NZ617749B2 - Geothermal binary cycle power plant with geothermal steam condensate recovery system - Google Patents
Geothermal binary cycle power plant with geothermal steam condensate recovery system Download PDFInfo
- Publication number
- NZ617749B2 NZ617749B2 NZ617749A NZ61774912A NZ617749B2 NZ 617749 B2 NZ617749 B2 NZ 617749B2 NZ 617749 A NZ617749 A NZ 617749A NZ 61774912 A NZ61774912 A NZ 61774912A NZ 617749 B2 NZ617749 B2 NZ 617749B2
- Authority
- NZ
- New Zealand
- Prior art keywords
- motive fluid
- geothermal
- organic
- power plant
- organic motive
- Prior art date
Links
- 238000011084 recovery Methods 0.000 title abstract description 9
- 239000012530 fluid Substances 0.000 claims abstract description 116
- 239000000110 cooling liquid Substances 0.000 claims abstract description 36
- 239000007788 liquid Substances 0.000 claims abstract description 30
- 239000006200 vaporizer Substances 0.000 claims abstract description 25
- 238000010438 heat treatment Methods 0.000 claims abstract description 11
- 230000000875 corresponding Effects 0.000 claims abstract description 5
- 239000012267 brine Substances 0.000 claims description 38
- 238000001816 cooling Methods 0.000 description 14
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 description 6
- 238000002347 injection Methods 0.000 description 5
- 239000007924 injection Substances 0.000 description 5
- 238000001556 precipitation Methods 0.000 description 5
- 238000004519 manufacturing process Methods 0.000 description 3
- 239000007787 solid Substances 0.000 description 3
- 239000007789 gas Substances 0.000 description 2
- 230000004941 influx Effects 0.000 description 2
- 238000005192 partition Methods 0.000 description 2
- 238000000926 separation method Methods 0.000 description 2
- VYPSYNLAJGMNEJ-UHFFFAOYSA-N silicium dioxide Chemical compound O=[Si]=O VYPSYNLAJGMNEJ-UHFFFAOYSA-N 0.000 description 2
- 150000004649 carbonic acid derivatives Chemical class 0.000 description 1
- 150000001805 chlorine compounds Chemical class 0.000 description 1
- 230000001276 controlling effect Effects 0.000 description 1
- 239000000498 cooling water Substances 0.000 description 1
- 238000005260 corrosion Methods 0.000 description 1
- 230000005611 electricity Effects 0.000 description 1
- 150000002500 ions Chemical class 0.000 description 1
- 230000004301 light adaptation Effects 0.000 description 1
- 239000000377 silicon dioxide Substances 0.000 description 1
- 239000000243 solution Substances 0.000 description 1
- 238000004326 stimulated echo acquisition mode for imaging Methods 0.000 description 1
- 238000009834 vaporization Methods 0.000 description 1
Classifications
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01K—STEAM ENGINE PLANTS; STEAM ACCUMULATORS; ENGINE PLANTS NOT OTHERWISE PROVIDED FOR; ENGINES USING SPECIAL WORKING FLUIDS OR CYCLES
- F01K25/00—Plants or engines characterised by use of special working fluids, not otherwise provided for; Plants operating in closed cycles and not otherwise provided for
- F01K25/08—Plants or engines characterised by use of special working fluids, not otherwise provided for; Plants operating in closed cycles and not otherwise provided for using special vapours
Abstract
geothermal based, binary cycle power plant is provided, comprising: a vaporizer for vaporizing pre-heated organic motive fluid by means of geothermal steam; two organic vapor turbines operating in parallel and coupled to a common generator, each of said turbines being driven by vaporized organic motive fluid supplied to each turbine; two recuperators for heating the organic motive fluid by means of a corresponding organic vapor turbine discharge; and two condensers for condensing heat depleted motive fluid exiting said two recuperators, respectively. A geothermal steam condensate recovery system is also provided, comprising a source of geothermal steam for vaporizing a organic motive fluid and producing geothermal steam condensate, and conduit means through which geothermal steam condensate is delivered to a supply of cooling liquid used to condense the organic motive fluid, the delivered geothermal steam condensate serving as make-up liquid for evaporated cooling liquid. otive fluid supplied to each turbine; two recuperators for heating the organic motive fluid by means of a corresponding organic vapor turbine discharge; and two condensers for condensing heat depleted motive fluid exiting said two recuperators, respectively. A geothermal steam condensate recovery system is also provided, comprising a source of geothermal steam for vaporizing a organic motive fluid and producing geothermal steam condensate, and conduit means through which geothermal steam condensate is delivered to a supply of cooling liquid used to condense the organic motive fluid, the delivered geothermal steam condensate serving as make-up liquid for evaporated cooling liquid.
