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Low exergy reactor for decentralized energy utilization
Progress in Nuclear Energy. Vol. 37, No. 1-4, Pp. 405-410. 2000 Q 2000 Elsevier Science Ltd. All rights reserved Printed in Great Britain 0149-1970/00/$ - see front matter
Pergamon www.elsevier.com/locate/pnucene
PII:SO149-1970(00)00079-2
LOW EXERGY REACTOR FOR DECENTRALIZED
YUKITAKA
Research
Laboratory
KATO
for Nuclear Reactors,
Tokyo Institute 0-okayama,
ENERGY UTILIZATION
of Technology,
Meguro-ku,
Tokyo 1528550,
Japan
ABSTRACT A new
conceptual
proposed by
the
and its possibility reactor
environmental
that
water reactors combined
thermal
energy
trend.
energy
Cogeneration energy
supply of the
(LER)’ was
The LER is defined at a temperature
systems
based
on the LER
The enthalpy
was evaluated
system
light
based on the
device and steam turbine
utilization.
systems LER
near
is lower
by the conventional
of the LER was discussed
heat pump, thermoelectric
efficiency
reactor
100°C and 300 “C, which
of the energy generated
for decentralized
those decentralized The
about
The necessity
with absorption
nuclear
qualitatively.
low-exergy
between
technology
were proposed
‘low exergy
was discussed
temperature (LWR).
energy
named
generates
temperature
than the output present
reactor
was
using practical
compared
conventional
LWR system.
decentralized
heating and cooling system. 0 2000 Elsevier
balance
with
Science
data.
that
The LER system was expected to be suitable
of of
for a
Ltd. All
rights reserved. 1. INTRODUCTION Because of recent rapid change in the electricity expected
to be changed
in order to enhance conventional Agency,
drastically
cogeneration
1998).
in the next decades.
energy utilization
systems are installed
Recently
developed
down of the supply area from districts Then, energy generation energy generator.
efficiency
generation
technology,
Cogeneration
and the reduction
systems
the energy supply system is have become
of carbon dioxide
in an area less than about 10 km in diameter
fuel cell and micro-gas to smaller
turbine
technology
areas, that is, buildings
Generally,
(Danish
have enhanced
and residences
Energy the size-
(Lenssen,
1999).
has been no longer special subject, and citizen will be able to own easily a personal
For new nuclear energy systems in future, we would have to consider
supply of non-nuclear
more popular
emission.
systems.
It means that decentralization
key issues for nuclear systems in future. 405
and cogeneration,
such a trend in the
and cost-down
would be
406
Y. Kato Cooling
Cooking
Fig. 1 Energy consumption share at residential and commercial use in Japan in 1997 (Energy
Residential use Commercial use
Data and Modeling
for decalized
commercial
system,
enew
uses in Japan in 1997 (Energy
of 26.0 % in whole national
energy
quality
such as hot water, heating
quality
of electricity
shows a comparison ordinate
Figure
power.
which
Data and Modeling
consumption
of energy
supply scale between
output
of each plant.
is the most developed
country
nuclear reactors is defined by International small reactor defined
by IAEA would
decentralized
system,
supply
energy
accompanied
by heat transfer
a plant like a conventional
scale less than about
because
1 and 2, a reactor
decentralized
cogeneration
smaller
for practical
expensive
0 m
IAEA.
reactor plants.
are operated
Industrial
use.
in
of the
For the discussion is indispensable.
because
these
of The
supplies
are
Larger amount of output from
but thermal
energy distribution
for practical
decentralized
scale for decentralized
in
Then an electrical energy
supply
energy system.
From
(temperature)
output
is suitable
for
REACTOR
in order to meet the requirements
for the decentralized
of
CHP
.
Ornhq CHP plant for 400 people , _........................................................
