Get concentrated solar power with out high efficiency kits.

90 watt Solar Panel
Steca PR1010 10 Amp Charge Controller (will accept a further 2 90 watt panels, or 2 X 130 watt)
5 Metres of Connecting Cable
Aluminium Side Brackets Or Moulded Plastic Corner Brackets included
TOTAL £ 349

KIT OPTIONS

With 130 watt panel £399
With 2 X 90 watt panel £499
With 2 X 130 watt panel £649
Battery Not Included - Connects to your existing 12V battery, or
See battery pricing below eg.PSG-12105FT £119
Mounting Screws / Sikaflex or similar strong and flexible Sealant Not Included

PRICING – 1.3 KW OFF-GRID SYSTEM

10 X 130 watt solar panels @ £1.89/per watt £ 2457

10metres 4mm2 pv cable module to controller £20

4 x MC4 Y branch connections £20

1 X Outback Flexmax MPPT 80 Amps 12VDC Controller £ 554.32
(PV controller with MPPT can increase energy converted from the PV modules by 30% and creates a higher current system)
1kw inverter 12vdc in - 240v 50hz out - Rip Jazz Pro £ 599 including VAT good quality Swiss made inverter with 2 years warranty.

rip jazz inverter - many other types and brands available
Both good solid reliable efficient units for long life and will provide high quality mains power.
Mounting Brackets for the panels £45 X10=£450

Batteries

Delivery £100

£ 4131.32

VAT £ 722.98

TOTAL £ 4,854.30

OFF GRID

Concentrated SOLAR POWER SYSTEMS

A basic off grid solar power system requires:

Solar Panels

Charge Controller (to charge the batteries)

Inverter to change DC power into household AC

Batteries to store the power

Ask your client (or yourself) these questions before buying an off grid system:

1) What is the required output in watts, which determines what type and how many solar panels you'll need

Add up all the household power loads and the time per day that they are in use to get the total

For example:

Lights 100w x 4 hours = 400watts
TV 150w x 4 hours = 900watts

Kettle/toaster/microwave 1000 watts X 1/2 hour = 500 watts

TOTAL = 1700 watts

When planning for an off grid renewable energy system it is vital to assess your specific requirements ... i.e. what appliances - lighting, heating, cooking, refrigeration, pumping etc - you want to power from the installation.

The power requirement of these functions must be determined, as well as their frequency of use (and in some circumstances the likely timing of their use, so that the peak requirement at any one time is known).

Conservation of energy usage may be feasible in some situations, through for example changing appliances or adjusting ones lifestyle.

Wind and Sun will be very happy to help you with these calculations if you wish. Just contact us and we can send you an off grid questionnaire to fill in, as a starting point for estimating your requirements.

After determining these requirements, and having decided which sources of renewable energy are most suited to the location, it is necessary to carefully match the individual parts of the system - batteries, inverters, generators etc.

This process enables one to make the most efficient use of the energy available, and to have energy available at the time(s) it is needed.

System Sizing

The precise balance and size of the components of a wind/solar system depends upon your location and anticipated power requirements, both 240V 'mains' and low voltage DC.

A wide range of high efficiency appliances, batteries, controllers and inverters are available to meet most needs.

The number of consecutive days without sun or wind, together with patterns of use and peak power demand, determine both the battery store size and inverter or back-up generator requirement. Seasonal as well as daily variations are important.

If preferred a flexible approach can be adopted with components added in order of priority and a system expanded by the addition of additional battery store or generating capacity as needs change or finance allows.

A useful tool for estimating monthly output using sunlight data for anywhere in Europe and Africa is available here.

Power Requirements in a battery based system

Both existing and/or anticipated power requirements must be ascertained as a first step in sizing a system.

Factors to consider include:

Variety of loads to be run: eg. domestic lighting, refrigeration, pumps, etc
Peak Consumption: total loads that might be required to be run at any one time
Average Consumption: typical loads that need to be run most of the time
Minimum/Continuous Consumption: any loads that need to be run all the time
Voltage and frequency: of required loads, DC or AC
Pattern of usage: daily, weekly, and seasonal
Degree of automation required: whether supply needs to have 100% availability

In designing a power supply it is important to consider the whole home as a system; loads are interrelated, eg. correctly placed windows can help with heating and lighting; insulation reduces heating requirements etc.

Conservation

This plays an important role in keeping the costs of any energy supply down.

The use of energy efficient appliances and lighting, use of non-electric alternatives wherever possible, and increased awareness of patterns of use, all contribute towards the success and potential for a renewable energy system.

Cooking and Heating

Conventional electric cooking, space heating and water heating use a prohibitive amount of electricity. Electric cookers use about 1500 watts per burner, so bottled gas and solid fuel stoves are usually used for cooking.

A microwave oven has a large power draw, but since food is cooked much more quickly, the total power consumption may not be too large.

Good passive solar design and proper insulation can reduce the need for heat, further space heating can be provided by propane or solid fuel. This is also used for water heating and can be combined with solar water heating systems.

In the larger wind turbine systems excess power will be available at times which can be used in immersion heaters, space heaters and storage heaters. This tends to coincide with colder windy weather but it's usefulness depends upon system sizing, so some supplementary heat source will still be necessary.

Refrigeration

Gas powered fridges are a good choice in small systems if bottled gas is available. If an electric fridge is to be used then it should be a high efficiency type. The higher cost of good quality DC refrigeration is more than made up by savings in other system costs.

