The cost of fuel has gone up again that people are thinking of alternative ways to save up on other things just so they can still continue to make use of their vehicles. Actually, there is a better way by which we can save up on fuel without having to let go of other necessities or luxuries that we have in our life. Sometimes we need all this to keep us going. When you take away one or two, you may take away your only source of happiness. So think twice before cutting off hobbies or things that you are already accustomed to.

One thing by which we can save gas is if we make it ourselves. It is possible since homemade biodiesel kits are available for consumers to buy them. There are instructions online and there are even step-by-step videos on how to make biodiesel fuel. These are especially useful for people who prefer to see it than reading about it. The great thing about seeing how it is made is you can actually see the equipments that are being used. So you can always pattern your equipment with what is being shown.

Since you will be doing it yourself, there are a couple of things you have to watch out for. You have to watch out for methanol and lye because it is dangerous. Aside from that, since you will be making use of heat and vegetable oils, fire is always a possibility. First time makers of biodiesel fuel should be extra careful when proceeding and like any other endeavor it takes practice to perfect it.

Throughout the history of our planet it has endured a constantly changing climate. It endured an ice age and has also experienced long periods of heat. But over the last two hundred years, give or take, the temperature of our planet has been steadily increasing. This change in the climate on earth is known as global warming, and global warming is the direct result of the industrial revolution.

Because of the industrial revolution, people are constantly burning fossil fuels such as oil and coal. But by burning these fuels dangerous greenhouse gases like carbon dioxide (CO2) are then released into the earth’s atmosphere. These gases block heat rising from the earth from being able to escape into space. The same basic function that glass panels on greenhouses have, hence the name. Our burning of fossil fuels causes more than three quarters of all carbon dioxide emissions. Power plants and other stationary sources contribute more than half of that amount.

Along with increasing CO2 emissions, deforestation is on the increase as well. This is disastrous, because trees recycle CO2 and release oxygen back into the atmosphere. Because of the rise in deforestation levels the fossil fuels we burn are seriously jeopardizing our planet. We know that global warming is the cause of glaciers getting smaller and for the rise in sea levels. Plants and animals show clear and undeniable signs that they are affected in many different ways. Earth is experiencing longer seasons which results in rivers and lakes freezing later than usual and melting sooner. Without a doubt, global warming causes many changes and affects our planet in many ways but can it also cause a tsunami?

Nobody will ever forget the utter destruction, grief and loss left behind after the huge tsunami that hit parts of Asia on December 26th, 2004. Hundreds of thousands of people were killed, injured and traumatized. The areas it hit were left completely destroyed.

Generally speaking a tsunami is made up of a series of waves. More often than not the first one is the mildest. Prior to the arrival of the first wave, the shoreline recedes dramatically and often leaves the ocean floor exposed. They mostly occur where the water is shallow but they can also occur around coastal areas. In deep water a tsunami appears as a big wave and nothing more. In shallow water this is not the case. The wave can reach as high as one hundred metres, although, in all honesty, this is not at all common.

We know that tsunami’s can be caused by an earthquake, but this is not the only cause. They can also be caused through volcanic eruptions and landslides. Another cause is if a large amount of water is somehow displaced, such as when meteors happen to fall into large bodies of water. Tsunami’s are caused by events that can be, and are, affected by global warming, however global warming itself does not directly trigger the formation of a tsunami. Basically, it is an indirect cause.

One thing is certain, global warming is not a myth as some suggest. The planet is displaying clear signs that we dare not ignore.

You cannot control that which you do not measure.

In more and more industries, the exact knowledge of particle contamination is gaining in importance. Contamination of materials in dimensions of a few micrometers was mainly of concern for the pharmaceutical and semiconductor industries. However, not only manufacturers of circuit board components, but also traditional car parts suppliers face new demands on particle recognition and contamination source identification.