0 -
100
200
Heat outpur temperature
300
400
500
Ryslinge folk high.__..._........._ school . . . ..___ r...f~~j~s~~~~~~
Fig. 2 Relationship between common energy systems and output scale [I]
600
from a process, T , [‘%I
Fig. 3 Definition of the low exergy reactor, LER 0.1
2
The
practically
The classification
process
cost.
and lower-quality
Figure
A smaller reactor than the ultra
system,
plumbing
energy.
plant
Tomatogleenhpuses _ . . . .. ..__‘“‘iii~~.i;eter~-..._
. .
plants
decentralized
expected
is appropriate
amount
reactor LER is proposed
m Vivorg LargeCHP for 30,000 people
,6
plants and nuclear
of higher cost for the heat transportation.
2. LOW EXERGY
‘jb 2
to low-exergy
Those cogeneration
100 MWtherma,is generally
having
corresponds
energy system.
A conceptual
.o .&
with low with high
larger area for consumption,
plant, and an area having a few km of diameter Figs.
Demand
to the heat transportation
loss and, especially,
the larger area is not economical output
for the energy
the scale of decentralized
reactor requires
and
Both uses occupy the share
in the field of cogeneration.
be required
restricts
1999).
share for residential
100°C is larger than that for the energy
Atomic Energy Agency,
the consideration
of heat and cold energy
Center,
(1.5 lx 10’6kJ/year). below
The energy with low quality
shows the electric
Denmark,
1 shows an energy consumption
and cooling
Center)
100
50 Energy consumption share [%]
0
use.
Decentralized
energy
utilization
407
Case 1
Case 2
Case 3
Fig. 4 Proposed systems for decentralized co- and tri-generation based on LER
The
LER
temperature
is defined around
conventional maximum
light
water
possible
temperature,
by the reactor 100 to 300°C. reactors
thermal
which
produces
low-exergy
Figure 3 shows the maximum (LWR)
efficiency
and fast breeder
(the thermal
environmental
The bold
cycle),
of LER and
line
shows
the
vc [-I, for heat output (1)
and 77, indicates
The reactor that produces output
reactor developments
the exergy range
and commercial
maximum
is not efficient
for power
uses as mentioned
generation,
in the following
The lower temperature benefits
and also (4) higher
reliability
for heating
and
The effort for nuclear
output for power generation
with higher
with high efficiency,
however,
for the reactor design such as (1) simpler design, (2) safety and (3) lower-cost, for operation,
(5) material
in the design, (7) easy maintenance
cost and simple design.
efficiency.
as LER in this paper.
but enough
sections.
output is not suitable for power generation
temperature,
power generation
output than the LWR is defined
in the past was oriented to higher temperature
brings simultaneously new-technology
of a reactor and the environmental
and also the theoretical
lower exergy (temperature)
temperature
at residential
efficiency.
(FBR).
of a Camot
near
efficiency
)/T,
where T, [K] and T,, [K] mean the heat output temperature respectively,
cooling
reactors
efficiency
energy
thermal
which is defined as
t7, = (r, -T,,,
The LER’s
thermal possible
endurance
enhancement,
and (8) easier mass production
Then, the LER would have a possibility
(6) no requirement
for
of plant induced by low-
for the promotion
of the nuclear
energy
utilization.
3. DECENTRALIZED The LER is expected system, machines.
because
LER output
As mentioned
COGENERATION
to be suitable temperature
in the Introduction,
uses is for heating and cooling below 100°C. with conventional
heat transformation
for thermal
agrees
SYSTEM energy
BASED ON LER
source
with the operation
for a decentralized
condition
a major part of energy demands The production
cogeneration
of common
at residential
cogeneration
and commercial
of heat and cold energy below 100°C by LER
system would have practical
possibility.
Three types of cogeneration
Y. Kato
408
systems based on the LER are proposed
in Fig. 4.
In Case 1, the LER is combined
pump and a heater to produce
cold and warm heats.
coolant
state.
water at vapor/liquid
device and the absorption and warm heats. generation.
In Case 2, the LER’s
systems
are driven
cascade. . . Q
instead
thermally
Thermal
specifications
of those cogeneration
output
heat is consumed
fundamentally,
device
and utilize
LER’s
The specifications
by
electricity,
is introduced thermal
of these cases is estimated
in Fig. 4.
heat
at a thermoelectric
system generating
of the thermoelectric
performance
components
with an absorption
output from the LER is transferred
That is a tri-generation
heat pump and heater.
