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Educational background for Katja Gieseking - Indeed, the adoption of renewable energy is meaningless unless accompanied by a wide-ranging improvement in energy efficiency.
For every mega-watts MW of electricity generated, MW enough to power 20, homes pours out as waste. As industrial processes go, few are more inefficient.
This wastage was accepted when fossil fuel was cheap and plentiful and global warming relatively unknown. Not much can be done to make power conversion itself more efficient.
However, what can and must happen is to recover the energy lost as heat in this process and reuse it for other purposes.
Recycling heat in this way is the basic principle behind District Heating or District Energy , a system for centrally supplying residential and commercial heating.
The concept is to capture waste energy from power production and use it to heat water, which is then distributed via underground pipes to homes and buildings for heating purposes.
The system can be used for cooling too by using recovered energy to power air-conditioning systems. The engineering behind District Energy is remarkably simple and stable, making it highly flexible in terms of both scalability and compatibility with fuel sources.
In fact District Energy networks can tap directly into renewable power sources such as wind turbines or biomass plants. Recycling heat, through District Energy networks, opens the way to massively reducing carbon emissions, particularly in urban centres, where heat demand is most intense.
These reductions are achieved without limiting economic and industrial output or endangering living standards.
Reassuringly District Energy is able to deliver these benefits here and now. It is a proven, practical approach to controlled decarbonisation and meeting international pledges on emissions control.
District Heating has a vital role to play in meeting that demand, while enabling the creation of ever more sustainable urban centres.
Europe has an opportunity to lead the world in demonstrating that vibrant, prosperous cities are compatible with environmental preservation.
The vision of an Ecopolis — a carbon-neutral thriving cosmopole — is within our grasp if we dare to reach for it. Urban leaders are embracing a new vision for supplying energy to their cities, one that combines local renewables, cogeneration plants and district energy in one low-carbon network.
District Energy can tap wind both directly and indirectly via cogeneration. Geothermal energy generated 10, MW1 in across some 24 countries.
New Zealand, Iceland and El Salvador all rely heavily on geothermal energy too. Solar hot water and heating capacity reached approximately GWth in , with China, Turkey, Germany, Japan and Greece leading the world market.
While thermal solar is often used for producing hot water only, there is a growing trend towards larger combined systems that provide both hot water and space heating.
The EU generates It is estimated that one third of that energy is discharged as waste into the atmosphere or cooling systems.
District Heating lets us effectively recapture some of these losses. Surplus energy from incineration can be used directly for electricity production or District Heating purposes.
Once generated, heat is distributed as water or steam to commercial and residential buildings via a network of pre-insulated pipes, consisting of supply and return lines.
The pipes are generally installed underground, although overground pipes do exist. Heat storage systems can be integrated into the network to even out peak-load demands.
Cogeneration also known as Combined Heat and Power or CHP plants are at the heart of any District Energy network, linking power generation with heating and cooling applications.
The basic principles behind District Energy are remarkably simple. At one end of the network is an energy source often a multi-fuel CHP plant.
Heat is then distributed via a network of insulated pipes to buildings. A District Energy network is extremely flexible and can be used to connect as few as houses.
This allows cities to grow an existing network as funding, planning and other opportunities become available. As a multi-fuel system, District Energy supports virtually all energy sources, making it future-proof to changes in the fuel mix and energy infrastructure of a city.
At the end-user level, individual buildings are connected to the District Heating network. The latest generation of District Energy infrastructure 4G enables city planners to vastly improve energy efficiency while creating a viable channel for accessing renewable sources.
Safe, sustainable, scalable — District Energy is an essential component in achieving real carbon savings today. District Energy also known as District Heating and Cooling is an extremely efficient, low-cost, low-maintenance system for heating residential, commercial and industrial buildings.
Its greatest attribute, however, is that is also provides an effective solution to help address global concerns in regard to fuel shortages, rising fuel costs and the growing impact of our energy demand on the environment.
A single District Energy network is able to provide heat to numerous end- users at the same time and even has the potential of storing energy through thermal storage facilities.
New heating sources can be easily added without disabling the system or disturbing consumers — far more efficient than the current method of having to change individual heat- ing units in separate buildings as new technology comes onto the market.
Because District Heating pipes have a longer life than a generating plant, networks can be put in place based on whichever heat supply technology is most economically, or politically, appropriate.
With technology moving at a rapid pace, this also provides a simple framework to introduce new energy sources that may become available in the future.
By their nature, District Energy systems also offer a safer alternative to conventional heating systems.
Unlike central heating boilers, there is no need for a naked flame within the home, which means less risk of accidental fires.
Also, the system does not require an individual gas supply, which can lead to dangerous gas leaks. Additionally, all high pressures and temperatures are confined to a central plant and network, shielding consumers from related risks.
As the financial, environmental and political costs of fossil fuels increase, District Energy allows a smooth development towards greener alternatives.
In fact, this technology has already been adopted in some countries across Europe, where as many as half the homes are connected to a District Energy network.
In certain European cities the proportion is even higher. It is estimated that if the current share of District Energy in the EU were to double, the following results would be achieved:.
This technology can help lead the way towards a more eco-friendly society where the increased demand for energy is fulfilled by actually using fewer energy sources.
The Swedish Government estimates that the EU as a whole could meet its commitments to CO2 reduction simply by doubling the number of District Energy installations.
In a District Heating system, heat energy that would otherwise be wasted is captured, stored and distributed to commercial, industrial and residential buildings through a network of insulated pipes as hot water or steam.
The latest generation of District Heating technology makes use of a wide variety of energy resources, which typically include:. They are at once the source of the problem and the solution.
Fortunately, as more and more local authorities embrace their right and responsibility to take ownership of their energy futures, they are also an increasingly vibrant hotbed of vision and leadership.
The inherently global nature of our climate and energy challenges has quite naturally led to a focus on resolving the problem via high-level international governance.
Hitler is saving our country. By January , however, he had been cleared by the U. Although there had been other protests in Australia and Peru, for example , his American tour was the only group of concerts actually cancelled due to the outcry.
He continued to play in many other countries, and in he finally returned to the United States. His concert in Carnegie Hall was sold out and well received, and he was more popular than ever.
Because of his gifts of a natural technique, perfect pitch , and abnormally acute faculty for memorization, Gieseking was able to master unfamiliar repertoire with relatively little practice.
From his early instruction in the Leimer method, he usually studied new pieces away from the piano. It became well known to the public, for instance, that he often committed new works to memory while traveling by train, ship or plane.
Sometimes, according to Harold C. Schonberg 's book The Great Pianists , he could even learn an entire concerto by heart in one day. Gieseking had a very wide repertoire, ranging from various pieces by Bach and the core works by Beethoven to the concertos of Rachmaninoff and more modern works by composers such as Busoni , Hindemith , Schoenberg and the lesser-known Italian Petrassi.
He gave the premiere of Pfitzner 's Piano Concerto in Today, though, he is particularly remembered for his recordings of the complete piano works of Wolfgang Amadeus Mozart and the two French impressionist masters Claude Debussy and Maurice Ravel , virtually all of whose solo piano music he recorded on LP for EMI in the early s the Mozart and Debussy sets have recently been re-released on CD , after recording much of it for Columbia in the s and s, some of which have also been re-released on CD.
Gieseking's performance of Beethoven's "Emperor" Concerto , in which anti-aircraft fire is audible in the background,  is one of the earliest stereo recordings, following a rendition of the same work in for Columbia, with Bruno Walter conducting the Vienna Philharmonic.
In December, , Gieseking suffered head injuries in a bus accident near Stuttgart, in which his wife was killed.