Opportunities for Sustainable Low Carbon Energy Research Development and Applications

doi:10.4236/lce.2011.23022

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Low Carbon Economy, 2011, 2, 173-191

doi:10.4236/lce.2011.23022 Published Online September 2011 (http://www.SciRP.org/journal/lce)

173

Opportunities for Sustainable Low Carbon Energy

Research Development and Applications

Abdeen Mustafa Omer

Energy Research Institute (ERI), Nottingham, United Kingdom.

Email: abdeenomer2@yahoo.co.uk

Received March 1st, 2011; revised March 28th, 2011; accepted April 3rd, 2011.

ABSTRACT

People to rely upon oil for primary energy and this for a few more decades. Other conventional sources may be more

enduring, but are not without serious disadvantages. The renewable energy resources are particularly suited for the

provision of rural power supplies and a major advantage is that equipment such as flat plate solar driers, wind ma-

chines, etc., can be constructed using local resources and without the advantage results from the feasibility of local

maintenance and the general encouragement such local manufacture gives to the build up of small-scale rural based

industry. This article comprises a comprehensive review of energy sources, the environment and sustainable develop-

ment. It includes the renewable energy technologies, energy efficiency systems, energy conservation scenarios, energy

savings in greenhouses environment and other mitigation measures necessary to reduce climate change. This article

gives some examples of small-scale energy converters, nevertheless it should be noted that small conventional, i.e, en-

gines are currently the major source of power in rural areas and will continue to be so for a long time to come. There is

a need for some further development to suit local conditions, to minimise spares holdings, to maximise interchangeabil-

ity both of engine parts and of the engine application. Emphasis should be placed on full local manufacture. It is con-

cluded that renewable environmentally friendly energy must be encouraged, promoted, implemented and demonstrated

by full-scale plant especially for use in remote rural areas.

Keywords: Renewable Energy Technologies, Energy Efficiency, Sustainable Development, Emissions, Environment

1. Introduction

Power from natural resources has always had great ap-

peal. Coal is plentiful, though there is concern about de-

spoliation in winning it and pollution in burning it. Nu-

clear power has been developed with remarkable timeli-

ness, but is not universally welcomed, construction of the

plant is energy-intensive and there is concern about the

disposal of its long-lived active wastes. Barrels of oil,

lumps of coal, even uranium come from nature but the

possibilities of almost limitless power from the atmos-

phere and the oceans seem to have special attraction. The

wind machine provided an early way of developing mo-

tive power. The massive increases in fuel prices over the

last years have however, made any scheme not requiring

fuel appear to be more attractive and to be worth reinves-

tigation. In considering the atmosphere and the oceans as

energy sources the four main contenders are wind power,

wave power, tidal and power from ocean thermal gradi-

ents. The sources to alleviate the energy situation in the

world are sufficient to supply all foresee able needs.

Conservation of energy and rationing in some form will

however have to be practised by most countries, to re-

duce oil imports and redress balance of payments posi-

tions. Meanwhile development and application of nuclear

power and some of the traditional solar, wind and water

energy alternatives must be set in hand to supple- ment

what remains of the fossil fuels.

The encouragement of greater energy use is an essen-

tial component of development. In the short term, it re-

quires mechanisms to enable the rapid increase in en-

ergy/capita, while in the long term it may require the use

of energy efficiency without environmental and safety

concerns. Such programmes should as far as possible be

based on renewable energy resources. Large-scale, con-

ventional, power plant such as hydropower has an im-

portant part to play in development although it does not

provide a complete solution. There is however an impor-

tant complementary role for the greater use of small scale,

rural based, power plants. Such plants can be employed

to assist development since they can be made locally.

Renewable resources are particularly suitable for provid-

Opportunities for Sustainable Low Carbon Energy Research Development and Applications

174

ing the energy for such equipment and its use is also

compatible with the long-term aims.

In compiling energy consumption data one can catego-

rise usage according to a number of different schemes:

 Traditional sector—industrial, transportation, etc.

 End-use—space heating, process steam, etc.

 Final demand—total energy consumption related to

automobiles, to food, etc.

 Energy source—oil, coal, etc.

 Energy form at point of use—electric drive, low

temperature heat, etc.

2. Renewable Energy Potential

The increased availability of reliable and efficient energy

services stimulates new development alternatives [1].

This article discusses the potential for such integrated

systems in the stationary and portable power market in

response to the critical need for a cleaner energy tech-

nology. Anticipated patterns of future energy use and

consequent environmental impacts (acid precipitation,

ozone depletion and the greenhouse effect or global

warming) are comprehensively discussed in this paper.

Throughout the theme several issues relating to renew-

able energies, environment and sustainable development

are examined from both current and future perspectives.

It is concluded that renewable environmentally friendly

energy must be encouraged, promoted, implemented and

demonstrated by full-scale plant especially for use in re-

mote rural areas. Globally, buildings are responsible for

approximately 40% of the total world annual energy

consumption. Most of this energy is for the provision of

lighting, heating, cooling, and air conditioning. Increas-

ing awareness of the environmental impact of CO2 and

NOx and CFCs emissions triggered a renewed interest in

environmentally friendly cooling, and heating technolo-

gies. Under the 1997 Montreal Protocol, governments

agreed to phase out chemicals used as refrigerants that

have the potential to destroy stratospheric ozone. It was

therefore considered desirable to reduce energy con-

sumption and decrease the rate of depletion of world en-

ergy reserves and pollution of the environment. One way

of reducing building energy consumption is to design

buildings, which are more economical in their use of

energy for heating, lighting, cooling, ventilation and hot

water supply. Passive measures, particularly natural or

hybrid ventilation rather than air-conditioning, can dra-

matically reduce primary energy consumption. However,

exploitation of renewable energy in buildings and agri-

cultural greenhouses can, also, significantly contribute

towards reducing dependency on fossil fuels. Therefore,

promoting innovative renewable applications and rein-

forcing the renewable energy market will contribute to

preservation of the ecosystem by reducing emissions at

local and global levels. This will also contribute to the

amelioration of environmental conditions by replacing

conventional fuels with renewable energies that produce

no air pollution or greenhouse gases.

There is strong scientific evidence that the average

temperature of the earth’s surface is rising. This is a re-

sult of the increased concentration of carbon dioxide and

other GHGs in the atmosphere as released by burning

fossil fuels. This global warming will eventually lead to

substantial changes in the world’s climate, which will, in

turn, have a major impact on human life and the built

environment. Therefore, effort has to be made to reduce

fossil energy use and to promote green energies, particu-

larly in the building sector. Energy use reductions can be

achieved by minimising the energy demand, by rational

energy use, by recovering heat and the use of more green

energies. This study was a step towards achieving that

goal. The adoption of green or sustainable approaches to

the way in which society is run is seen as an important

strategy in finding a solution to the energy problem. The

key factors to reducing and controlling CO2, which is the

major contributor to global warming, are the use of al-

ternative approaches to energy generation and the explo-

ration of how these alternatives are used today and may

be used in the future as green energy sources [2]. Even

with modest assumptions about the availability of land,

comprehensive fuel-wood farming programmes offer

significant energy, economic and environmental benefits.

These benefits would be dispersed in rural areas where

they are greatly needed and can serve as linkages for

further rural economic development. The nations as a

whole would benefit from savings in foreign exchange,

improved energy security, and socio-economic im-

provements. With a nine-fold increase in forest – planta-

tion cover, a nation’s resource base would be greatly

improved. The international community would benefit

from pollution reduction, climate mitigation, and the in-

creased trading opportunities that arise from new income

sources. The non-technical issues, which have recently

gained attention, include: 1) Environmental and ecologi-

cal factors, e.g., carbon sequestration, reforestation and

revegetation; 2) Renewables as a CO2 neutral replace-

ment for fossil fuels; 3) Greater recognition of the im-

portance of renewable energy, particularly modern bio-

mass energy carriers, at the policy and planning levels; 4)

Greater recognition of the difficulties of gathering good

and reliable renewable energy data, and efforts to im-

prove it; 5) Studies on the detrimental health efforts of

biomass energy particularly from traditional energy users.