In Case 3, a steam turbine
Those
The thermal
cold
for trioutput
in
using conventional
of those components
are
defined as follows. (1) Absorption
heat pump
An absorption
heat pump (Ab) of a double effect steam absorption
media
is employed
indicates results
efficiency (SANYO
employed,
from inlet-water Co., Ltd.,
operation
(heat transformation
A value of coefftcient
mode),
of performance
of the heat pump, is taken from practical
1997).
The COP for the cooling,
(COP,
absorption
COP+
as working a chilled [-I), which heat pump’s
=~Wco,JWg,of 1.20 is
Wcoo, [kW] and W, [kW] mean a cold heat output from Ab and a recovered heat at a Under the heating operation (using a single effect absorption heat pump of Ab, respectively.
where
regenerator
heating operation, generated
operation),
from inlet-water at 20°C. The COP at the [kW] indicates a warm heat output where W,,,,,
warm water at 70°C is produced
COP,,,=I W,,,(IW,,
of 1.70 is employed,
from Ab.
(2) Thermoelectric
device
The Bi,Te, thermoelectric
device using (Bi,Sb),Te,
for the estimate
temperature maximum
the cooling
at 12°C.
of heat transformation Electric
under heat amplifier
adopted
Under
for the estimate.
water at 5°C is produced
chiller type using LiBr-water
because
the working
for p-type element temperature
range around 200°C with high thermoelectric thermoelectric
wcle =L= ma* 77 wr
transformation
r, - Td,h T
efficiency,
and Bi,(Se,Te),
of the device
transformation
r,r,,,,,[-I, is expressed
for n-type element
covers
efficiency
the LER
(Nishida,
is
operation
1996).
The
by,
M-l
(2)
A4 + Td,hIT,
M=JE
(3)
In which a figure of merit, Z [K-l], of 2.3~10.~ is employed
for the device material,
Wd,e[kW] and Td,h[K] depict the heat output rate and output temperature from the device, and the cooling side temperature
where W, [kW], T, [K],
from the LER, the electric output The generation efficiency of
on the device, respectively.
the device r,r,,,, is used for the estimate. (3) Steam turbine A Rankine
cycle steam turbine having an isentropic
efficiency
of 85% is employed.
4. RESULTS AND DISCUSSION Results for the thermal performance estimate of the thermal performance at 200°C (TJ as a representative.
of the proposed
systems
are shown in Figure 5.
It is presumed
in the
for the cases l-3 that the thermal output from the LER is 100 kW,, (W,) Figure 5(a) shows the operation
temperature
range in each process and
Fig. 5(b) shows the enthalpy balance in each case. (1) Case 1:
The thermal
output
of 200°C from LER is consumed
by the absorption
heat pump
(Ab)
Decentralized
energy
Case 2
409
utilization
Case 3
Ab: Absorption heat pump Ht: Heater TE: Themx&ctric device ST: Steam turbine
I A
B
C
Fig. 5 Enthalpy balance of LER cogeneration
systems: A: enthalpy balance of the each case operation, B
and C: generated cold and warm heat by absorption heat pump, D: consumed enthalpy by the heat pump, E: generated
warm heat by a heater, F: generated
electricity
device, G: generated
by the thermoelectric
electricity by the steam turbine, H generated electricity by a steam turbine, J and K generated cold and warm heat by a compression
heat pump driven by the electricity of H.
between
200°C and 95°C and by the heater (Ht) between
reheated
to 200°C in the LER.
exhausted
from the regenerator
The temperature
of Ab, adapts for practical
warm water temperature
for general
comprises
of a consumed
three columns
the cooling
operation
The temperature (2) Case 2:
purpose
(B), and a generated enthalpy
operation.
in residential
enthalpy
The exhausted
(A), a generated
uses.
The enthalpy
as
balance
cold heat output at 5°C by Ab in operation
(0.
Parts of D (96 kW) and E (4.2 kW) in the column
by Ab and the thermal output from Ht, respectively.
