Cordero 6 a

Modeling and Simulation for Power Systems
Salvador Cordero, MSSE
Regional Cyber and Energy Security Center
rces@utep.edu
915-747-5206
18 October 2012
Re-Energize the Americas Conference

Topics

• Why Modeling & Simulation?
• Modeling & Simulation Tasks
• Modeling Tool Parameters
• Case Study
• Solar PV System
• Microgrid System
• Summary

Copyright @ The University of Texas at El Paso. Proprietary Information 2

Why Modeling & Simulation?


Modeling & Simulation Tasks

• Task 1: Modeling and Prediction of Baseline Energy Consumption.
– Discover and quantify the energy consumption so that power system models can
be developed for renewable energy sources, integration to current infrastructure,
and deployment.
– Discover the “As-Is” Energy System
– Validate the models using measurement data

• Task 2: Analysis for Co-generation and Renewable Energy
Penetration
– Evaluate performance model for the co-generation and renewable energy
integration.
– Combine the models for energy consumption and cost, and add cost benefit
analysis model. The combined model allows the effects of renewable energy and
co-generation installments to be studied from a performance and cost viewpoint
– Develop a common template for evaluating different technologies.


Modeling Tool Parameters

Inputs Results

Loads, Financial Metrics:
Components, Grid LCOE, IRR, NPV,
Tie Payback, etc.
HOMER
Utility Rate *National Renewable
Performance
Structure Energy Laboratory (NREL)
Metrics:
Performance Capacity Factor,
Component Model Annual Output
Parameters
Financial Model Other:
Costs Energy flows, Cash
Sensitivity Analysis flows, Graphs
Economics, System
Control, Emissions,
Controls


Case Study: Model Inputs

Main Campus and Physical Plants
• Project Lifetime
• 30 Years

• Annual Interest Rate
• 2%

• Natural Gas Cost
• $5.00/Mcf based on Facilities’ billing
adjustment credits with supplier

• Combined Rate Schedule
• Current electric rate for Physical Plants
• Current rate was considered for Main Campus
• Blended flat rate for both loads (includes fuel adjustment)
1. Current is at 6.5¢/kWh
2. 15% increase at 7.4¢/kWh
3. 30% increase at 8.5¢/kWh


Case Study: Load Profiles

Physical Plants

*Electric Utility 30 minute meter readings Main Campus


Case Study: Load Profiles

Thermal Load


Case Study: Baseline Model Results

Main Campus & Physical Plants

• Annual Electric Consumption of 62,619,500 kWh/yr

• Annual Gas Consumption of 52,333,392 kWh/yr = 176,546 MMBtu


Case Study: Solar PV System

• One load: Main Campus
• Flat rate structure
• Sensitivity Analysis on cost of Electricity (Current, 15%, 30% Increases)
• Grid Tie Connection
• Two Scenarios:
1. Baseline with 3.3 MW Solar PV
2. Baseline with 5.5 MW Solar PV
• Solar PV System Specifications:

3.38 MW 5.5 MW
Micro-Inverter(95.5% efficiency)
10 Degree Tilt
85% De-rating Factor
30 yr. Lifetime *SUNPOWER T10 Solar Roof Tile
Capital Cost-$12,864,280 Capital Cost-$20,900,000
$ 3.80 per watt ( Panels & Inverters) $ 3.80 per watt ( Panels & Inverters)



3.38 MW PV System 5.50 MW PV System

7,250KW 7,250KW

3,825KW

2,130KW

29.4% of Peak Load 52.8% of Peak Load



• Annual Electrical Production
1. Baseline 0 kWh

2. 3.38 MW PV System 6,236,530 kWh
kWh’s
3. 5.50 MW PV System 10,139,876 kWh Saved
• Annual Grid Purchases
1. Baseline 46,880,920 kWh
13%
2. 3.38 MW PV System 40,644,392 kWh Reduction

3. 5.50 MW PV System 36,929,608 kWh
22%
Reduction



Current Rate 15% Increase 30% Increase

Main Campus Baseline
Cost of Electricity $3,261,809 $3,751,083 $4,240,354
LCOE 7.0¢/kWh 8.1¢/kWh 9.1¢/kWh
3.38 MW System
Savings $416,701 $479,209 $541,714
ROI -2.8% 11.7% 26.3%
5.50 MW System
Savings $676,736 $778,250 $879,760
ROI -3.0% 11.5% 26.1%


Case Study: Microgrid System

Assumptions:
• Two electrical loads: Main Campus and
Physical Plants
• One thermal load
• Constant cost for Natural Gas
• No Grid Tie Connection
• Self-Generation
• 5.5 MW PV System
• CHP System with two 7.5 MW Turbines
• Energy Storage System (1 MWh)



Component Specifications:
• Solar PV System
• Size- 5.5 MW
• Derating factor- 82%
• Cost- $20,900,000
• CHP System
• Size- Two 7.5 MW turbine generators *SUNPOWER T10 Solar Roof Tile
• Efficiency- 83.7%
• Heat recovery- 75%
• Cost- $20,741,284
• Energy Storage System
• Capacity- 1 MWh
• Voltage- 12 V *Solar Turbines Centaur 70
• Round trip efficiency- 90%
• Cost- $1,000,000
• Total Investment Cost = $42,641,284 *Xtreme Power DPR


Facility Case Study: Microgrid System

Current Rate 15% Increase 30% Increase
Baseline for Combined Loads
Cost of Electricity (Annual) $4,070,259 $4,633,833 $5,322,647
Cost of Gas (Annual) $1,001,033 $1,001,033 $1,001,033
Total Utility Cost (Annual) $5,071,292 $5,756,367 $6,382,561
Microgrid System
LCOE 7.7¢/kWh
Total Operating Cost $3,942,864/yr.
Savings $1,128,428 $1,813,503 $2,439,697
ROI -21% 28% 72%

*ROI based on initial investment of $42,641,284 and only 30 year lifecycle.


Summary: Case Study

Integrating energy resources into a comprehensive management strategy
can optimize energy security and system reliability to avoid grid standby
charges and/or outages.

• Solar PV reduces peak demand and yearly operating costs

• Multiple units will provide power generation redundancy to improve reliability and avoid
electric rate stand-by charges.

• Multiple units reduces individual operational running times which extend system’s
lifetime and provides maintenance flexibility.

• Hybrid co-generation of Solar PV and gas turbines provide load balancing capability
to a micro-grid:
o Co-generation backs up the solar PV systems during periods of intermittency to
avoid grid demand charges


Questions


Cordero 6 a

Recommended

Recommended

More Related Content

What's hot

What's hot (20)

Viewers also liked

Viewers also liked (8)

Similar to Cordero 6 a

Similar to Cordero 6 a (20)

Cordero 6 a

Editor's Notes