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.

Recycling of EPS Foam Packaging

Municipalities and organisations are facing a growing problem in disposal and recycling of EPS foam packaging and products. EPS foam (Encapsulated Poly-Styrene) packaging is a highly popular plastic packaging material which finds wide application in packaging of food items, electronic goods, electrical appliances, furniture etc due to its excellent insulating and protective properties. EPS foam (also known as polystyrene) is also used to make useful products such as disposable cups, trays, cutlery, cartons, cases etc. However, being large and bulky, polystyrene take up significant space in rubbish bins which means that bins becomes full more quickly and therefore needs to be emptied more often.

Polystyrene is lightweight compared to its volume so it occupies lots of precious landfill space and can be blown around and cause a nuisance in the surrounding areas. Although some companies have a recycling policy, most of the polystyrene still find its way into landfill sites around the world.

Environmental Hazards of EPS Foam

While it is estimated that EPS foam products accounts for less than 1% of the total weight of landfill materials, the fraction of landfill space it takes up is much higher considering that it is very lightweight.  Furthermore, it is essentially non-biodegradable, taking hundreds perhaps thousands of years to decompose.

Even when already disposed of in landfills, polystyrene can easily be carried by the wind and litter the streets or end up polluting water bodies. When EPS foam breaks apart, the small polystyrene components can be eaten by marine organisms which can cause choking or intestinal blockage.

Polystyrene can also be consumed by fishes once it breaks down in the ocean.  Marine animals higher up the food chain could eat the fishes that have consumed EPS, thus concentrating the contaminant.  It could be a potential health hazard for us humans who are on top of the food chain considering that styrene, the plastic monomer used in manufacturing EPS has been classified by the US National Institutes of Health (NIH) and the International Agency for Research on Cancer (IARC) as a possible human carcinogen.

Styrene is derived from either petroleum or natural gas, both of which are non-renewable and are rapidly being depleted, creating environmental sustainability problems for EPS.

Trends in EPS Foam Recycling

Although the Alliance of Foam Packaging Recyclers have reported that the recycling rate for post-consumer and post-commercial EPS in the United States have risen to 28% in 2010 from around 20% in 2008, this value is still lower than most solid wastes.  According to USEPA, auto batteries, steel cans and glass containers have recycle rates of 96.2%, 70.6% and 34.2% respectively.

Because it is bulky, EPS foam takes up storage space and costs more to transport and yet yields only a small amount of polystyrene for re-use or remolding (infact, polystyrene accounts for only 2% of the volume of uncompacted EPS foams). This provides little incentive for recyclers to consider EPS recycling.

Products that have been used to hold or store food should be thoroughly cleaned for hygienic reasons, thus compounding the costs.  For the same reasons, these products cannot be recycled to produce the same food containers but rather are used for non-food plastic products.  The manufacture of food containers, therefore, always requires new polystyrene.  At present, it is more economical to produce new EPS foam products than to recycle it, and manufacturers would rather have the higher quality of fresh polystyrene over the recycled one.

The cost of transporting bulky polystyrene waste discourages recyclers from recycling it.  Organizations that receive a large amount of EPS foam (especially in packaging) can invest in a compactor that will reduce the volume of the products. Recyclers will pay more for the compacted product so the investment can be recovered relatively easier.

There are also breakthroughs in studies concerning EPS recycling although most of these are still in the research or pilot stage.  Several studies have found that the bacteria Pseudomonas putida is able to convert polystyrene to a more biodegradable plastic.  The process of polystyrene depolymerization – converting polystyrene back to its styrene monomer – is also gaining ground.

How Are Agriculture and Industrial Sector Dealing with Environmental Protection Laws in New Zealand?

If you take a look at sector shortages in New Zealand, you’ll find that agriculture and farming is one of the sectors struggling the most. There are long term shortages in the industry, so what’s putting people off from investing in this type of career path?

Although agriculture has dwindled in popularity since technology took over, there are other factors contributing to its decline. In New Zealand, there are strong environmental protection laws in place which need to be followed.

Here, we’ll look at how the agriculture industry deals with environmental protection laws in New Zealand.

What do the environmental protection laws cover?