Cleanliness for the automotive parts manufacturers has become a huge topic in today’s ever challenging continuous improvement world. The need to define, measure and control the levels of particulate contamination on product is the new norm for suppliers and automotive OEM’s.

Cleanliness directly relates to product warranties, reliability, performance and safety issues. It has long been known that a dirty product gives us poor quality and low life expectancy. The dirtier the transmission from new, the less time it will last.

It is crucial now to identify particles and their source so that effective elimination can be achieved. Residual contamination consists of particles that persist on the component’s surface after the final step in manufacturing. Such contaminants are introduced via parts from suppliers or arise during processing. After vehicle assembly, the contaminant particles can cause severe damage, loss of function or reduce the lifetime of the product.

Cleanliness is defined as the contamination level of a component surface. Common measures to quantify the cleanliness are mass of the contaminants as well as number, size of the dirt particles. In general, the customer will specify contamination limits. The supplier then has to maintain these levels and document them regularly by means of contamination analysis.

The analysis of the contamination has to be proven to not affect the result and to be effective in evaluating all the contamination present. Methods of extraction and evaluation are specified in the international standard ISO 16232. Particular attention must be paid to the extraction method to ensure no contributing factors are introduced to the evaluation. There are different methods of counting the resulting extracted particles but by far the most accurate, repeatable and cost effective is automated microscope analysis. The microscope with software can scan the filter membrane; sort the particles by size class and even determine basic material composition (metal, non-metal, fiber). Once the data is gathered a custom report can be generated based on the customer requirements.

For more information on cleanliness analysis, visit http://www.onclean.com

Plasma Gasification Plant (PGP) projects are being developed by at least five gas plasma technology companies, and there are real benefits to be obtained from this technology for the destruction of Municipal Solid Waste (MSW).

There is some debate still whether the process has been demonstrated to be a vaible technology which can be reliably operated by our waste management companies at reasonable cost and in compliance with all emissions regulations. However, the consensus seems to be largely in acceptance now that the technology is largely proven and inherently cleaner than incineration.

Although, gasification is used as a power generating technology, and gas plasma plants do provide a power feed-in to the local power grid, it should be realised by all that the purpose of selecting plasma gasification is currently that of achieving maximum waste mass destruction. The intent of the PGP is primarily to provide an efficent and clean method of dispoing of large quantities of residual MSW. Plasma gasification, although it does produce energy from waste is not primarliy an Energy from Waste (EfW) or Waste to Energy technology. There are other better proven, more efficient, and potentially always also cheaper ways to produce Energy from Waste, such as incineration.

PGPs suffer a high sacrificial load from the use of power at the electrodes to generate the plasma, and energy is also expended before the MSW reaches the plasma zone in the gasifier in chopping up and ensuring that the particle size of the waste is quite small. For this reason they do expend a large proportion of the power generated just in maintaining their own internal power demand.

However, as a waste destruction method producing an inert residue without creating at the same time high levels of toxic gaseous emissions the gas plasma process excels according to reports made to date. It has every reason to be cleaner as well because the reactions which take place in the plasma state take place so quickly and completely that the toxic organic chemicals produced in other combustion processes simply don’t get a change to be produced.

For a waste management process PGP therefore holds a very good prospect of adoption, as it is a process which is very efficient at diverting waste away from landfill, and thus scores highly among local authority waste disposal engineers who are constantly seeking to comply with regulations to reduce the amount of organic waste sent to landfill.

The PGP process however, also holds another merit and that is that it is being viewed more favourably by the public than incineration, and one main reason for that would be its clean emissions record when compared with incinerators historically.

Throughout Europe the requirement for BMW to be reduced by ever larger percentages necessitates the use of new technology to achieve this high rate of waste diversion, even after high recycling has also been achieved.

Look out for a plasma gasification plant appearing in a district near you soon, and look favourably upon it!

It is no new scientific fact that there is a slow steady increase of temperature; we’ve been studying and recording changes for a few decades. For some reason people are only now starting to take notice of how desperate the situation is.

