Well of knowledge informs debate on new energy source.
AS the energy debate hots up, North East experts have outlined how the UK could tap into a clean supply deep beneath the ground.
They were speaking at a London conference yesterday on geothermal energy organised by EGS Energy Ltd and a partnership managed at Durham University.
The event was set against a backdrop of concerns over climate change, emissions from fossil fuel burning, rising energy bills and fears over security of supplies, and controversy surrounding alternative power generation such as onshore wind farms. The conference saw the launch of the BritGeothermal Research Partnership, which consists of Durham, Newcastle and Glasgow universities and the British Geological Survey.
Geothermal energy comes from drilling wells between one and four kilometres deep to reach water warmed by the radiating heat from the Earth's molten core.
It can be used to heat buildings or for power generation.
There is also the potential to use warm water which has flooded abandoned coal mines - with the North East sitting on top of a maze of old workings.
Durham University is researching how to utilise water which has lower temperatures than that from deep geothermal wells. Another source of geothermal energy is the heat generated by granite layers, especially in the North Pennines.
The North East also has two deep wells which are now being used for research purposes by the partnership.
A borehole was drilled in 2011 at the Science Central site in Newcastle to a depth of 1,821 metres to intercept the 90 Fathom Fault, which runs from the North Pennines to Cullercoats Bay.
The aim was to find water at temperatures of 70C. Temperatures of 73C were encountered during testing following completion.
The Eastgate borehole in Weardale in County Durham was sunk in 2004 into granite at the site of the former Lafarge cement works to a depth of 995 metres, encountering abundant supplies at 46C.
Around half of the energy consumed in the UK is used for providing heating.
It is estimated that deep geother-mal sources in the UK could supply heat to meet the UK domestic heating demand for 100 years.
"Geothermal is a carbon neutral, home-sourced, sustainable and reliable source of heat and power which can help the UK become more selfsufficient with respect to energy," said Dr Charlotte Adams, who is the Durham-based research manager for the BritGeothermal Partnership.
The conference brought together policy makers, academics and indus-try representatives from around the UK and Europe.
Among the speakers was Professor Jon Gluyas, Dean of Knowledge Exchange and Impact at Durham University, and representatives from the Department of Energy and Climate Change.
Dr Adams said: "It is the right time to launch the BritGeothermal Partnership. This conference will provide a meeting of minds from academia, industry and Government."
Guy Macpherson-Grant, managing director of EGS Energy, said: "Interest in deep geothermal has never been greater in the UK. Tapping into this clean, baseload source of heat and power has never been a more attractive or realistic option."
One of the ways of reducing costs is to use abandoned coal and metal mines where workings are flooded with water at between 12C and 18C.
Although at lower temperatures than deep geothermal systems, these provide a source of low grade heat which can provide warmth for buildings.
"Many of these mine water resources are beneath our towns and cities. Sources like abandoned mines are ripe for heating communities," said Dr Adams.
Oilfield wells where output is falling can also be exploited as they produce vast amounts of water.
JOURNEY FROM THE EARTH'S CORE Geothermal energy is produced from naturally occurring radioactive decay within the centre of the Earth.
The heat generated radiates from the centre of the Earth to its surface.
Geothermal energy should not be confused with ground source heat that lies within a few tens of metres of the surface and results from solar warming of the Earth.
Geothermal systems generally comprise a geothermal well or borehole for extracting geothermal fluid with an above ground heat exchanger which removes heat from the fluid.
The fluids are returned underground via a second well.
Dr Charlotte Adams
Science Central in Newcastle, where a pioneering project saw a borehole <B Science Central in Newcastle, where a pioneering project saw a borehole <B
drilled to a depth of over 1,800 metres to tap into a supply of hot water
|Printer friendly Cite/link Email Feedback|
|Publication:||The Journal (Newcastle, England)|
|Date:||Oct 14, 2014|
|Previous Article:||Search is on for inspirational parents.|
|Next Article:||Baby scare student spared jail.|