This document discusses how combined heat and power with spinning reserve (CHP-SR) can benefit multiple parties by balancing intermittent wind power. CHP-SR involves an electrically oversized thermally matched CHP system that normally operates at reduced power output. It can balance high and low wind power periods more efficiently than a standalone gas turbine by recycling waste heat. Economic analysis shows CHP-SR lowers operating costs for an ethanol plant compared to its boiler, and provides cheaper power than a utility's coal plant or a gas turbine balancing wind. CHP-SR benefits include reduced steam costs for the ethanol plant, reliable power for the grid, and help for utilities to address emissions regulations while retaining customers.
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Additionally, this presentation contains information on Power Purchase Agreement (PPA)/On-Site Utility.
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1. Organized by: Supported by: Including:
Gas CHP with Spinning Reserve
Balances Wind Power
Suresh Jambunathan
Director of Business Development
Recycled Energy Development
sjambunathan@recycled-energy.com
630-335-4544
April 3, 2014
2. Who is Recycled Energy Development (RED)?
• Private Equity backed energy project developer – we finance, own, operate energy projects
at industrial sites (“Host”).
• We take full energy-project responsibility including CapEx and OpEx risk.
• Host executes a long-term Energy Services Agreement and enjoys lower energy costs, thus
becoming more competitive.
• Our principals have collectively invested >$3 billion and commissioned > 250 projects
during the last 35 years
•In September 2013, we acquired Kodak’s utility infrastructure at the Eastman Business Park
(EPB), Rochester, NY.
• Utility services (125 MW power, steam, chilled water, compressed air, sewer
services, nitrogen, natural gas and potable water) to >40 businesses at the park.
• Investments in gas fired assets to meet the EPA’s Boiler MACT criteria.
• We also own and operate CHP assets in CA, NJ and MA
3. Trends: wind-power & gas are up; coal is flat
Ethanol production is
well positioned to profit
from recent macro-
economic trends
4. IMAGE SOURCES: Ethanol <ethanolrfa.org>, Wind <awea.org> Coal <ACEEE>, Gas (<eia.gov>
Observation: Plenty of natural gas, ethanol plants,
wind turbines and coal power plants
Ethanol plants
Wind mills
Wind increasing
Coal decreasing
Gas: cheap & plentiful
Ethanol plant has :
Gas supply
Elec. Sub-station
5. Energy generation at corn ethanol plant, utility
coal boiler and a wind-turbine farm
* Plant
Boiler
ή = 80%
Ethanol
plant
operations
Gas
** Utility
Boiler
ή = 75%
Condenser
& Cooling
Tower
Coal
* Usually a Thermal Oxidizer Boiler. **Often a stoker or pulverized coal
Steam
Steam Steam Turbine
Generator
STG
Steam
Heat is used
Heat is wasted
Grid power
Wind-
turbine
Farm
Wind
Grid power
An ethanol plant
pays for heat
A coal power plant
pays to get rid of heat
Wind? Green power !
So what’s the concern?
No heat
6. Can you run your plant
with unpredictable
power, however “green”
it might be?
Wind power is intermittent and unpredictable
24-hour actual wind power supply in the Midwest ISO (MISO)
50% supply
swing in ~5 hours
8. Coal power faces boiler MACT & low gas prices
Boiler Maximum Available Control Technology (MACT) are emissions control rules for Mercury
(Hg), Filterable Particulate Matter (PM), Hydrochloric Acid (HCl) and Carbon Monoxide (CO)
Finalized by US EPA on Dec. 20, 2012 with short compliance window. Options include
• Spend on pollution control equipment
• Convert coal boiler to burn natural gas or Invest in natural gas boiler
• Invest in a gas Combined Heat and Power system with Spinning Reserve (CHP-SR)
Bag House
ESP
Vintage stoker or
pulverized coal boiler
ή~80%
FSF~ 1,600 Btu/lb
Steam Turbine
Generator
Coal
Steam
3,000 Kpph
300 MW to grid
Flue
Gas
Cleaned
Flue GasFD
fan
or
Condenser
Coal boiler operators
have to comply with
Boiler MACT.
Today, “burner-tip” price
of coal and gas is
essentially the same.
9. Combined Heat and Power with Spinning Reserve
(CHP-SR) can mitigate overlapping concerns
Ethanol plant Utility owned
Coal power plant
Wind Power
producer
CHP-
SR
Entity Concern Traditional solutions
Ethanol Plant
• Cost of steam and grid power
• Drought or flood
• Blend wall
• “Agenda group” criticism
• Preheat feed-water, improve controls
• Demand reduction measures
• Point to oil-import reductions
Coal Utility
• Cost of Boiler MACT regulations
• Cost of coal
• Cost of coal boiler O&M
• Spend on pollution control equipment
• Switch to gas
• Shut down coal plant
Wind Power
Producer
• Loss of value due to inability to
deliver firm capacity
• Blamed for grid instability
• Blamed for being a “subsidy hog”
• Spend on simple cycle Gas Turbine
(GT) to “firm” wind
• Spend on fuel for GT
•Spend on O&M for GT
Traditional solutions
mostly echo
spend, spend and spend
Combined Heat and
Power with Spinning
Reserve (CHP-SR) can
profitably address
concerns
10. The wind balancing value of Combined Heat and
Power with Spinning Reserve (CHP-SR)
CHP-SR is a “common
sense” solution
Spinning Reserve Gas Turbine (SR GT):
A Gas Turbine that continually varies power output
to balance variable wind power generation
Combined Heat & Power with Spinning Reserve
(CHP-SR):
An "electrically oversized” thermally matched CHP
system, normally operating at reduced power output
Heat Rate (HR):