The renewable energy resources are particularly suited

for the provision of rural power supplies and a major

advantage is that equipment such as flat plate solar driers,

wind machines, etc., can be constructed using local re-

Opportunities for Sustainable Low Carbon Energy Research Development and Applications175

sources and without the advantage results from the feasi-

bility of local maintenance and the general encourage-

ment such local manufacture gives to the build up of

small scale rural based industry. This article gives some

examples of small-scale energy converters, nevertheless

it should be noted that small conventional, i.e, engines

are currently the major source of power in rural areas and

will continue to be so for a long time to come. There is a

need for some further development to suit local condi-

tions, to minimise spares holdings, to maximise inter-

changeability both of engine parts and of the engine ap-

plication. Emphasis should be placed on full local manu-

facture.

The renewable energy resources are particularly suited

for the provision of rural power supplies and a major

advantage is that equipment such as flat plate solar driers,

wind machines, etc., can be constructed using local re-

sources and without the high capital cost of more con-

ventional equipment. Further advantage results from the

feasibility of local maintenance and the general encour-

agement such local manufacture gives to the build up of

small scale rural based industry. Table 1 lists the energy

sources available.

Currently the ‘non-commercial’ fuels wood, crop resi-

dues and animal dung are used in large amounts in the

rural areas of developing countries, principally for heat-

ing and cooking; the method of use is highly inefficient.

Table 2 presented some renewable applications.

Table 3 lists the most important of energy needs.

Considerations when selecting power plant include the

following:

 Power level—whether continuous or discontinuous.

 Cost—initial cost, total running cost including fuel,

maintenance and capital amortised over life.

 Complexity of operation.

 Maintenance and availability of spares.

Table 1. Sources of energy [3].

Energy source Energy carrier Energy end-use

Vegetation Fuel-wood

Cooking

Water heating

Building materials

Animal fodder preparation

Oil Kerosene Lighting

Ignition fires

Dry cells Dry cell batteries Lighting

Small appliances

Muscle power Animal power

Transport

Land preparation for farming

Food preparation (threshing)

Muscle power Human power

Transport

Land preparation for farming

Food preparation (threshing)

Table 2. Renewable applications [4].

Systems Applications

Water supply

Wastes disposal

Cooking

Food

Electrical demands

Space heating

Water heating

Control system

Building fabric

Rain collection, purification, storage and

recycling

Anaerobic digestion (CH4)

Methane

Cultivate the 1 hectare plot and greenhouse

for four people

Wind generator

Solar collectors

Solar collectors and excess wind energy

Ultimately hardware

Integration of subsystems to cut costs

Table 3. Energy needs in rural areas [6].

Muscle power

Internal combustion engines

Reciprocating

Rotating

Heat engines

Vapour (Rankine)

Reciprocating

Rotating

Gas Stirling (Reciprocating)

Gas Brayton (Rotating)

Electron gas

Electromagnetic radiation

Hydraulic engines

Wind engines (wind machines)

Electrical/mechanical

Man, animals

Petrol-spark ignition

Diesel-compression ignition

Humphrey water piston

Gas turbines

Steam engine

Steam turbine

Steam engine

Steam turbine

Thermionic, thermoelectric

Photo devices

Wheels, screws, buckets, turbines

Vertical axis, horizontal axis

Dynamo/alternator, motor

 Life.

 Suitability for local manufacture.

Table 4 listed methods of energy conversion.

There is a need for greater attention to be devoted to

this field in the development of new designs, the dis-

semination of information and the encouragement of its

use. International and government bodies and independ-

ent organisations all have a role to play in renewable

energy technologies.

Table 4. Methods of energy conversion [7].

Transport, e.g., small vehicles and boats

Agricultural machinery, e.g., two-wheeled tractors

Crop processing, e.g., milling

Water pumping

Small industries, e.g., workshop equipment

Electricity generation, e.g., hospitals and schools

Domestic, e.g., cooking, heating, and lighting

Water supply, e.g., rain collection, purification, storage and reccling

Building fabric, e.g., integration of subsystems to cut costs

Wastes disposal, e.g., anaerobic digestion (CH4)

Opportunities for Sustainable Low Carbon Energy Research Development and Applications

176

The household wastes, i.e ., for family of four persons,

could provide 280 kWh/yr of methane, but with the addi-

tion of vegetable wastes from 0.2 ha or wastes from 1 ha

growing a complete diet, about 1500 kWh/yr may be

obtained by anaerobic digestion [5]. The sludge from the

digester may be returned to the land. In hotter climates,

this could be used to set up a more productive cycle

(Figure 1).

Society and industry in Europe and elsewhere are in-

creasingly dependent on the availability of electricity

supply and on the efficient operation of electricity sys-

tems. In the European Union (EU), the average rate of

growth of electricity demand has been about 1.8% per

year since 1990 and is projected to be at least 1.5%

yearly up to 2030 [8]. Currently, distribution networks

generally differ greatly from transmission networks,

mainly in terms of role, structure (radial against meshed)

and consequent planning and operation philosophies.

2.1. Energy Consumption

Over the last decades, natural energy resources such as

petroleum and coal have been consumed at high rates.

The heavy reliance of the modern economy on these fu-

els are bound to end, due to their environmental impact,

and the fact that conventional sources might eventually

run out. The increasing price of oil and instabilities in the

oil market led to search for energy substitutes.

In addition to the drain on resources, such an increase

in consumption consequences, together with the in-

creased hazards of pollution and the safety problems as-

sociated with a large nuclear fission programmes. This is

a disturbing prospect. It would be equally unacceptable

to suggest that the difference in energy between the de-

veloped and developing countries and prudent for the

developed countries to move towards a way of life which,

whilst maintaining or even increasing quality of life, re-

duce significantly the energy consumption per capita.

Such savings can be achieved in a number of ways:

Figure 1. Biomass energy utilisation cycle [9].

 Improved efficiency of energy use, for example

better thermal insulation, energy recovery, and total

energy.

 Conservation of energy resources by design for long

life and recycling rather than the short life throw-

away product.

 Systematic replanning of our way of life, for exam-

ple in the field of transport.

Energy ratio is defined as the ratio of:

Energy content of the food product/Energy input to

produce the food (1)

A review of the potential range of recyclables is pre-

sented in Table 5.

Currently the non-commercial fuelwood, crop residues

and animal dung are used in large amounts in the rural

areas of developing countries, principally for heating and

cooking, the method of use is highly inefficient. As in the

developed countries, the fossil fuels are currently of great

importance in the developing countries. Geothermal and

tidal energy are less important though, of course, will

have local significance where conditions are suitable.

Nuclear energy sources are included for completeness,

but are not likely to make any effective contribution in

the rural areas.

2.2. Biogas Production

Biogas is a generic term for gases generated from the

decomposition of organic material. As the material

breaks down, methane (CH4) is produced as shown in

Figure 2. Sources that generate biogas are numerous and

varied. These include landfill sites, wastewater treatment

plants and anaerobic digesters [11]. Landfills and waste-

water treatment plants emit biogas from decaying waste.

