Wednesday, October 31, 2018

STREAMS AND RIVERS WATER QUALITY - A stream is impaired when it cannot fulfill its functions like fish protection & propagation, recreation, and public water supply. Coliform bacteria inhabit the gut of animals, and are a good indicator of fecal contamination. When there is a high count of coliform bacteria the water also contains microorganism that can make us sick. Silt and clay may occur naturally in the environment but when they enter streams in large quantity, they become a serious pollution problem. Nutrient pollution occurs when excess nitrogen and phosphorus make their way into a stream or river. These elements are then picked up by algae, allowing them to grow rapidly to the detriment of the aquatic ecosystem.

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Streams And Rivers Water Quality
Water Pollution in Streams and Rivers
by Frederic Beaudry


About one third of the nation’s rivers and streams are routinely assessed for water quality by the Environmental Protection Agency (EPA).
Out of the 1 million miles of streams examined, over half had waters considered impaired.
A stream is categorized as impaired when it cannot fulfill at least one of its uses, which include a variety of functions like fish protection & propagation, recreation, and public water supply.
Here are the 3 most significant causes of stream and river pollution, in order of importance:
1. Bacteria. Contamination of water by certain types of bacteria is certainly a human health issue, as we are particularly susceptible to disease-causing gut bacteria. 
Beach safety is routinely monitored through coliform bacteria counts. Coliform bacteria inhabit the gut of animals, and are a good indicator of fecal contamination.
When there is a high count of coliform bacteria, the odds are high that the water also contains microorganism that can make us sick.
Gut bacteria contamination can come from municipal sewage treatment plants that overflow during heavy rain events, or from leaky septic tank systems. Abundant animals near the water, for example ducks, geese, gulls, or cattle, can also result in bacteria contamination.
2. Sediment.  Fine-grained particles like silt and clay may occur naturally in the environment but when they enter streams in large quantity, they become a serious pollution problem.
Sediments come from the many ways soil can be eroded on land and carried into streams. Common causes of erosion are road construction, building construction, deforestation, and agricultural activities.
Anytime there is a significant removal of the natural vegetation, the potential for erosion exists. In the United States, vast farm fields are left barren much of the year, and as a result rain and melting snow wash away soil into streams and rivers.
In streams, sediments block sunlight and thus impede the growth of aquatic plants. Silt can smother the gravel beds necessary for fish to lay eggs.
Sediments that remain suspended in the water are eventually carried off into coastal zones, where they affect marine life.
3. Nutrients. Nutrient pollution occurs when excess nitrogen and phosphorus make their way into a stream or river. These elements are then picked up by algae, allowing them to grow rapidly to the detriment of the aquatic ecosystem.
Overabundant algae blooms can lead to toxin build-up, oxygen level drops, fish kills, and poor conditions for recreation.
Nutrient pollution and the subsequent algae blooms are to blame for Toledo’s drinking water shortage in the summer of 2014.
Nitrogen and phosphorus pollution comes from inefficient sewage treatment systems, and from a common practice in large-scale farms: synthetic fertilizers are often applied in fields at greater concentrations than the crops can use, and the excess winds up in streams.
Concentrated livestock operations (for example, dairy farms or cattle feedlots) lead to large accumulations of manure, with nutrient runoff difficult to manage.
Not surprisingly, the most widespread source of stream pollution is reported by the EPA to be agriculture.
Other important sources of problems are atmospheric deposition (usually air pollution that is brought into streams with rainfall), and the presence of dams, reservoirs, stream channels, and other engineered structures.