The environmental protection laws in New Zealand are some of the strictest in the world. The country has earned a reputation for its clean, beautiful landscapes. A lot of its tourism is driven by its cleanliness and thriving ecosystem. This means the government has needed to introduce strict environmental protection laws to ensure New Zealand retains its pristine reputation. These laws include:

  • Resource Management Act 1991
  • Conservation Act 1987
  • Environment Act 1986
  • Ozone Layer Protection Act 1996

These are just a small number of the regulations and laws pertaining to the environment. There’s also a large list of related laws in New Zealand, making it difficult for businesses to keep up. This is especially true for those working within agriculture and industrial sectors.

New Zealand’s rivers under serious threat

Although New Zealand has developed a reputation as one of the most environmentally friendly countries in the world, it’s rivers are currently under serious threat. The environment ministry claims that two-thirds of the country’s rivers are now deemed un-swimmable. Even more worrying is that three-quarters of all of the country’s freshwater native fish are under threat of extinction.

In a bid to tackle the problem, the government has announced a rather ambitious plan. They are aiming to see a noticeable improvement over five years. Freshwater protection plans are being drafted and are expected to be put into place by 2025. In the meantime, immediate interim controls have been introduced. Swimming pools will be subject to increased water quality standards. However, it’s the farming sector which is going to see the biggest changes in regulations.

How are the agricultural and industrial sector dealing with the laws?

The agricultural and industrial sectors are currently struggling with the change in legislation. Although the government has pledged $229 million NZD to help farmers transition to the new laws, there’s still a lot of challenges the sector needs to overcome.

Farmers need to stop risky farm practices, such as allowing cows to stray to nearby waterways. Cow manure is partially being blamed for the increase in river pollution. New irrigation practices will also be denied unless farmers can prove it won’t harm the environment. There’s a lot of new laws being introduced which are causing issues for farmers and the industrial sector. Those working within the sector would do well to seek advice from specialists such as RSM.

Overall, New Zealand is making its environmental protection laws stricter over the next five years. This is already having an impact on the agricultural sector. However, seeking professional advice can ensure those working within the sector understand and adhere to the new legislation.

Air Genius: An Indoor Air Quality Monitor With a Difference

Indoor Air Quality (IAQ) refers to the air quality within and around buildings and structures, especially as it relates to the health and comfort of building occupants. Understanding and controlling common pollutants indoors can help reduce your risk of indoor health concerns. Health effects from indoor air pollutants may be experienced soon after exposure or, possibly, years later.

Immediate Health Effects

Some health effects may show up shortly after a single exposure or repeated exposures to a pollutant. These include irritation of the eyes, nose, and throat, headaches, dizziness, and fatigue. Such immediate effects are usually short-term and treatable.

Sometimes the treatment is simply eliminating the person’s exposure to the source of the pollution, if it can be identified. Soon after exposure to some indoor air pollutants, symptoms of some diseases such as asthma may show up, be aggravated or worsened.

The likelihood of immediate reactions to indoor air pollutants depends on several factors including age and preexisting medical conditions. In some cases, whether a person reacts to a pollutant depends on individual sensitivity, which varies tremendously from person to person. Some people can become sensitized to biological or chemical pollutants after repeated or high level exposures.

In long-term effects, Other health effects may show up either years after exposure has occurred or only after long or repeated periods of exposure. These effects, which include some respiratory diseases, heart disease and cancer, can be severely debilitating or fatal. It is prudent to try to improve the indoor air quality in your home even if symptoms are not noticeable.

Factors Behind Poor IAQ

Gas and respirable particulates in the air are the primary sources that contribute to poor IAQ. Sources can include inadequate ventilation, poorly maintained HVAC systems, cooking stoves, non-vented gas heaters, tobacco smoke, vehicle exhaust emissions, building materials, carpeting, furniture, maintenance products, solvents, cleaning supplies etc.

The actual concentrations of these pollutants can also be amplified by other external factors including poor ventilation, humidity, and temperature.

Air Genius – Best Indoor Air Quality Monitor

Air Genius is a state-of-the-art indoor air quality monitor that you should have at your house or in your office to monitor the air that we breathe. The device, developed by India-based Next Sense Technologies, uses the latest sensors to determine particulate matter, VOCs, total volatile organic compounds (TVOCs), carbon dioxide, temperature, humidity and other important parameters.

