5 Ways The Oil Industry Helps To Keep The Environment Clean

When you think of oil companies, it’s likely you don’t also think of “environmentally-friendly”. We see news about spilled oil, burning tankers, and other issues, and assume that all oil companies are disregarding the health of our planet. This simply isn’t the case, and you’ll be happy to know that the oil industry is actually working to keep the environment clean.

Here are five ways the industry is helping out with Mother Earth.

1. Information

The first step to improving anything is realizing there’s a problem to begin with, then gathering necessary information on the problem. Every time a spill, accident, or fire occurs, the oil industry is gathering precious data to use to combat future problems.

When a spill occurs, it can be devastating for the local ecosystems. Flora and fauna alike are affected by the viscous liquid, often restricting their ability to move, breathe, or perform daily functions. The Deepwater Horizon Rig that caused a massive spill in the Gulf of Mexico in 2010 was much more than just an industrial and environmental disaster; it was a learning experience for the oil industry.

Scientists and researchers from all over the world descended on the Gulf after the spill, and though we’re still learning from it a decade later, the information that was collected has been incredibly beneficial to the industry and has helped pave the way for new containment processes.

2. Better Pipe Maintenance

Maintaining pipelines is a crucial component of keeping the environment clean. Pipes can rupture, leaking oil or natural gas into the environment or even causing explosions and fires under the right conditions. The oil and natural gas industries have focused heavily on creating better maintenance processes and safety standards for pipelines across the country in recent years.

Not only do faulty pipelines put the environment at risk, but they also put thousands of workers at risk as well. Keeping workers and the environment safe not only shows care for the Earth and the industry’s employees but also helps potentially save millions in cleanup dollars.

3. Decreasing Freshwater Usage

Certain processes, such as fracking or separating oil from sands, use millions of gallons of fresh water. This is incredibly damaging to the environment not only because there’s already a shortage of freshwater on a global scale, but also because the wastewater that’s produced is stored in man-made containment units that aren’t always good at containing it.

Fracking wastewater is laced with chemicals that are both harmful to the environment directly and can contaminate other freshwater sources. The oil industry is working hard to minimize the use of freshwater in fracking and separation processes, as well as reducing the amount of wastewater and improving containment.

There’s also some promise in the area of recycling the water itself for use in future processes. In the US, produced water from fracking is being used in certain applications and even some water treatment plants are focusing on better treatment processes to make the water drinkable.

4. Investing In Renewable Energy

Renewable energy is on the horizon, and with the continued focus on wind, solar, hydro, and even tidal energy, the oil industry is starting to take notice. These energy sources offer a promising future, but as of yet, they’re not able to meet the world’s energy demands in an affordable way.

Right now, gasoline, natural gas, and crude oil are much cheaper and more profitable to source, acquire, and sell to the public. Pipelines can transport natural gas thousands of miles away, serving isolated regions and maintaining a constant flow of raw resources throughout the country.

Not to mention, the Canadian economy is highly invested in oil and natural gas, being the 5th and 6th largest producer of each respectively. However, the oil industry isn’t ignoring renewables. With continued investments, we could see a partial or full transition to renewable energy within our lifetime.

5. Using Technology For Better Planning

As technology improves, so too do the processes by which pipelines are planned and built. With new software, engineers can better plan a pipe’s path through an ecosystem in order to minimize the environmental impact. Better diagnostic software can identify issues long before they become spills or ruptures, and even AI tech is playing a role in the oil industry.

Moving Forward

Believe it or not, the oil industry is committed to a safer and more sustainable world. By using technology and data, the industry is improving its processes and ensuring that renewable energy remains an option for the future of energy production.

How Can Launder Covers Help Water Environments

The conservation of water, its proper flow, and assured safety for home or industrial use can be achieved by reusing water through renewable energy. However, algae control is challenging even for modern wastewater treatment plants. One of the best ways of resolving this problem is by installing launder covers.

Aside from this concern, water ecosystems also face other issues, the most notable being water and wastewater treatment facilities. So how can launder covers be of any help in such a scenario?

The discussion that follows will serve as a useful reference point when choosing the right launder cover for your water and wastewater treatment facility. Let’s get up to speed on how launder covers can help water environments.

Prevent Algae Growth

Algae growth has a proven tendency of developing in water and wastewater treatment facilities. It causes changes in the hydraulic dynamics of clarifiers, which leads to obstruction of design features found in weir configurations. Once launder covers are installed, they provide an attractive and extremely low maintenance structure to help eliminate algae growth problems.

