Open Access Articles- Top Results for Energy industry

Energy industry

The energy industry is the totality of all of the industries involved in the production and sale of energy, including fuel extraction, manufacturing, refining and distribution. Modern society consumes large amounts of fuel, and the energy industry is a crucial part of the infrastructure and maintenance of society in almost all countries.

In particular, the energy industry comprises:

Sectors within the electrical field

  • Basic Electrical
  • Electronics and communication
  • Computer systems
  • Data communication
  • Refrigeration and air conditioning
  • Instrumentation and control
  • Rail signaling
  • Lifts
  • Electricity supply (generation, transmission) and distribution
  • Gas industry

Career paths in the energy sector:

  • Australian Qualification Framework (AQF)
  • Scope of work – Installation
  • Maintenance and Servicing

Learning Pathways:

  • Traineeships
  • Apprenticeships
  • Licensed Electrician minimum requirements and career advancements\

Industry Organisations:

  • NECA – National Electrical and Communications Association
  • ECA – Electrical Contractors Association
  • ME – Master Electrician
  • ENA – Energy Networks Association
  • Trade unions
    • CEPU – Communication Electrical Plumbing Union
    • ETU – Electrical Trade Union

Government Training Organisations:

  • ITAB – Industry Training Advisory Bodies
  • TAFE – Technical and Further Education
  • RTO – Registered Training Organisations
  • ERAC – Electrical Regulatory
  • + Private Providers / Small businesses

Policies and Practices to follow in the industry:

  • Adhere to licencing Requirements
  • OH&S Requirements
  • Awards within the field

Process into applying for jobs:

  • Research the company
  • Requirements within job scope
  • Method to the process

Job Interview Process:

  • Preparation
  • Research into Company
  • Presentation
  • Evaluation

Electrical Concepts:

  • Electrical supply and distribution with a building/ premises
  • Arrangements of circuits
  • Protection for safety requirements and this practices
  • Difference between AC and DC
  • Measurement and calculation of voltage
  • Current
  • Resistance and power in practical circuits
  • The concepts and applications of magnetism and electromagnetic induction
  • Transformer operating principles and their function/ application
  • The hazards associated with electrical systems and apparatus

Parts and component selection:

  • Part and component identification:
    • Type
    • Number and ratings of a range of typical components used in electro technology
  • Information about parts and components:
    • Catalogues
    • Computer access
    • Alternative parts
    • Telephone enquiry
      • (May include availability/ delivery/ price/ discount and total cost)
  • Ordering Process:
    • Customer approval
    • Supplier requirements
    • In house requirements
    • Includes actual need
  • Receiving/ dispatching procedures:
    • Supplier requirements
    • In house requirements
    • Handling and storage of equipment

Maintaining Documentation:

  • Enterprise communication methods:
    • Communicating with personal
    • Oral communication
    • Written procedures and work instructions
    • Communicating with both suppliers and customers
  • Work activity records:
    • Purpose and extent of maintaining work activities
    • Records in an enterprise
    • Methods for recording and maintaining work records
    • Work records required by regulation and requirements
  • Problem solving concepts and techniques:
    • Identify problems – process and quality problems
    • Equipment selection
    • Availability and failure of product
    • Teamwork and work allocation problems
    • Safety and emergency situations and incident
    • Performance gaps
    • Profit improvements and the like
    • Using mathematical tools; Mean, mode, medium and standard deviation
    • Documentation to assist problem solving; data sheets, job cards, plant drawings and maintenance logs
  • Enterprise customer relations protocols:
  • Purpose of customer relations
    • Procedures for dealing with customers
    • Dealing with customer problems/ issues
  • Enterprise quality management system:
    • Purpose of quality system
  • Instructing users in the use of specific items of equipment and systems:
    • Methods for evaluating user needs – correct usage techniques
      • Efficient and safe procedures for use
File:Energy per capita.png
Energy consumption in kilograms of oil equivalent (kgoe) per person per year per country (2001 data). Darker tones indicate larger consumption (dark grey areas are missing from the dataset). Red hue indicates increasing consumption, green hue indicates decreasing consumption, in the time between 1990 and 2001.