The thermal output at 200°C from the LER is used by the thermoelectric by the TE.
of the water
70°C is suitable
warm heat output at 70°C by Ab in the heating
200°C and 16O”C, and by the Ab between output generated
heat at 70°C is
temperature
The temperature
and commercial
balance
5°C is proper for a room space cooling.
A show the consumed
95°C and 70°C.
95”C, which is a condensing
The temperature
160°C is high enough for the operation
two columns
show cooling and heating output generated
(3) Case 3:
Output between
device (TE) between
A part of F (1.6 kW) shows the electricity
160°C and 95°C.
of the Ab.
The other
by the Ab.
200°C and 160°C from the LER is used by the steam turbine (ST), and between
160°C and 95°C by the Ab. (4) Case 4: the comparison
This case utilizes
lOOkW,, output at 300°C generated
of LER and LWR performances.
warm heat generated
from a compression
steam turbine using the LWR (Egawa,
Columns
by common
of J (136 kW) and K (170 kW) depicts cold and
heat pump driven by an electricity
1998).
light water reactor (LWR) for generated
The cold and warm heat conditions
(H, 34 kW) from a
are the same condition
of
Ab. In Case 1, the cooling Ab.
output of 115 kW at 5°C and heating
The heat pump utilizes well the LER output.
output of 163 kW at 70°C are generated
Electricity
consumption
of the absorption
by the
heat pump is
410
Y. Kato
less than 1% of whole thermal input. Then, in Case 2, the system could be operated independently without electricity supply from outside. In case 3 the electricity output (W,,=6.9 kW) is small since only steam pressure change is used for power generating. When the LER output from 200°C to 95°C is consumed fully by the ST, the electricity of 20 kW, is generated. Then the electricity generation by the LER is required for further discussion because the generation efficiency is obviously smaller than LWR’s in Case 4 (34 kW). On the other hand, cooling or heating outputs of Cases 1 or 2 is almost comparable with one of Case 4, because the absorption heat pump has generally high heat transformation efficiency compared with a compression heat pump. A fundamental thermal performance of a thermal process is defined by the ideal thermal efftciency, r,rc,proceu, defined by Eq. (1). Then, a thermodynamic validity of the LER can be depicted as follows, (4) where CL,, and CL, [price/kW] are the energy production costs per unit output of the LER and LWR system, respectively. If CL, of an LER system satisfies Eq. 4, the LER system could have economical validity as a rational energy system.
5. CONCLUSIONS A combined-cogeneration system based on LER and LWR is proposed from the estimate. LER system is suitable for thermal energy supply, which are major energy demands at residential and commercial uses. Since common LWR is superior to LER for electricity supply, then an LER and LWR combinedcogeneration system has a possibility for one of future energy systems. The combined system supplies cold and warm heat by LER at a decentralized energy network and electricity by large centralized network of LWR. LER is realized by using fission products (Sato, 1976) and some advanced small LWR reactor designs. When the LER output is mainly utilized by an absorption heat pump, above 90°C of LER’s output temperature is available. When an LER system. satisfies the condition defined as Eq. 4, the LER system will have rational validity. Acknowledgement The author greatly thanks to Mitsubishi Heavy Industry Ltd., Sanyo Electric Co., LTD., Tokyo Electric Power Company, Tokyo Gas Co., Ltd. and Dr. Tom Obara for their useful advice. References Danish Energy Agency (1998), Combined Heat and Power in Denmark. Egawa K. (1998), DHC Systems Utilizing Computer Heat, Swage Heat and Sea Water. Energy and Resources 19,504. The Energy Data and Modeling Center (1999), 1999 Handbook of Energy & Economic Static in Japan, The Energy Conservation Center, Tokyo Lenssen N. (1999), The Current Situation of Micro-cogeneration in the United States, Proceedings of Cogeneration Symposium ‘99, p. 339, Tokyo, October. Nishida A. (1996), Evaluation of Thermoelectric Properties and High Performances in Improvement Program for Thermoelectric Materials, Material Japan 35,943 SANYO Electric Co., Ltd. (1997), Absorption Heat Pumps, No. 9711ASlB Sato 0. (1976), Utilization of Fission Produced Radioisotopes, Seisan-ken@ 28, 11
Pergamon www.elsevier.com/locate/pnucene
PII:SO149-1970(00)00079-2
LOW EXERGY REACTOR FOR DECENTRALIZED
YUKITAKA
Research
Laboratory
KATO
for Nuclear Reactors,
Tokyo Institute 0-okayama,
ENERGY UTILIZATION
of Technology,
Meguro-ku,
Tokyo 1528550,
Japan
ABSTRACT A new
conceptual
proposed by
the
and its possibility reactor
environmental
that
water reactors combined
thermal
energy
trend.