To date, the waste industry has focused on controlling

these emissions to our environment and in some cases,

tapping this potential source of fuel to power gas turbines,

thus generating electricity [12]. The primary components

of landfill gas are methane (CH4), carbon dioxide (CO2),

and nitrogen (N2). The average concentration of methane

is ~45%, CO2 is ~36% and nitrogen is ~18% [13]. Other

components in the gas are oxygen (O2), water vapour and

trace amounts of a wide range of non-methane organic

compounds (NMOCs). Landfill gas-to-cogeneration pro-

jects present a win-win-win situation. Emissions of par-

ticularly damaging pollutant are avoided, electricity is

generated from a free fuel and heat is available for use

locally.

2.3. Wave Power Conversion Devices

The patent literature is full of devices for extracting en-

ergy from waves, i.e, floats, ramps, and flaps, covering

channels [14]. Small generators driven from air trapped

Opportunities for Sustainable Low Carbon Energy Research Development and Applications177

Table 5. Summary of material recycling practices in the

construction sector [10].

Construction and

demolition material

Recycling technology

options Recycling product

Asphalt

Cold recycling: heat

generation; Minnesota

process; parallel drum

process; elongated

drum; microwave as-

phalt recycling sys-

tem; finfalt; surface

regeneration

Recycling asphalt;

asphalt aggregate

Brick Burn to ash, crush

into aggregate

Slime burn ash; filling

material; hardcore

Concrete Crush into aggregate

Recycling aggregate;

cement replacement;

protection of levee;

backfilling; filter

Ferrous metal Melt; reuse directly Recycled steel scrap

Glass

Reuse directly; grind

to powder; polishing;

crush into aggregate;

burn to ash

Recycled window

unit; glass fibre; fill-

ing material; tile;

paving block; asphalt;

recycled aggregate;

cement replacement;

manmade soil

Masonry Crush into aggregate;

heat to 900˚C to ash

Thermal insulating

concrete; traditional

clay

Non-ferrous metal Melt Recycled metal

Paper and cardboard Purification Recycled paper

Plastic

Convert to powder by

cryogenic milling;

clopping; crush into

aggregate; burn to ash

Panel; recycled plas-

tic; plastic lumber;

recycled aggregate;

landfill drainage; as-

phalt; manmade soil

Timber

Reuse directly; cut

into aggregate; blast

furnace deoxidisation;

gasification or pyro-

lysis; chipping;

moulding by pressur-

ising timber chip un-

der steam and water

Whole timber; furni-

ture and kitchen uten-

sils; lightweight recy-

cled aggregate; source

of energy; chemical

production;

wood-based panel;

plastic lumber; geofi-

bre; insulation board

by the rising and falling water in the chamber of a buoy

are in use around the world [15]. Wave power is one

possibility that has been selected Figure 3 shows the

many other aspects that will need to be covered. A wave

power programme would make a significant contribution

to energy resources within a relatively short time and

with existing technology.

Wave energy has also been in the news recently. There

is about 140 megawatts per mile available round British

coasts. It could make a useful contribution people needs

in the UK. Although very large amounts of power are

Figure 2. Biogas production process [14].

available in the waves, it is important to consider how

much power can be extracted. A few years ago only a

few percent efficiency had been achieved. Recently,

however, several devices have been studied which have

very high efficiencies. Some form of storage will be es-

sential on a second-to-second and minute-to-minute basis

to smooth the fluctuations of individual waves and

wave’s packets but storage from one day to the next will

certainly not be economical. This is why provision must

be made for adequate standby capacity.

The increased availability of reliable and efficient en-

ergy services stimulates new development alternatives.

This article discusses the potential for such integrated

systems in the stationary and portable power market in

response to the critical need for a cleaner energy tech-

nology. Anticipated patterns of future energy use and

consequent environmental impacts (acid precipitation,

ozone depletion and the greenhouse effect or global

warming) are comprehensively discussed in this paper.

hroughout the theme several issues relating to renew- T

Opportunities for Sustainable Low Carbon Energy Research Development and Applications

178

Figure 3. Possible systems for exploiting wave power, each element represents an essential link in the chain from sea waves to

consumer [15].

able energies, environment and sustainable development

are examined from both current and future perspectives.

It is concluded that renewable environmentally friendly

energy must be encouraged, promoted, implemented and

demonstrated by full-scale plant especially for use in re-

mote rural areas. Globally, buildings are responsible for

approximately 40% of the total world annual energy

consumption. Most of this energy is for the provision of

lighting, heating, cooling, and air conditioning. Increas-

ing awareness of the environmental impact of CO2 and

NOx emissions and CFCs triggered a renewed interest in

environmentally friendly cooling, and heating technolo-

gies. Under the 1997 Montreal Protocol, governments

agreed to phase out chemicals used as refrigerants that

have the potential to destroy stratospheric ozone. It was

therefore considered desirable to reduce energy con-

sumption and decrease the rate of depletion of world en-

ergy reserves and pollution of the environment. One way

of reducing building energy consumption is to design

buildings, which are more economical in their use of

energy for heating, lighting, cooling, ventilation and hot

water supply. Passive measures, particularly natural or

hybrid ventilation rather than air-conditioning, can dra-

matically reduce primary energy consumption. However,

exploitation of renewable energy in buildings and agri-

cultural greenhouses can, also, significantly contribute

towards reducing dependency on fossil fuels. Therefore,

promoting innovative renewable applications and rein-

forcing the renewable energy market will contribute to

preservation of the ecosystem by reducing emissions at

local and global levels. This will also contribute to the

amelioration of environmental conditions by replacing

Opportunities for Sustainable Low Carbon Energy Research Development and Applications179

conventional fuels with renewable energies that produce

no air pollution or greenhouse gases. The provision of

good indoor environmental quality while achieving en-

ergy and cost efficient operation of the heating, ventilat-

ing and air-conditioning (HVAC) plants in buildings

represents a multi variant problem. The comfort of

building occupants is dependent on many environmental

parameters including air speed, temperature, relative hu-

midity and quality in addition to lighting and noise. The

overall objective is to provide a high level of building

performance (BP), which can be defined as indoor envi-

ronmental quality (IEQ), energy efficiency (EE) and cost

efficiency (CE).

2.4. Ethanol Production

Alternative fuels were defined as methanol, ethanol,

natural gas, propane, hydrogen, coal-derived liquids,

biological material and electricity production [8]. The

fuel pathways currently under development for alcohol

fuels are shown in Figure 4. The production of agricul-

tural biomass and its exploitation for energy purposes

can contribute to alleviate several problems, such as the

dependence on import of energy products, the production

of food surpluses, the pollution provoked by the use of

fossil fuels, the abandonment of land by farmers and the

connected urbanisation. Biomass is not at the moment

competitive with mineral oil, but, taking into account

also indirect costs and giving a value to the aforemen-

tioned advantages, public authorities at national and in-

ternational level can spur its production and use by in-

centives of different nature. In order to address the prob-

lem of inefficiency, research centres around the world

have investigated the viability of converting the resource

to a more useful form, namely solid briquettes and fuel

gas [1] (Figure 5).

The main advantages are related to energy, agriculture

and environment problems, are foreseeable both at re-

gional level and at worldwide level and can be summa-

rised as follows:

 Reduction of dependence on import of energy and

related products.

 Reduction of environmental impact of energy pro-

duction (greenhouse effect, air pollution, and waste

degradation).

 Substitution of food crops and reduction of food

surpluses and of related economic burdens, utilisa-

tion of marginal lands and of set aside lands.

 Reduction of related socio-economic and environ-

mental problems (soil erosion, urbanisation, land-

scape deterioration, etc.).

 Development of new know-how and production of

technological innovation.

