|
Calculations
of Fuel Savings
Assume
that the feed water
consists of 60% condensate
and 40% make-up. By
recovering additional
condensate, the feed water
quality is improved,
resulting in a lower blow
down rate. The blow down
rate reduction and
corresponding fuel savings
can be calculated. Thus if
the additional recovery
results in a feed water of
67% condensate rather than
60%, the total alkalinity
will be reduced from 70
ppm to 58 ppm and we can
increase the feed water
concentration from 10 to
12. The blow down rate can
then be reduced from 10%
to 8-1/3%. The actual blow
down and feed water
requirement in pounds can
be calculated as follows:
Apply
the following equation to
determine reduction
savings:
Assume
a steam production of
1,000.000 lbs / day.
Where;
F
= feed water requirement
(lbs)
S
= steam generated
(lbs)
%
B D = percent blow
down, expressed as a
decimal.
|
At
10% blow down
F =
|
1,000,000
|
=
|
1,000,000
|
=
1,111,110 lbs.
|
|
1
- (0.10)
|
0.9
|
|
At 8-1/3% blow
down
F =
|
1,000,000
|
=
|
1,000,000
|
=
1,090,870 lbs.
|
|
1
- (0.0833)
|
0.9167
|
The
difference represents the
actual blow down
reduction:
1,111,110 lbs. –
1,090,870 lbs. = 20,240
lbs. reduction
Apply
the following equation to
determine the fuel costs
savings:
|
Br
* H
|
*
C = $Savings
|
|
V
* % E
|
Where:
Br
= blow down reductions
(lbs/day)
H
= heat content of blow
down (from Table II)
C
= cost of fuel
($/unit)
V
= heating value of
fuel (Btu/unit)
%
E = boiler
efficiency
Using
our former example and
burning No. 6 fuel oil
with a heating value of
142,440 Btu/gallon at a
cost of $0.32 per gallon
(adjust to market cost as
desired), we can calculate
the following daily
savings:
|
20,240
lbs. * 309
Btu / lb
|
*
$0.32 =
|
6254160
|
*
0.32 =
$17.56 / day
|
|
142,440
Btu/gal. *
0.80
|
113952
|
In
this example, by returning
only an additional 7% of
condensate, a significant
savings has been realized.
Also, the heating value of
the returned condensate
would yield additional
savings.
These
calculations are based on
the assumption that blow
down heat is not being
recovered. A blow down
heat recovery system
would, reduce the
potential savings.
|
Drum
Pressure (psig)
|
TDS
(ppm)
|
Total
Alkalinity (ppm
CoCO3)
|
Suspended
Solids (ppm)
|
Silica
(ppm)
|
|
|
Fire
Tube
|
Water
Tube
|
With
Turbines
|
Without
Turbines
|
|
0-300
|
3500
|
700
|
800
|
(a)
|
100
|
150
|
|
301-450
|
3000
|
600
|
400
|
(a)
|
100
|
90
|
|
451-600
|
2500
|
500
|
-
|
(a)
|
40
|
40
|
|
601-750
|
2000
|
400
|
-
|
(a)
|
25
|
30
|
(a)
The feed water for all
modern water tube boilers
should contain, little or
so iron, copper or
hardness for most reliable
operations.
|
Pressure
(psig)
|
Heat
of Saturated
Liquid (BTU/lb)
|
|
10
|
208
|
|
15
|
219
|
|
20
|
228
|
|
25
|
236
|
|
30
|
243
|
|
40
|
256
|
|
50
|
267
|
|
60
|
277
|
|
70
|
287
|
|
80
|
294
|
|
90
|
302
|
|
100
|
309
|
|
120
|
322
|
|
140
|
333
|
|
160
|
344
|
|
180
|
353
|
|
210
|
366
|
|
235
|
376
|
|
260
|
385
|
|
285
|
394
|
|
335
|
410
|
|
385
|
424
|
|
435
|
437
|
|
485
|
450
|
|
585
|
472
|
|
685
|
493
|
|
785
|
512
|
|
Technical
Charts