We have taken a leap in technological advancement by relaying the data automatically to the server so that you can access the data remotely and in real-time. Through this, one could take initiatives on switching on the Air purifier or by keeping the window open for allowing the fresh air.

Typical Applications for Air Genius Indoor Air Quality Monitor

  • IAQ complaint investigation and analysis
  • HVAC system performance monitoring
  • Air quality engineering analysis
  • Mold investigation and remediation
  • Health and comfort assessment
  • Airport lounges, shopping malls, offices
  • Colleges, schools and kindergartens
  • Hospitals and healthcare establishments

For business enquiries about Air Genius Air Quality Monitor, please visit  http://www.nextsensetechnologies.com/ or contact Mr. Mohammad Hamza on +91-9540990415 or email on enggenvsolution@gmail.com or salman@bioenergyconsult.com

Different Types of Thermocouples

Thermocouples are sensors used to measure temperatures. These devices consist of different metals to form two wire legs forming a junction. Manufacturers weld together these two wire legs to make sure the connection is stable. Thermocouple junctions are used to check for changes in temperatures. There are different types of thermocouples available in the market, and these models have distinct characteristics and features.

The Types of Thermocouples

The manufacturing of a thermocouple requires producers to classify units with distinct color codes. Manufacturers classify these codes in either ANSI/ASTM E230 OR IEC60584. The thermocouples, their calibrations, and their color designations (in ANSI/ASTM E320) are:

  • Type K: Yellow (+) / Red (-)
  • Type T: Blue (+) / Red (-)
  • Type N: Orange (+) / Red (-)
  • Type S: Black (+) / Red (-)
  • Type C: N/A
  • Type J: White (+) / Red (-)
  • Type E: Purple (+) / Red (-)
  • Type R: Black (+) / Red (-)
  • Type B: Black (+) / Red (-)

Conversely, here are the thermocouples once more and their calibrations, but with their IEC 60584 color designations:

  • Type K: Green (+) / White (-)
  • Type T: Brown (+) / White (-)
  • Type N: Rose (+) / White (-)
  • Type S: Orange (+) / White (-)
  • Type C: N/A
  • Type J: Black (+) / White (-)
  • Type E: Purple (+) / White (-)
  • Type R: Orange (+) / White (-)
  • Type B: Orange (+) / White (-)

Thermocouple Temperature Range

Aside from the color codes, thermocouple types have specific melting points and continuous maximum temperatures. For example, the thermocouple Type B with a platinum 30% rhodium (+) composition may have a temperature range of 2,500 to 3,100 degrees Fahrenheit. Conversely, a platinum 6% rhodium (-) composition of the same thermocouple type may yield a similar temperature range.

Another example is a thermocouple type E with a chromel (+) composition. For this model, you may use it for handling temperature ranges of 200 to 1,650 degrees Fahrenheit. Still, consider the environment before using specific thermocouple types.

Uses of Thermocouples

Different thermocouple types may have diverse uses. Hospital thermometers, automotive technologies, and machines handling renewable energies might use thermocouples to help users detect changes in temperatures. Here are a few thermocouple types and their uses:

  • Type J

This thermocouple type may have an iron and Constantan leg. Various organizations in different industries find this model to be helpful in several operations. For example, it may be useful in reducing, oxidizing, and vacuuming atmospheres. Type J models may have durable constructions. Thus, these units may not require sensitive handling when installing them in other machines or industrial environments.

  • Type K

This thermocouple has a Chromel and Alumel composition for its wire legs. Consider using this type to oxidize or inert atmospheres with temperatures of up to 2,300 Fahrenheit. Companies may use this thermocouple model thanks to its relatively accurate and stable readings even at high temperatures.

  • Type N

Type N thermocouples may be akin to better Type K models. This type has a Nicrosil and Nisil composition for its wire legs. It also has a similar temperature range as the Type K. However, type N models might have better resistance than its type K counterparts thanks to its temperature cycling features. Furthermore, its hysteresis and green rot allow type N models to be more cost-effective units than type Ks.

  • Type T

A copper and Constantan composition reside in the wire legs of type T thermocouples. Like the type J models, type Ts help users reduce, oxidize, vacuum, and inert atmospheres. Still, this thermocouple class has excellent resistance against corrosion in several atmospheres. It may also offer high-stability readings at sub-zero temperatures.