Frederic Beaudry
·   Associate professor of environmental science
·   Wildlife biologist
·   Holds a Ph.D. Wildlife Ecology and a Master's degree in Natural Resources
Experience
Dr. Frederic Beaudry is a former writer for ThoughtCo and contributed work for three years. He is an associate professor of environmental science at Alfred University in New York. Prior to teaching, he worked as a wildlife biologist focusing on the ecology and conservation of birds and turtles. Dr. Beaudry has authored several scientific papers on land use and conservation and has conducted research examining land use changes and their effects on bird and amphibian communities.
Education
·   Ph.D., Wildlife Ecology, University of Maine
·   M.A., Natural Resources, Humboldt State University
·   B.S., Biology, Université du Québec à Rimouski
·   Postdoctoral research at the University of Wisconsin-Madison
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Tuesday, October 30, 2018

AUTOMOTIVE GLASS - Because of its strength and solid safety record, some car manufacturers are considering the implementation of laminated glass into all areas of their cars. Laminated glass also acts as a good sound dampener because of the PVB inside it. There's one problem with laminated glass throughout a vehicle: In an emergency, an occupant couldn't break the laminated glass without help. Glass manufacturers continue to explore new ideas for making glass stronger, safer and adaptable for new vehicles. Our vehicles wouldn't be as safe as they are without modern tempered and laminated glass.

Automotive glass is specially treated to protect vehicle passengers from the elements. See more car safety pictures.
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Automotive Glass

Laminated glass is strong enough to keep flying objects from penetrating a car's windshield.How Automotive Glass Works