Also, larger algae can dislodge and move around in plants that utilize ultraviolet disinfection technology. If the floating algae ends up covering UV bulbs, this may cause bulb failure and render UV bulbs ineffective, which are unfortunately very expensive to replace.

That’s why the installation of reliable launder covers, like IEC Covers, is recommended to help prevent algae growth in water and wastewater treatment plants. This would save money on repairs and UV bulb replacement at the same time.

Control Gas And Odor Emissions

Launder covers are useful in providing a continuous protective environment above the effluent stream. They can contain odor and gas to prevent environmental pollution and protect the health of workers in the area.

A reliable and corrosion-free launder cover system prevents direct sunlight from reaching the elevated growth areas of the weir and clarifier launder. Since launder covers serve as odor control hoods, they trap noxious gases that are generated during wastewater treatment processes.

Provide Essential Value To Water Environments

Custom designed launder covers can be placed in rectangular and round tanks, providing essential value for different water and wastewater operations.

Here are the advantages of installing launder covers in water environments:

  • Continuous inhibition of algae growth
  • Lightweight and cost-effective solution for water problems
  • Operable access for safety inspections and preventive maintenance

Maintain Weir Structural Integrity And Function

Eliminating direct sunlight inhibits algae growth, which also enhances the flow consistency of weir and reduces the need for maintenance. Launder covers shield other openings where access is normally required, but for safety reasons they need to be covered when not being used.

You can request custom-designed launder covers according to your preferred requirements. Custom-designed launder covers can be used in both round and rectangular clarifiers, as well as channels, sludge thickeners, and other openings.

Acts As Debris Barrier

Plastic bags, leaves, dead tree branches, and other windblown debris often lands in water environments. Launder covers help prevent such waste materials from ending up in your water and wastewater plant.

Also, aside from preventing debris from entering the water stream, launder covers can also be helpful in containing localized odor emissions if present in the weir area (effluent trough). Choosing fiberglass launder covers helps seal water environments in order to control odor.

Protect Launder From Weather

Strong winds, storms, snow, or heavy rainfall may introduce debris to water environments. Installing launder covers helps protect them against debris and damage caused by natural disasters. Choosing high-quality launder covers will ensure that they can withstand harsh weather conditions while protecting water and wastewater treatment plants.

Here’s a quick guide for when you are choosing launder covers:

  • NSF/ANSI Certified: Choose launder covers that are NSF or ANSI 61 certified. Also, opt for launder covers made of AWWA F101 compliant materials. NSF/ANSI Standard 61 or NSF-61 refers to a national standard relating to water treatment, establishing strict requirements and controls for equipment coming in contact with potable water or other products supporting the potable water production.
  • Quality Make: Select launder covers with superior strength and corrosion resistance that use FRP components to ensure long and maintenance-free service life. Choose clarifier launder covers that utilize fiberglass and stainless steel hardware, specifically made for municipal or industrial wastewater treatment purposes. These launder covers are easy to use, ensuring smooth operation and meeting the required NPDES effluent levels of Total Suspended Solids or TSS.
  • ISO Certified: Choose an ISO 9001 certified launder cover for manufacturing facilities.

Conclusion

Launder covers provide great protection against debris, harsh weather conditions, and direct sunlight. They further help protect weir structures, prevent algae growth, and are handy in avoiding the potential damage that algae can do to UV bulbs in treatment facilities using UV disinfection technology. Choosing high-quality launder covers would mean having long-term peace of mind that your water quality is preserved and wastewater treatment operations can function smoothly.

How Can Oil-Free Air Compressors Benefit You and The Environment?

If you already have an air compressor, you will be aware of how they are an incredibly valuable tool for industries and DIY enthusiasts. Commonly used to power pneumatic tools but can be used for a variety of applications. Air compressors provide you with complete power over spraying, nailing, sanding and hammering at a fraction of the time it would take with manual tools.

You can also find these smaller sized air compressors everywhere that are very portable and best at doing small work. Bob Robinson of BestOfMachinery swears by these portable tools. “Small air compressors essentially push air from the tank in the unit, into the tools that you want to use for either DIY, hobbies or work purposes without the need to lug heavy stuff.”, he commented.

These machines can also be used for inflating tyres, auto repairs and even creating home-made snow machines. Sandblasters, impact wrenches, grease guns, die grinders and angle disc grindles can also be attached.

We all love our power tools and would be lost without them; however, we are becoming more aware regarding the issue of carbon emissions. Reducing our carbon footprint is one of the most important things companies and individuals can do in their lifetime. Small changes within your business and homes can be a great start to decrease our carbon emissions and help save the planet.