  • Type E

For this thermocouple, it has one Chromel and one Constantan leg. Like the type T thermocouple, it may also be resistant to corrosion in various atmospheres. However, there’s one characteristic that may put type E thermocouples better than other models: Type Es may have the highest EMF per degree in comparison with different thermocouple types. Nonetheless, it might not be resistant to sulfurous environments.

  • Type C

Environments that have sweltering temperatures may use type C thermocouples. This model has a tungsten and rhenium composition for its wire legs. Organizations may use this thermocouple type in extremely high-temperature environments of up to 4,200 degrees Fahrenheit. While it can withstand high temperatures, this thermocouple may have a brittle construction. Proceed with caution when handling it as one false move might break the device.

Conclusion

Always consider the right thermocouple type when you want to read temperatures accurately in specific environments. For instance, consider the right thermocouple when reading temperature levels in automotive technologies and their hot engines. These devices may also activate gas shut-off modules aside from reading temperatures. Take time in researching the right model for the job to avoid complications.

Properties and Uses of POME

POMEPalm Oil processing gives rise to highly polluting waste-water, known as Palm Oil Mill Effluent (POME), which is often discarded in disposal ponds, resulting in the leaching of contaminants that pollute the groundwater and soil, and in the release of methane gas into the atmosphere. POME is an oily wastewater generated by palm oil processing mills and consists of various suspended components. This liquid waste combined with the wastes from steriliser condensate and cooling water is called palm oil mill effluent.

On average, for each ton of FFB (fresh fruit bunches) processed, a standard palm oil mill generate about 1 tonne of liquid waste with biochemical oxygen demand 27 kg, chemical oxygen demand 62 kg, suspended solids (SS) 35 kg and oil and grease 6 kg. POME has a very high BOD and COD, which is 100 times more than the municipal sewage.

POME is a non-toxic waste, as no chemical is added during the oil extraction process, but will pose environmental issues due to large oxygen depleting capability in aquatic system due to organic and nutrient contents. The high organic matter is due to the presence of different sugars such as arabinose, xylose, glucose, galactose and manose. The suspended solids in the POME are mainly oil-bearing cellulosic materials from the fruits. Since the POME is non-toxic as no chemical is added in the oil extraction process, it is a good source of nutrients for microorganisms.

Biogas Potential of POME

POME is always regarded as a highly polluting wastewater generated from palm oil mills. However, reutilization of POME to generate renewable energies in commercial scale has great potential. Anaerobic digestion is widely adopted in the industry as a primary treatment for POME. Biogas is produced in the process in the amount of 20 mper ton FFB. This effluent could be used for biogas production through anaerobic digestion. At many palm oil mills this process is already in place to meet water quality standards for industrial effluent. The gas, however, is flared off.

Palm oil mills, being one of the largest industries in Malaysia and Indonesia, effluents from these mills can be anaerobically converted into biogas which in turn can be used to generate power through CHP systems such as gas turbines or gas-fired engines. A cost effective way to recover biogas from POME is to replace the existing ponding/lagoon system with a closed digester system which can be achieved by installing floating plastic membranes on the open ponds.

As per conservative estimates, potential POME produced from all Palm Oil Mills in Indonesia and Malaysia is more than 50 million m3 each year which is equivalent to power generation capacity of more than 800 GW.

New Trends

Recovery of organic-based product is a new approach in managing POME which is aimed at getting by-products such as volatile fatty acid, biogas and poly-hydroxyalkanoates to promote sustainability of the palm oil industry.  It is envisaged that POME can be sustainably reused as a fermentation substrate in production of various metabolites through biotechnological advances. In addition, POME consists of high organic acids and is suitable to be used as a carbon source.

POME has emerged as an alternative option as a chemical remediation to grow microalgae for biomass production and simultaneously act as part of wastewater treatment process. POME contains hemicelluloses and lignocelluloses material (complex carbohydrate polymers) which result in high COD value (15,000–100,000 mg/L).

POME-Biogas

Utilizing POME as nutrients source to culture microalgae is not a new scenario, especially in Malaysia. Most palm oil millers favor the culture of microalgae as a tertiary treatment before POME is discharged due to practically low cost and high efficiency. Therefore, most of the nutrients such as nitrate and ortho-phosphate that are not removed during anaerobic digestion will be further treated in a microalgae pond. Consequently, the cultured microalgae will be used as a diet supplement for live feed culture.