energy
Cogeneration energy
supply of the
(LER)’ was
The LER is defined at a temperature
systems
based
on the LER
The enthalpy
was evaluated
system
light
based on the
device and steam turbine
utilization.
systems LER
near
is lower
by the conventional
of the LER was discussed
heat pump, thermoelectric
efficiency
reactor
100°C and 300 “C, which
of the energy generated
for decentralized
those decentralized The
about
The necessity
with absorption
nuclear
qualitatively.
low-exergy
between
technology
were proposed
‘low exergy
was discussed
temperature (LWR).
energy
named
generates
temperature
than the output present
reactor
was
using practical
compared
conventional
LWR system.
decentralized
heating and cooling system. 0 2000 Elsevier
balance
with
Science
data.
that
The LER system was expected to be suitable
of of
for a
Ltd. All
rights reserved. 1. INTRODUCTION Because of recent rapid change in the electricity expected
to be changed
in order to enhance conventional Agency,
drastically
cogeneration
1998).
in the next decades.
energy utilization
systems are installed
Recently
developed
down of the supply area from districts Then, energy generation energy generator.
efficiency
generation
technology,
Cogeneration
and the reduction
systems
the energy supply system is have become
of carbon dioxide
in an area less than about 10 km in diameter
fuel cell and micro-gas to smaller
turbine
technology
areas, that is, buildings
Generally,
(Danish
have enhanced
and residences
Energy the size-
(Lenssen,
1999).
has been no longer special subject, and citizen will be able to own easily a personal
For new nuclear energy systems in future, we would have to consider
supply of non-nuclear
more popular
emission.
systems.
It means that decentralization
key issues for nuclear systems in future. 405
and cogeneration,
such a trend in the
and cost-down
would be
406
Y. Kato Cooling
Cooking
Fig. 1 Energy consumption share at residential and commercial use in Japan in 1997 (Energy
Residential use Commercial use
Data and Modeling
for decalized
commercial
system,
enew
uses in Japan in 1997 (Energy
of 26.0 % in whole national
energy
quality
such as hot water, heating
quality
of electricity
shows a comparison ordinate
Figure
power.
which
Data and Modeling
consumption
of energy
supply scale between
output
of each plant.
is the most developed
country
nuclear reactors is defined by International small reactor defined
by IAEA would
decentralized
system,
supply
energy
accompanied
by heat transfer
a plant like a conventional
scale less than about
because
1 and 2, a reactor
decentralized
cogeneration
smaller
for practical
expensive
0 m
IAEA.
reactor plants.
are operated
Industrial
use.
in
of the
For the discussion is indispensable.
because
these
of The
supplies
are
Larger amount of output from
but thermal
energy distribution
for practical
decentralized
scale for decentralized
in
Then an electrical energy
supply
energy system.
From
(temperature)
output
is suitable
for
REACTOR
in order to meet the requirements
for the decentralized
of
CHP
.
Ornhq CHP plant for 400 people , _........................................................
0 -
100
200
Heat outpur temperature
300
400
500
Ryslinge folk high.__..._........._ school . . . ..___ r...f~~j~s~~~~~~
Fig. 2 Relationship between common energy systems and output scale [I]
600
from a process, T , [‘%I
Fig. 3 Definition of the low exergy reactor, LER 0.1
2
The
practically
The classification
process
cost.
and lower-quality
Figure
A smaller reactor than the ultra
system,
plumbing
energy.
plant
Tomatogleenhpuses _ . . . .. ..__‘“‘iii~~.i;eter~-..._
. .
plants
decentralized
expected
is appropriate
amount
reactor LER is proposed
m Vivorg LargeCHP for 30,000 people
,6
plants and nuclear
of higher cost for the heat transportation.
