Technical Field
[0001] The present invention relates to a method of repowering existing boiler turbine generator
plants and achieving the optimum cost-efficient output as well as such repowered plants
per se.
Background Art
[0002] It is well known that the thermal efficiency of a boiler turbine generator plant
(BTG) may be increased by repowering the BTG plant with an internal combustion engine
or a gas turbine. Repowering entails that the power output and thermal efficiency
of the BTG system are increased by combining the BTG system with a gas turbine or
an internal combustion engine using the energy in the exhaust gas of the engine by
introducing the exhaust gas into the boiler space as described in U.S. patent No.
4,928,635 and the PCT publication WO 99/23360 disclosing that the thermal efficiency
can be further increased by carefully optimising the introduction of the engine exhaust
gas into the boiler space. Hereby is also obtained a staged combustion leading to
a NO
x-reduction as previously disclosed in the Japanese patent JP 64-22328 (89). The background
of the latter method is described in greater detail in a paper from Mitsubishi Heavy
Industry Vol 26. No. 4 (1989).
[0003] In the Japanese patent application JP 07-239977 a method is described for repowering
with a two-stroke diesel engine and it is shown that the economy of the repowering
is improved compared to conventional repowering by converting the diesel engine as
well as the refurbished boiler for operation on residual oil.
[0004] Further experiments have shown that the best operational economy for the repowering
is not obtained by the configuration having the highest thermal efficiency.
[0005] It is therefore an object of the invention to provide a method of repowering boiler
turbine generator plants to improve the operational economy (defined as the highest
net present value) in comparison with the above prior art.
Brief Description of the Invention
[0006] In accordance with the above object there is provided a repowered boiler turbine
generator plant comprising one or more oil-fired or pulverised coal-fired boilers,
each boiler generating steam supplied through a steam piping to one or more steam
turbines, each of which being connected with a power generator; one or more gas turbines
or internal combustion engines, each of which being connected with a generator and
each of which supplying the boiler with exhaust gas; a wind-box for the boiler having
a burner being supplied with fuel; a superheater and optionally a reheater and a hot
economiser upstream of an outlet piping for flue gas from the boiler; a steam piping
for passing steam from the boiler through the superheater to the steam turbine(s);
optionally a catalyst downstream of the hot economiser for reducing the content of
NO
x in the flue gas; means for adding ammonia or urea upstream of the catalyst, if present;
and optionally a bypass for flue gas from the boiler to the catalyst; which plant
further comprises
- an exhaust gas piping supplying all the exhaust gas from the gas turbine(s) or internal
combustion engine(s) to the wind-box of the boiler and optionally a piping for adding
heated air to said exhaust gas; and
- a controller of fuel fired in the boiler ensuring a content of oxygen in the flue
gas from the boiler being either approximately between 1 % and approximately 6%, preferably
approximately between 1 % and approximately 4 %, and especially 3 % by volume as a
dry gas, or generating approximately between 100 ppm and approximately 1000 ppm, preferably
between 100 ppm and approximately 500 ppm, and especially 100 ppm by volume as a dry
gas of CO, whichever oxygen content is the highest.
[0007] According to a further embodiment of the invention the plant may further comprise
a cold economiser downstream of the superheater and the catalyst, if present, for
cooling the flue gas to a temperature normally used to prevent sulphuric acid corrosion
at the cold end of the economiser and for preheating said boiler feed water.
[0008] In addition the plant according to the invention may further comprise a heat exchanger
using the heat from engine cooling medium, if available, for additional preheating
of said boiler feed water.