In recent years, POME is also gaining prominence as a feedstock for biodiesel production, especially in the European Union. The use of POME as a feedstock in biodiesel plants requires that the plant has an esterification unit in the back-end to prepare the feedstock and to breakdown the FFA. In recent years, biomethane production from POME is also getting traction in Indonesia and Malaysia.

Progress of Waste-to-Energy in the USA

Rising rates of consumption necessitate an improved approach to resource management. Around the world, from Europe to Asia, governments have adapted their practices and policies to reflect renewability. They’ve invested in facilities that repurpose waste as source of energy, affording them a reliable and cheap source of energy.

This seems like progress, given the impracticality of older methods. Traditional sources of energy like fossil fuels are no longer a realistic option moving forward, not only for their finite nature but also within the context of the planet’s continued health. That said, the waste-to-energy sector is subject to scrutiny.

We’ll detail the reasons for this scrutiny, the waste-to-energy sector’s current status within the United States and speculations for the future. Through a concise analysis of obstacles and opportunities, we’ll provide a holistic perspective of the waste-to-energy progress, with a summation of its positive and negative attributes.

Status of Waste-to-Energy Sector

The U.S. currently employs 86 municipal waste-to-energy facilities across 25 states for the purpose of energy recovery. While several have expanded to manage additional waste, the last new facility opened in 1995. To understand this apparent lack of progress in the area of thermochemical treatment of MSW, budget represents a serious barrier.

One of the primary reasons behind the shortage of waste-to-energy facilities in the USA is their cost. The cost of construction on a new plant often exceeds $100 million, and larger plants require double or triple that figure to build. In addition to that, the economic benefits of the investment aren’t immediately noticeable.

The Palm Beach County Renewable Energy Facility is a RDF-based waste-to-energy (WTE) facility.

The U.S. also has a surplus of available land. Where smaller countries like Japan have limited space to work within, the U.S. can choose to pursue more financially viable options such as landfills. The expenses associated with a landfill are far less significant than those associated with a waste-to-energy facility.

Presently, the U.S. processes 14 percent of its trash in waste-to-energy (WTE) plants, which is still a substantial amount of refuse given today’s rate of consumption. On a larger scale, North America ranks third in the world in the waste-to-energy movement, behind the European nations and the Asia Pacific region.

Future of WTE Sector

Certain factors influence the framework of an energy policy. Government officials have to consider the projected increase in energy demand, concentrations of CO2 in the atmosphere, space-constrained or preferred land use, fuel availability and potential disruptions to the supply chain.

A waste-to-energy facility accounts for several of these factors, such as space constraints and fuel availability, but pollution remains an issue. Many argue that the incineration of trash isn’t an effective means of reducing waste or protecting the environment, and they have evidence to support this.

The waste-to-energy sector extends beyond MSW facilities, however. It also encompasses biofuel, which has seen an increase in popularity. The aviation industry has shown a growing dedication to biofuel, with United Airlines investing $30 million in the largest producer of aviation biofuel.

If the interest of United Airlines and other companies is any indication, the waste-to-energy sector will continue to expand. Though negative press and the high cost of waste-to-energy facilities may impede its progress, advances in technology promise to improve efficiency and reduce expenses.

Positives and Negatives

The waste-to-energy sector provides many benefits, allowing communities a method of repurposing their waste. It has negative aspects that are also important to note, like the potential for pollution. While the sector offers solutions, some of them come at a cost.

It’s true that resource management is essential, and adapting practices to meet high standards of renewability is critical to the planet’s health. However, it’s also necessary to recognize risk, and the waste-to-energy sector is not without its flaws. How those flaws will affect the sector moving forward is critical to consider.

The Technology Revolutionizing Commercial Waste Management

Every single one of us can do something to improve our impact on the planet, but it is a given that businesses of all sizes have a bigger footprint than families – commercial accounts for 12% of total greenhouse gas emissions. A big factor of that is waste management. From the physical process of picking up garbage, to the methane-released process of decomposition, there are numerous factors that add up to create a large carbon footprint.

Between hiring green focused waste management solutions and recycling in a diligent fashion, there are a few technologies that are helping to break down the barrier between commercial waste management and an environmentally positive working environment.