Description
GEOTHERMAL BINARY CYCLE POWER PLANT
WITH GEOTHERMAL STEAM CONDENSATE RY SYSTEM
Field
The present invention relates to the field of geothermal energy. More
particularly, the invention relates to a geothermal binary cycle power plant with
a system for utilizing geothermal steam condensate.
Background
At many prior art geothermal based power plants, geothermal fluid
exiting production wells is separated into a steam portion and a brine n. In
binary power plant cycles, the steam portion can be used to provide latent heat in
a vaporizer for ing organic motive fluid vapor while the geothermal steam
condensate produced, together with the brine may be brought in heat exchanger
relation with the motive fluid of a binary power cycle, e.g. organic motive fluid,
for preheating the motive fluid. The organic motive fluid vapor ed can be
supplied to an c vapor turbine for producing electricity.
US 5,664,419 describes an apparatus that comprises a recuperator for
transferring heat from heat depleted organic fluid produced by an organic vapor
turbine to organic condensate produced by an organic vapor condenser. The
heated organic condensate produced by the rator is supplied to a pre-
heater which receives brine and steam condensate from the vaporizer for
erring sensible heat to the organic fluid before the brine and steam
sate are disposed of while cooled organic vapor produced by the
recuperator is supplied to the organic vapor condenser. The combined flow of
cooled brine and cooled steam sate forms a combined flow of diluted, cooled
brine for re-injection into a re-injection well. Thus, in US 5,664,419, the presence
of the recuperator permits additional heat to be used by the organic working fluid
in excess of that transferred directly by the geothermal fluid in the vaporizer and
the preheater, without sing the vaporization temperature of the organic
fluid. Thus, the exit temperature of the brine g the preheater is no longer
the controlling factor for ishing the amount of heat that can be added to the
working fluid.
The present invention provides a geothermal steam condensate recovery
system for utilizing the steam condensate in a way that it has not been exploited
heretofore.
In addition, the present invention provides a geothermal fluid recovery
system for utilizing the brine in a way that it has not been exploited heretofore.
Other ages of the invention will become nt as the
description proceeds.
Summary
The present invention is directed to a geothermal based, binary cycle
power plant, comprising a vaporizer for vaporizing pre-heated organic motive
fluid by means of geothermal steam; two organic vapor es operating in
parallel and which can be coupled to a common generator, each of said turbines
being driven by vaporized organic motive fluid supplied to each turbine; two
rators for heating the organic motive fluid by means of a corresponding
organic vapor turbine rge; and two condensers for condensing heat
depleted organic motive fluid exiting said two recuperators, tively.
By using two recuperators wherein, in one aspect, the combined liquid
output of the recuperators is used for preheating the organic motive fluid and
wherein, another aspect, one recuperator es the preheated organic motive
fluid condensate output to a pre-heater, this recuperator being supplied with the
organic motive fluid condensate output from the other recuperator, high power
efficiency levels and power output are achieved. In addition, thereby, less heat
can be extracted from the geothermal brine so that the power plant of the present
invention is less sensitive to separation or precipitation of solids from the
geothermal liquid or brine and permits optimal and sustainable utilization of a
geothermal ce. Moreover, in accordance with the present invention wherein
the geothermal liquid or brine and geothermal steam and condensate are
maintained te from one another, the temperature of the rmal steam
condensate can be made sufficiently cool for making it suitable for use as make-
up liquid for cooling liquid supplied to the cooling tower or other suitable uses
such as industrial uses e.g. providing cooling liquid for evaporative g of air—
cooled sers or cooling liquid for fogging or deluge of the cooling pipes of air-
cooled condensers, etc.
