Transcript Slide 1

Renewable technology
• Solar Photovoltaic’s (PV)
• Solar Water Heating (Thermal)
• Wind Turbine
Solar Photovoltaic's (PV)
Up to three entries can now be input into software
This is to account for the increased popularity of PV
Where a property has PV on more than one part of the roof,
the PV data may differ due to different orientation, tilt etc
If the kWp cannot be ascertained, record the percentage of the
total roof area occupied by PVs. Here total roof area includes main
dwelling and all extensions where present
Solar Energy
Photovoltaic panels
Solar Energy
Photovoltaic panels
PHOTOVOLTAIC CELLS
Photovoltaic systems convert energy from the sun into electricity through semi
conductor cells. Systems consist of semi-conductor cells connected together
and mounted into modules. Modules are connected to an inverter to turn
their direct current (DC) output into alternating current (AC) electricity for use
in buildings. Photovoltaic supply electricity to the building they are attached to
or to any other load connected to the electricity grid. Excess electricity can be
sold to the National Grid when the generated power exceeds the local need.
PV systems require only daylight, not sunlight to generate electricity (although
more electricity is produced with more sunlight), so energy can still be
produced in overcast or cloudy conditions. Photovoltaic are generally
blue/grey in colour and can be used successfully in all parts of the UK.
Solar Energy
Photovoltaic panels
Solar Energy Photovoltaic panels
Photovoltaic panels come in modular panels which can be fitted to the top
of roofs (looking similar to a roof light) and in slates or shingles which are
an integral part of the roof covering (looking similar to normal roof tiles).
Photovoltaic cells can be incorporated into glass for atria walls and roofs
or used as cladding or rain screen on a building wall. They can also be
attached to individual items such as street lights, parking meters,
motorway noise barriers or the sides of bridges.
Photovoltaic systems can be discreet through being designed as an
integral part of the roof. An ‘invisible’ design using slates or shingles as
opposed to an architectural statement is likely to be preferable if in a
sensitive area.
SOLAR WATER HEATING
SOLAR WATER HEATING
Solar water heating systems use the energy from the sun to heat
water, most commonly in the UK for domestic hot water
needs. The systems use a heat collector, generally mounted
on the roof in which a fluid is heated by the sun.
This fluid is used to heat up water that is stored in either a
separate hot water cylinder or a twin coil hot water cylinder
inside the building. The systems work very successfully in all
parts of the UK, as they can work in diffuse light conditions.
Solar Panels
There are two types of collectors used for solar
water heating applications – flat plate
collectors and evacuated tube collectors.
The flat plate collector is the predominant type
used in domestic systems as they tend to be
cheaper and more robust.
Solar Panels
Flat Plate
Evacuated tube
Wind energy
WIND TURBINE
Wind energy is one of the most cost effective methods of renewable
power generation. Wind turbines can produce electricity without carbon
dioxide emissions ranging from watts to megawatt outputs. The most
common design is for three blades mounted on a horizontal axis, which is
free to rotate into the wind on a tall tower. The blades drive a generator
either directly or via a gearbox (generally for larger machines) to produce
electricity. The electricity can either be linked to the grid of charge
batteries. An inverter is required to convert the electricity from direct
current (DC) to alternating current (AC) for feeding into the grid.
Wind Energy
Wind Energy
Modern quiet wind turbines are becoming viable in low density areas
where ease of maintenance and immediate connection to the grid or
directly for use of the electricity in a building, may make them cost
effective, despite lower wind speeds than open areas. Wind turbines are
generally less suited to dense urban areas as their output will be affected
by potentially lower and more disrupted wind speeds, and their use of
much more cost effective machines may be prohibited by their proximity
to some building types. However small turbines can be used in inner city
areas.
Small turbines can be mounted on buildings. There are currently few
practical installations of roof mounted wind turbines in the UK but it is
anticipated that this will be a growing market and a number of companies
are marketing shall roof mounted turbines.
Wind Energy
Wind resource evaluation is a critical element in projecting turbine
performance at a given site. The energy available in a wind stream is
proportional to the cube of its speed, which means that doubling the wind
speed increases the available energy by a factor of eight. Furthermore, the
wind resource itself is seldom a steady, consistent flow. It varies with the
time of day, season, height above ground, and type of terrain. Proper siting
in windy locations, away from large obstructions, enhances a wind turbine's
performance. In general, annual average wind speeds of 5 meters per
second (11 miles per hour) are required for grid-connected applications.
Annual average wind speeds of 3 to 4 m/s (7-9 mph) may be adequate for
non-connected electrical and mechanical applications such as battery
charging and water pumping.
BIOMASS & BIOFUEL BOILERS
BIOMASS & BIOFUEL BOILERS
Biomass can be burnt directly to provide heat in buildings. Wood from
forests, urban tree pruning, farmed coppices or farm and factory waste, is
the most common fuel and nowadays is used commercially in the form of
wood chips or pellets, although traditional logs are also used.
Biomass boilers can be designed to burn smokelessly to comply with the
Clean Air Acts. Boilers can be fed automatically by screw drives from fuel
hoppers. This typically involves daily addition of bagged fuel to the hopper.
Electric firing and automatic de-ashing are also available.
Biomass boilers replace conventional fossil fuel boilers and come with the
automated features mentioned above. Fuels other than wood, such as
straw can also be used.
Biomass is normally considered a carbon neutral fuel, as the carbon
dioxide emitted on burning has been (relatively) recently absorbed from
the atmosphere by photosynthesis and no fossil fuel is involved. The wood
is seen as a by-product of other industries and the small quantity of
energy for drying, sawing, pelleting and delivery are discounted.
Biomass from coppicing is likely to have some external energy inputs, for
fertiliser, cutting, drying etc. and these may need to be considered in the
future. In this toolkit, all biomass fuels are considered to have zero net
carbon emissions.
GROUND SOURCE HEAT PUMPS
GROUND SOURCE HEAT PUMPS
Geo-thermal energy is basically heat collected from the ground. Geothermal energy is mainly associated in the form of hot springs or geysers
gushing out of the ground in Iceland. However heat obtained from the
ground may also be considered it as a source of heating and cooling within
the UK by the use of a Geo-thermal heat pump or ground source heat
pumps.
A ground source heat pump is a device for converting energy in the form
of low level heat to heat at a usable temperature. The heat pump consists
of five main parts; ground collector loop, or bores heat exchanger,
compressor, condenser heat exchanger and expansion valve.
At about 1.2-1.5 metres down below ground level the temperature is a
constant 10 to 12ºC. The bores would need to be sunk to an effective
depth of 80 – 120m and a ground feasibility report would be required to
ascertain if this method of heat source was indeed viable. Typical costs for
this are in the region of £20,000 with installation costs at £1200 /kW of
energy produced.
From the bores pre-insulated pipework is laid in the ground to the heat
exchanger device. The system is filled with water and antifreeze. The
cooled water is pumped around the loop / bore gathering energy as it
goes. The water now heated to 10-12ºC is returned to the ground source
heat exchanger where the energy is transferred to the refrigerant gas. The
water in transferring its collected energy is cooled by the refrigerant to 7ºC and returns to the ground bores to collect more energy.