[0009] In accordance with the above object there has also been provided a method of repowering
boiler turbine generator plants comprising one or more oil-fired or pulverized coal-fired
boilers, each boiler generating steam supplied through a steam piping to one or more
steam turbines, each of which being connected with a power generator; one or more
gas turbines or internal combustion engines, each of which being connected with a
generator and each of which supplying the boiler with exhaust gas; a wind-box for
the boiler having a burner being supplied with fuel; the flue gas of said boiler being
passed to an outlet piping for flue gas through a superheater and optionally a reheater
and a hot economiser for said steam being passed through the steam piping; said flue
gas optionally being passed through a catalyst for reducing the content of NO
x in the flue gas, in which case ammonia or urea is added upstream of the catalyst;
and the temperature at the inlet to the catalyst, if necessary, being maintained at
the required level by bypassing the superheater with flue gas;
said method comprising the steps of:
(i) supplying all the exhaust gas from the gas turbine(s) or internal combustion engine(s)
to the wind-box of the boiler and optionally adding heated air to said exhaust gas
so as to obtain a composition of exhaust gas and air with the oxygen content required
for obtaining stable combustion in the boiler; and
(ii) regulating the amount of fuel fed into in the boiler to obtain a flue gas from
the boiler having an oxygen content, which is either approximately between 1 % and
approximately 6% by volume as a dry gas, or having such a content of oxygen, which
generates approximately between 100 ppm and approximately 1000 ppm by volume as a
dry gas of CO, whichever oxygen content is the highest.
[0010] Preferably the method according to the invention further comprises the step of controlling
the amount of fuel to obtain a flue gas having a minimum content of oxygen between
approximately 1 % and approximately 4% by volume as a dry gas, or having such a content
of oxygen which generates approximately between 100 ppm and approximately 500 ppm
by volume as a dry gas of CO, whichever oxygen content is the highest, and more preferably
the method according to the invention further comprises the step of controlling the
amount of fuel to obtain a flue gas having a content of oxygen of approximately 3
% by volume as a dry gas, or having such a content of oxygen generating approximately
at least 100 ppm by volume as a dry gas of CO, whichever oxygen content is the highest.
[0011] According to a further embodiment of the method according to the invention the size
of the gas turbine(s) or the internal combustion engine(s) is selected so that the
exhaust gas with the optionally added heated air provides said stable combustion in
the boiler with the amount of fuel to produce steam in an amount required to generate
95 to 100 % of the output of the power generator in comparison with the use of heated
air alone for the combustion at full load.
[0012] According to an yet another embodiment of the method according to the invention a
prior-art boiler turbine generator plant pre-heater of air for the combustion in the
boiler is replaced by a cold economiser cooling the flue gas to a temperature normally
used to prevent sulphuric acid corrosion at the cold end of the economiser, and the
heat from said economiser used to heat boiler feed water.
[0013] According to an additional embodiment of the method according to the invention the
heat from engine cooling medium, if available, is used for additional preheating of
said boiler feed water.
[0014] Further scope of applicability of the present invention will become apparent from
the detailed description given hereinafter. However, it should be understood that
the detailed description and specific examples, while indicating preferred embodiments
of the invention, are given by way of illustration only, since various changes and
modifications within the scope of the invention will become apparent to those skilled
in the art from this detailed description.
Brief Description of the Drawing
[0015] Fig. 1 shows a schematic diagram of a boiler turbine generator plant being repowered
by an embodiment of the method according to the invention.
Best Mode for Carrying Out the Invention
[0016] All exhaust gas from the gas turbines or internal combustion engines 5 is supplied
to the wind-box 7 of the boiler 1 and the boiler 1 is fired to achieve normal maximum
output of the steam turbine generator(s) 2. The exhaust gas from the gas turbine(s)
or internal combustion engine(s) 5 is optionally mixed with the preheated air necessary
to achieve stable combustion in the boiler. The amount of exhaust gas used (optionally
mixed with heated air) corresponds to the minimum requirement for combustion in the
boiler 1 and to the maximum requirement for generating a fluegas from the boiler 1
with either an oxygen (O
2) content generating in the flue gas a CO content of maximum approximately 100 ppm
to approximately 1000 ppm, more preferred approximately 100 to approximately 500 ppm,
and especially approximately at least 100 ppm by volume as a dry gas or other maximum
values acceptable to the plant owner and authorities, or alternatively approximately
1 % to approximately 6%, more preferred approximately 1 % to approximately 4%, and
especially 1 % O
2 by volume as a dry gas, whichever oxygen content is the highest. The pre-heater of
air for the combustion existing in prior-art plants is replaced by a cold economiser
12 generating heat for heating boiler feed water 11 and any heat from engine cooling
is also used for heating boiler feed water. This novel boiler feed water heating replaces
otherwise necessary extraction of steam from the steam turbine 2 for feed water preheating
and thereby increases the steam turbine output and compensates together with the increased
combustion gas temperature and amount for the lower furnace temperature because of
the reduced oxygen-content in the boiler combustion gas. Under the preferred operation
conditions the NO
x-emission is minimal and may be reduced further by selective catalytic NO
x-reduction with the catalyst 13 located between the boiler and the new economiser.