In one aspect, the c motive fluid is ted by means of
geothermal fluid, i.e. brine or heat depleted geothermal steam or steam
condensate exiting the vaporizer in pre-heaters. In addition, in a r aspect,
organic motive fluid exiting the condensers is additionally pre-heated in a further
pre-heater utilizing heat in further heat depleted rmal steam or steam
condensate exiting a pre-heater.
In one aspect, the power plant further comprises a further vaporizer for
vaporizing pre-heated organic motive fluid by means of geothermal steam.
In one aspect, the vaporizer is supplied with pre-heated organic motive
fluid pre-heated in a pre-heater by geothermal liquid or brine and the further
zer is supplied with pre—heated organic motive fluid pre-heated in a further
pre-heater by geothermal steam or steam condensate exiting the further
vaporizer.
In one aspect, the pre-heater is supplied with organic motive fluid
condensate exiting one of the two recuperators, said one of the two recuperators
being ed with organic motive fluid condensate exiting the other
recuperator.
By use of the pre—heaters as well as the recuperators in the power plant
in ance with an aspect of the present invention, high power plant efficiency
levels are achieved as well as increased power output levels.
The present invention also provides a geothermal steam condensate
recovery system, comprising a source of rmal steam for zing an
organic motive fluid, and conduit means h which geothermal steam
condensate is red to a supply of cooling liquid used to condense said organic
motive fluid, said delivered geothermal steam condensate serving as p
liquid for evaporated cooling liquid.
The system further comprises a vaporizer for vaporizing organic motive
fluid by means of the geothermal steam, and a first pre—heater for pre-heating
c motive fluid sate by means of geothermal steam or condensate,
wherein the conduit means through which the geothermal steam condensate is
delivered to the supply of g liquid supplies heat depleted geothermal steam
condensate from said first pre—heater.
In one aspect, the organic motive fluid condensate preheated by the first
pre-heater is deliverable to the vaporizer.
In one aspect, the organic motive fluid condensate preheated by the first
preheater is heated by geothermal steam exiting the vaporizer.
In one aspect, the organic motive fluid condensate preheated by the first
preheater is heated by geothermal steam or steam condensate exiting each of two
vaporizers and combined by a common conduit supplying the geothermal steam
or steam condensate to the first preheater.
In one aspect, the system further comprises a r pre-heater heat
exchanger means for pre-heating preheated organic motive fluid with geothermal
steam or steam condensate exiting the first pre-heater.
In one aspect, the organic motive fluid condensate preheated by the first
preheater is pre-heated by the geothermal steam or steam condensate exiting the
first pre-heater.
In one aspect, the first ater includes a pre—heater heat exchanger
means having two stages, the pre-heater heat exchanger means comprising a
first stage which is a second ater for pre-heating organic motive fluid by
means of the geothermal liquid or brine, and a further pre-heater stage for also
pre-heating organic motive fluid with geothermal steam or steam condensate
exiting the vaporizer.
In one aspect, heat depleted brine which is not mixed with the heat
ed geothermal steam or steam condensate is reinjected into a reinjection
well.
In one aspect, the first and further stages of pre-heater heat exchanger
means are separated by a partition.
In one aspect, the temperature of the heat depleted geothermal brine
exiting the pre-heater heat exchanger means is greater than its precipitation
point.
In one aspect, the c motive fluid is organic fluid of an Organic
Rankine Cycle (ORC) type power system.
