Thu
,
M. W.
Shahzad
, and
W. G.
Chun
,
Int. Desalin. Assoc. J. Water Desalin. Reuse
6
,
44
(
2014
).
72.
N.
Wang
,
X.
Li
,
L.
Wang
,
L.
Zhang
,
G.
Zhang
, and
S.
Ji
,
ACS Appl. Mater. Interfaces
8
,
21979
(
2016
).
73.
A.
Chakraborty
,
K. C.
Leong
,
K.
Thu
,
B. B.
Saha
, and
K. C.
Ng
,
Appl. Phys. Lett.
98
,
221910
(
2011
).
74.
T. M.
Missimer
,
K. C.
Ng
,
K.
Thuw
, and
M. W.
Shahzad
,
Desalin. Water Treat.
57
,
23110
(
2016
).
75.
Y.-D.
Kim
,
K.
Thu
,
K. C.
Ng
,
G. L.
Amy
, and
N.
Ghaffour
,
Water Res.
100
,
7
(
2016
).
76.
N.
Ghaffour
,
S.
Lattemann
,
T.
Missimer
,
K. C.
Ng
,
S.
Sinha
, and
G.
Amy
,
Appl. Energy
136
,
1155
(
2014
).
77.
T. M.
Missimer
,
Y.-D.
Kim
,
R.
Rachman
, and
K. C.
Ng
,
Desalin. Water Treat.
51
,
1161
(
2013
).
You do not currently have access to this content.