Cleaning up commercial kitchens

A key form of commercial waste is food waste. Between the home and restaurant, it is estimated by the US Department of Agriculture that 133 billion pounds of food is wasted every year. Much will end up in the landfill. How is technology helping to tackle this huge source of environmental waste? Restaurants themselves are benefiting from lower priced and higher quality commercial kitchen cooking equipment, that helps to raise standards and reduce wastage.

Culinary appliances for varied cuisines also benefit from a new process being developed at the Netherland’s Wageningen University. A major driver of food waste is rejected wholesale delivery, much of which will be disposed of in landfill. The technology being developed in Holland aims to reduce wastage by analyzing food at the source, closer to where recycling will be achievable.

Route optimization

Have you ever received a parcel from an online retailer only to find the box greatly outsizes the contents? On the face of it, this is damaging to the environment. However, many retailers use complex box sorting algorithms. The result is that the best route is chosen on balance, considering the gas needed to make the journey, the amount of stock that can be delivered and the shortest route for the driver. This is an area of intense technological innovation.

The National Waste & Recycling Association reported in 2017 on how 2018 would see further advances, particularly with the integration of artificial intelligence and augmented reality into the route-finding process.

Balancing the landfill carbon footprint

It is well established that landfills are now being used to power wind turbines, geothermal style electricity and so on. They are being improved to minimize the leachate into groundwater systems and to prevent methane escaping into the atmosphere. However, further investigation is being pushed into the possibility of using landfill as a carbon sequester.

AI-based waste management systems can help in route optimization and waste disposal

Penn State University, Lawrence Berkeley and Texas University recently joined together to secure a $2.5m grant into looking into the function of carbon, post-sequestration. This will help to shed light on the carbon footprint and create a solid foundation on which future technology can thrive.

Businesses of all sizes have an impact on the carbon footprint of the world. The various processes that go into making a business profitable and have a positive impact on their local and wider communities need to be addressed. As with many walks of life, technology is helping to bridge the gap.

How To Tackle Vibrations Using A Coriolis Mass Flow Meter

Coriolis mass flow meters are acknowledged or well-known as an extremely precise and accurate flow measuring device. Plus, it offers plenty of benefits than other instruments. But take note that every measuring principle has its obstacles, and it is also true for the Coriolis principle.

For the most part, it can be difficult and hard to use Coriolis devices in most low flow applications in industries manufacturing large and heavy products. In these applications, you might have to face all types of vibrations.

Thus, the question is, how can you deal with these vibrations using the coriolis mass flow meter. For a little help, we will walk you through how to deal with all types of vibrations. So, take a read!

Coriolis Principle

This flow measuring device provides multiple benefits and advantages compared to other measuring instruments. First and foremost, coriolis flow meters calculate or gauge direct mass flow.

For many industries, it is a critical feature because it removes or eradicates inaccuracies induced by the fluid’s physical properties or characteristics. Aside from this, coriolis flow meters are extremely precise and accurate, have no mechanical parts in motion, have immense repeatability, a towering dynamic range, and many more.

The coriolis principle is simple yet very effective. Its operating principle is all around us in this world, such as the rotation of the earth and its impact on the weather. Coriolis flow meters have a tube powered by a fixed vibration. So, when a liquid or gas traverses through this tunnel or duct, the mass flow momentum will, more often than not, create a change or alteration in the vibration of the tube.

Then, the duct will contort culminating a phase shift. This shift can be calculated or computed deriving a linear output corresponding to the flow. As the coriolis principle calculates mass flow regardless of what’s inside the tube, it can be, for the most part, promptly implemented to any fluid traversing through it, gas or liquid.

While the thermal mass flow instruments are reliant on the fluid’s physical properties, thus, similar to the phase shift in frequency between outlet and inlet, it’s possible to calculate the actual natural frequency change.

This frequency change is incongruity to the fluid’s density, and it can derive a further signal output. It’s possible to calculate the volume flow rate having computed both the density and the mass flow rate.

How it Works

Coriolis mass flow meters calculate or gauges the mass via inertia. A dense gas or liquid moves or traverse through a tunnel or duct which is pulsated by a small actuator. This vibration generates a measurable contorting force on the duct corresponding to the mass. More advanced models of this flow measuring technology apply dual-curved tunnels for lower pressure drop and higher sensitivity.