If you are looking to purchase your first air compressor or to update an existing model, Direct Air has created a guide on why an oil-free air compressor is a great choice, not just for the environment, but to help you save on energy bills. You can see their full range of oil-free air compressors at https://www.directair.co.uk/products/oil-free-air-compressors/.

Every air compressor requires lubrication in order to efficiently and safely draw in air to its cylinder, commonly using a piston movement. The traditional method to achieve this is using oil, while oil-based air compressors do have their benefits as they are more robust and can handle large-scale applications, they are higher in initial cost, harder to maintain and far heavier than their oil-free counterparts.

Oil-free air compressors gain lubrication through a non-stick coating, generally Teflon. As extra elements to hold oil are eradicated from these machines, they are far lighter and smaller than oil-based air compressors which make them ideal for applications that are not static. Due to less components, oil-free air compressors are often cheaper to purchase.

Oil-based air compressors must remain static and upright when in use, oil-free are far more versatile. As you do not need to consider the oil flow, they can be positioned wherever you see fit. They are also operatable at any temperature, oil can become viscous in cooler climates and can cause problems when attempted to start the motor, oil-free erases this issue.

With these benefits in mind, you can achieve even more with your oil-free air compressor by helping to reduce the use of fossil fuels maintain the planet’s natural resources. You can also make a direct impact on your running costs, saving you and your business money on your energy bills.

With an oil-free air compressor, all costs to collect and dispose of oil-laden condensate will be removed, not to mention the initial cost of the oil itself. These compressors are less wasteful as they do not require the replacement of the air/oil separator and filtration elements which are required to get rid of oil aerosols, these parts are notorious for wearing down quickly. You will not needlessly be sending these parts to landfill and be bearing the cost of new ones on a regular basis.

If you are worried about direct harmful emissions from your air compressor, oil-free air compressors produce the purest form of air which will reduce any negative impact into the atmosphere, great for the planet and for those working around it. You will also not have the trouble of potentially contaminated products from oil spillages during projects.

A big bonus of oil-free air compressors is that they are safer than their counterparts, as there is no oil, you eliminate the risk of compressed air pipeline fires. An incredibly important factor to consider for the safety of you, your staff and your premises.

Oil-free air compressors can dramatically reduce your energy bills compared to the oil-based counterpart as they require less energy to run which will cut down your environmental impact. Oil-free air compressors do not need increased forces of power when the unit has a drop in the filtration in the downstream pressure, unlike oil-based. Oil-free units can, on average, unload in 2 seconds of your command which only uses around 18% of its full load horsepower.

Of course, all machines come with their downsides and oil-free air compressors are no exception. Oil-free air compressors are known to generate more noise which can be an annoyance and hazard to those using it and those around them.

There is a solution, you can invest in a low-noise air compressor. These reduce noise levels to around 40dB. The lowest safe level is considered 60 dB and anything over 80dB can cause long-term problems with hearing.

With the addition of an acoustic cylinder to contain this noise, opting for a low-noise air compressor is an investment worth making. It is recommended when using any power tool that protective gear is worn to eliminate lasting damage and long-term effects, even with a low-noise machine.

If you were considering purchasing a new air compressor or have simply been doing research on them, you should now have a comprehensive understanding of the benefits an oil-free air compressor possesses.

Carbon Black: Promise and Potential

Carbon Black is a commercial form of solid carbon that is manufactured in highly controlled processes to produce specifically engineered aggregates of carbon particles that vary in particle size, aggregate size, shape, porosity and surface chemistry. Carbon Black typically contains more than 95 % pure carbon with minimal quantities of oxygen, hydrogen and nitrogen.

In the manufacturing process, Carbon Black particles range from 10 nm to approximately 500 nm in size. These fuse into chain-like aggregates, which define the structure of individual Carbon Black grades.

What is Carbon Black

Carbon Black is used in a diverse group of materials in order to enhance their physical, electrical and optical properties. Its largest volume use is as a reinforcement and performance additive in rubber products.

In rubber compounding, natural and synthetic elastomers are blended with Carbon Black, elemental sulphur, processing oils and various organic processing chemicals, and then heated to produce a wide range of vulcanized rubber products. In these applications, Carbon Black provides reinforcement and improves resilience, tear-strength, conductivity and other physical properties.