In one aspect, the supply of cooling liquid is cooled by means of a cooling
tower.
In one aspect, the geothermal steam condensate which is not red
to the supply of g liquid is re-injected into a re-injection well.
In one aspect, extracted geothermal fluid is separated into a steam
portion and into a brine portion by means of a separator.
Brief Description
In the drawings:
- Fig. 1 is a schematic illustration of a binary cycle power plant
sing a geothermal steam condensate recovery system, according
to one embodiment of the present invention; and
- Fig. 2 is a schematic illustration of a binary cycle power plant
comprising a geothermal steam condensate recovery system, according
to another embodiment of the present invention.
Similar nce numerals and symbols refer to similar components.
Detailed Description
Fig. 1 illustrates a geothermal based, binary cycle power plant according
to one embodiment of the present invention, and is designated 40. Power plant 40
comprises Organic Rankine Cycle (ORG) type power system 10 and rmal
steam condensate recovery (SCr) system 30 operable in conjunction with CBC
system 10. The dashed lines indicate ts or lines through which fluid in a
vapor phase flows, and the solid lines indicate conduits or lines through which a
substantially liquid fluid flows.
In SCr system 30, a tor (not shown) separates the geothermal
fluid exiting a production well at a temperature of about 0°C into a steam
portion and a liquid or brine portion. The steam n is delivered via outlet 5
of the tor and conduit or line 6 to vaporizer 20, for vaporizing organic
motive fluid of an organic motive fluid power cycle. The heat depleted geothermal
steam or condensate exiting vaporizer 20 flows through conduit or line 21, and is
heated within two-stage pre-heater heat exchanger 12 by means of the brine
portion delivered thereto from outlet 7 of the separator via conduit or line 8. In
first stage A of pre—heater heat exchanger 12, which may be of the shell and tube
type, the separated brine portion preheats the organic motive fluid recuperator
discharge supplied through conduit 61. In stage B of pre—heater heat ger
12, heat ed geothermal steam or condensate also es heat for r
pre-heating the organic motive fluid condensate. The second stage B of pre-heater
heat exchanger 12, wherein a portion, or all, of the heat depleted geothermal
steam or condensate transfers heat to the organic motive fluid in on to the
brine in first stage A, may be separated from first stage A by partition 19 through
which the brine passes. Heat depleted brine which is not mixed with heat
depleted geothermal steam or condensate exits pre-heater heat exchanger 12 via
conduit 16 and is re—injected into a ction well via inlet 9.
Heat depleted geothermal steam condensate exits second stage B of pre-
heater heat exchanger 12 via conduit or line 17 and is delivered to additional pre-
heater 22, which also preheats the organic motive fluid condensate supplied
thereto. By employing pre-heater 22, further heat present in geothermal
condensate is transferred to the organic motive fluid supplied to additional pre-
heater 22 and therefore the rate of heat transfer for preheating the organic
motive fluid condensate will also be increased.
An onal advantage of the aspect of the present embodiment is that
the heat depleted geothermal steam condensate thus having a reduced
temperature may be exploited to provide make-up water for the g tower
water supply 49, or for any other suitable use by means of which the organic
motive fluid condensate is heated. Such uses could include such industrial uses
e.g. providing cooling liquid for evaporative cooling of air-cooed condensers or
cooling liquid for fogging or deluge of the g pipes of air-cooled condensers,
etc. Some of the rmal steam sate exiting additional pre-heater 22
via conduit or line 23 is diverted to conduit 26, from which the geothermal steam
condensate is delivered to main cooling liquid supply conduit 64 extending from
cooling liquid supply 49, to serve as make-up water for the cooling liquid that was
evaporated. The remaining portion of the geothermal steam condensate is re-
injected into a re-injection well via supply 25.
While prior art power plants require a source of p g liquid,
which significantly adds to the operating costs of the plant, the heretofore
unexploited geothermal steam condensate resource normally reinjected into a re—
ion well can provide much benefits to the power plant in terms of assisting
in condensing the organic motive fluid, obviating the need of make-up cooling
liquid, and preheating the condensed organic motive fluid.