Biomass resources play a significant role in energy

supply in all developing countries. Biomass resources

should be divided into residues or dedicated resources,

the latter including firewood and charcoal can also be

produced from forest residues. Ozone (O3) is a naturally

occurring molecule that consists of three oxygen atoms

held together by the bonding of the oxygen atoms to each

other. The effects of the chlorofluorocarbons (CFCs)

molecule can last for over a century. This reaction is

shown in Figure 6.

It is a common misconception that the reason for recy-

cling old fridge is to recover the liquid from the cooling

circuit at the back of the unit. The insulating foams used

inside some fridges act as sinks of CFCs- the gases hav-

ing been used as blowing agents to expand the foam dur-

ing fridge manufacture. Although the use of ozone de-

pleting chemicals in the foam in fridges has declined in

the West, recyclers must consider which strategy to adopt

Figure 4. Schematic process flowsheet [4].

Opportunities for Sustainable Low Carbon Energy Research Development and Applications

180

Figure 5. Biomass resources from several sources are converted into a range of products for use by transport, industry and

building sectors [3].

to deal with the disposal problem they still present each

year. It is common practice to dispose of this waste wood

in landfill where it slowly degraded and takes up valu-

able void space. This wood is a good source of energy

and is an alternative to energy crops. Agricultural wastes

are abundantly available globally and can be converted to

energy and useful chemicals by a number of microorgan-

isms. The success of promoting any technology depends

on careful planning, management, implementation, trai-

ning and monitoring. Main features of gasification pro-

ject are:

 Networking and institutional development/streng-

thening.

 Promotion and extension.

 Construction of demonstration projects.

 Research and development, and training and moni-

toring.

2.5. Biomass CHP

Combined heat and power (CHP) installations are quite

common in greenhouses, which grow high-energy, input

crops (e.g., salad vegetables, pot plants, etc.). Scientific

assumptions for a short-term energy strategy suggest that

the most economically efficient way to replace the ther-

mal plants is to modernise existing power plants to in-

crease their energy efficiency and to improve their envi-

ronmental performance. However, utilisation of wind

power and the conversion of gas-fired CHP plants to

biomass would significantly reduce the dependence on

imported fossil fuels. Although a lack of generating ca-

pacity is forecast in the long-term, utilisation of the ex-

isting renewable energy potential and the huge possibili-

ties for increasing energy efficiency are sufficient to

meet future energy demands in the short-term.

Opportunities for Sustainable Low Carbon Energy Research Development and Applications181

Figure 6. The process of ozone depletion [5].

A total shift towards a sustainable energy system is a

complex and long process, but is one that can be

achieved within a period of about 20 years. Implementa-

tion will require initial investment, long-term national

strategies and action plans. However, the changes will

have a number of benefits including: a more stable en-

ergy supply than at present, and major improvement in

the environmental performance of the energy sector, and

certain social benefits. A national vision [12] used a

methodology and calculations based on computer model-

ling that utilised:

 Data from existing governmental programmes.

 Potential renewable energy sources and energy effi-

ciency improvements.

 Assumptions for future economy growth.

 Information from studies and surveys on the recent

situation in the energy sector.

In addition to realising the economic potential identi-

fied by the National Energy Savings Programme, a long-

term effort leading to a 3% reduction in specific electric-

ity demand per year after 2020 is proposed. This will

require: further improvements in building codes, and

continued information on energy efficiency.

The environmental Non Governmental Organisations

(NGOs) are urging the government to adopt sustainable

development of the energy sector by:

 Diversifying of primary energy sources to increase

the contribution of renewable and local energy re-

sources in the total energy balance.

 Implementing measures for energy efficiency in-

crease at the demand side and in the energy trans-

formation sector.

The price of natural gas is set by a number of market

and regulatory factors that include:

Supply and demand balance and market fundamentals,

weather, pipeline availability and deliverability, storage

inventory, new supply sources, prices of other energy

alternatives and regulatory issues and uncertainty.

Classic management approaches to risk are well docu-

mented and used in many industries. This includes the

following four broad approaches to risk:

 Avoidance includes not performing an activity that

could carry risk. Avoidance may seem the answer to

all risks, but avoiding risks also means losing out on

potential gain.

 Mitigation/reduction involves methods that reduce

the severity of potential loss.

 Retention/acceptance involves accepting the loss

when it occurs. Risk retention is a viable strategy

for small risks. All risks that are not avoided or

transferred are retained by default.

 Transfer means causing another party to accept the

risk, typically by contract.

Methane is a primary constituent of landfill gas (LFG)

and a potent greenhouse gas (GHG) when released into

the atmosphere. Globally, landfills are the third largest

anthropogenic emission source, accounting for about

13% of methane emissions or over 818 million tones of

carbon dioxide equivalent (MMTCO2e) [13] as shown in

Figures 7-9.

2.6. Geothermal Energy

Geothermal steam has been used in volcanic regions in

many countries to generate electricity. The use of geo-

thermal energy involves the extraction of heat from rocks

in the outer part of the earth. It is relatively unusual for

the rocks to be sufficiently hot at shallow depth for this

to be economically attractive. Virtually all the areas of

present geothermal interest are concentrated along the

margins of the major tectonic plates, which form the sur-

Figure 7. Global CHP trends from 1992-2003 [17].

Opportunities for Sustainable Low Carbon Energy Research Development and Applications

182

Figure 8. Distribution of industrial CHP capacity in the EU

and USA [17]. 1 Food, 2 Textile, 3 Pulp & paper, 4 Chemi-

cals, 5 Refining, 6 Minerals, 7 Primary metals, and 8 Oth-

ers.

Figure 9. World landfill methane emissions (MMTCO2e)

[17].

face of the earth. The forced or natural circulation of wa-

ter through permeable hot rock conventionally extracts

heat.

There are various practical difficulties and disadvan-

tages associated with the use of geothermal power:

Transmission: geothermal power has to be used where

it is found. In Iceland it has proved feasible to pipe hot

water 20 km in insulated pipes but much shorter dis-

tances are preferred.

Environmental problems: these are somewhat variable

and are usually not great. Perhaps the most serious is the

disposal of warm high salinity water where it cannot be

reinjected or purified. Dry steam plants tend to be very

noisy and there are releases of small amounts of methane,

hydrogen, nitrogen, amonia and hydrogen sulphide and

of these the latter presents the main problem.

The geothermal fluid is often highly chemically corro-

sive or physically abrassive as the result of the entrained

solid matter it carries. This may entail special plant de-

sign problems and unusually short operational lives for

both the holes and the installations they serve.

Because the useful rate of heat extraction from a geo-

thermal field is in nearly all cases much higher than the

rate of conduction into the field from the underlying

rocks, the mean temperatures of the field is likely to fall

during exploitation. In some low rainfall areas there may

also be a problem of fluid depletion. Ideally, as much as

possible of the geothermal fluid should be reinjected into

the field. However, this may involve the heavy capital

costs of large condensation installations. Occasionally,

the salinity of the fluid available for reinjection may be

so high (as a result of concentration by boiling) that is

unsuitable for reinjection into ground. Ocasionally, the

impurities can be precipitated and used but this has not

generally proved commercially attractive.

World capacity of geothermal energy is growing at a

rate of 2.5% per year from a 2005 level of 28.3 GW [13].

The GSHPs account for approximately 54% of this ca-

pacity almost all of it in the North America and Europe

[13]. The involvement of the UK is minimal with less

than 0.04% of world capacity and yet is committed to

substantial reduction in carbon emission beyond the

12.5% Kyoto obligation to be achieved by 2012. The

GSHPs offer a significant potential for carbon reduction

and it is therefore expected that the market for these sys-

tems will rise sharply in the UK in the immediate years

ahead given to low capacity base at present.