Carbon Black is the most widely used and cost effective rubber reinforcing agent (typically called Rubber Carbon Black) in tire components (such as treads, sidewalls and inner liners), in mechanical rubber goods (“MRG”), including industrial rubber goods, membrane roofing, automotive rubber parts (such as sealing systems, hoses and anti-vibration parts) and in general rubber goods (such as hoses, belts, gaskets and seals).

Applications of Carbon Black

Besides rubber reinforcement, Carbon Black is used as black pigment and as an additive to enhance material performance, including conductivity, viscosity, static charge control and UV protection. This type of Carbon Black (typically called Specialty Carbon Black) is used in a variety of applications in the coatings, polymers and printing industries, as well as in various other special applications.

Actually, after oil removal and ash removal processing from tire pyrolysis, we can get high-purity commercial carbon black, which can be used to make color master batch, color paste, oil ink and as addictive in plastic and rubber products. Besides, after activation treatment, the carbon black will become good materials to produce activated carbon.

In the coatings industry, treated fine particle Carbon Black is the key to deep jet black paints. The automotive industry requires the highest black intensity of black pigments and a bluish undertones.

Carbon Black has got a wide array of applications in different industries

Small particle size Carbon Blacks fulfill these requirements. Coarser Carbon Blacks, which offer a more brownish undertone, are commonly used for tinting and are indispensable for obtaining a desired grey shade or color hue.

In the polymer industry, fine particle Carbon Black is used to obtain a deep jet black color. A major attribute of Carbon Black is its ability to absorb detrimental UV light and convert it into heat, thereby making polymers, such as polypropylene and polyethylene, more resistant to degradation by UV radiation from sunlight. Specialty Carbon Black is also used in polymer insulation for wires and cables. Specialty Carbon Black also improves the insulation properties of polystyrene, which is widely used in construction.

In the printing industry, Carbon Black is not only used as pigment but also to achieve the required viscosity for optimum print quality. Post-treating Carbon Black permits effective use of binding agents in ink for optimum system properties. New Specialty Carbon Blacks are being developed on an ongoing basis and contribute to the pace of innovation in non-impact printing.

Waste Management in Food Processing Industry

Food processing industry around the world is making serious efforts to minimize by-products, compost organic waste, recycle processing and packaging materials, and save energy and water. The three R’s of waste management – Reduce, Reuse and Recycle – can help food manufacturers in reducing the amount of waste sent to landfill and reusing waste.

EPA’s Food Recovery Hierarchy

EPA’s Food Recovery Hierarchy is an excellent resource to follow for food processors and beverage producers as it provides the guidance to start a program that will provide the most benefits for the environment, society and the food manufacturer.

Notably, landfill is the least favored disposal option for waste generated in food and beverage producers worldwide. There are sustainable, effective and profitable waste management options including:

  • making animal feed,
  • composting to create nutrient-rich fertilizer,
  • anaerobic digestion to produce energy-rich biogas,
  • recycling/reusing waste for utilization by other industries,
  • feeding surplus food to needy people

Waste Management Options

Food manufacturers has a unique problem – excess product usually has a relatively short shelf life while most of the waste is organic in nature. Food waste created during the production process can be turned into animal feed and sold to goat farms, chicken farms etc. As far as WWTP sludge is concerned, top food manufacturers are recycling/reusing it through land application, anaerobic digestion and composting alternatives.

Organic waste at any food processing plant can be composted in a modern in-vessel composting and the resultant fertilizer can be used for in-house landscaping or sold as organic fertilizer as attractive prices.

Another plausible way of managing organic waste at the food manufacturing plant is to biologically degrade it in an anaerobic digester leading to the formation of energy-rich biogas and digestate. Biogas can be used as a heating fuel in the plant itself or converted into electricity by using a CHP unit while digestate can be used as a soil conditioner. Biogas can also be converted into biomethane or bio-CNG for its use as vehicle fuel.

Items such as cardboard, clean plastic, metal and paper are all commodities that can be sold to recyclers Lots of cardboard boxes are used by food manufacturers for supplies which can be broken down into flat pieces and sold to recyclers.

Cardboard boxes can also be reused to temporarily store chip packages before putting them into retail distribution boxes. Packaging can be separated in-house and recovered using “jet shredder” waste technologies which separate film, carton and foodstuffs, all of which can then be recycled separately.

Organizing a Zero-Landfill Program

How do you develop a plan to create a zero-landfill or zero waste program in food and beverage producing company? The best way to begin is to start at a small-level and doing what you can. Perfect those programs and set goals each year to improve. Creation of a core team is an essential step in order to explore different ways to reduce waste, energy and utilities.