The ing conditions of power plant 40, ularly of each organic
fluid condenser and of ater heat ger means 12, may be suitably
selected to ensure that the ature of the geothermal liquid or brine exiting
pre-heater heat exchanger means 12 will be greater than its precipitation point.
Maintaining the geothermal liquid or brine above its precipitation point will
prevent undesired corrosion and scaling onto the metallic conduit and heat
exchanger surfaces of significant quantities of silica, chlorides, and carbonates
that are typically dissolved in the geothermal liquid.
In ORC system 10, the discharge from two organic turbines 53 and 55
operating in parallel and advantageously coupled to a common generator 59 is
red to recuperators 63 and 65, respectively, via conduits 64 and 66,
respectively. The heat depleted organic fluid vapor exiting recuperators 63 and 65
is delivered to condensers 33 and 35, respectively, via conduits 31 and 32,
respectively. Organic condensate is produced by providing cooling liquid, which is
supplied through ts or lines 71 and 74 branching from main cooling liquid
supply conduit or line 64, to condensers 33 and 35, respectively. The heated
cooling liquid exits condensers 33 and 35 via conduits 41 and 43, respectively,
leading to the cooling liquid conduit 75 which extends to return inlet 77 of the
cooling tower. Electric generator 59 and other rotating components included in
power plant 40 may be cooled by means of auxiliary cooling supply 81, which
receives cooling liquid from main cooling liquid supply conduit 64 and rges
heated cooling liquid to conduit 75.
The organic motive fluid condensate discharged from organic motive
fluid condensers 33 and 35 through conduits 34 and 36, respectively, is directed
to common conduit 38, pressurized by organic motive fluid condensate pump 37,
and delivered to preheater 22. The preheated organic motive fluid sate
flows through conduit 29 and then branches into conduits 67 and 68 extending to
recuperators 63 and 65, respectively. The enthalpy of the preheated organic
motive fluid condensate is increased by means of the corresponding organic
motive fluid vapor turbine discharge delivered to recuperators 63 and 65, and is
further increased, after flowing h conduits 51, 52, and 61, by means of the
brine flowing through first stage A of pre—heater heat exchanger 12 and also
steam condensate flowing through further stage B of ater heat exchanger
12. The heated organic motive fluid is then delivered via conduit 18 from first
stage A of heat exchanger 12 to vaporizer 20. In vaporizer 20, the organic motive
fluid is vaporized by the geothermal steam portion, and is delivered via ts
or lines 47 and 48 to organic motive fluid vapor turbines 53 and 55, respectively.
Non-condensable gases (NCG) if produced can be bled off via conduit 28 to drive
the cooling tower fans.
The heat influx transferred to the organic fluid by the brine in two
stages, i.e. by rmal liquid or brine in first stage A and by the steam
condensate in further stage B of pre-heater heat exchanger 12 as well as in pre-
heater 22, sufficiently heats the organic fluid such that the heat capacity of the
geothermal steam can be utilized to generate enough vapor to drive two turbines
ing in parallel. The discharge of each of the two es operating in
el is also utilized to further add to the heat influx ed to the organic
fluid by means of recuperators 63 and 65. Furthermore, by using steam
condensate in 2 pre—heaters, the steam sate is cooled sufficiently to make
it suitable for use as make-up water for the cooling liquid in the cooling tower.
While one geothermal based, binary cycle power plant 40 is described
above in this embodiment, advantageously, in accordance with this ment
of the present invention, a plurality of such binary cycle power plants can be
used.
Fig. 2 illustrates another embodiment of the ion wherein
geothermal based, binary cycle power plant 140 also comprises an ORC system
110 ed with two turbines 153 and 155 operating in parallel and a SCr
system 130 operable in conjunction with ORC system 110; r, in this
embodiment, two vaporizers 119 and 120 are employed to supply organic motive
fluid vapor to organic vapor turbines 153 and 155, respectively, and two
recuperators 163 and 165 supply organic fluid in series exiting recuperator 165.