There are numerous ways of harnessing low-grade

heat from the ground for use as a heat pump source or air

conditioning sink. For small applications (residences and

small commercial buildings) horizontal ground loop heat

exchangers buried typically at between 1 m and 1.8 m

below the surface can be used provided that a significant

availability of land surrounding the building can be ex-

ploited which tends to limit these applications to rural

settings.

Heat generation within the earth is approximately 2700

GW, roughly an order of magnitude greater than the en-

ergy associated with the tides but about four orders less

than that received by the earth from the sun [7].

Temperature distributions within the earth depend on:

 The abundance and distribution of heat producing

elements within the earth.

 The mean surface temperature (which is controlled

Opportunities for Sustainable Low Carbon Energy Research Development and Applications183

by the ocean/atmosphere system).

 The thermal properties of the earth’s interior and

their lateral and radial variation.

 Any movements of fluid or solid rock materials

occurring at rates of more than a few millimetres

per year.

Of these four factors the first two are of less impor-

tance from the point of view of geothermal energy. Mean

surface temperatures range between 0˚C - 30˚C and this

variation has a small effect on the useable enthalpy of

any flows of hot water. Although radiogenic heat pro-

duction in rocks may vary by three orders of magnitude,

there is much less variation from place to place in the

integrated heat production with depth. The latter factors,

however, are of great importance and show a wide range

of variation. Their importance is clear from the relation-

ship:

β = q/k (2)

where:

β is the thermal gradient for a steady state (˚C/km), q

is the heat flux (10–6 cal·cm–2·sec–1) and k is the thermal

conductivity (cal·cm–1·sec–1·˚C –1).

The first requirement of any potential geothermal

source region is that β being large, i.e., that high rock

temperatures occur at shallow depth. Beta will be large if

either q is large or k is small or both. By comparison with

most everyday materials, rocks are poor conductors of

heat and values of conductivity may vary from 2 × 10–3

to 10–2 cal·cm–1·sec–1·˚C–1. The mean surface heat flux

from the earth is about 1.5 heat flow units (1 HFU = 10–6

cal·cm–2·sec–1) [7]. Rocks are also very slow respond to

any temperature change to which they are exposed, i.e.,

they have a low thermal diffusivity:

K = k/ρ·Cp (3)

where:

K is thermal diffusivity; ρ and Cp are density and spe-

cific heat respectively.

These values are simple intended to give a general idea

of the normal range of geothermal parameters (Table 6).

In volcanic regions, in particular, both q and β can vary

considerably and the upper values given are somewhat

nominal.

2.7. Landfill Gap

Landfill gas (LFG) is currently extracted at over 1200

Table 6. Values of geothermal parameters [16].

Parameter Lower Average Upper

q (HFU)

k = cal·cm–2·sec–1·℃–1

β = ˚C/km

0.8

2 × 10–3

1.5

6 × 10–3

3.0 (non volcanic) ≈ 100

(volcanic)

12 × 10–3

60 (non volcanic) ≈ 300

(volcanic)

landfills worldwide for a variety of energy purposes

(Table 7), such as:

 Creating pipeline quality gas or an alternative fuel

for vehicles.

 Processing the LFG to make it available as an al-

ternative fuel to local industrial or commercial cus-

tomers.

 Generation of electricity with engines, turbines,

micro-turbines and other emerging technologies.

In terms of solid waste management policy, many

NGOs have changed drastically in the past ten years from

a mass production and mass consumption society to

‘material-cycle society’. In addition to national legisla-

tion, municipalities are legally obliged to develop a plan

for handling the municipal solid waste (MSW) generated

in administrative areas. Such plans contain:

 Estimates of future waste volume.

 Measures to reduce waste.

 Measures to encourage source separation.

 A framework for solid waste disposal and the con-

struction and management of solid waste manage-

ment facilities.

Landfilling is in the least referred tier of the hierarchy

of waste management options: Waste minimisation, reuse

and recycling, incineration with energy recovery, and

optimised final disposal. The key elements are as follows:

construction impacts, atmospheric emissions, noise, water

quality, landscape, visual impacts, socio economics,

ecological impacts, traffic, solid waste disposal and cul-

tural heritage.

3. Energy Efficiency

Energy efficiency is the most cost-effective way of cut-

ting carbon dioxide emissions and improvements to

households and businesses. It can also have many other

additional social, economic and health benefits, such as

warmer and healthier homes, lower fuel bills and com-

pany running costs and, indirectly, jobs. Britain wastes

20 per cent of its fossil fuel and electricity use. This im-

Table 7. Types of LFG implemented recently worldwide.

Landsill caps Electricity generation Fuel production

Soil caps Reciprocating Medium BTU gas

Clay caps engines High BTU gas

Geo-membrane capsCombustion turbines Liquefied methane

Micro-turbines

LFG destruction Steam turbines Thermal generation

Flares Fuel cells Boilers

Candlestick Kilns

Enclosed CHP Greenhouse heaters

Turbines Leachate evaporators

Engines

Opportunities for Sustainable Low Carbon Energy Research Development and Applications

184

plies that it would be cost-effective to cut £10 billion a

year off the collective fuel bill and reduce CO2 emissions

by some 120 million tones. Yet, due to lack of good in-

formation and advice on energy saving, along with the

capital to finance energy efficiency improvements, this

huge potential for reducing energy demand is not being

realised. Traditionally, energy utilities have been essen-

tially fuel providers and the industry has pursued profits

from increased volume of sales. Institutional and market

arrangements have favoured energy consumption rather

than conservation. However, energy is at the centre of the

sustainable development paradigm as few activities af-

fect the environment as much as the continually increas-

ing use of energy. Most of the used energy depends on

finite resources, such as coal, oil, gas and uranium. In

addition, more than three quarters of the world’s con-

sumption of these fuels is used, often inefficiently, by

only one quarter of the world’s population. Without even

addressing these inequities or the precious, finite nature

of these resources, the scale of environmental damage

will force the reduction of the usage of these fuels long

before they run out.

Throughout the energy generation process, there are

impacts on the environment on local, national and inter-

national levels, from opencast mining and oil exploration

to emissions of the potent greenhouse gas carbon dioxide

in ever increasing concentration. Recently, the world’s

leading climate scientists reached an agreement that hu-

man activities, such as burning fossil fuels for energy and

transport, are causing the world’s temperature to rise.

The Intergovernmental Panel on Climate Change has

concluded that “the balance of evidence suggests a dis-

cernible human influence on global climate”. It predicts a

rate of warming greater than any one had seen in the last

10,000 years, in other words, throughout human history.

The exact impact of climate change is difficult to predict

and will vary regionally. It could, however, include sea

level rise, disrupted agriculture and food supplies and the

possibility of more freak weather events such as hurri-

canes and droughts. Indeed, people already are waking

up to the financial and social, as well as the environ-

mental, risks of unsustainable energy generation methods

that represent the costs of the impacts of climate change,

acid rain and oil spills. The insurance industry, for ex-

ample, concerned about the billion dollar costs of hurri-

canes and floods, has joined sides with environmentalists

to lobby for greenhouse gas emissions reduction. Friends

of the earth are campaigning for a more sustainable en-

ergy policy, guided by the principal of environmental

protection and with the objectives of sound natural re-

source management and long-term energy security. The

key priorities of such an energy policy must be to reduce

fossil fuel use, move away from nuclear power, improve

the efficiency with which energy is used and increase the

amount of energy obtainable from sustainable and re-

newable energy sources. Efficient energy use has never

been more crucial than it is today, particularly with the

prospect of the imminent introduction of the climate

change levy (CCL). Establishing an energy use action

plan is the essential foundation to the elimination of en-

ergy waste. A logical starting point is to carry out an en-

ergy audit that enables the assessment of the energy use

and determine what actions to take. The actions are best

categorised by splitting measures into the following three

general groups:

1) High Priority/Low Cost

These are normally measures, which require minimal

investment and can be implemented quickly. The fol-

lowings are some examples of such measures:

 Good housekeeping, monitoring energy use and tar-

geting waste-fuel practices.

