Photovoltaic Systems Engineering Session 19 Solar+Storage Systems

Slides:

Advertisements

Similar presentations

PhotoVoltaic System Sizing © ARJ This is not a How-To presentation. It is a What and Why presentation.

Advertisements

7. PV System Sizing Herb Wade Consultant

Solar Schoolhouse and San Mateo College Designing and Installing Solar Electric Systems Types of Solar Electric Systems For Technology Teachers San Mateo.

Saskatoon Wildlife Sports and Leisure Show, March 6-9, 2003 Slide 1 Electricity from the Sun A Brief Introduction to Photovoltaic Energy Systems.

Rooftop Solar Systems Rooftop Solar System (Off-Grid) Reliance Solar Energy™, Ratnagiri.

THE PROCESS OF DESIGNING A PV SYSTEM

Nameplate Test Results for 30 Watt Solar Panel Shown in Class, Nov.

Inverters. Inverter Functions Change DC to AC Change DC to AC Increases or decreases voltage from array voltage to: Increases or decreases voltage from.

Photovoltaic Solar Cells and Solar Energy Systems for Home Usages Mohammad Anisuzzaman.

Power Electronics Battery Charging System Supplying Power to Ink.

UDC ZERO ENERGY VISTOR CENTER. System Components Solar Array –Primary Power Generator –Array consists of 12 BP SX3190B Solar Modules.

How to determine whether solar energy is right for your site EE80S: Sustainability Engineering and Practice Fall 2007.

Solar Lightings Solar Module. Charge Controller. Battery. Inverter. Loads Accessories.

Solar PV Design Implementation O& M March 31- April 11, 2008 Marshall Islands ２． Solar Home Systems (SHS) ２． Solar Home Systems (SHS) Herb Wade PPA Consultant.

Off-Grid Power Using Enphase Micro-Inverters Off-grid inverter systems, using batteries, can be used to provide AC power when the grid is down. It is possible.

Station Battery Solar AC Source Home Batteries Battery Chargers.

Designing Solar PV Systems (Rooftops ). Module 1 : Solar Technology Basics Module 2: Solar Photo Voltaic Module Technologies Module 3: Designing Solar.

PV System Components Advanced Engineering The Technology Landstown High School.

Components Three Basic Parts to an Active PV System: –Collector/Harvestor –Storage –Distribution More complex systems need –Inverter –Charge Controller/Voltage.

PV off Grid Design Eng. Laith Basha

Nuclear Fissionary, April 2, 2010 Why are prices declining?  Generally, solar panels make up about 50% of the cost of a system (40% for thin film),

Michael Ikerionwu 4 th year Electronic Engineering.

Power Electronics Needs and Performance Analysis for Achieving Grid Parity Solar Energy Costs T. Esram, P. T. Krein, P. L. Chapman Grainger Center for.

Photovoltaic Systems – Residential Scale Part 2 April 2, 2014.

Europe Sun Light Map System Voltage : Volts ConsumeGüç(W) Hour Energy Need(W) Kapasite(Ah) Kitchen led Bathroom led101.

Balance of Systems (BOS)

Station Backup Power & Solar Powering your station.

Stand-Alone PV Systems, Part 2

Battery Backup PV Systems Design Considerations

Economic Comparison off Grid System. Q1 : Sizing of Solar Panel System Let us consider that one house needs following loads; 10W, 2 lamps for 3 hours.

1. 2 PRODUCTS OF C.E.L Solar Photovoltaic Cells Solar Photovoltaic Modules Cathodic Protection Electronic Ceramics Railway Electronics Microwave Electronics.

Solar Tank Storage vs Batteries. Two important concepts Water per day –Total water requirements for the application –Pump water during daylight hours.

Unit 15 Dimensioning of a Solar/Battery Backup system Developed by: Alberto Escudero Pascual. IT+46.

SEC598F16 Photovoltaic Systems Engineering Session 12 PV System Components Inverters Balance of Systems (BOS) October 04, 2016.

Assessment and Design of Rooftop Solar PV system

Photovoltaic and Battery Primer

Photovoltaic and Battery Primer

Solar photovoltaic (PV)

Asst. Prof. Dr. Sameer Saadoon Algburi

Solar Energy Improvement Techniques

Photovoltaic Systems Engineering Electronic Control Devices (ECDs)

Photovoltaic Systems Engineering Electronic Control Devices (ECDs)

Example of PV System Design

Photovoltaic Systems Engineering Session 15 Stand-Alone PV Systems

Photovoltaic Systems Engineering Session 16 Stand-Alone PV Systems

Photovoltaic Systems Engineering Session 21

Photovoltaic Systems Engineering Session 22 Solar+Storage Systems

Photovoltaic Systems Engineering Stand-Alone PV Systems – Review

Photovoltaic Systems Engineering Session 19

Photovoltaic Systems Engineering Residential Scale – Part 2

Photovoltaic Systems Engineering Session 27

Photovoltaic Systems Engineering Session 26

SOLAR INSTALLATION AND DESIGN: THE DOS AND DON’TS

Photovoltaic cell energy output:

Photovoltaic (PV) Systems

Sizing Methodologies • Sizing Calculations

Photovoltaic Systems Engineering Session 10

Photovoltaic Systems Engineering Session 11

Photovoltaic Systems Engineering Session 16 Solar+Storage Systems

Photovoltaic Systems Engineering Session 12

Elements of a Small Off-Grid 24 Volt Solar System

THE STUDY OF SOLAR-WIND HYBRID SYSTEM PH301 RENEWABLE ENERGY

Photovoltaic Systems Engineering Session 17 Solar+Storage Systems

Photovoltaic Systems Engineering Residential Scale – Part 2

Photovoltaic Systems Engineering Session 19a Solar+Storage Systems

Photovoltaic Systems Engineering Session 18 Solar+Storage Systems

Components inverters Except where otherwise noted these materials are licensed Creative Commons Attribution 4.0 (CC BY)

Photovoltaic Systems Engineering Session 22

Photovoltaic Systems Engineering Session 23

Electricity demand in the UK and modelled solar production, assuming 40 GW of solar capacity. Electricity demand in the UK and modelled solar production,

Presentation transcript:

Photovoltaic Systems Engineering Session 19 Solar+Storage Systems SEC598F18 Photovoltaic Systems Engineering Session 19 Solar+Storage Systems Stand-Alone Systems, part 1 November 07, 2018

Session 19 content Stand-Alone PV Systems Scale of stand-alone systems Design basics Inverter and battery selection BOS components

Learning Outcomes An examination of the original photovoltaic systems at small scale (solitary electrical components).

Stand-Alone PV Systems – Design Steps Examples of stand-alone PV systems Solar powered accent lights Solar powered portable devices Solar powered water pump Solar powered fan Solar powered lighting systems Stand-alone refrigerator Stand-alone residences Stand-alone communication systems

Stand-Alone PV Systems – Design Steps Solar powered portable devices

Stand-Alone PV Systems – Design Steps Solar powered portable devices

Stand-Alone PV Systems – Design Steps Solar powered fan

Stand-Alone PV Systems – Design Steps Stand-alone (and remote) structure

Stand-Alone PV Systems – Design Steps Stand-alone communication system

Stand-Alone PV Systems – Design Steps Steps in stand-alone component design Evaluation of solar availability, electrical consumption, essential electrical loads Battery selection PV array sizing Module selection Charge controller selection Inverter selection Balance of system

Example 1. A stand-alone solar-powered refrigerator for home brewing. A friend has an old house in Phoenix with a set back garage that has limited electrical service. Upgrading the service would require extensive trenching from the service panel, which he would prefer to avoid. In this project, we shall design a stand-alone PV system designed to power a refrigerator that will be used for fermentation and aging 5-gallon containers of home-brewed beer. This beer will be Peter’s Solar IPA or something similar.

Example 1. A stand-alone solar-powered refrigerator for home brewing. Evaluation of solar availability, electrical consumption, essential electrical loads The Kenwood refrigerator draws about 386kWh per year (Energy Star sticker), so that it has a daily use of roughly 1.1kWh. This is consistent with its nominal power draw (200W) and 5 hours/day operation. To account for inverter losses of approximately 5% and to meet electrical surges at start, I shall choose a 300W pure sine wave inverter:

Example 1. A stand-alone solar-powered refrigerator for home brewing. Inverter: Aims, model pwri30012s 120 V ac, 10V-12V dc input Load on the batteries would be : where the refrigerator load is adjusted by the inverter losses (0.95) and approximate wire losses (0.98).

Example 1. A stand-alone solar-powered refrigerator for home brewing. The energy capacity of the batteries has to be adjusted for round trip charge/discharge efficiency of the batteries and the depth of discharge limit. We shall use Pb-Acid batteries, so c/d (roundtrip) efficiency is about 88% and the state of charge (SOC) has to remain above 20% (or the depth of discharge less that 80%), so the adjusted load is: We can use 12V batteries, so the daily charge capacity would be:

Example 1. A stand-alone solar-powered refrigerator for home brewing. This is sunny Phoenix, so let’s design the system for one day of autonomy. There are many Pb-acid batteries at 12V with capacity of 75 or more Ah. Let’s use two DEKA AGM batteries with these characteristics: Batteries: DEKA, 12V, AGM Pb-acid Capacity at C/100: 91Ah Capacity at C: -40F to +140F (good for use in Phoenix) The solar modules will be mounted on the west-facing roof of the garage (ok for Phoenix, plenty of sun late of the afternoon), and according to NREL, there is an average of 6 Peak Solar Hours per day. Assuming that the output from the solar modules will be reduced by losses in the charge controller (efficiency of 85%), the readjusted energy going to the inverter is:

Example 1. A stand-alone solar-powered refrigerator for home brewing. So the PV array must produce electrical power of this value: There are a lot of manufacturers that produce 200+ Watt modules. So choose: Charge Controller: Morningstar SunSaver MPPT PV Modules: Canadian Solar 225W

Example 1. A stand-alone solar-powered refrigerator for home brewing. Note: This figure (from M&A) is for illustration only. The correct component values are on the previous slides