When car companies run ads on television touting their vehicle's new safety features, they rarely mention the car's windshield or the surrounding windows, but the glass surrounding you in those vehicles has been designed and manufactured with your safety in mind.
Although automotive glass looks the same as any other type of glass, it functions very differently.
In most homes, the windows in each room are made from a standard type of glass that will shatter into large shards when it breaks.
With the exception of a sliding glass door or front door, these home windows don't receive the same amount of strain that an automotive window does.
A car, on the other hand, will encounter many potholes, rocks and fender benders in its lifetime.
Because of this, automotive glass is manufactured into two different types of safety glass to protect both the structure of the vehicle and the occupants inside.
The first type of glass is called laminated glass, which is for the windshield.
The second type of glass is known as tempered glass, which is used for the vehicle's side and back windows.
Later on, we'll learn how glass makers insert a thin layer of film between two layers of glass and fuse them together through heat and pressure to make laminated glass.
We'll also take a look at how tempered glass gains its strength through a process of heating and rapid cooling.
Without these different styles of manufacturing and strengthening, automotive glass would be little more than a simple barrier between us and the elements outside.
Laminated and tempered glass each have different functions, but together, they keep you inside the vehicle in an accident, shield you from flying sharp glass, retain the roof's rigidity in a rollover and allow the side air bag to protect you when it's deployed.
Let's go on to the next page and learn when these types of glass were first used and why.
The History of Automotive Glass
During the early 20th century, horseless carriages started using glass to protect drivers from harsh winds. However, the standard form of glass used in those times didn't adequately protect occupants from flying debris.
It also posed a risk to the occupants if an object struck the glass or if the vehicle was involved in an accident.
In 1903, French chemist Edouard Benedictus stumbled upon the secret to shatter-resistant glass when he dropped a glass flask filled with a dried collodion film.
He found that the glass coated with the film cracked, but kept its original shape. However, this laminated glass wouldn't be implemented in automobiles until the 1920s [source: Time].
Automakers used laminated glass in their windshields to optimize occupant safety during accidents and to protect passengers from projectiles during normal driving conditions.
For all its benefits, though, the first types of laminated glass offered limited puncture resistance.
Today's laminated glass consists of a thin layer of polyvinyl butyral (PVB) inserted between two layers of solid glass.
In addition to laminated glass, automakers began to use tempered glass in the late 1930s.
This type of glass is used in the vehicle's side and back windows and gains its strength through a heating and rapid cooling process that strengthens the glass' outer surface as well as its core.
By the 1960s, the American public had become increasingly aware that automobiles needed to be designed for more than just looks.
This realization derived partly from consumer crusader Ralph Nader’s  work to expose the dangers posed by certain vehicles and the need for government safety standards. In response, the U.S government formed the National Highway Traffic Safety Administration (NHTSA) in 1970 [source: Bowen].
Since then, NHTSA has implemented regulations affecting all areas of vehicle safety, including automotive glass.
Some of the Federal Motor Vehicle Safety Standards (FMVSS) for automotive glass include:
·  FMVSS 205 -- This set clear standards for automotive window transparency and the strength of automotive glass required to keep occupants inside the vehicle during accidents.
·  FMVSS 212 --This windshield mounting standard was established to ensure a certain level of windshield retention strength during accidents.
·  FMVSS 216 -- This legislation implemented a standard for roof rigidity in case of a rollover.
·  FMVSS 219 -- This standard states that no part of most passenger vehicles can penetrate the windshield more than 6 millimeters (0.24 inches) in a crash.
Now that we know how automotive glass came to be, let's find out how it's made.
TIPS FOR BUYING AND REPLACING AUTOMOTIVE GLASS [source: ABC News]
·  Replacing your windshield is a major safety concern. If your windshield has been severely damaged, don't put off getting it replaced.
·  Make sure the technician replacing your windshield is certified to do so by the National Glass Association.
·  Once your windshield has been replaced, make sure to wait the recommended time before driving the vehicle. In some cases, this can last up to 10 hours.
Laminated Glass and PVB
Laminated glass is made by sandwiching a layer of polyvinyl butyral (PVB) between two pieces of glass. The glass and the PVB are sealed by a series of pressure rollers and then heated.
This combination of pressure and heat chemically and mechanically bonds the PVB to the glass.
The mechanical bond occurs through the adhesiveness of the PVB, while the chemical bond is created through hydrogen bonding of the PVB to the glass.
That inserted layer of PVB is what allows the glass to absorb energy during an impact and gives the glass resistance to penetration from flying projectiles. It also deflects up to 95 percent of ultraviolet (UV) rays from the sun [source: Reuters].
Laminated glass can break and be punctured, but it will stay intact because of its chemical bond with the PVB.