Measuring different waste streams and setting a benchmark is the initial step in the zero-landfill program. Once the data has been collected, we should break these numbers down into categories, according to the EPA’s Food Recovery Challenge and identify the potential opportunities.

For example, inorganic materials can be categorized based on their end lives (reuse, recycle or landfill).  The food and beverage industry should perform a waste sort exercise (or dumpster dive) to identify its key streams.

Nestlé USA – A Case Study

In April 2015, Nestlé USA announced all 23 of its facilities were landfill free. As part of its sustainability effort, Nestlé USA is continually looking for new ways to reuse, recycle and recover energy, such as composting, recycling, energy production and the provision of safe products for animal feed, when disposing of manufacturing by-products.

Employees also work to minimize by-products and engage in recycling programs and partnerships with credible waste vendors that dispose of manufacturing by-products in line with Nestlé’s environmental sustainability guidelines and standards. All Nestlé facilities employ ISO 14001-certified environmental management systems to minimize their environmental impact.

Waste Management in Olive Oil Industry

The olive oil industry offers valuable opportunities to farmers in terms of seasonal employment as well as significant employment to the off-farm milling and processing industry.  While this industry has significant economic benefits in regards to profit and jobs; the downside is it leads to severe environmental harm and degradation. In 2012, an estimated 2,903,676 tons of olive oil was produced worldwide, the largest olive oil producers being Spain, Italy, and Greece followed by Turkey and Tunisia and to a lesser extent Portugal, Morocco and Algeria. Within the European Union’s olive sector alone, there are roughly 2.5 million producers, who make up roughly one-third of all EU farmers.

olive-oil-wastes

Types of Wastes

Currently, there are two processes that are used for the extraction of olive oil, the three-phase and the two-phase. Both systems generate large amounts of byproducts.  The two byproducts  produced by the three-phase system are a solid residue known as olive press cake (OPC) and large amounts of aqueous liquid known as olive-mill wastewater (OMW).  The three-phase process usually yields 20% olive oil, 30% OPC waste, and 50% OMW.  This equates to 80% more waste being produced than actual product.

Regardless of system used, the effluents produced from olive oil production exhibit highly phytotoxic and antimicrobial properties, mainly due to phenols.  Phenols are a poisonous caustic crystalline compound.  These effluents unless disposed of properly can result in serious environmental damage.  There is no general policy for waste management in the olive oil producing nations around the world.  This results in inconsistent monitoring and non-uniform application of guidelines across these regions.

State of Affairs

Around 30 million m3 of olive mill wastewater is produced annually in the Mediterranean area.  This wastewater cannot be sent to ordinary wastewater treatment systems, thus, safe disposal of this waste is of serious environmental concern.  Moreover, due to its complex compounds, olive processing waste (OPW) is not easily biodegradable and needs to be detoxified before it can properly be used in agricultural and other industrial processes.

This poses a serious problem when the sophisticated treatment and detoxification solutions needed are too expensive for developing countries in North Africa, such as Morocco, Algeria and Tunisia, where it is common for OMW to be dumped into rivers and lakes or used for farming irrigation.  This results in the contamination of ground water and eutrophication of lakes, rivers and canals.  Eutrophication results in reductions in aquatic plants, fish and other animal populations as it promotes excessive growth of algae. As the algae die and decompose, high levels of organic matter and the decomposing organisms deplete the water of oxygen, causing aquatic populations to plummet.

Another common tactic for disposal of olive mill wastewater is to collect and retain it in large evaporation basins or ponds.  It is then dried to a semi-solid fraction. In less developed countries where olive processing wastes is disposed of, this waste, as well as olive processing cake and SOR waste is commonly unloaded and spread across the surrounding lands where it sits building up throughout the olive oil production season.  Over time these toxic compounds accumulate in the soil, saturating it, and are often transported by rain water to other nearby areas, causing serious hazardous runoff. Because these effluents are generally untreated it leads to land degradation, soil contamination as well as contamination of groundwater and of the water table itself.

Even a small quantity of olive wastewater in contact with groundwater has the potential to cause significant pollution to drinking water sources. The problem is more serious where chlorine is used to disinfect drinking water. Chlorine in contact with phenol reacts to form chlorophenol which is even more dangerous to human health than phenol alone.