In SCr system 130, a separator (not shown) separates the geothermal
fluid from a production well into a steam portion and a liquid or brine portion.
The separated steam portion flows via outlet 105 of the separator and conduit or
line 106, the latter branching into conduits or lines 111 and 113 through which
the steam is delivered to vaporizers 119 and 120, respectively, for ing
organic fluid vapor. The flow of heat depleted geothermal steam or steam
condensate exiting zers 119 and 120 via conduits or lines 121 and 124,
respectively, is combined and the combined flow of heat depleted geothermal
steam or steam condensate is supplied through conduit or line 127 to steam
condensate pre-heater 122, for transferring the heat present in both heat
depleted geothermal steam or steam condensate flows in conduits or lines 121
and 124, respectively, for pre—heating the organic motive fluid condensate
delivered from organic condenser 135 by means of pump 137 via conduit 136 and
y cooling the heat ed geothermal steam or steam condensate.
The cooled geothermal steam condensate is also exploited to provide
p water for cooling liquid or water supplied to cooling tower 149 or for any
other suitable use such as industrial uses e.g. providing cooling liquid for
evaporative cooling of air—cooled condensers or cooling liquid for fogging or deluge
of the cooling pipes of air—cooled condensers, etc. Some of the geothermal steam
condensate exiting pre-heater 122 via conduit 123 can be diverted to conduit 126,
from which the geothermal steam condensate is red to main g liquid
supply conduit 164 extending from cooling liquid supply 149, to serve as make-up
water for the cooling liquid that was evaporated. The remaining portion of the
geothermal steam condensate can be re-injected into a ection well via inlet
125.
The geothermal liquid or brine portion is supplied via outlet 107 of the
separator and conduit or line 108 to brine pre-heater 112, for preheating the
c motiVe fluid exiting recuperator 165. The heat depleted geothermal liquid
or brine flows through conduit or line 116 and is reinjected into re—injection well
via inlet 109.
In ORC system 110, the discharge from the two organic vapor turbines
153 and 155 operating in parallel and advantageously coupled to a common
tor 159 is delivered to recuperators 163 and 165, respectively, via conduits
or lines 164 and 166, respectively. The heat depleted c motive fluid exiting
recuperators 163 and 165 is delivered to condensers 133 and 135, respectively,
via conduits or lines 131 and 132, respectively, and is condensed by means of the
cooling liquid flowing through conduits 171 and 174, respectively. The heated
cooling liquid exits condensers 133 and 135 via conduits or lines 141 and 143,
respectively, and supplied via cooling liquid conduit 175 to return inlet 177 of the
cooling tower. Auxiliary cooling supply 181 es cooling liquid from main
g liquid supply conduit 164 and rges heated cooling liquid to conduit
175.
The c condensate discharged from organic motive fluid condenser
133 by means of pump 138 via conduit 134 is delivered to recuperator 163. After
being heated by the discharge of organic vapor turbine 153 in recuperator 163,
the heated organic motive fluid condensate flows through t 139 and is
additionally heated by means of the discharge of organic vapor turbine 155 in
recuperator 165. The heated organic motive fluid condensate is then supplied
from the outlet of recuperator 165 via conduit 161 to geothermal liquid or brine
pre-heater 112, from which the pre-heated organic motive fluid is supplied to
vaporizer 119 Via conduit 118. The vaporized organic motive fluid is supplied to
organic vapor turbine 153 via conduit or line 147. Thus, due to the heat supplied
to the organic motive fluid in recuperator 163 as well as in recuperator 165, less
heat can be extracted from the rmal liquid or brine in pre-heater 112,
consequently allowing the ature of the geothermal liquid or brine to be
maintained above a temperature Where precipitation or separation of solids from
the geothermal liquid or brine.