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Lighting

In a small home, vehicle, caravan or boat, the best choice for lighting is usually to run lighting on low voltage DC directly from the battery.

Wiring runs can be kept short so relatively small gauge wire can be used, an inverter is not required so system cost is lower, and if high efficiency DC fluorescent lights etc are used then high levels of lighting can be obtained from even small systems.

In very large installations, or ones with existing wiring, or where combined with a diesel generator, use of an inverter to supply AC power for conventional lighting may be cost effective.

In this case high efficiency electronic compact fluorescent lights should be used.

Major Appliances

Suitable large electrical appliances are usually only available in AC versions, -vacuum cleaners, pumps, power tools, fans, etc. These require a suitably sized inverter.

Washing machines are usually the largest electrical load in a typical domestic situation.

These will require a large inverter unless the motors can be replaced by DC motors and the controls modified. However, since they are run for fixed periods it is usually better to use a standby generator for such loads and at the same time use any spare capacity for battery charging.

Small Appliances

Many small appliances such as toasters, irons and hair dryers consume very large amounts of power but require very short or infrequent use periods.

This means that if the system inverter, battery and charging system are large enough they may be useable.

Electronic equipment, eg. stereos, televisions, videos and computers etc have a low power consumption.

Many of these are available in low voltage DC as well as conventional AC versions, and usually the DC models use less power than their AC counterparts.

Pumping

This needs to be considered carefully. In sunny climates direct solar pumping may be advantageous.

Wind Generator/PV Sizing

This is decided so that the battery store can be maintained from available local renewable resources of wind/solar/& water or even via a backup generator.

Wind generator &/or PV output characteristics, together with averages and patterns of windspeed or sunlight hours, must be considered in choosing the generating equipment.

Wind and solar resources are often complimentary (high winds & low sun in winter and vice versa) so combining both can result in a smaller battery store and a overall cheaper and more efficient system.

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Location

The expected output from wind and PV generators depends very much on location, time of year and weather etc. In designing the optimum system it is important to have as much information as possible regarding local climatic conditions.

For example:

Site description
Including position of proposed wind/solar generators relative to loads, location of any nearby buildings, trees or hills etc.,soil conditions, access conditions, space for batteries etc.
Local wind conditions
average wind speed, prevailing directions, seasonal variations and periods of calm
Solar conditions
average daily hours of sunshine, summer & winter. whether there is any shading
Other weather conditions
average rainfall, frequency of fog, snow and lightning etc.; average, maximum & minimum temperatures.

Choosing the Battery Voltage

The most commonly used voltage is 12 Volts, for which a wide range of lights and appliances are available.

If long cable runs are required or if an inverter of more than 1000 watts is needed then a 24 volt system is advisable.

Good 24V lighting and some appliances are available but most appliances will be run at 240 VAC via the inverter.

Higher voltages (usually multiples of 12) are used in much larger systems and all loads are then inverter powered.

Sizing the Battery

This depends on the power requirements and also on the required period of available storage -determined by climate and seasonal weather patterns; availability of standby power (or not); and not least budget!

For a small system three days storage might be sufficient. For a remote telecommunications site maybe several weeks.

The amount of electricity stored in a battery is measured in amp hours. This storage should be sufficient to last several days without any recharging -bearing in mind that for long life a battery should only be discharged to 20% capacity before recharging.

Battery amp hour capacity

Load x No. of days storage required x 1.2

Normally three to four days storage will be sufficient, especially if a back-up supply eg. generator is available.

Actual sizing is very difficult since the amount of wind or solar charging energy is highly dependent on the weather, consequently a system that incorporates both wind and solar inputs will require a considerably smaller battery than one with a sole power source.

Other factors such as criticality of the loads (resulting in a larger battery store for fail safe operation) and whether seasonal patterns of consumption match seasonal patterns of generation (allowing a smaller battery) are also important.

NB. Larger battery banks should consist of large 2 volt cells connected in series rather than lots of 12V batteries in parallel in order to avoid circulating currents within the battery and possible early battery failure.

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Sizing The Inverter

In addition to the average power consumption, peak power consumption needs to be considered in sizing the inverter.

This is estimated by adding the wattages of the largest number of devices that are likely to be operated at the same time. The continuous rating of the inverter should be greater than this figure.

Most inverters have an overload capability, for short periods, of two or more times their rated output, and this is needed for it to cope with the starting surges involved in electric motors -often three times their rated power. If several motors can start automatically (eg. fridge and freezer) then it is possible for them to start simultaneously, so their combined starting surge must be taken account of. If a motor starts when an inverter is already heavily loaded this can overload the inverter giving a 'black out', so it is advisable to have any other motors (eg. well pump) on manual control to reduce peak power consumption.

Most of the time an inverter will only be lightly loaded so it is important to choose one that is efficient at low load levels as well as at rated output.

Using a Generator

In order not to oversize the inverter (and so also save on battery and wind/solar costs) a back up generator can be incorporated and the use of the heaviest loads (eg. washing machine, well pump etc) restricted to when the generator is running. A battery charger can then also be run with any spare generating capacity.

The generator should be sized to cover the likely peak power consumption of all appliances, and the aim should be to run it for short periods at full capacity.

Such load management and proper timing of peak power consumption can lead to considerable cost benefits. If loads are spread out a smaller inverter can be utilised for vacuum cleaning when it's windy or pumping when sunny means power generated is being used directly - in times of little wind and sun, energy should be conserved.

Again, selection of efficient appliances can improve system efficiency.

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