Due to the increased temperature, sea levels are on the rise. It now is easier for boats full of scientists to access the Northwest Passage for research due to the polar icecaps melting . Areas that were once almost unreachable are now becoming navigational and the search for precious gems, gold, and oil is on! There is no end to mans greed.It makes sense that when the sea levels rise the ground surfaces slowly disappear. We will lose our agriculture farmlands. There may not be enough food needed to sustain ourselves, let alone other countries that we already support. Many farmers will lose their farms and their lifestyle.

Should sea levels on the rise be a worry about freshwater? Our drinking water is not a luxury it is a necessity and is as important for people, plants, and animals. The possible damage to freshwater due to rising sea levels should be a major worry to all of us.

For hundreds of years polar bears have been the king of the Arctic ice and roamed over vast areas of icy tundra. But with the icecaps melting away, and the distance between ice flows becoming greater, many polar bears have drowned from exhaustion before reaching shore. It also makes hunting their primary source of food, the seal, more difficult. Dying of hunger is now a probable fate for many of them.

The total extinction of many of the world’s beloved land animals may be just around the bend due to rising sea levels.

The international passion to protect our planet from the ravages of pollution and to preserve our natural resources for future generations has become an everyday fact of life. With international support by “green” political parties, consumer organizations, celebrities and politicians, the green movement has become a powerful force with an agenda that needs to be addressed by industry, politicians and consumers. Discussions about the environment are taking place in corporate board rooms, legislative hearings, and by consumers in supermarkets and department stores.

Can we fully understand environmental concerns and energy implications without a working knowledge of basic green vocabulary? Do we understand all the issues relevant to tax incentives for oil companies? Can we properly compare the organic and nonorganic products that we decide to eat or wear every day? In essence, to think and live green you need to speak and understand green.

Understanding some key green terms and their implications can help us evaluate alternatives between our planet and sacrificing aspects our personal lifestyle. It can help us decide how we cast our vote or spend our money or how we live our lives. A green vocabulary can help us reduce our “carbon footprint “. The following represents what is best described as a green vocabulary of definitions and commentary to help eco-oriented consumers make informed green decisions.

A Green Vocabulary for Green People

Organic identifies products made under the authority of the Organic Foods Production Act. Organic production guidelines are established to use organic materials and practices that improve ecological balance. Organic production incorporates agricultural system components to enhance natural biological systems.

Organic Agriculture is an ecological farming system that promotes natural chemical and biological cycles that improve soil fertility and maintains a balanced and productive farming system. Any products introduced to this system for fertility or pest protection are of natural composition. It eliminates the use of harmful synthetic pesticides, herbicides, fertilizers, growth stimulants or antibiotics. These essential restrictions can reduce contamination or pollution to our air, water or food supply.

Natural Fibersare “certified” organic fibers derived from organic agriculture such as cotton, bamboo and hemp.

Certified Organic Cotton is derived from organic agriculture. The cotton is grown without artificial pesticides or fertilizers. Conventional cotton farming ranks about fourth in the use of pesticides in the US. Several of the top pesticides used in nonorganic cotton farming are EPA recognized carcinogens. It takes 1/3 of a pound of pesticides and synthetic fertilizers to make one organic T-shirt disregarding the use of any toxic dyes (Organic Trade Association). A typical organic tee shirt is also about the same weight but without these harmful chemicals. Organic cotton is produced using conservation minded or “sustainable” approaches to crop production. Such practices help to retain and promote soil fertility and the natural recycling of soil resources.

Organic Certification is provided by various organizations. The most widely recognized standards are GOTS (Global Organic Textile Standard) which is the basis for the statement “100% certified organic cotton” used by many green companies.

Fair Labor Practices are not necessarily restricted to agriculture but generally support fair wages and healthy working conditions.