2. LOW EXERGY
‘jb 2
to low-exergy
Those cogeneration
100 MWtherma,is generally
having
corresponds
energy system.
A conceptual
.o .&
with low with high
larger area for consumption,
plant, and an area having a few km of diameter Figs.
Demand
to the heat transportation
loss and, especially,
the larger area is not economical output
for the energy
the scale of decentralized
reactor requires
and
Both uses occupy the share
in the field of cogeneration.
be required
restricts
1999).
share for residential
100°C is larger than that for the energy
Atomic Energy Agency,
the consideration
of heat and cold energy
Center,
(1.5 lx 10’6kJ/year). below
The energy with low quality
shows the electric
Denmark,
1 shows an energy consumption
and cooling
Center)
100
50 Energy consumption share [%]
0
use.
Decentralized
energy
utilization
407
Case 1
Case 2
Case 3
Fig. 4 Proposed systems for decentralized co- and tri-generation based on LER
The
LER
temperature
is defined around
conventional maximum
light
water
possible
temperature,
by the reactor 100 to 300°C. reactors
thermal
which
produces
low-exergy
Figure 3 shows the maximum (LWR)
efficiency
and fast breeder
(the thermal
environmental
The bold
cycle),
of LER and
line
shows
the
vc [-I, for heat output (1)
and 77, indicates
The reactor that produces output
reactor developments
the exergy range
and commercial
maximum
is not efficient
for power
uses as mentioned
generation,
in the following
The lower temperature benefits
and also (4) higher
reliability
for heating
and
The effort for nuclear
output for power generation
with higher
with high efficiency,
however,
for the reactor design such as (1) simpler design, (2) safety and (3) lower-cost, for operation,
(5) material
in the design, (7) easy maintenance
cost and simple design.
efficiency.
as LER in this paper.
but enough
sections.
output is not suitable for power generation
temperature,
power generation
output than the LWR is defined
in the past was oriented to higher temperature
brings simultaneously new-technology
of a reactor and the environmental
and also the theoretical
lower exergy (temperature)
temperature
at residential
efficiency.
(FBR).
of a Camot
near
efficiency
)/T,
where T, [K] and T,, [K] mean the heat output temperature respectively,
cooling
reactors
efficiency
energy
thermal
which is defined as
t7, = (r, -T,,,
The LER’s
thermal possible
endurance
enhancement,
and (8) easier mass production
Then, the LER would have a possibility
(6) no requirement
for
of plant induced by low-
for the promotion
of the nuclear
energy
utilization.
3. DECENTRALIZED The LER is expected system, machines.
because
LER output
As mentioned
COGENERATION
to be suitable temperature
in the Introduction,
uses is for heating and cooling below 100°C. with conventional
heat transformation
for thermal
agrees
SYSTEM energy
BASED ON LER
source
with the operation
for a decentralized
condition
a major part of energy demands The production
cogeneration
of common
at residential
cogeneration
and commercial
of heat and cold energy below 100°C by LER
system would have practical
possibility.
Three types of cogeneration
Y. Kato
408
systems based on the LER are proposed
in Fig. 4.
In Case 1, the LER is combined
pump and a heater to produce
cold and warm heats.
coolant
state.
water at vapor/liquid
device and the absorption and warm heats. generation.
In Case 2, the LER’s
systems
are driven
cascade. . . Q
instead
thermally
Thermal
specifications
of those cogeneration
output
heat is consumed
fundamentally,
device
and utilize
LER’s
The specifications
by
electricity,
is introduced thermal
of these cases is estimated
in Fig. 4.
heat
at a thermoelectric
system generating
of the thermoelectric
performance
components
with an absorption
output from the LER is transferred
That is a tri-generation
heat pump and heater.