Similarly the specific CO
2-emission is minimal at the preferred operational conditions. Surprisingly it has
been found that the maximum thermal efficiency is obtained at operational conditions
differing from the preferred operational conditions of the method according to the
invention.
[0017] The specific gas and oil prices in equal units are assumed to vary in the range:
0.6 < Gas/Oil < 1.17
[0018] The repowering process as schematically shown in Fig. 1 comprises the following elements:
I. A steam-generating oil-fired boiler 1 with a steam piping 19 for supplying a steam
turbine 2, powering a generator 3. Steam may be extracted 4 for process or other use.
II. One or more internal combustion engines or gas turbines (in the following denoted
as the "engine") 5, each powering a generator 6.
III. All of the exhaust gas from the engine 5 is passed to the wind-box of the boiler
(1), and, if necessary, air is added 8. The air is preheated with steam 9.
IV. If the engine 5 requires cooling, the heat from the cooling medium 10 is used
for heating the feed water 11 for the boiler 1.
V. A cold economiser 12 replacing the conventional air pre-heater is used for heating
of boiler feed water 11.
VI. If required, the NOx in the flue gas from the boiler may be reduced further by incorporating of a catalyst
13 between the boiler 1 and the cold economiser 12. The NOx is reduced to the required level by an introduction 14 of ammonia or urea upstream
the catalyst 13.
VII. The temperature upstream from the catalyst 13 is kept at the required level by
use of a flue gas bypass 15.
[0019] Fig. 1 shows the basic elements of a boiler turbine generator (BTG) plant repowered
by use of the method according to the invention. The principle is described for a
system with one boiler 1. The steam produced in the boiler 1 is supplied to a steam
turbine 2. Steam is extracted from the turbine 4 for internal use in the boiler plant
or for use as process steam outside the boiler plant. The steam turbine 2 is powering
a generator 3. The boiler steam turbine cycle may be a simple cycle system or a reheat
type cycle. The engine 5 may be formed of one or more gas turbines powered by gas
or an internal combustion engine powered by heavy fuel oil or residual oil (i.e. an
oil with a viscosity up to 10,000 cSt at 100 C).
[0020] All of the exhaust gas from the engines is supplied to the wind-box 7 of the boiler
1. If necessary, air 8 is added to the exhaust gas. The air 8 is heated by steam 9.
The oxygen content in the gas used for combustion, if necessary with addition of air
8, corresponds to the minimum required amount for securing stable combustion in the
boiler 1. Existing burners in the boiler are preferably changed to a type 16 with
two gas inlet chambers of which one can be closed with a damper for operation of the
boiler on fresh air only. The fuel 17 fed into the boiler 1 might be heavy fuel oil,
residual oil or coal.
[0021] The minimum oxygen content in the combustion gas is in the range of 13.5-13.8 % O
2 by volume on dry basis. The amount of gas used by the combustion for a given amount
of fuel 17 fed into the boiler 1 at full load condition for the steam turbine generator
is controlled by the oxygen content and the CO-content in the flue gas discharged
from the boiler 1 through the piping 18.
[0022] Under the preferably optimum condition the amount of gas used by the combustion corresponds
to an amount leaving an oxygen content in the flue gas discharged through piping 18,
which generate an CO content of maximum approximately 100 ppm by volume on dry basis
or other maximum values acceptable to the plant owner and authorities. However, the
oxygen content has to be at least 1 % by volume on dry basis to ensure stable boiler
operation.
