Solar Energy: Is It FeasibleSolar Energy: Is It FeasibleIn Greenhouse OperationsIn Greenhouse Operations

By Paul A. Thomas, By Paul A. Thomas, University of GeorgiaUniversity of Georgia

2006 Oklahoma Conference

A naturally balanced budget

Fact:

A patch of 100 square miles of open space covered with efficient solar panels such as in Nevada, where sun rays are powerful, could generate all the electrical power needs of the United States.

National Renewable Energy Laboratory

FACT!

Making sense of that statement….

How much area is this per person?

416 m2 per person 4,500 square feet to meet the average persons energy needs

Ways of using solar energy

• Direct heating of flat panel (fluids, space heating)

• Passive heating of well-designed buildings

• Thermal power generation (heat engine) via concentration of sunlight

• Direct conversion to electrical energy

Types of Solar Power: Thermal

• Active • Passive

Passive Solar Storage (Heat)

Thermal Panel Features

Hot Water Floor Heating

Solar water heating systems are ideal for greenhouses that use hot water systems under the floors. It is very efficient.

Hot water systems do

require planning, and

a backup heating

system!

Energy Source6/1/2005

Comparitive Cost (Dollars per 90 mmBTU)

Coal $ 816.00

Gas (Natural, Propane) $ 900.00 / $1360.00

Heating Oil $ 1,467.00

Hydro-Electric Not applicable

Biomass $ 750.00

Wind Generated Not Applicable

Solar Heat $ 3,000.00

Retail Electricity (General ) $ 3,065.00

Wood $ 709.00

Nuclear Not Applicable

Photo-Voltaic Not Applicable

HE

AT

ING

EN

ER

GY

Types of Solar Power: Electrical

Who are the biggest users of Solar Power…Hippies?

• The National Park Service

• The Department of Transportation

• State Governments

• Primary and Secondary School Systems

• Most Universities

• Large Corporations

• California / Arizona / Nevada Homeowners

Countries Other Than the U.S.!

What Does The White House Think Of Solar Power?

In 2002, George Bush had 167 Solar Panels installed at the white house, and two solar hot water systems installed. The systemsSupport the outdoor security lighting, the swimming pool and the domestic hot water system.

Shell

The Big PlayersIn Solar Technology

Cumulative Installed PV in the US

0

20

40

60

80

100

120

140

Meg

aWat

ts(p

eak)

1992 1993 1994 1995 1996 1997 1998 1999 2000

Year

Total On-Grid

Total Off-Grid

Source: The 2000 National Survey Report ofPhotovoltaic Power Applications in the U.S.For the IEA Co-Operative Program on PV Power Systems. Prepared by Paul D.Maycock and Ward Bower.

Efficiency Evolution In Solar Power

Energy Source*** Environmentally Sound

Levelized Costs (Cents per kWh)

Coal 4.8 – 5.5

Gas (Natural, Propane) 13.9 – 20.2

Heating Oil 9.0 - 18.0

Hydro-Electric 5.1 – 11.3** NR

Biomass 5.8 - 11.6

Wind Generated 3.8 - 6.0 ***

Solar Heat 11.0 – 15.5***

Retail Electricity ( General ) 8.70 – 19.0

Wood 10.0 – 36.0

Nuclear 11.1 – 14.5 NR

Photo-Voltaic 12.5 - 20.0 ***

EL

EC

TR

IC E

NE

RG

Y

!

!

!

Cost Of Electricity Rising Slowly

Cost Of Solar Energy Is Declining Rapidly !

Solar Technology Fits!

Solar Farms?

Solar Energy Works In The South!

VERY GOOD!

Roof Top Solar Facility

The conversion is accomplished by the material absorbing light and ionizing crystal atoms, thereby creating free, negatively charged electrons and positively charged ions.

These then go to opposing sides of a charged system and form a flow of electrons or “electricity!

Source: Karl W. Boer

Practical GreenhouseUses For Solar Technology

Horizontal Air Flow FansCooling Pad PumpsEmergency LightsPhotoperiod LightingHeating PadsWater Heaters Well / Storage Water PumpsAuto Shade Cloth SystemComputer Controll systems / Solenoids

Consider the HAF Fan

• It runs during “peak cost” hours during the winter.

• It is needed most at night if pad and fans system is used during the summer.

• The SUMMER sun could power the pad and fan pump system directly, and charge the batteries to run the fans at night! In WINTER the system could run the fans during the day using direct DC power.

Typical Yearly Saving Curve For Solar Power

Savings With Photovoltaics

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Monthly Savings

Moving Average

So What Does It Take To Install a PV System

1: Assess Your Energy NeedsIn Terms Of Watts Per Hour

Energy Assessment

• Add up the watts used on each appliance.

• Determine how many hours / day

• Determine seasonal use patterns

• Ad up the total amp-hours needed to be supplied during the greatest period of use for your system’s voltage. Design accordingly!

The Water Wheel

If you have a small, old fashioned water wheel, a hose, and an adjustable spray nozzel you can understand electricity!

If you point the hose at the water wheel, the wheel turns…increase the pressure (volts) or increase the volume of water (amps), and you’ll find the increased force (watts) makes the wheel turns faster!