Fair Trade Certification “…guarantees consumers that strict economic, social and environmental criteria were met in the production and trade of an agricultural product.”(www.transfairusa.org).

Sweatshop-free describes the absence of manufacturing conditions currently existing in many countries, referred to as “sweatshops”. They are production facilities or factories where goods are produced cheaply by minimizing workers’ salaries, and increasing working hours. Proper environmental health standards are diminished, yet demands for high levels of productivity still remain. These sweatshops may thrive from corporations seeking to increase profits by subcontracting inexpensive labor.

Sustainable means conserving and preserving limited natural resources and energy supplies. It is connected with the term “recycling” when natural products are re-used like rubber (for tires, shoes) or paper/trees (for books, business cards, magazines etc.), or wood (for recycled furniture). They are made from or made into recycled, carbon based products. A good example of preserving our resources is Trees for the Future, a charitable organization dedicated to replacing and planting trees. Unfortunately, most of our energy production is derived from organic (carbon based) fossil fuels that cannot be recycled as compared to wind or solar energy. All of this is connected to our lifestyle and our “carbon footprint” discussed next.

Carbon Footprint is a descriptor of environmental impact. It describes the consumption of carbon based natural resources or the production of carbon by-products like carbon dioxide, carbon monoxide or “greenhouse emissions”. It’s about lifestyle and the amount of carbon based resources we consume through transportation, climate control, manufacturing etc. Basically it relates to how much each of us consume in terms of natural resources to meet our needs. In general each of us should be committed to reducing the size of our “footprint” to sustain resources for present and future generations.

Eco-fashion is a general term describing organic clothing that has addressed the needs of the environment as well as socially responsible working conditions.

Eco-friendly suggests a product or process than has a reduced impact on the environment.

Low Impact Dyes refers to dyes used the manufacture of goods that should have minimal impact on the environment. Sometimes the term non-toxic is used here as well.

Green is a generally positive term referring to the environment, organics or even a green lifestyle to be discussed shortly.

Conscientious Clothingdescribes organic clothing has addressed environmental, ethical and socially responsible standards.

The Green Lifestyle

Green Lifestyle or Green Living describes a lifestyle reflecting a strong commitment to the environment. In addition, it addresses compassionate and positive thinking. It means choosing a life with charitable deeds and practices, reflecting compassion for the environment and others. Green living is being proactive and incorporates spiritual growth leading to ethical thinking.

Social Responsibility can be defined as accepting responsibility for others and taking action against social injustice. It includes meeting the needs of others through charitable giving.

Charitable Giving describes a sense of genuine compassion and reacting to it with charitable practices towards others.

In summary, a green lifestyle represents caring for the environment combined with positive thinking leading to ethical behavior and compassionate living. Ultimately, your deeds represent positive thoughts in action. The result can be a clean, safe environment and a better quality of life for yourself and others.

If you learned some green vocabulary, be sure to use it to make decisions and set priorities in your life. Think about adopting a greener lifestyle!

Lots of people talk about trying to live a greener life, with some even going so far as to completely change their lifestyle, but most people aren’t sure how to go green because they don’t know exactly what that means. Sure, most people know the basics that scratch the surface such as reusing, recycling and reducing the amount of waste output for their homes but there many other steps you can take to move towards a cleaner, greener environment.

If you’re wondering how you can make your life greener, here are five different tips that are simple and easy to implement and that don’t cost the you anything.  All it takes is a little dedication and after a few months, these five little things will become second-nature to you.

1. The next time you go shopping use cloth bags at the grocery store instead of paper or plastic.  These cloth bags can be purchased for as little as a few dollars each and they’re much stronger than paper or plastic bags and will last you through years of use. 

These bags help reduce waste since most people throw away the plastic and paper bags.  The hardest part of using cloth bags is remembering to take them to the store, but once you get in the habit of using them, it becomes unconscious habit.