[0023] At steam turbine generator full-load conditions the engines 5, in case of gas turbines,
operate at 95-100% of full-load conditions at given ambient conditions, whereas, if
the engines 5 are internal combustion engines, the engines 5 may operate in the range
85-100 % of full-load conditions. One or more engines 5 may be used for each boiler
1 depending on the amount of exhaust gas at full load for each engine and for required
part load operation conditions.
[0024] Because of the reduced oxygen content in the present boiler combustion gas compared
with air, the combustion temperature is reduced. The mass flow of gas through the
boiler 1 is however increased, whereby the transfer of heat in the boiler part from
the superheater 21 to the hot economiser 22 is increased. Further the apparent boiler
efficiency is increased, because the higher temperature of the combustion gas compared
with air compensates for the reduced combustion temperature.
[0025] The heat energy from the cold economiser 12 is used for heating of boiler feed water
11. If internal combustion engines are used, the heat energy in the cooling water
10 is also used for heating of the boiler feed water 11 by means of the heat exchanger
20. The heating of the boiler feed water by means of waste heat reduces the amount
of extracted steam 4, whereby the steam turbine generator output is increased for
same steam supply conditions through steam piping 19. In any case the output from
the steam turbine generator 3 after repowering can be kept at full load at 95-100
% of the maximum output when using air for the combustion.
[0026] The temperature at the inlet to the superheater 21 is also reduced and it should
therefore be checked, if the wall temperature comes near the ash sticking temperature.
This is even more necessary, if the fuel 17 for the boiler 1 is replaced with residual
oil, which with its higher content of vanadium has a reduced ash sticking temperature.
If critical, the first superheater should be replaced with another design coping with
this problem.
[0027] Operating with an oxygen content of 11 to 15 % in the gas used by the combustion
in the boiler 1 corresponds to operating a stand alone boiler with a large degree
of flue gas recirculation leading to a reduced NO
x-emission from the boiler. In fact the preferred operation conditions as described
leads to the lowest thermal NO
x production under the given conditions. An additional portion of the NO
x introduced into the boiler 1 from the engine 5 with the exhaust gas is converted
into N
2 and H
2O in the furnace. Under the preferred operation conditions 40-60% of the NO
x introduced is converted. Consequently, under the preferred optimum condition the
NO
x emission from the boiler 1 is minimal.
[0028] If the NO
x level is to be further reduced, a catalyst 13 is placed between the boiler 1 and
the cold economiser 12. The catalyst 13 is used for selective catalytic NO
x reduction. For that purpose, urea or ammonia 14 is injected upstream the catalyst
13.
[0029] The temperature of the flue gas at the inlet of the catalyst 13 is kept at the required
high level by bypassing 15 flue gas.
[0030] If oil is used for powering the engine 5 and/or for firing the boiler 1, a filter
is installed downstream of the economiser 12 to reduce the particulate content to
the required level and a desulphurisation system is installed after the filter. The
flue gas after the desulphurisation system is heated by use of a gas/gas heat exchanger
using the heat of exhaust gas at the inlet of the desulphurisation system.
[0031] Further, the specific CO
2 emission is minimal at the preferred operational conditions.
Examples
[0032] The method according to the invention is described with reference to a system comprising
of a 250 MW reheat type boiler steam turbine generator plant repowered with one to
four GTX 100 gas turbines operating on natural gas and the boiler converted into operating
on residual oil having a viscosity up to 10,000 cSt at 100°C. The natural gas has
a lower heat of combustion of 45,130 kJ/kg and the residual oil a lower heat of combustion
of 39,800 kJ/kg. The ambient temperature is 25 °C and 60 % RH at sea level.
[0033] The gas/power cost level in equal units is 0.266 and the residual oil cost to the
power cost level in equal units is similar 0.266.
[0034] The oxygen content after the boiler generating 100 ppm CO by volume on dry basis
is 3%.