Basic Electricity

• Amphere = The number of electrons flowing past a point at any given time. (gallons per minute = volume!)

• Volts = The pressure the electrons are under. Remember pounds per sq inch (PSI) for water!

• Watts = The total force the electron flow exerts

• Ohms = The resistance the hose exerts on the flow of the water.

Here Are Some Household Examples

• Typical Electrical Appliance Wattages

Television: 300-400 running watts, 300-400 starting/surge watts

Microwave oven: 700 running watts, 1000 starting/surge watts

Furnace blower (1/3 hp): 600 running watts, 1800 starting/surge watts

Vacuum cleaner: 600 running watts, 750 starting/surge watts

Refrigerator/Freezer: 800 running watts, 2400 starting/surge watts

Toaster: 1200 running watts, 1200 starting/surge watts

Coffee maker: 1200 running watts, 1200 starting/surge watts

Stove element burner: 1500 running watts, 1500 starting/surge watts

Water heater: 5000 running watts, 5000 starting/surge watts

Water well pump (1/2 hp): 1000 running watts, 3000 starting/surge watts

Sump pump (1/3 hp): 700 running watts, 2100 starting/surge watts

Washer: 1440 running watts, 1440 starting/surge watts

Dryer: 5520 running watts (which is why it was hard to use)

Series: Volts increase, Amp-hours remain the same

Parallel: Volts remain the same and theAmp-hours increase!

This allows you to configure how many volts, at how many amp-hours your need

Wire Sizes

The more amps you send, the thicker the wire needs to be……and the longer the run of wire, the more amps you need!

Resistance eats power!

2: Determine The Type of Solar Panels You Wish To Use

How Panels Are Rated

BP 4175 – Silicon-nitride monoRated Power (Pmax): 175 wattsPower tolerance: ± 5%Nominal voltage: 24 voltsLimited Warranty: 25 years

SOLAR PANELS

$ / watts generated

http://upload.wikimedia.org/wikipedia/en/4/4f/Nrel_best_research_pv_cell_efficiencies.png

Solar Energy Works In The South!

riseset

time

Wm-2

1000

500

Steered collector

Solar power incident on a collector at30 deg. South, winter day.

slanted

horizontal

Panel Orientation

• Affects output!

Charge ControllersPrevent overloads and night energy leakage

MPPT vs PWM Controllers

Maximum power-point tracking. It is like a transmission system in your car, it adjusts charging based on need or demand of the battery…very accurate and efficient.

Pulse Width Modulation – Reduces charge current according to the batteries need or status. It slows charging down when near fully changed to prevent overloads. Good, but less efficient.

MPPT vs PWM Controllers

MPPT is much,

much better at

maintaining

battery life than

PWM controllers,

and more costly!

Solar Batteries• Output measured in Amp-Hours!

Example: A battery which delivers 5 amperes for 20 hours delivers 5 amperes times 20 hours, or 100 ampere-hours.)

Types of Batteries

• Starter Batteries - This lead plates &rapid release of power, if discharged often, losses battery life

• Deep Cycle Batteries - Thicker led plates and can be discharged often and fully without loss of life

Flooded - Require frequent addition of battery acid

Sealed - Require less care, difficult to balance

Gel - Requires very little maintenance – Balance?

What Kind Is Best

A typical 6-volt golf cart battery will store about 1 kilowatt-hour of useful energy (6 volt X 220 amp-hr X 80% discharge = 1056 watt-hours).

Avoid using deep-cycle marine batteries …theycan explode! Golf cartbatteries are designed for complete discharge!

Batteries Designed for Solar

Rolls-Surrette Tasman

Batteries Designed for Solar

Battery Storage

Needs to be isolated

Requires maintenance

Must be vented!

Needs to be plannedfor peak demands

Safety equipment required!

DC to AC Power Converters

• Reduces the cost effectiveness of solar

• Must be “scaled” to the load of the system

You May Need to Convert to Direct-Current Equipment

• Lighting and fans are easy to swap out.

• Sump-pumps, solenoids, motors are not!

• The RV industry is 10 years ahead of agriculture, in that almost anything you can use in an RV is now sold as a DC unit!

Basic Solar (PV) System

Basic Greenhouse System

Dual-Backup Electrical System

Grid Connect System System

Grid Access Control Systems

Control excess or redirected power flow to the grid system

Absolutelyrequired by all power companies

Being Your Own Utility Company

The federal PURPA regulations passed in 1978 allow you to interconnect a suitable renewable energy powered generator to your house or business to reduce your consumption of utility supplied electricity.

This same law requires utilities to purchase any excess electricity production at a price (avoided cost) usually below the retail cost of electricity.

The Greenhouse Of The Future?

The Farm Yard of the Future!

SUMMARY

• Solar energy may be useful as primary electricity source if energy efficient, direct-current equipment is used in the greenhouse facility, or if battery efficiency improves.

• Solar energy is already a useful backup or emergency energy source for key systems such as pumps, lights, vents and fans.

• As cost decreases and solar panel efficiency increases, the use of a combined solar electricity and thermal water solar systems to heat greenhouses may be the best way to go. Hot water is the most efficient transfer method!