 Adjusting controls to match requirements.

 Improved greenhouse space utilisation.

 Small capital item time switches, thermostats, etc.

 Carrying out minor maintenance and repairs.

 Staff education and training.

 Ensuring that energy is being purchased through the

most suitable tariff or contract arrangements.

2) Medium Priority/Medium Cost

Measures, which, although involve little or no design,

involve greater expenditure and can take longer to im-

plement. Examples of such measures are listed below:

 New or replacement controls.

 Greenhouse component alteration, e.g., insulation, seal-

ing glass joints, etc.

 Alternative equipment components, e.g., energy effi-

cient lamps in light fittings, etc.

3) Long Term/High Cost

These measures require detailed study and design.

They can be best represented by the followings:

 Replacing or upgrading of plant and equipment.

 Fundamental redesign of systems, e.g., combined heat

and power CHP installations.

This process can often be a complex experience and

therefore the most cost-effective approach is to employ

an energy specialist to help.

3.1. Policy Recommendations for a Sustainable

Energy Future

Sustainability is regarded as a major consideration for

both urban and rural development. People have been ex-

ploiting the natural resources with no consideration to the

effects, both short-term (environmental) and long-term

(resources crunch). It is also felt that knowledge and

technology have not been used effectively in utilising

energy resources. Energy is the vital input for economic

Opportunities for Sustainable Low Carbon Energy Research Development and Applications185

and social development of any country. Its sustainability

is an important factor to be considered. The urban areas

depend, largely, on commercial energy sources. The rural

areas use non-commercial sources like firewood and ag-

ricultural wastes. With the present day trends for im-

proving the quality of life and sustenance of humankind,

environmental issues are considered highly important. In

this context, the term energy loss has no significant tech-

nical meaning. Instead, the exergy loss has to be consid-

ered, as destruction of exergy is possible. Hence, exergy

loss minimisation will help in sustainability.

The development of a renewable energy in a country

depends on many factors. Those important to success are

listed below:

3.1.1. Motivation of the P op u l ation

The population should be motivated towards awareness

of high environmental issues, and rational use of energy

in order to reduce cost. Subsidy programme should be

implemented as incentives to install biomass energy

plants. In addition, image campaigns to raise awareness

of renewable technology.

3.1.2. Technical Product Development

To achieve technical development of biomass energy

technologies the following should be addressed:

 Increasing the longevity and reliability of renewable

technology.

 Adapting renewable technology to household tech-

nology (hot water supply).

 Integration of renewable technology in heating

technology.

 Integration of renewable technology in architecture,

e.g., in the roof or façade.

 Development of new applications, e.g., solar cool-

ing.

 Cost reduction.

3.1.3. Distribution and Sales

Commercialisation of biomass energy technology re-

quires:

 Inclusion of renewable technology in the product

range of heating trades at all levels of the distribu-

tion process (wholesale, and retail).

 Building distribution nets for renewable technology.

 Training of personnel in distribution and sales.

 Training of field sales force.

3.1.4. Consumer Consultation and Installation

To encourage all sectors of the population to participate

in adoption of biomass energy technologies, the follow-

ing has to be realised:

 Acceptance by craftspeople, and marketing by them.

 Technical training of craftspeople, initial and fol-

low-up training programmes.

 Sales training for craftspeople.

 Information material to be made available to crafts-

people for consumer consultation.

3.1.5. Projecti ng and Planning

Successful application of biomass technologies also re-

quire:

 Acceptance by decision makers in the building sec-

tor (architects, house technology planners, etc.).

 Integration of renewable technology in training.

 Demonstration projects/architecture competitions.

 Biomass energy project developers should prepare

to participate in the carbon market by:

1) Ensuring that renewable energy projects comply

with Kyoto Protocol requirements.

2) Quantifying the expected avoided emissions.

3) Registering the project with the required offices.

4) Contractually allocating the right to this revenue

stream.

 Other ecological measures employed on the devel-

opment include:

1) Simplified building details.

2) Reduced number of materials.

3) Materials that can be recycled or reused.

4) Materials easily maintained and repaired.

5) Materials that do not have a bad influence on the

indoor climate (i.e., non-toxic).

6) Local cleaning of grey water.

7) Collecting and use of rainwater for outdoor pur-

poses and park elements.

8) Building volumes designed to give maximum ac-

cess to neighbouring park areas.

9) All apartments have visual access to both backyard

and park.

3.1.6. Energy Saving Measures

The following energy saving measures should also be

considered:

 Building integrated solar PV system.

 Day-lighting.

 Ecological insulation materials.

 Natural/hybrid ventilation.

 Passive cooling.

 Passive solar heating.

 Solar heating of domestic hot water.

 Utilisation of rainwater for flushing.

Improving access for rural and urban low-income ar-

eas in developing countries must be through energy effi-

ciency and renewable energies. Sustainable energy is a

prerequisite for development. Energy-based living stan-

dards in developing countries, however, are clearly be-

low standards in developed countries. Low levels of ac-

cess to affordable and environmentally sound energy in

both rural and urban low-income areas are therefore a

Opportunities for Sustainable Low Carbon Energy Research Development and Applications

186

predominant issue in developing countries. In recent

years many programmes for development aid or technical

assistance have been focusing on improving access to

sustainable energy, many of them with impressive re-

sults.

Apart from success stories, however, experience also

shows that positive appraisals of many projects evaporate

after completion and vanishing of the implementation

expert team. Altogether, the diffusion of sustainable tech-

nologies such as energy efficiency and renewable ener-

gies for cooking, heating, lighting, electrical appliances

and building insulation in developing countries has been

slow.

Energy efficiency and renewable energy programmes

could be more sustainable and pilot studies more effec-

tive and pulse releasing if the entire policy and imple-

mentation process was considered and redesigned from

the outset. New financing and implementation processes

are needed, which allow reallocating financial resources

and thus enabling countries themselves to achieve a sus-

tainable energy infrastructure. The links between the

energy policy framework, financing and implementation

of renewable energy and energy efficiency projects have

to be strengthened and capacity building efforts are re-

quired.

3.2. Environmental Aspects of Energy

Conversion and Use

Environment has no precise limits because it is in fact a

part of everything. Indeed, environment is, as anyone

probably already knows, not only flowers blossoming or

birds singing in the spring, or a lake surrounded by

beautiful mountains. It is also human settlements, the

places where people live, work, rest, the quality of the

food they eat, the noise or silence of the street they live

in. Environment is not only the fact that our cars

consume a good deal of energy and pollute the air, but

also, that we often need them to go to work and for

holidays. Obviously man uses energy just as plants,

bacteria, mushrooms, bees, fish and rats do. Man largely

uses solar energy-food, hydropower, wood- and thus

participates harmoniously in the natural flow of energy

through the environment. But man also uses oil, gas, coal

and nuclear power. By using such sources of energy, man

is thus modifying his environment.

The atmospheric emissions of fossil fuelled installa-

tions are mosty aldehydes, carbon monoxide, nitrogen

oxides, sulpher oxides and particles (i.e., ash) as well as

carbon dioxide. Table 8 shows estimates include not

only the releases occuring at the power plant itself but

also cover fuel extraction and treatment, as well as the

storage of wastes and the aea of land required for

operations. Table 9 shows energy consumption in diffe-

Table 8. Annual greenhouse emissions from different sour-

ces of power plants.