[0035] Operating parameters are indicated in the following Table. In Case 2.9, the gas turbine
size is assumed adjusted geometrically to the preferred operational conditions:
|
Case 1 |
Case 2 |
Case 2.9 |
Case 3 |
Case 4 |
Total power/steam turbine power |
116 % |
132 % |
146 % |
148 % |
164 % |
Engine Exhaust O2 % Vol Dry |
11.8 |
11.8 |
11.8 |
11.8 |
11.8 |
Engine Exhaust temperature °C |
550 |
550 |
550 |
550 |
550 |
Economiser Outlet temp. °C |
170 |
170 |
170 |
170 |
170 |
Boiler Flue gas O2 % Vol Dry |
3.0 |
3.0 |
3.0 |
3.6 |
7.0 |
Total Flue gas kg/kWs Gross |
986 |
946 |
919 |
945 |
1120 |
Boiler Added Air/Total Flue Gas |
59.5 % |
31.8 % |
11.3 % |
11.3 % |
11.4 % |
Net Power Efficiency % |
41.1 % |
44.0 % |
46.3 % |
46.6 % |
48.0% |
Power /Ref. Power |
100% |
114 % |
126 % |
128 % |
141 % |
Power Income* |
1.000 |
1.141 |
1.263 |
1.281 |
1.412 |
Engine Fuel |
0.104 |
0.208 |
0.299 |
0.312 |
0.417 |
Boiler Fuel |
0.555 |
0.505 |
0.461 |
0.456 |
0.415 |
|
0.341 |
0.428 |
0.503 |
0.513 |
0.580 |
O&M New Equipment |
0.029 |
0.045 |
0.058 |
0.061 |
0.079 |
Capital Cost |
0.195 |
0.258 |
0.295 |
0.308 |
0.409 |
Surplus |
0.117 |
0.125 |
0.150 |
0.144 |
0.092 |
Relatively |
78 % |
83 % |
100 % |
96 % |
61 % |
CO2 kg/MWh 3 % O2 Vol-Dry |
115 % |
106 % |
100 % |
103 % |
120 % |
* Power Income = (power capacity) • (full load operation hours per year) • (power
price/MWh) |
[0036] For a given boiler steam turbine generator system the optimum economy is achieved,
where the existing steam turbine after repowering may be operated in the range of
95-100 % of the normal maximum output, when using air by the combustion and gas turbines
are operated at full load at given ambient conditions and only either marginal extra
air is needed at inlet of the boiler or a marginal higher oxygen content at the outlet
boiler compared to the optimum condition.
[0037] The main differences between Case 4 and Case 2.9 are that the specific flue gas amount
is 22 % higher in Case 4 compared to Case 2.9. The flue gas mass flow itself is 37%
higher in Case 4 compared to Case 2.9.
[0038] The ratio between the specific gas cost and the specific oil cost at equal metric
units is assumed to be: 0.6 < gas cost/oil cost < 1.17.
[0039] The invention being thus described, it will be obvious that the same may be varied
in many ways. Such variations are not to be regarded as a departure from the scope
of the invention, and all such modifications as would be obvious to one skilled in
the art are intended to be included within the scope of the following claims.
1. Repowered boiler turbine generator plant comprising one or more oil-fired or pulverized
coal-fired boilers, each boiler (1) generating steam supplied through a steam piping
(19) to one or more steam turbines (2), each of which being connected with a power
generator (3); one or more gas turbines or internal combustion engines, (5) each of
which being connected with a generator (6) and each of which supplying the boiler
(1) with exhaust gas; a wind-box (7) for the boiler (1) having a burner (16) being
supplied with fuel (17); a superheater (21) and optionally a reheater (23) and a hot
economiser (22) upstream of an outlet piping (18) for flue gas from the boiler (1);
a steam piping (19) for passing steam from the boiler (1) through the superheater
(21) to the steam turbine(s) (2); optionally a catalyst (13) downstream of the hot
economiser (22) for reducing the content of NO
x in the flue gas; means for adding ammonia or urea (14) upstream of the catalyst (13),
if present; and optionally a bypass (15) for flue gas from the boiler (1) to the catalyst
(13);
said plant further comprising:
- an exhaust gas piping supplying all the exhaust gas from the gas turbine(s) or internal
combustion engine(s) (5) to the wind-box (7) of the boiler (1) and optionally a piping
(8) for adding heated air to said exhaust gas; and
- a controller of fuel (17) fired in the boiler (1) ensuring a content of oxygen in
the flue gas from the boiler (1) being either approximately between 1% and approximately
6%, preferably approximately between 1 % and approximately 4%, and especially 3 %
by volume as a dry gas, or generating approximately 100 ppm to approximately 1000
ppm, preferably 100 ppm to approximately 500 ppm, and especially 100 ppm by volume
as a dry gas of CO, whichever oxygen content is the highest.