The strength of laminated automotive glass allows it to perform two very important functions in cars.
First, it allows the passenger-side air bag to deploy correctly.
Driver's side air bags tend to fly straight toward the driver from the steering wheel, but when the passenger air bag is deployed, it bounces off the windshield toward the passenger.
An air bag deploys with incredible speed --1/30th of a second -- and can withstand 2,000 pounds (907 kilograms) of force.
The windshield has to absorb both the speed and force of the air bag in order to protect the passenger in an accident.
Because of its strength, laminated glass can keep occupants inside the car during an accident.
In the past, occupants could be ejected through the windshield because the glass wasn't strong enough, but today's windshields provide more security.
In addition to absorbing the force of deployed air bags and keeping passengers inside the vehicle, laminated windshields also provide strength to a car's roof.
Windshields keep the roof from buckling and crashing down on passengers completely during a rollover.
Without the rigidity and strength of laminated glass windshields, many roofs would pose greater risks to passengers in certain kinds of accidents.
If you happen to find a small chip in your windshield, don't worry. You don't have to go out and get your entire windshield replaced to retain its strength.
Some small chips can be quickly and easily repaired with a windshield chip repair kit.
Most automotive stores carry these kits for around $10 and allow you to inject resin into the trouble spot and remove excess air in the problem area.
Once you've repaired the glass, you'll barely be able to notice your patch job.
Let's move on to the next page to find out how tempered glass is made and how it protects.
Tempered Glass
Tempered glass is just as important to a vehicle's safety as laminated glass, but it differs greatly in both form and function.
This type of glass is used for the surrounding windows of car (also called the sidelites) and the back window (or backlite).
Tempered glass is created by heating and then rapidly cooling the glass to room temperature by ushering it through a system of blowers.
The surface of the glass cools much faster than the center of the glass and contracts, causing compressive stresses, while the center of the glass expands because of its temperature, producing tensile stresses.
What does that mean? Imagine a piece of glass that could be pulled or stretched to a certain length (tensile stress), while being pushed down and compressed (compressive stress) simultaneously.
Both the pulling and pushing stresses achieved through the heating and cooling process give tempered glass its tensile and compressive strength.
The differences between these two give the glass 5 to 10 times the amount of strength it originally had.
The edges on a typical piece of tempered glass are very weak. This is caused in part by the rapid release of heat during the cooling phase of the tempering process.
To help compensate for this weaker area, the glass is ground down on the edges. When tempered glass breaks, it shatters into small, dull pieces.
The differences between the compressive and tensile stresses are what enable the glass to break in this way.
The pulling and the pushing of the glass produce a significant amount of energy during the tempering process. When the glass breaks, this energy is released and causes the glass to break into small pieces [source: AIS Glass Solutions].
Because of its strength, tempered glass can withstand the daily use of automobile driving. Without it, our cars would be filled with glass every time we encountered a pothole, got into a fender bender or closed a door.
Future Developments in Automotive Glass
Because of its strength and solid safety record, some car manufacturers are considering the implementation of laminated glass into all areas of their cars.
It's already in use in some larger vehicles: General Motors has installed it in the back windows of their passenger vans to keep occupants inside the vehicle during major accidents.
Some manufacturers, like BMW, have already placed laminated glass in the sidelites of some of their models as an extra protection from theft.
In addition to the safety boost it provides, laminated glass also acts as a good sound dampener because of the PVB inside it [source: Allen].
However, there's one problem with implementing laminated glass throughout a vehicle: In an emergency, an occupant needing to exit the vehicle quickly couldn't break the laminated glass without help.
Due to its strength, laminated glass can take 10 times longer to break than tempered glass, which can make escape difficult for a weakened and injured passenger [source: Allen].
This dilemma hasn't stopped automotive designers from devising new ways to get more laminated glass into our cars.
For example, cielo roofs (the name comes from the Spanish word for "sky") have been popping up all over the concept car circuit. Cielo roofs extend a car's windshield behind the driver's head, converting the entire roof into a single piece of laminated glass [source: Allen].
Automotive glass isn't only being designed for safety and comfort. Glass makers and car manufacturers are also trying to find avenues for recycling the glass.
Although some excess glass produced during the making of automotive glass does get recycled, once the automotive glass is fitted for a car, it becomes harder to recycle because of additions like coatings and heating elements.
Despite these dilemmas, glass manufacturers continue to explore new ideas for making glass stronger, safer and adaptable for new vehicles.
You might not think about it much, but our vehicles wouldn't be as safe as they are without modern tempered and laminated glass.