Although considered or known as the most precise flow meters, coriolis mass flow meters are prone to errors or inaccuracies when bubbles are existing in the liquid. These bubbles can produce or generate splashing inside the tube, make noise, and modify or alter the energy required for tube vibration. Huge spaces boost the energy required for tube vibration in excess and can end up in complete failure.

Impact of Vibrations on Accuracy of Coriolis Flow Meters

In manufacturing, factory, commercial, business, trade applications, all types of vibrations with various sizes are eminently common. Coriolis mass flow meters calculate a mass flow through a vibrating sensor duct, which variation gets purposely out of phase when the gas or liquid traverses through.

This technique or approach is relatively susceptible to unnecessary vibrations with a recurrence close to the sensor tube’s resonance frequency or a towering concordant of this frequency. However, it depends on the design of the sensor tube.

The odds of the frequency of these unnecessary vibrations is greater than in an industrial environment. Manufacturers of coriolis mass flow meters do their best to minimize the effect of vibrations on the measurement using some technical solutions including pigtails, active and passive vibration compensation, mass inertia, different sensor shapes, dual-sensor tubes, and higher driving frequencies.

In other words, vibrations can affect the accuracy of the measurements of coriolis mass flow meters. However, only if the frequency of the vibrations is close to the concordant frequency.

Types of Vibrations

In industrial applications, vibrations can be produced by usage-based vibration sources, building-based vibration sources, and environmentally related vibration sources. These vibrations move or traverse through a medium such as the fluid itself, through pipes, in the air, or the floor. If any of these vibrations disrupt the frequency of the device, then the output could be incorrect.

Takeaway

It is helpful to determine the sources to lessen or reduce the effects of unwanted vibrations. Oftentimes, it’s possible to move the measuring device or instrument just a little bit, take advantage of huge mass blocks, use suspension alternatives, or use flexible tubes.

About the Author

Sylvia Hopkins is a writer and a blogger who specializes in email marketing campaigns and ghost blogging. She writes about flow measurement instrumentation, flow measurement application, and technology. When not working, Sylvia spends some quality time with her family and friends.

Which Option to Consider While Purchasing Forklift: Buy, Lease or Rent?

There are various options to consider when you want to acquire a forklift. As this is no cheap piece of equipment. Making a decision requires you to use a unique lens to decide on what’s best for your scale of operation. Are you torn between renting, leasing or buying? To help you through this challenging process, below, you will find points that will assist you in determining the best cause of action for your business:

 

  1. Renting a forklift

If you in a seasonal peak during your business period or in need of moving extra freight, renting is the choice you can take. When you choose to rent a forklift, you are sure to benefit from experimenting with different classes of forklifts to see which one increases productivity.

 However, rentals are somewhat expensive compared to leasing or buying. This is because you will have to cover maintenance costs as well as the time that the forklift will be idle while at the dealership between rental assignments.

During renting, remember that there will be building waste that needs attention. You need to take care of transportation waste, construction waste sorting as well as recycling streams.

  1. Leasing a forklift

While you are contemplating leasing, you can set your number of years on which you intend to rent the machine. Having a short lease will allow you to work better if you want to become fluid. Leasing will provide you with less monthly payments when compared to renting or buying.

This option allows you to test-drive new models without making a permanent commitment to buying it. You will be at a position to make adjustments where you see fit in terms of decreasing the fleet size, changing product mix or modifying terms of the lease

  1. Buying a forklift

Does your business have a preference for owning all the capital equipment it has? Do you want to access a higher competitive credit line? Is your business stable, or you anticipate to use the material for more than 20 years? Do you have cash at hand to make a purchase immediately? If yes, the best course of action that you should proceed with it buying your forklift machine.

This way, you are sure to make a better return on investment because when you rent over a long period, rental fee tends to become higher as compared to monthly financial costs.

Buying a forklift will allow you to make your modifications than with a rental or leased equipment. You get customized options which suit your specific needs.

You can enjoy a tax deduction as purchased forklift are entitled to a reduced tax.

Conclusion

When deciding on what purchasing technique to use, be sure to analyze your business needs before making any rash decisions. Do not forget to offer your workers a Solutions on Waste, Recycling and Processing Recyclable Materials during your contraction tenure. This will go hand in hand with the ultimate choice you make in purchasing option that will work for your company.