Fuel MMBtu burned per MWh electricity generated
Case
Wind power
supply
Gas Turbine
load
SR GT operating
profile
A High Low Stand-alone
B Low High Stand-alone
C High Low CHP-SR
D Low High CHP-SR
IMAGE SOURCES: Solar turbines
11. Case A: High wind and low load SR GT.
Stand-alone ethanol plant boiler steam
Burning fuel twice is wasteful and inefficient
12. Case B: Low wind balanced by high load SR GT.
Stand-alone ethanol plant boiler steam
Burning fuel twice is wasteful and inefficient
13. Case C: High wind and low load CHP-SR.
Waste heat to ethanol plant.
Burning fuel once and recycling waste heat is efficient and profitable (see next)
14. Case D: Low wind balanced by high load CHP-SR.
Waste heat to ethanol plant.
Burning fuel once and recycling waste heat is efficient and profitable (see next)
15. Economic snapshot: operating assumptions
PARAMETER UNIT VALUE COMMENT
Availability
Of which
hours/year 8,400
Ethanol plant, wind-turbine farm, SRGT,
coal power plant and CHP-SR
High wind hours/year 4,200 Wind trailed by SRGT or CHP-SR
Low wind hours/year 4,200 Wind balanced by SRGT or CHP-SR
Delivered fuel costs
Natural gas $/MMBtu, HHV $5.0
Coal $/MMBtu, HHV $4.0 $100 per ton
System non-fuel O&M
SR GT $/MWh $5.0 Typical, sited at wind-turbine farm
CHP-SR $/MWh $10.0 Typical, sited at Ethanol plant
Coal power plant $/MWh $15.0 Typical
Ethanol plant boiler $/MMBtu steam $1.0 Assumed for Thermal Oxidizer Boiler
Utility Coal boiler
Heat Rate
MMBtu/MWh 12
Typical for older, sub-critical Rankine
cycle coal power plants
Ethanol plant boiler
efficiency
% LHV 80% Assumed
Assumptions are
indicative and
can vary significantly at
individual sites
16. Economics: CHP-SR slashes operating costs
Ethanol Plant Boiler cost $MM/yr $/MMBtu steam
Fuel: Natural gas $13.0 $6.9
non-fuel O&M $1.9 $1.0
TOTAL $14.9 $7.9
Power cost *steam credit Net cost
CHP-SR cost $MM/yr $/MWh $/MWh $/MWh
Fuel: Natural gas $22.8 $60.4 ($34.3) $26.1
non-fuel O&M $3.8 $10.0 ($5.0) $5.0
TOTAL $26.6 $70.4 ($39.3) $31.1
Power cost *steam credit Net cost
SR GT cost $MM/yr $/MWh $/MWh $/MWh
Fuel: Natural gas $22.8 $60.4 - $60.4
non-fuel O&M $1.9 $5.0 - $5.0
TOTAL $24.7 $65.4 - $65.4
*steam credit Net cost
Utility: power plant cost $MM/yr $/MWh $/MWh $/MWh
Fuel: coal $18.5 $49.0 - $49.0
non-fuel O&M $5.7 $15.0 - $15.0
TOTAL $24.2 $64.0 - $64.0
CHP-SR power is
cheaper than
A. Utility self-
generated coal
power
B. Wind power
producer with a
balancing SR GT
* Steam credit reflects value of displaced Ethanol boiler steam
** Value of avoided CapEx impact savings and depends on scope, weighted average cost of capital and Investment
term for all entities – utility, SRGT, CHP-SR and ethanol plant.
17. Benefit to the thermal host (Ethanol plant)
• Reduced cost of steam and increased steam supply reliability
• More reliable power supply
Benefit to Grid (Utility owned Coal Power Plant)
• Balance intermittent renewable power and increase its share of generation fleet
• Profitably address Boiler MACT - avoid compliance CapEx and future increased OpEx
• Enjoy local grid stability including power factor support and reduced line loss.
• Retain thermal host (ethanol plant) as all-requirements power customer
CHP-SR can profitably reduce greenhouse gas
emissions by recycling waste heat
18. Value creation process
Query: What is a Utility (coal boiler power plant) executive contemplating?
View: Probably need to shutter coal power plant due to pressure from
• Boiler MACT
• Disappearing gas-coal price differential
• Renewable energy mandates
Query: What can be done to maintain reliable electric service?
View:
• Execute a Purchase Agreement (PPA) with a CHP-SR developer who can, on grid
operator command balance intermittent wind power
Query: What can an Ethanol plant manager / owner do to profit from these trends?
View:
• Execute a Steam Sale Agreement (SSA) with CHP-SR developer
• Assist CHP-SR developer engage with local utility to implement a CHP-SR project
• Share the profits generated from the project !
CHP-SR recycles
otherwise wasted
energy
CHP-SR benefits all
entities