In Case 3, a steam turbine
Those
The thermal
cold
for trioutput
in
using conventional
of those components
are
defined as follows. (1) Absorption
heat pump
An absorption
heat pump (Ab) of a double effect steam absorption
media
is employed
indicates results
efficiency (SANYO
employed,
from inlet-water Co., Ltd.,
operation
(heat transformation
A value of coefftcient
mode),
of performance
of the heat pump, is taken from practical
1997).
The COP for the cooling,
(COP,
absorption
COP+
as working a chilled [-I), which heat pump’s
=~Wco,JWg,of 1.20 is
Wcoo, [kW] and W, [kW] mean a cold heat output from Ab and a recovered heat at a Under the heating operation (using a single effect absorption heat pump of Ab, respectively.
where
regenerator
heating operation, generated
operation),
from inlet-water at 20°C. The COP at the [kW] indicates a warm heat output where W,,,,,
warm water at 70°C is produced
COP,,,=I W,,,(IW,,
of 1.70 is employed,
from Ab.
(2) Thermoelectric
device
The Bi,Te, thermoelectric
device using (Bi,Sb),Te,
for the estimate
temperature maximum
the cooling
at 12°C.
of heat transformation Electric
under heat amplifier
adopted
Under
for the estimate.
water at 5°C is produced
chiller type using LiBr-water
because
the working
for p-type element temperature
range around 200°C with high thermoelectric thermoelectric
wcle =L= ma* 77 wr
transformation
r, - Td,h T
efficiency,
and Bi,(Se,Te),
of the device
transformation
r,r,,,,,[-I, is expressed
for n-type element
covers
efficiency
the LER
(Nishida,
is
operation
1996).
The
by,
M-l
(2)
A4 + Td,hIT,
M=JE
(3)
In which a figure of merit, Z [K-l], of 2.3~10.~ is employed
for the device material,
Wd,e[kW] and Td,h[K] depict the heat output rate and output temperature from the device, and the cooling side temperature
where W, [kW], T, [K],
from the LER, the electric output The generation efficiency of
on the device, respectively.
the device r,r,,,, is used for the estimate. (3) Steam turbine A Rankine
cycle steam turbine having an isentropic
efficiency
of 85% is employed.
4. RESULTS AND DISCUSSION Results for the thermal performance estimate of the thermal performance at 200°C (TJ as a representative.
of the proposed
systems
are shown in Figure 5.
It is presumed
in the
for the cases l-3 that the thermal output from the LER is 100 kW,, (W,) Figure 5(a) shows the operation
temperature
range in each process and
Fig. 5(b) shows the enthalpy balance in each case. (1) Case 1:
The thermal
output
of 200°C from LER is consumed
by the absorption
heat pump
(Ab)
Decentralized
energy
Case 2
409
utilization
Case 3
Ab: Absorption heat pump Ht: Heater TE: Themx&ctric device ST: Steam turbine
I A
B
C
Fig. 5 Enthalpy balance of LER cogeneration
systems: A: enthalpy balance of the each case operation, B
and C: generated cold and warm heat by absorption heat pump, D: consumed enthalpy by the heat pump, E: generated
warm heat by a heater, F: generated
electricity
device, G: generated
by the thermoelectric
electricity by the steam turbine, H generated electricity by a steam turbine, J and K generated cold and warm heat by a compression
heat pump driven by the electricity of H.
between
200°C and 95°C and by the heater (Ht) between
reheated
to 200°C in the LER.
exhausted
from the regenerator
The temperature
of Ab, adapts for practical
warm water temperature
for general
comprises
of a consumed
three columns
the cooling
operation
The temperature (2) Case 2:
purpose
(B), and a generated enthalpy
operation.
in residential
enthalpy
The exhausted
(A), a generated
uses.
The enthalpy
as
balance
cold heat output at 5°C by Ab in operation
(0.
Parts of D (96 kW) and E (4.2 kW) in the column
by Ab and the thermal output from Ht, respectively.