Emissions

Primary source

of energy Atmosphere Water

Waste (× 103

metric tons) Area (km2)

Coal

Oil

Gas

Nuclear

380

70 - 160

7 - 41

3 - 6

60 - 3000

negligible

2600

120

70 - 84

rent regions of the world.

3.3. Greenhouses Environment

Greenhouse cultivation is one of the most absorbing and

rewarding forms of gardening for anyone who enjoys

growing plants. The enthusiastic gardener can adapt the

greenhouse climate to suit a particular group of plants, or

raise flowers, fruit and vegetables out of their natural

season. The greenhouse can also be used as an essential

garden tool, enabling the keen amateur to expand the

scope of plants grown in the garden, as well as save

money by raising their own plants and vegetables. There

was a decline in large private greenhouses during the two

world wars due to a shortage of materials for their con-

struction and fuel to heat them. However, in the 1950s

mass-produced, small greenhouses became widely avail-

able at affordable prices and were used mainly for raising

plants [18]. Also, in recent years, the popularity of con-

servatories attached to the house has soared. Modern

double-glazing panels can provide as much insulation as

a brick wall to create a comfortable living space, as well

as provide an ideal environment in which to grow and

display tender plants.

The comfort in a greenhouse depends on many envi-

ronmental parameters. These include temperature, rela-

tive humidity, air quality and lighting. Although green-

house and conservatory originally both meant a place to

house or conserve greens (variegated hollies, cirrus, myr-

tles and oleanders), a greenhouse today implies a place in

which plants are raised while conservatory usually de-

scribes a glazed room where plants may or may not play

a significant role. Indeed, a greenhouse can be used for

so many different purposes. It is, therefore, difficult to

Table 9. Energy consumption in different continents.

Region Population (millions) Energy (Watt/m2)

Africa

Asia

Central America

North America

South America

Western Europe

Eastern Europe

Oceania

Russia

820

3780

180

335

475

445

130

330

0.54

2.74

1.44

0.34

0.52

2.24

2.57

0.08

0.29

Opportunities for Sustainable Low Carbon Energy Research Development and Applications187

decide how to group the information about the plants that

can be grown inside it.

Throughout the world, urban areas have increased in

size during recent decades. About 50% of the world’s

population and approximately 76% in the more devel-

oped countries are urban dwellers [18]. Even though

there is an evidence to suggest that in many ‘advanced’

industrialised countries there has been a reversal in the

rural-to-urban shift of populations, virtually all popula-

tion growth expected between 2000 and 2030 will be

concentrated in urban areas of the world. With an ex-

pected annual growth of 1.8%, the world’s urban popula-

tion will double in 38 years [18]. This represents a seri-

ous contributing to the potential problem of maintaining

the required food supply. Inappropriate land use and

management, often driven by intensification resulting

from high population pressure and market forces, is also

a threat to food availability for domestic, livestock and

wildlife use. Conversion to cropland and urban-industrial

establishments is threatening their integrity. Improved

productivity of peri-urban agriculture can, therefore,

make a very large contribution to meeting food security

needs of cities as well as providing income to the peri-

urban farmers. Hence, greenhouses agriculture can be-

come an engine of pro-poor ‘trickle-up’ growth because

of the synergistic effects of agricultural growth such as

[18]:

 Increased productivity increases wealth.

 Intensification by small farmers raises the demand

for wage labour more than by larger farmers.

 Intensification drives rural non-farm enterprise and

employment.

 Alleviation of rural and peri-urban poverty is likely

to have a knock-on decrease of urban poverty.

Despite arguments for continued large-scale collective

schemes, there is now an increasingly compelling argu-

ment in favour of individual technologies for the devel-

opment of controlled greenhouses. The main points con-

stituting this argument are summarised by [18] as fol-

lows:

 Individual technologies enable the poorest of the

poor to engage in intensified agricultural production

and to reduce their vulnerability.

 Development is encouraged where it is needed most

and reaches many more poor households more

quickly and at a lower cost.

 Farmer-controlled greenhouses enable farmers to

avoid the difficulties of joint management.

Such development brings the following challenges

[19]:

 The need to provide farmers with ready access to

these individual technologies, repair services and

technical assistance.

 Access to markets with worthwhile commodity

prices, so that sufficient profitability is realised.

 This type of technology could be a solution to food

security problems. For example, in greenhouses,

advances in biotechnology like the genetic engi-

neering, tissue culture and market-aided selection

have the potential to be applied for raising yields,

reducing pesticide excesses and increasing the nu-

trient value of basic foods.

However, the overall goal is to improve the cities in

accordance with the Brundtland Report [19] and the in-

vestigation into how urban green could be protected. In-

deed, greenhouses can improve the urban environment in

multitude of ways. They shape the character of the town

and its neighbourhoods, provide places for outdoor rec-

reation, and have important environmental functions such

as mitigating the heat island effect, reduce surface water

runoff, and creating habitats for wildlife. Following

analysis of social, cultural and ecological values of urban

green, six criteria in order to evaluate the role of green

urban in towns and cities were prescribed [19]. These are

as follows:

 Recreation, everyday life and public health.

 Maintenance of biodiversity—preserving diversity

within species, between species, ecosystems, and of

landscape types in the surrounding countryside.

 City structure—as an important element of urban

structure and urban life.

 Cultural identity—enhancing awareness of the his-

tory of the city and its cultural traditions.

 Environmental quality of the urban sites—impro-

vement of the local climate, air quality and noise

reduction.

 Biological solutions to technical problems in urban

areas—establishing close links between technical

infrastructure and green-spaces of a city.

The main reasons why it is vital for greenhouses plan-

ners and designers to develop a better understanding of

greenhouses in high-density housing can be summarised

as follows [20]:

 Pressures to return to a higher density form of hous-

ing.

 The requirement to provide more sustainable food.

 The urgent need to regenerate the existing, and of-

ten decaying, houses built in the higher density,

high-rise form, much of which is now suffering

from technical problems.

The connection between technical change, economic

policies and the environment is of primary importance as

observed by most governments in developing countries,

whose attempts to attain food self-sufficiency have led

them to take the measures that provide incentives for

adoption of the Green Revolution Technology [20].

Opportunities for Sustainable Low Carbon Energy Research Development and Applications

188

Since, the Green Revolution Technologies were introdu-

ced in many countries actively supported by irrigation

development, subsidised credit, and fertiliser programm-

es, self-sufficiency was found to be not economically

efficient and often adopted for political reasons creating

excessive damage to natural resources. Also, many deve-

loping countries governments provided direct assistance

to farmers to adopt soil conservation measures. They

found that high costs of establishment and maintenance

and the loss of land to hedgerows are the major

constraints to adoption [20]. The soil erosion problem in

developing countries reveals that a dynamic view of the

problem is necessary to ensure that the important ele-

ments of the problem are understood for any remedial

measures to be undertaken. The policy environment has,

in the past, encouraged unsustainable use of land [20]. In

many regions, government policies such as provision of

credit facilities, subsidies, price support for certain crops,

subsidies for erosion control and tariff protection, have

exacerbated the erosion problem. This is because techno-

logical approaches to control soil erosion have often been

promoted to the exclusion of other effective approaches.

However, adoption of conservation measures and the

return to conservation depend on the specific agro-

ecological conditions, the technologies used and the

prices of inputs and outputs of production.

3.3.1. Types of Greenhouses

Choosing a greenhouse and setting it up are important,

and often expensive, steps to take. Greenhouses are ei-

ther freestanding or lean-to, that is, built against an ex-

isting wall. A freestanding greenhouse can be placed in

the open, and, hence, take advantage of receiving the full

sun throughout the day. It is, therefore, suitable for a

wide range of plants. However, its main disadvantage

when compared to a lean-to type is that more heat is lost

through its larger surface area. This is mainly why lean-

to greenhouses have long been used in the walled gar-

dens of large country houses to grow Lapageria rosea and

other plants requiring cool, constant temperature, such as

half-hardly ferns. However, generally, good ventilation

and shading in the spring and summer to prevent over-

heating are essential for any greenhouse. The high day-

time temperatures will warm the back wall, which acts as

a heat battery, releasing its accumulated heat at night.