Automotive glass is specially treated to protect vehicle passengers from the elements. See more car safety pictures.

POULTRY LITTER - Poultry litter is a mixture of droppings, feathers, bedding material, feeds and water in the chicken coop. The nutrient concentration of the litter depends on the type and amount of bedding material, poultry kept, number of birds, the nutrients included in the poultry diet and the age of the chickens. Poultry litter is profitable for use either as manure or animal feed since it minimises cost and maximises total nutrient input. Ensure that the bedding material does not contain chemicals, always wear gloves when handling the litter and avoid using poultry litter from sick birds.

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Poultry Litter
Image result for images uses of poultry litterYou can do so much with poultry litter

In Summary

·  Composting may reduce the risk of nutrients from poultry litter entering water courses, thus, cutting the weight and volume of the original material. Composted poultry litter is a more valuable fertiliser than fresh litter.
·  Fertilising all types of pastures: It can be applied to mixed pastures comprising grasses and legumes. Do not graze pastures for at least three weeks after spreading poultry litter to allow regrowth period on a well-grazed paddock.
Poultry litter is a mixture of droppings, feathers, bedding material, feeds and water in the chicken coop after cleaning.
The nutrient concentration of the litter depends on the type and amount of bedding material, poultry kept, number of birds, the nutrients included in the poultry diet and the age of the chickens.
It is advisable to collect this litter once after every two weeks.
Strategies should be used to ensure that it does not get into water courses.
Poultry litter is profitable for use either as manure or animal feed since it minimises cost and maximises total nutrient input.
While it might appear suitable for direct garden use, domestic poultry litter is generally unsuitable for this purpose.
This is because if used fresh, it could burn plant roots, attract vermin and rodents.
STORAGE
Store well the litter to use it as fertiliser and minimise health and pollution risks.
Pile it in an open small stack not more than 1.8m high to reduce loss of nitrogen and organic matter due to overheating.
The site should be well-drained and away from water courses and fenced to keep off livestock.
Compact the base of the stack to reduce chances of coming into contact with surface water. Store the litter for shorter periods, in amounts that meet the needs of the current growing season.
This will help maintain the material’s nutrient value and reduce environmental risk and liability.
COMPOSING
Composting may reduce the risk of nutrients from poultry litter entering water courses, thus, cutting the weight and volume of the original material.
Composted poultry litter is a more valuable fertiliser than fresh litter.
Heap the litter in rows of about 1.2m high and 2.4m wide to achieve temperatures of 60°C to 70°C or simply add a 5cm layer to every 15cm of the other material.
Composting normally increases cost and time required for processing, but reduces the total amount of nitrogen and organic matter available during land application.
The composted material can be used in nurseries, gardens and flower farms.
USES OF POULTRY MANURE
Fertilising all types of pastures: It can be applied to mixed pastures comprising grasses and legumes.
Do not graze pastures for at least three weeks after spreading poultry litter to allow regrowth period on a well-grazed paddock.
Application can be done by broadcasting, followed by cultivation into the soil where possible to reduce smell and loss of nitrogen into the air.
Do not apply litter on steep land.
Fertilising fruit crops and vegetables: This can be applied at the rate of 150g per square metre for most crops.
Additional potassium fertiliser may be needed. Note that fresh poultry manure is known to harbour pathogens, therefore, it is crucial to mitigate the possibility of vegetable contamination.
This is achieved through the use of composted manure. Incorporate the manure in the soil, and using polyethylene, mulch to cover the soil.
Biogas production: A digester tank of 2,000kg can handle approximately 17 tonnes of chicken litter per day, which would yield 3,400g biogas.
You need to dilute with water to remove ammonia, which inhibits anaerobic digestion. It takes about 30 days for complete digestion of chicken litter.
Animal feed production: Poultry litter can be fed to cattle by incorporating into their rations. Litter fed at 40 per cent can cover almost completely the protein and mineral requirements of beef cattle.
A significant level of energy and the total required minerals like calcium and phosphorus can be fully met when broiler litter is fed to beef cattle at 20 per cent inclusion level.
Give preference to feeds low in ash such as sugar, cassava and other tubers, cereal grain, and fruit wastes.
Fruit wastes are rich in digestible energy and are excellent balancing ingredients for poultry waste.
Supplement with additional energy in the form of molasses and starchy feeds to increase palatability, feed intake and maximum utilisation of the non-protein nitrogen fraction of poultry waste.
You can also ensile litter with forages and high moisture grains like maize.
Such silage has higher palatability with better performance than silage containing soybean as protein source.
When handling poultry manure, observe the following precautions.
Remove any dead birds and parts of birds like feathers and bones to minimise harm especially when used in livestock feeds.
Ensure that the bedding material does not contain chemicals, always wear gloves when handling the litter and avoid using poultry litter from sick birds.

Ms Andisi is based at Department of Animal Sciences, Egerton University.

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Monday, October 29, 2018

AIRCRAFT MISSED APPROACH - With today’s advanced Category III or “Cat III” landing parameters, aircraft can be automatically guided all the way down to a safe landing on the runway in “zero-zero” conditions (no ceiling/no visibility) without the pilots ever seeing the ground.


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Aircraft Missed Approach
WHAT IS A “MISSED APPROACH?”
By Airline Ratings






In the past, if pilots could not see either the approach lights or runway after descending to a certain height called the MDA, or “Minimum Descent Altitude,” they had to execute a missed approach by adding power, climbing back to a higher altitude and trying the approach again, or diverting to an alternate airport.
With today’s advanced Category III or “Cat III” landing parameters, aircraft can be automatically guided all the way down to a safe landing on the runway in “zero-zero” conditions (no ceiling/no visibility) without the pilots ever seeing the ground.

https://www.airlineratings.com/did-you-know/what-is-a-missed-approach/


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