The organic motive fluid condensate rged from organic motive
fluid condenser 135 via t 136 is supplied to steam condensate pre-heater
122 using pump 137. The pre-heated organic motive fluid produced therein is
ed via conduit or line 117 to vaporizer 120, after which the vaporized
organic motive fluid is supplied to organic vapor turbine 155 via conduit 148. Non
condensable gases ed from the geothermal steam in vaporizers 119 and
120 is bled off via conduits 128 and 129, respectively, to using the g tower
fans.
While one geothermal based, binary cycle power plant 140 is described
above in this embodiment, advantageously, in accordance with this embodiment
of the present invention, a plurality of such binary cycle power plants can be
used.
.13.
While some ments of the invention have been described by way of
illustration, it will be apparent that the invention can be carried out with many
ations, variations and adaptations, and with the use of numerous
equivalents or alternative solutions that are within the scope of persons skilled in
the art, without departing from the spirit of the invention or exceeding the scope
of the claims.
Claims (11)
1. A geothermal based, binary cycle power plant, comprising: a) a preheater connected to receive geothermal fluid for preheating an organic motive fluid; b) a vaporizer for vaporizing pre—heated organic motive fluid by means of geothermal steam; 0) two organic vapor turbines operating in parallel and coupled to a common generator, each of said turbines being driven by vaporized organic motive fluid supplied to each turbine; (1) two recuperators for heating the organic motive fluid by means of a corresponding organic vapor e discharge; and e) two condensers for condensing heat ed organic motive fluid exiting said two recuperators, tively.
2. The power plant according to claim 1, wherein the rmal fluid which preheats the organic motive fluid is rmal liquid or brine.
3. The power plant according to claim 2 including a further pre-heater connected to receive heat depleted geothermal steam or steam condensate from said vaporizer for pre-heating organic motive fluid supplied to said vaporizer.
4. The power plant according to claim 3, n the preheated organic motive fluid exiting the further pre-heater is supplied to said two recuperators. .15.
5. The power plant ing to claim 4 wherein heated organic motive fluid condensate exiting said two recuperators is combined and the ed flow is supplied to said pre—heater.
6. The power plant according to claim 5 further comprising a further vaporizer for vaporizing pre-heated organic motive fluid by means of geothermal steam.
7. The power plant according to claim 6 wherein said vaporizer is supplied with pre-heated organic motive fluid pre-heated in a pre- heater by geothermal liquid or brine and said r vaporizer is ed with pre—heated c motive fluid pre-heated in said further pre-heater by geothermal steam or steam condensate exiting said further zer.
8. The power plant according to claim 7 wherein said pre-heater is supplied with organic motive fluid condensate exiting one of said two recuperators, said one of said two recuperators being supplied with organic motive fluid condensate exiting the other recuperator.
9. The power plant according to claim 8 wherein said further pre-heater is supplied with organic motive fluid condensate exiting one of said two condensers.
10. The power plant according to claim 9 wherein said further pre-heater is supplied with heat depleted geothermal steam or steam condensate exiting said two vaporizers.
11. The power plant according to claim 10 wherein further heat depleted geothermal steam or steam condensate g said further pre-heater is supplied to a supply of cooling liquid used to condense said c motive fluid in said one of said two condensers, said further heat depleted geothermal steam condensate serving as make-up liquid for evaporated cooling liquid.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US13/088,901 US8601814B2 (en) | 2011-04-18 | 2011-04-18 | Geothermal binary cycle power plant with geothermal steam condensate recovery system |
US13/088,901 | 2011-04-18 | ||
PCT/IB2012/000748 WO2012143772A1 (en) | 2011-04-18 | 2012-04-16 | Geothermal binary cycle power plant with geothermal steam condensate recovery system |
Publications (2)
Publication Number | Publication Date |
---|---|
NZ617749A NZ617749A (en) | 2016-07-29 |
NZ617749B2 true NZ617749B2 (en) | 2016-11-01 |
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