2. Replace your standard light bulbs with compact fluorescent bulbs.  These bulbs use less energy and last for four to five years, almost 15 times longer than traditional bulbs.  While the cost of a compact fluorescent bulb is more than your standard bulb, they easily pay for themselves over time requiring less frequent replacement and reduced energy consumption.  In fact, studies show that a CF bulb can actually pay for itself within one to two months.  One CF bulb also saves about five pounds of greenhouse gas carbon dioxide a month.  Replacing every bulb in your home can have a huge impact on the environment and on your wallet.

3. Use public transportation.  By car pooling, taking the bus, or using the subway you can cut down on the amount of gas you use and the amount of exhaust your car emits.  While it may be an inconvenience in some ways, it is one of the best ways of helping the environment.  Even better, walk or ride your bike to work if possible.  This not only saves you money and helps the environment but it also keeps you fit and healthy!

4. Adjust your thermostat by a few degrees.  By turning your thermostat down by just two degrees in the winter, you can save over 50 pounds of greenhouse gas carbon dioxide per month while lowering your heating bill.  Turning it up a few degrees in the summer can likewise save you money and save the environment. 

5. Finally, only wash your clothes or run your dish washer when you have a full load.  It wastes water and electricity to wash and dry only a few pieces of clothing.  In fact, if you can, try to wash your clothes using the cold water cycle as it uses up to 50% less energy than a warm water one. 

Under the relevant European Directives, an Environmental Statement is the formal product of an Environmental Impact Assessment. Environmental Statements are often organised in a way that describes the environmental baseline, mitigation and effects for each type of environmental receptors: ecology, water resources, archaeological resources, human beings etcetera. Contaminated land is often managed in the same ways as the various environmental receptor groups, although it is principally a cause of impacts rather than a receptor. It also often refers to a pre-existing condition and its damaging effect is on a variety of different receptors such as human health, structures and buildings, surface water features, groundwater features and ecology. This often means that land contamination specialists struggle with integrating the issue in a logical manner in an Environmental Statement. Sticking to the structured approach of an environmental statement is essential to ensure a clear description of the existing environmental condition, the potential impacts and the actions taken to avoid, minimise, offset or manage the impacts. This article is based on UK practice and legislation, although fundamentally the issues should be similar within other contexts.

Contaminated land is in many countries considered on a source-pathway-receptor basis. This is important to understand the impact land development can have on the issue of contaminated land. Development can interfere with any of these three elements. It can introduce sensitive receptors by changing the use of land, for instance by building new residential units on a site that was previously used for heavy industry. New pathways linking pre-existing contamination with an existing receptor can be formed, for instance when piling through a non-permeable layer connecting a layer of contaminated soils with a deep aquifer. Finally by introducing pollutants on the site a development project can introduce a potential source of contamination.

The second element to consider is the structured approach of an environmental statement. Apart from the introductory and procedural elements described in the environmental statement, a good environmental statement comprised the following sections:

• environmental baseline conditions
• potential environmental impacts
• mitigating measures
• residual environmental impacts

There should be a logical relation between the different sections. Any receptor that is affected and described in the section about the potential impacts and effects should have been introduced in the section describing the baseline. Any material impact should be assigned a mitigation or management action etc. Implementing this structure allows a clear description and understanding of the environmental impacts and the way it will be managed.

Applying these principles to contaminated land will result in a baseline condition section that describes the current sensitive receptors that are present within the potential sphere of influence of the development, the sensitivity and importance of these receptors, the presence of any pre-existing contamination and the presence of actual and potential pathways. The next section, potential environmental impacts or effects, first considers the impacts that the development will have in terms of the introduction (or removal) of sensitive receptors and the creation of new pathways between existing and potential pollution sources and receptors. In addition this section will describe the potential environmental impacts that are associated with the introduction of new sources of contamination. In the third section, mitigating measures, a description of the actions to mitigate each of the impacts that may occur should be provided. Finally a statement of the residual impact of the development is provided in the last section: residual environmental impacts.