Therefore, plants in a greenhouse with this orientation

will need the most attention, as they will dry out rapidly.

Also, greenhouses vary considerably in their shapes

and internal dimensions. Traditional greenhouses have

straight sides, which allow the maximum use of internal

space, and are ideal for climbers [21]. On the other hand,

greenhouses with sloping sides have the advantage of

allowing the greatest penetration of sunlight, even during

winter [21]. The low winter sun striking the glass at 90˚C

lets in the maximum amount of light. Where the sun

strikes the glass at a greater or lesser angle, a proportion

of the light is reflected away from greenhouse. Sloping

sides, also, offer less wind resistance than straight sides

and therefore, less likely to be damaged during windy

weather. This type of greenhouse is most suitable for

short winter crops, such as early spring lettuce, and flow-

ering annuals from seed, which do not require much

headroom.

A typical greenhouse is shown schematically in Fig-

ure 10. However, there are several designs of green-

houses, based on dimensions, orientation and function.

The following three options are the most widely used:

 A ready-made design.

 A designed, which is constructed from a number of

prefabricated modules.

 A bespoke design.

Of these, the prefabricated ready-made design, which

is utilised to fit the site, is the cheapest greenhouses and

gives flexibility. It is, also, the most popular option [22].

Specific examples of commercially available designs

are numerous. Dutch light greenhouses, for example,

have large panes of glass, which cast little shade on the

plants inside. They are simple to erect, consisting of

frames bolted together, which are supported on a steel

framework for all but the smallest models. They are easy

to move and extra sections can be added on to them, a

useful attraction [22]. Curvilinear greenhouses, on the

other hand, are designed primarily to let in the maximum

amount of light throughout the year by presenting at least

one side perpendicular to the sun. This attractive style of

greenhouse tends to be expensive because of the number

of different angles, which require more engineering [22].

Likewise, the uneven span greenhouses are designed for

maximum light transmission on one side. These are gen-

erally taller than traditional greenhouses, making them

suitable for tall, early season crops, such as cucumbers

Figure 10. Greenhouse and base wi th hor t ic ultur a l glass.

Opportunities for Sustainable Low Carbon Energy Research Development and Applications189

[21]. In addition, the polygonal greenhouses are designed

more as garden features than as practical growing houses,

and consequently, are expensive. Their internal space is

somewhat limited and on smaller models over-heading

can be a problem because of their small roof ventilations.

They are suitable for growing smaller pot plants, such as

pelargoniums and cacti [23]. Another example is the so-

lar greenhouses. These are designed primarily for areas

with very cold winters and poor winter light. They take

the form of lean-to structures facing the sun, are well

insulated to conserve heat and are sometimes partially

sunk into the ground. They are suitable for winter vege-

table crops and early-sown bedding plants, such as bego-

nias and pelargoniums [23]. Mini lean-to greenhouses are

suitable for small gardens where space is limited. They

can, also, be used to create a separate environment within

larger greenhouses. The space inside is large enough to

grow two tomato or melon plants in growing bags, or can

install shelves to provide a multi-layered growing envi-

ronment, ideal for many small potted plants and raising

summer bedding plants [23].

3.3.2. Cons truction Materials

Different materials are used for the different parts. How-

ever, wood and aluminium are the two most popular ma-

terials used for small greenhouses. Steel is used for larger

structures and rigid polyvinyl chloride, UPVC for con-

servatories, which is used mainly in conservatory building,

does not decay or rust and is, therefore, maintenance-free

[24]. However, after a period of time it can become

abraded by dirt in the atmosphere and lose its smart finish.

Greenhouses clothed in plastic or glass. Plastic offers the

cheapest form of protection, while glass is the most aes-

thetically pleasing of the two materials.

3.3.3. Ground Radiation

Reflection of sunrays is mostly used for concentrating

them onto reactors of solar power plants. Enhancing the

insolation for other purposes has, so far, scarcely been

used. Several years ago, application of this principle for

increasing the ground irradiance in greenhouses, glass

covered extensions in buildings, and for illuminating

northward facing walls of buildings was proposed [25].

Application of reflection of sun’s rays was motivated by

the fact that ground illuminance/irradiance from direct

sunlight is of very low intensity in winter months, even

when skies are clear, due to the low incident angle of

incoming radiation during most of the day. This is even

more pronounced at greater latitudes. As can be seen in

Figure 11, which depicts a sunbeam split into its vertical

and horizontal components, nearly all of the radiation

passes through a greenhouse during most of the day.

The primary objective of greenhouses is to produce

agricultural products outside the cultivation season. They

Figure 11. Relative horizontal and vertical components of

solar radiation.

offer a suitable microclimate for plants and make possi-

ble growth and fruiting, where it is not possible in open

fields. This is why a greenhouse is also known as a “con-

trolled environment greenhouse”. Through a controlled

environment, greenhouse production is advanced and can

be continued for longer duration, and finally, production

is increased [26]. The off-season production of flowers

and vegetables is the unique feature of the controlled

environment greenhouse. Hence, greenhouse technology

has evolved to create the favourable environment, or

maintaining the climate, in order to cultivate the desir-

able crop the year round. The use of “maintaining the

climate” concept may be extended for crop drying, dis-

tillation, biogas plant heating and space conditioning.

4. Conclusions

Two of the most essential natural resources for all life on

the earth and for man’s survival are sunlight and water.

Sunlight is the driving force behind many of the renew-

able energy technologies. The worldwide potential for

utilising this resource, both directly by means of the solar

technologies and indirectly by means of biofuels, wind

and hydro technologies is vast. During the last decade,

interest has been refocused on renewable energy sources

due to the increasing prices and fore-seeable exhaustion of

presently used commercial energy sources. Thermal

comfort is an important aspect of human life. Buildings

where people work require more light than buildings

where people live. In buildings where people live the

energy is used for maintaining both the temperature and

lighting. Hence, natural ventilation is rapidly becoming a

significant part in the design strategy for non-domestic

buildings because of its potential to reduce the environ-

mental impact of building operation, due to lower energy

demand for cooling. A traditional, naturally ventilated

building can readily provide a high ventilation rate. On the

other hand, the mechanical ventilation systems are very

expensive. However, a comprehensive ecological concept

can be developed to achieve a reduction of electrical and

heating energy consumption, optimise natural air condi-

Opportunities for Sustainable Low Carbon Energy Research Development and Applications

190

tion and ventilation, improve the use of daylight and

choose environmentally adequate building materials.

Plants, like human beings, need tender loving care in the

form of optimum settings of light, sunshine, nourishment,

and water. Hence, the control of sunlight, air humidity and

temperatures in greenhouses are the key to successful

greenhouse gardening. The mop fan is a simple and novel

air humidifier; which is capable of removing particulate

and gaseous pollutants while providing ventilation. It is a

device ideally suited to greenhouse applications, which

require robustness, low cost, minimum maintenance and

high efficiency. A device meeting these requirements is

not yet available to the farming community. Hence, im-

plementing mop fans aides sustainable development

through using a clean, environmentally friendly device

that decreases load in the greenhouse and reduces energy

consumption.

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Current Distortion Evaluation in Traction 4Q Constant Switching Frequency Converters 191

Nomenclature

a: annum

ha: hectares

HFU: heat flow unit

l: litre

MSW: municipal sewage waste