Remedial Measures

The problems associated with olive processing wastes have been extensively studied for the past 50 years.  Unfortunately, research has continued to fall short on discovering a technologically feasible, economically viable, and socially acceptable solution to OPW.  The most common solutions to date have been strategies of detoxification, production system modification, and recycling and recovery of valuable components.  Because the latter results in reductions in the pollution and transformation of OPW into valuable products, it has gained popularity over the past decade. Weed control is a common example of reusing OPW; due to its plant inhibiting characteristics OPW once properly treated can be used as an alternative to chemical weed control.

Research has also been done on using the semisolid waste generated from olive oil production to absorb oil from hazardous oil spills.  Finally, in terms of health, studies are suggesting that due to OPW containing high amounts of phenolic compounds, which have high in antioxidant rates, OPW may be an affordable source of natural antioxidants. Still, none of these techniques on an individual basis solve the problem of disposal of OMW to a complete and exhaustive extent.

At the present state of olive mill wastewater treatment technology, industry has shown little interest in supporting any traditional process (physical, chemical, thermal or biological) on a wide scale.This is because of the high investment and operational costs, the short duration of the production period (3-5 months) and the small size of the olive mills.

Conclusion

Overall, the problems associated with olive processing wastes are further exemplified by lack of common policy among the olive oil producing regions, funding and infrastructure for proper treatment and disposal, and a general lack of education on the environmental and health effects caused by olive processing wastes.

While some progress has been made with regards to methods of treatment and detoxification of OPW there is still significant scope for further research.  Given the severity of environmental impact of olive processing wastes, it is imperative on policy-makers and industry leaders to undertake more concrete initiatives to develop a sustainable framework to tackle the problem of olive oil waste disposal.

Why Should Your Company Commit to Renewable Power?

Roughly one-third of U.S. greenhouse gas emissions come from burning fossil fuels to create electricity, according to Climate Collaborative. Using non-renewable gas, oil and coal adds to a rapidly growing carbon footprint, increases global warming and spells disaster for our fragile planet’s future. Companies and large corporations have the ability to change this, however, by committing to transition to renewable energy in the coming months and years. Not only will this benefit our planet, but it also promises success for companies who choose to commit to it.

Reduce energy costs by producing your own energy

Utility bills are a huge expense for businesses, many of which are at the mercy of utility companies that could raise their rates at any moment. Renewable energy is an attractive alternative to electricity and the bills that come with it. Wind installations are one option, but solar panels are even better as they are more predictable, efficient and affordable.

In fact, the cost of renewable energy is dropping at an incredibly rapid rate. The total cost of developing wind power has dropped 55% in the last five years while solar energy has dropped a shocking 74%. These low prices stem from massive global investment and rapid technological advancement. And major corporations that are already using clean energy are only looking to buy more in the coming months.

renewables-investment-trends

Boosting public relations

An increasing number of companies are committing to renewable power to boost public image. Smart businesses know that, in today’s world, renewable power is a source of competitive advantage. Social pressure to reduce emissions continues to rise as consumers look for ways to be involved in saving the planet. This green movement has driven a demand for green products. And companies that can sustainably create these products are winners in the public eye.

Renewable power is also reliable and predictable

Unlike coal or oil, we’ll never run out of wind or sun. This makes the cost and savings of wind and solar power quite stable. Solar panels installed on top of business structures will produce a consistent amount of energy year after year as long as they are properly maintained. This strong reliability makes budgeting easier and ensures a less volatile bottom line.

Reducing carbon emissions

Every one killowatt-hour of energy produced keeps 300 pounds of carbon out of the atmosphere. So, replacing non-renewable energy with renewable resources naturally decreases global warming emissions. And that’s good news for everyone on earth because if we’re left with more carbon than oxygen, it’s going to be a little difficult to breathe.

How Can You Commit to Renewable Power?

The first step in committing to renewable power is shifting your perspective. Take time to personally research these benefits of renewable power. Once you decide sustainable energy is worth implementing, on both an individual and global scale, you can begin to look for ways to create your own strategy.

The best way to brainstorm and execute strategy is to develop a team with specific goals in mind. This team should include members from different departments such as legal, financial, environmental, sustainability and operations. Once there is a team in place, you can begin to integrate energy into the company’s vision and operations.

The team should begin by assessing current energy impacts and how they might change them. Analyzing impact and comparing your own to competitors’ will reveal performance opportunities and gaps. The team can then develop a plan of action. Aggressive targets should reflect the degree and pace of emission reductions necessary to mitigate climate change.

Once goals are outlined, the team must create incentives for employees and consumers alike to make energy an actionable priority. From there, they can measure and manage energy usage as the company transitions from non-renewable to renewable energy sources.