The use of energy has been a key in the development of the human society by helping it to control and adapt to the environment. Managing the use of energy is inevitable in any functional society. In the industrialized world the development of energy resources has become essential for agriculture, transportation, waste collection, information technology, communications that have become prerequisites of a developed society. The increasing use of energy since the Industrial Revolution has also brought with it a number of serious problems, some of which, such as global warming, present potentially grave risks to the world.

In society and in the context of humanities, the word energy is used as a synonym of energy resources, and most often refers to substances like fuels, petroleum products and electricity in general. These are sources of usable energy, in that they can be easily transformed to other kinds of energy sources that can serve a particular useful purpose. This difference vis a vis energy in natural sciences can lead to some confusion, because energy resources are not conserved in nature in the same way as energy is conserved in the context of physics. The actual energy content is always conserved, but when it is converted into heat for example, it usually becomes less useful to society, and thus appears to have been "used up".

Ever since humanity discovered various energy resources available in nature, it has been inventing devices, known as machines, that make life more comfortable by using energy resources. Thus, although the primitive man knew the utility of fire to cook food, the invention of devices like gas burners and microwave ovens has increased the usage of energy for this purpose alone manifold. The trend is the same in any other field of social activity, be it construction of social infrastructure, manufacturing of fabrics for covering; porting; printing; decorating, for example textiles, air conditioning; communication of information or for moving people and goods (automobiles).

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Main article: Energy economics

Production and consumption of energy resources is very important to the global economy. All economic activity requires energy resources, whether to manufacture goods, provide transportation, run computers and other machines.

Widespread demand for energy may encourage competing energy utilities and the formation of retail energy markets. Note the presence of the "Energy Marketing and Customer Service" (EMACS) sub-sector.[1]

The energy sector accounts for 4.6% of outstanding leveraged loans, compared with 3.1% a decade ago, while energy bonds make up 15.7% of the $1.3tn junk bond market, up from 4.3 per cent over the same period.[2]


Since the cost of energy has become a significant factor in the performance of economy of societies, management of energy resources has become very crucial. Energy management involves utilizing the available energy resources more effectively that is with minimum incremental costs. Many times it is possible to save expenditure on energy without incorporating fresh technology by simple management techniques.[3] Most often energy management is the practice of using energy more efficiently by eliminating energy wastage or to balance justifiable energy demand with appropriate energy supply. The process couples energy awareness with energy conservation.



The United Nations developed the International Standard Industrial Classification, which is a list of economic and social classifications.[4] There is no distinct classification for an energy industry, because the classification system is based on activities, products, and expenditures according to purpose.[5]

Countries in North America use the North American Industry Classification System (NAICS). The NAICS sectors #21 and #22 (mining and utilities) might roughly define the energy industry in North America. This classification is used by the U.S. Securities and Exchange Commission.

Financial market

The Global Industry Classification Standard used by Morgan Stanley define the energy industry as comprising companies primarily working with oil, gas, coal and consumable fuels, excluding companies working with certain industrial gases.[6]

Add also to expand this section: Dow Jones Industrial Average[7]

Environmental impact

Government encouragement in the form of subsidies and tax incentives for energy-conservation efforts has increasingly fostered the view of conservation as a major function of the energy industry: saving an amount of energy provides economic benefits almost identical to generating that same amount of energy. This is compounded by the fact that the economics of delivering energy tend to be priced for capacity as opposed to average usage. One of the purposes of a smart grid infrastructure is to smooth out demand so that capacity and demand curves align more closely.

Some parts of the energy industry generate considerable pollution, including toxic and greenhouse gases from fuel combustion, nuclear waste from the generation of nuclear power, and oil spillages as a result of petroleum extraction. Government regulations to internalize these externalities form an increasing part of doing business, and the trading of carbon credits and pollution credits on the free market may also result in energy-saving and pollution-control measures becoming even more important to energy providers.

Consumption of energy resources, (e.g. turning on a light) requires resources and has an effect on the environment. Many electric power plants burn coal, oil or natural gas in order to generate electricity for energy needs. While burning these fossil fuels produces a readily available and instantaneous supply of electricity, it also generates air pollutants including carbon dioxide (CO2), sulfur dioxide and trioxide (SOx) and nitrogen oxides (NOx). Carbon dioxide is an important greenhouse gas which is thought to be responsible for some fraction of the rapid increase in global warming seen especially in the temperature records in the 20th century, as compared with tens of thousands of years worth of temperature records which can be read from ice cores taken in Arctic regions. Burning fossil fuels for electricity generation also releases trace metals such as beryllium, cadmium, chromium, copper, manganese, mercury, nickel, and silver into the environment, which also act as pollutants.