The thermal output at 200°C from the LER is used by the thermoelectric by the TE.
of the water
70°C is suitable
warm heat output at 70°C by Ab in the heating
200°C and 16O”C, and by the Ab between output generated
heat at 70°C is
temperature
The temperature
and commercial
balance
5°C is proper for a room space cooling.
A show the consumed
95°C and 70°C.
95”C, which is a condensing
The temperature
160°C is high enough for the operation
two columns
show cooling and heating output generated
(3) Case 3:
Output between
device (TE) between
A part of F (1.6 kW) shows the electricity
160°C and 95°C.
of the Ab.
The other
by the Ab.
200°C and 160°C from the LER is used by the steam turbine (ST), and between
160°C and 95°C by the Ab. (4) Case 4: the comparison
This case utilizes
lOOkW,, output at 300°C generated
of LER and LWR performances.
warm heat generated
from a compression
steam turbine using the LWR (Egawa,
Columns
by common
of J (136 kW) and K (170 kW) depicts cold and
heat pump driven by an electricity
1998).
light water reactor (LWR) for generated
The cold and warm heat conditions
(H, 34 kW) from a
are the same condition
of
Ab. In Case 1, the cooling Ab.
output of 115 kW at 5°C and heating
The heat pump utilizes well the LER output.
output of 163 kW at 70°C are generated
Electricity
consumption
of the absorption
by the
heat pump is
410
Y. Kato
less than 1% of whole thermal input. Then, in Case 2, the system could be operated independently without electricity supply from outside. In case 3 the electricity output (W,,=6.9 kW) is small since only steam pressure change is used for power generating. When the LER output from 200°C to 95°C is consumed fully by the ST, the electricity of 20 kW, is generated. Then the electricity generation by the LER is required for further discussion because the generation efficiency is obviously smaller than LWR’s in Case 4 (34 kW). On the other hand, cooling or heating outputs of Cases 1 or 2 is almost comparable with one of Case 4, because the absorption heat pump has generally high heat transformation efficiency compared with a compression heat pump. A fundamental thermal performance of a thermal process is defined by the ideal thermal efftciency, r,rc,proceu, defined by Eq. (1). Then, a thermodynamic validity of the LER can be depicted as follows, (4) where CL,, and CL, [price/kW] are the energy production costs per unit output of the LER and LWR system, respectively. If CL, of an LER system satisfies Eq. 4, the LER system could have economical validity as a rational energy system.
5. CONCLUSIONS A combined-cogeneration system based on LER and LWR is proposed from the estimate. LER system is suitable for thermal energy supply, which are major energy demands at residential and commercial uses. Since common LWR is superior to LER for electricity supply, then an LER and LWR combinedcogeneration system has a possibility for one of future energy systems. The combined system supplies cold and warm heat by LER at a decentralized energy network and electricity by large centralized network of LWR. LER is realized by using fission products (Sato, 1976) and some advanced small LWR reactor designs. When the LER output is mainly utilized by an absorption heat pump, above 90°C of LER’s output temperature is available. When an LER system. satisfies the condition defined as Eq. 4, the LER system will have rational validity. Acknowledgement The author greatly thanks to Mitsubishi Heavy Industry Ltd., Sanyo Electric Co., LTD., Tokyo Electric Power Company, Tokyo Gas Co., Ltd. and Dr. Tom Obara for their useful advice. References Danish Energy Agency (1998), Combined Heat and Power in Denmark. Egawa K. (1998), DHC Systems Utilizing Computer Heat, Swage Heat and Sea Water. Energy and Resources 19,504. The Energy Data and Modeling Center (1999), 1999 Handbook of Energy & Economic Static in Japan, The Energy Conservation Center, Tokyo Lenssen N. (1999), The Current Situation of Micro-cogeneration in the United States, Proceedings of Cogeneration Symposium ‘99, p. 339, Tokyo, October. Nishida A. (1996), Evaluation of Thermoelectric Properties and High Performances in Improvement Program for Thermoelectric Materials, Material Japan 35,943 SANYO Electric Co., Ltd. (1997), Absorption Heat Pumps, No. 9711ASlB Sato 0. (1976), Utilization of Fission Produced Radioisotopes, Seisan-ken@ 28, 11