Why Businesses Need to Reduce Their Carbon Output

According to a recent Nielsen study, 81 percent of consumers feel strongly that businesses should be taking measures to reduce their impact on the environment. This passion is shared across generations, and it’s safe to say that businesses that have little regard for their corporate social responsibility are significantly less desirable to consumers.

Despite this, a 2018 survey by Carbon Credentials found that only 10 percent of UK businesses had strategies in place to cut carbon emissions. Of those that did, none had a set science-based target in their carbon reduction plan. We know that climate change will devastate the economy and drastically increase the cost of doing business. That’s not even mentioning how it will impact resource scarcity and the global population as a whole. At the same time, businesses that take the initiative to reduce their carbon footprint can look forward to many more immediate benefits. Here’s why your business needs to reduce its carbon output and what you can do to champion climate action.

Cost Savings

Naturally, your expenses go down with your resource usage. From using more efficient equipment to streamlining your transportation operations to recycling office supplies, there are countless measures every business can take to make this happen. Within the first month, you’ll have more money to allocate towards growth – instead of utility bills.

Regulatory and Tax Compliance

Year-on-year, laws are passed to penalise businesses that don’t make an effort to reduce their impact on the environment and reward those that do. In the UK, this includes the Climate Change Levy, the EU Emissions Trading System and capital allowances on energy-efficient equipment, among other schemes.

Public Image

A 2015 Nielsen study of 30,000 consumers found that 66 percent of them would pay more for sustainably manufactured products. Among millennials, that portion increases to 77 percent. Gen Z is known to be even more conscious in this regard. The more your business cares, the more your customers will care about your business.

Employee Morale

In a similar light, going green fosters positive feelings from your employees as well. This has many benefits. For one, your staff will be more productive and motivated to achieve if they know they’re working for a good cause. Additionally, turnover will be reduced as employees will be less compelled to leave a work community that cares.

The Bigger Picture

This should go without saying, but reducing your company’s environmental impact has lasting benefits for your community and the economy as a whole. The likelihood of your long-term success and prosperity is far greater if the environment is in better shape.

What You Can Do

The list of measures your business can take to become more environmentally conscious is quite frankly endless. Get started by taking a look at this post on Utility Bidder, an energy supplier comparison website, about some simple ways that businesses can reduce their carbon output. The internet serves as a wealth of information on this topic.

Implementing greener practises is extremely beneficial to your business and more often than not, it is a dead-simple process. Getting started today will help you reap the benefits and reach your business goals sooner.

Global Waste to Energy Market

Waste-to-Energy is the use of modern combustion and biochemical technologies to recover energy, usually in the form of electricity and steam, from urban wastes. These new technologies can reduce the volume of the original waste by 90%, depending upon composition and use of outputs. The main categories of waste-to-energy technologies are physical technologies, which process waste to make it more useful as fuel; thermal technologies, which can yield heat, fuel oil, or syngas from both organic and inorganic wastes; and biological technologies, in which bacterial fermentation is used to digest organic wastes to yield fuel.

WTE_Market

The global market for waste-to-energy technologies was valued at US$6.2bn in 2012 which is  forecasted to increase to US$29.2bn by 2022. While the biological WTE segment is expected to grow more rapidly from US$1.4bn in 2008 to approximately US$2.5bn in 2014, the thermal WTE segment is estimated to constitute the vast bulk of the entire industry’s worth. This segment was valued at US$18.5bn in 2008 and is forecasted to expand to US$23.7bn in 2014.

The global market for waste to energy technologies has shown substantial growth over the last five years, increasing from $4.83 billion in 2006, to $7.08 billion in 2010 with continued market growth through the global economic downturn. Over the coming decade, growth trends are expected to continue, led by expansion in the US, European, Chinese, and Indian markets.

By 2021, based on continued growth in Asian markets combined with the maturation of European waste management regulations and European and US climate mitigation strategies, the annual global market for waste to energy technologies will exceed $27 billion, for all technologies combined.

Asia-Pacific’s waste-to-energy market will post substantial growth by 2015, as more countries view the technology as a sustainable alternative to landfills for disposing waste while generating clean energy. In its new report, Frost & Sullivan said the industry could grow at a compound annual rate of 6.7 percent for thermal waste-to-energy and 9.7 percent for biological waste-to-energy from 2008 to 2015.

The WTE market in Europe is forecasted to expand at an exponential rate and will continue to do so for at least the next 10 years. The continent’s WTE capacity is projected to increase by around 13 million tonnes, with almost 100 new WTE facilities to come online by 2012. In 2008, the WTE market in Europe consisted of approximately 250 players due in large to the use of bulky and expensive centralized WTE facilities, scattered throughout Western Europe.