The large-scale use of renewable energy technologies would "greatly mitigate or eliminate a wide range of environmental and human health impacts of energy use".[8][9] Renewable energy technologies include biofuels, solar heating and cooling, hydroelectric power, solar power, and wind power. Energy conservation and the efficient use of energy would also help.

In addition, it is argued that there is also the potential to develop a more efficient energy sector. This can be done by:[10]

Best available technology (BAT) offers supply-side efficiency levels far higher than global averages. The relative benefits of gas compared to coal are influenced by the development of increasingly efficient energy production methods. According to an impact assessment carried out for the European Commission, the levels of energy efficiency of coal-fired plants built have now increased to 46-49% efficiency rates, as compared to coals plants built before the 1990s (32-40%).[11] However, at the same time gas is can reach 58-59% efficiency levels with the best available technology.[11] Meanwhile, combined heat and power can offer efficiency rates of 80-90%.[11]


Since now energy plays an essential role in industrial societies, the ownership and control of energy resources plays an increasing role in politics. At the national level, governments seek to influence the sharing (distribution) of energy resources among various sections of the society through pricing mechanisms; or even who owns resources within their borders. They may also seek to influence the use of energy by individuals and business in an attempt to tackle environmental issues.

The most recent international political controversy regarding energy resources is in the context of the Iraq wars. Some political analysts maintain that the hidden reason for both 1991 and 2003 wars can be traced to strategic control of international energy resources.[12] Others counter this analysis with the numbers related to its economics. According to the latter group of analysts, U.S. has spent about $336 billion in Iraq[13] as compared with a background current value of $25 billion per year budget for the entire U.S. oil import dependence[14]


Main article: Energy policy

Energy policy is the manner in which a given entity (often governmental) has decided to address issues of energy development including energy production, distribution and consumption. The attributes of energy policy may include legislation, international treaties, incentives to investment, guidelines for energy conservation, taxation and other public policy techniques.


Main article: Energy security

Energy security is the intersection of national security and the availability of natural resources for energy consumption. Access to cheap energy has become essential to the functioning of modern economies. However, the uneven distribution of energy supplies among countries has led to significant vulnerabilities. Threats to energy security include the political instability of several energy producing countries, the manipulation of energy supplies, the competition over energy sources, attacks on supply infrastructure, as well as accidents, natural disasters, the funding to foreign dictators, rising terrorism, and dominant countries reliance to the foreign oil supply.[15] The limited supplies, uneven distribution, and rising costs of fossil fuels, such as oil and gas, create a need to change to more sustainable energy sources in the foreseeable future. With as much dependence that the U.S. currently has for oil and with the peaking limits of oil production; economies and societies will begin to feel the decline in the resource that we have become dependent upon. Energy security has become one of the leading issues in the world today as oil and other resources have become as vital to the world's people. However with oil production rates decreasing and oil production peak nearing the world has come to protect what resources we have left in the world. With new advancements in renewable resources less pressure has been put on companies that produce the world's oil, these resources are, geothermal, solar power, wind power and hydro-electric. Although these are not all the current and possible future options for the world to turn to as the oil depletes the most important issue is protecting these vital resources from future threats. These new resources will become more useful as the price of exporting and importing oil will increase due to increase of demand.


Main article: Energy development

Producing energy to sustain human needs is an essential social activity, and a great deal of effort goes into the activity. While most of such effort is limited towards increasing the production of electricity and oil, newer ways of producing usable energy resources from the available energy resources are being explored. One such effort is to explore means of producing hydrogen fuel from water. Though hydrogen use is environmentally friendly, its production requires energy and existing technologies to make it, are not very efficient. Research is underway to explore enzymatic decomposition of biomass.[16]

Other forms of conventional energy resources are also being used in new ways. Coal gasification and liquefaction are recent technologies that are becoming attractive after the realization that oil reserves, at present consumption rates, may be rather short lived. See alternative fuels.


All societies require materials and food to be transported over distances, generally against some force of friction. Since application of force over distance requires the presence of a source of usable energy, such sources are of great worth in society.