2. The plant of claim 1, further comprising:
- a cold economiser (12) downstream of the superheater (21) and optional reheater
(23), hot economiser (22) and catalyst (13), if present, for cooling the flue gas
to a temperature normally used to prevent sulphuric acid corrosion at the cold end
of the economiser (12) and for preheating said boiler feed water (11).
3. The plant of claims 1 to 2, further comprising:
- a heat exchanger using the heat from engine cooling medium, if available, for additional
preheating of said boiler feed water (11).
4. A method of repowering boiler turbine generator plants comprising one or more oil-fired
or pulverized coal-fired boilers, each boiler (1) generating steam supplied through
a steam piping (19) to one or more steam turbines (2), each of which being connected
with a power generator (3); one or more gas turbines or internal combustion engines
(5), each of which being connected with a generator (6) and each of which supplying
the boiler (1) with exhaust gas; a wind-box (7) for the boiler (1) having a burner
(16) being supplied with fuel (17); the flue gas of said boiler (1) being passed to
an outlet piping (18) for flue gas through a superheater (21) and optionally a reheater
(23) and a hot economiser (22) for said steam being passed through the steam piping
(19); said flue gas optionally being passed through a catalyst (13) for reducing the
content of NO
x in the flue gas, in which case ammonia or urea (14) is added upstream of the catalyst
(13); and the temperature at the inlet to the catalyst (13), if necessary, being maintained
at the required level by bypassing the superheater (21) with flue gas (15);
said method comprising the steps of:
- supplying all the exhaust gas from gas turbine(s) or internal combustion engine(s)
(5) to the wind-box (7) of the boiler (1) and optionally adding heated air to said
exhaust gas so as to obtain a composition of exhaust gas and air with the oxygen content
required for obtaining stable combustion in the boiler (1); and
- regulating the amount of fuel (17) fired in the boiler (1) to obtain a flue gas
after the boiler (1) having a content of oxygen, which is either between approximately
1 % and approximately 6% by volume as a dry gas, or having such a content of oxygen
generating approximately 100 ppm to approximately 1000 ppm by volume as a dry gas
of CO, whichever oxygen content is the highest.
5. The method of claim 4, further comprising the step of :
- regulating the amount of fuel (17) to obtain a flue gas having a minimum content
of oxygen of between approximately 1 % and approximately 4 % by volume as a dry gas,
or having such a content of oxygen, which generates approximately 100 ppm to approximately
500 ppm by volume as a dry gas of CO, whichever oxygen content is the highest.
6. The method of claims 4 to 5, further comprising the step of:
- regulating the amount of fuel to obtain a flue gas having a minimum content of oxygen
of approximately 1 % by volume as a dry gas, or having such a content of oxygen, which
generates approximately at least 100 ppm by volume as a dry gas of CO, whichever oxygen
content is the highest.
7. The method of claims 4 to 6, further comprising the step of:
- selecting the size of the gas turbine(s) or internal combustion engine(s) (5) so
that the exhaust gas with the optionally added heated air provides said stable combustion
in the boiler (1) with the amount of fuel (17) so as to produce steam in an amount
required to generate 95 to 100 % of the output of the power generator (3) in comparison
with the use of heated air alone for the combustion at full load.
8. The method of claims 4 to 7, further comprising the steps of:
- replacing a prior-art boiler turbine generator plant pre-heater of air for the combustion
in the boiler (1) with a cold economiser (12) cooling the flue gas to a temperature
normally used to prevent sulphuric acid corrosion at the cold end of the economiser
(12); and
- using the heat from said economiser (12) to heat boiler feed water (11).
9. The method of claims 4 to 8, further comprising the step of:
- using the heat from engine cooling medium, if available, for additional preheating
of said boiler feed water (11).