4 Reasons Why Inflatable Packer is a Must Have

Non-stop operating challenges in the field of the gas, oilfield, and underground mining has led the inflatable technology to become a mainstream go-to solution for those in jobs of high-pressure drilling, borehole measurement, and tunneling. And it is none other than the inflatable packers that have been extensively catering to the niche since a decade now. The best thing about these tools is that they easily pass through restrictions and they are extremely sturdy to stand all the extremities and challenges of their projects.

With these tools rapidly gaining the ground in almost all parts of boring, sealing and mechanical jobs, it’s probably time to take a look at what makes these testing powerhouses really an unmatched solution in the field of special civil engineering and geotechnical studies. There are a plenty of informative and reliable sources, including http://www.aardvarkpackers.com/products-list/inflatable-packers/ and others that can tell you how these tools work and benefit their users.

What is an Inflatable Packer

As the name suggests, an inflatable packer is a plug equipment that can be extended and used in a wide array of decommissioning projects more specialized in terms of hole temperature and washouts etc. These plugs are both robust and versatile in nature and can be deployed where activities like hydraulic fracturing and high-pressure permeability require an in-depth planning and execution.

It’s the pipe that makes the main body of the packer and its the outside of the pipe that can inflate multiple times its original diameter to offer the space needed for all conventional jobs like coil tubing, pumping injections, tubes, and more.

Types of Inflatable Packers

When you have a clear idea about the job, it will be easy to choose your kind of pick from a wide selection of packers. They are many types, though…

  1. Fixed end packers
  2. Single or sliding end packers available in three styles, non reinforced, partially reinforced or fully reinforced
  3. Steel fortified
  4. Wire-line packers
  5. Custom packers (metal or other combinations)

Remember, every job needs an inflatable tool that can serve the bespoke purpose.

Uses of Inflatable Packers

As already mentioned earlier, inflatable packers are used in a wide range of energy-optimized fields, including groundwater projects, dewatering, high-pressure mining, contamination, block caving, core drilling, rock blasting and other kinds of stress testing

However, below mentioned is a list of broad range applications where these inflated tools are hugely deployed…

  1. Multi-depth ground consolidation
  2. Unconsolidated material consolidation
  3. Solid rock consolidation
  4. Improvement of mechanical properties
  5. Underground soil injections
  6. Lifting injections
  7. Sealing projects
  8. Injections in foundations

So, now that you know about most of the high-key projects where packers are used, there are certain unique features that make a packer ideal for a job.

  1. Extension capability of the packer’s hose,
  2. High-pressure rating
  3. The interior measurement of the pipe
  4. The exterior measurement of the pipe
  5. Longness of the sealing section that complies with the uneven borehole

The real advantage of having an inflated tool with an increased number of features is that it will make sure you can use it in multifaceted projects.

Advantages of inflatable packers

There are four main reasons that make these tools a must-have. They are as follows:

  1. Inflatable packers are reusable

Yes, most of their parts can be used for a great number of times. All the parts from a mandrel, inflation point, rubber element to connectors are exchangeable and their models are available in different lengths.

  1. Material parts are built sturdy

A non-welded packer is made robust and its patented and reinforcing ribs offer a tighter grip in the target areas to withstand challenges and vulnerabilities during and post inflation. What’s more, the packer ensures a uniform inflation between its metal ribs to offer maximum efficiency at disposal operations.

  1. Good use in inconsistent contact pressure

The packer’s metal ribs offer reinforcing anchoring in the end subs. This allows the inflatable tool to optimize its pressure differential holding capacity in varying depths.

  1. Flawless and safe sealing

While the ribs and the high-quality threads of an inflatable packer offer a greater surface preparation, eliminating any need for using crossover sub, welding or epoxy, the larger expansion range of a packer’s valve system provides an extra room for the fluid and the sealing functions, What’s more, all its material tubes and check valves can be cleaned easily when you separate them.

But the benefits of using these tools don’t end just here. There are a tall-list of other advantages too when you buy a packer of this type.

Final Thoughts

In a nutshell, inflatable packers prove extremely efficient where a perfect decommissioning job can add hundreds of thousands of dollars to the ever-flourishing energy industry. Their proven track records make them a must-have for projects like test injections, geological boring, water pressure control and special cases like plugging and abandoning wells just to name a few. The good news is, nowadays these tools are made available just a click away. Just go through the specifications carefully and pick the one that best suits your niche.