While energy resources are an essential ingredient for all modes of transportation in society, the transportation of energy resources is becoming equally important. Energy resources are frequently located far from the place where they are consumed. Therefore their transportation is always in question. Some energy resources like liquid or gaseous fuels are transported using tankers or pipelines, while electricity transportation invariably requires a network of grid cables. The transportation of energy, whether by tanker, pipeline, or transmission line, poses challenges for scientists and engineers, policy makers, and economists to make it more risk-free and efficient.


Main article: Energy crisis
File:Oil Prices Since 1861.svg
Oil prices from 1861 to 2007

Economic and political instability can lead to an energy crisis. Notable oil crises are the 1973 oil crisis and the 1979 oil crisis. The advent of peak oil, the point in time when the maximum rate of global petroleum extraction is reached, will likely precipitate another energy crisis.

See also

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  1. ^ Allen, J (1998). "Emacs ushers in customer-, marketing-driven industry". Electrical world (Hightstown, NJ: McGraw-Hill) 212 (3): 41–43. ISSN 0013-4457. Retrieved 2010-10-13. The Energy Marketing and Customer Service (EMACS) conference/exhibition focuses exclusively on the selling of energy in competitive retail markets. 
  2. ^ Alloway, Tracy (26 November 2014). "Oil price fall starts to weigh on banks". Retrieved 27 November 2014. 
  3. ^ Energy Management :: MEPoL
  4. ^ United Nations economic and social classifications Accessed 6 April 2007.
  5. ^ United Nations Available Classifications Accessed 6 April 2007.
  6. ^ MSCI-Barra GICS Tables Accessed 6 April 2007.
  7. ^ Industry Classification Benchmark for Dow Jones Indexes (United States) and FTSE Indexes (United Kingdom) (pdf)
  8. ^ Jacobson, Mark Z. and Delucchi, Mark A. (2010). "Providing all Global Energy with Wind, Water, and Solar Power, Part I: Technologies, Energy Resources, Quantities and Areas of Infrastructure, and Materials" (PDF). Energy policy. 
  9. ^ UNDP | Environment & Energy
  10. ^ European Movement for Efficient Energy 2011. Energy efficient solutions for the conservation of energy. Retrieved: 11 October 2011 18:52
  11. ^ a b c European Commission 2011. Impact Assessment Accompanying the document Directive of the European Parliament and of the Council on energy efficiency and amending and subsequently repealing Directives 2004/8/EC and 2006/32/EC. p. 106 Retrieved 11 October 2011 19:01
  12. ^ Oil and Empire - the backstory to the invasion of Iraq
  13. ^ The War in Iraq Costs, A running total of the U.S. taxpayer cost to date of the Iraq War. The number is based on Congressional appropriations.
  14. ^ Gibson Consulting US OIL DEMAND, 2004.
  15. ^ "Power plays: Energy and Australia's security". Retrieved 2010-06-01. 
  16. ^ Energy Task Force Resources - Hydrogen and Fuel Cells

Further reading

  • Bradley, Robert (2004). Energy: The Master Resource. Kendall Hunt. p. 252. ISBN 978-0757511691. 
  • Fouquet, Roger, and Peter J.G. Pearson. "Seven Centuries of Energy Services: The Price and Use of Light in the United Kingdom (1300-2000)." Energy Journal 27.1 (2006).
  • Gales, Ben, et al. "North versus South: Energy transition and energy intensity in Europe over 200 years." European Review of Economic History 11.2 (2007): 219-253.
  • Nye, David E. Consuming power: A social history of American energies (MIT Press, 1999)
  • Pratt, Joseph A. Exxon: Transforming Energy, 1973-2005 (2013) 600pp
  • Smil, Vaclav (1994). Energy in World History. Westview Press. ISBN 0-8133-1902-1. 
  • Stern, David I. "The role of energy in economic growth." Annals of the New York Academy of Sciences 1219.1 (2011): 26-51. online
  • Warr, Benjamin, et al. "Energy use and economic development: A comparative analysis of useful work supply in Austria, Japan, the United Kingdom and the US during 100 years of economic growth." Ecological Economics 69.10 (2010): 1904-1917. online
  • Yergin, Daniel (2011). The Quest: Energy, Security, and the Remaking of the Modern World. Penguin. p. 816. ISBN 978-1594202834. 

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