COMPOSTING OF SOLID WASTE, OBJECTIVES & ITS STEPS - Composting of Solid Waste is defined as "biological decomposition of biodegradable organic constituents of waste under controlled conditions to a state sufficiently stable for nuisance free storage & handling and for safe use in land applications." About 70% of municipal solid waste is decomposable or compostable. Objectives of composting of solid waste. To transform biodegradable organic matter into biologically stable material thereby reducing the original volume of the waste, to destroy pathogens, insect eggs and other unwanted organisms and weed seeds that may be present in municipal solid waste. to retain maximum nutrient content; and to produce a product that can be used to support plant growth and as a soil amendment as fertilizer and soil conditioner. Composting time depends on: The nature of waste. Moisture content of solid waste. Available nutrients in the solid wastes. Other environmental factors. Under controlled conditions, can be made more effective and efficient. Organic matter + O2 + nutrients + microbes Reduces weight/volume of the organic fraction of MSW. Produces compost ( a humus like material that can be used as a soil conditioner). To produce methane - Bio Gas. Composting period 2-6 weeks

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Composting of Solid Waste, Objectives & Its Steps

By: Haseeb Jamal 

Composting of Solid Waste:

·      Composting of Solid Waste is defined as "biological decomposition of biodegradable organic constituents of waste under controlled conditions to a state sufficiently stable for nuisance free storage & handling and for safe use in land applications".

·      About 70% of municipal solid waste is decomposable or compostable.

·       Main organisms involved in composting are:

o     actino-mycetes (filamentous bacteria), fungi and protozoa.

Objectives of Composting of solid waste

·      To transform biodegradable organic matter into biologically stable material thereby reducing the original volume of the waste,

·      To destroy pathogens, insect eggs and other unwanted organisms and weed seeds that may be present in municipal solid waste.

·      To retain maximum nutrient content; and

·      To produce a product that can be used to support plant growth and as a soil amendment as fertilizer and soil conditioner.

Composting time depends on:

1.    The nature of waste.

2.    Moisture content of solid waste.

3.    Available nutrients in the solid wastes.

4.    Other environmental factors.

5.    Under controlled conditions, can be made more effective and efficient.

6.    Organic matter + O2 + nutrients + microbes ------- New cells + resistant OM + CO₂ + H₂O + NH₃ + SO4 + heat.

7.    Reduces weight/volume of the organic fraction of MSW.

8.    Produces compost ( a humus like material that can be used as a soil conditioner).

9.    To produce methane - Bio Gas.

Steps in Composting of solid waste:

PRE-PROCESSING

Receiving

·      Sorting/separation: removal of recyclable material, metals, debris, glass etc. - affects the quality

Size Reduction/Screening:

·      to provide greater surface area for microbes to attack, to improve insulation, to facilitate homogenizing of initially heterogeneous material, to reduce depth for oxygen diffusion.

·      If size is too small, it impedes the diffusion of oxygen and CO₂ from the sites being attacked especially during thermophylic stage when Oxygen demand is the highest.

·      Typical range for feed material = ½ - 2 inches.

·      Adjustment for waste properties (e.g C/N ratio)

·      Decomposition and curing/maturation

Types are: Static piles and in-Vessel composting

·      Preparation and marketing of the final compost product: Grinding, screening, air classification, blending with various additives, granulation, bagging, storage and transportation

Windrow Composting

·      Triangular piles 7 feet high and 14-16 feet wide at the base

·      Turning by front end loader or mechanical turner twice per week

·      Composting period 2-6 weeks

Haseeb Jamal. I am a Civil Engineer, graduated from University of Engineering and Technology, Peshawar, Pakistan in 2010. I also have a PG-Diploma in Disaster Management and MS in Urban Infrastructure Engineering (In Progress). My expertise include civil related softwares like AutoCAD, SAP2000, MS Project, Primavera, MS Office and GIS. My technical skills include project management, monitoring and evaluation, structural assessment, disaster risk management, Quantity survey, land survey, material testing, site management and technical writing. I am trained in writing project progress reports as well as proposals and concept papers. I have also received advanced training on surveying, proposal writing, Monitoring and Evaluation of projects as well as organizations.I have worked as Project Engineer at National Research and Development Foundation, Peshawar and CENCON Associates. I also worked with Spectra Engineering Solutions as Senior Civil Engineer in monitoring of World Bank and UNDP funded projects all over Khyber Pakhtunkhwa and FATA. Currently, I am working as Deputy Manager Development at NayaTel, Peshawar.

https://www.aboutcivil.org/windrow-composting-of-solid-waste.html

CLOUD SEEDING - Humans can now control the weather, including ‘making it rain’ literally – through a process called cloud seeding. It basically is the enhancement of natural precipitation. The process makes water vapor into clouds, turning into precipitation and into rain that would otherwise not fall on earth. It is the most widely used technique in the modification of weather. Cloud seeding, rainmaking, or man-made precipitation enhancement is a way to artificially modify the weather by spreading clouds with small particles, to make it snow or rain. Cloud seeding is all about manipulating the clouds so that it rains. Clouds consist of water droplets or ice crystals. They form when water vapor in the atmosphere cools and later condenses around a particle of dust or salt. These dust or ice particles, also known as condensation nuclei, facilitate the formation of raindrops or snowflakes. Without the condensation nuclei, rainfall cannot form and, therefore, precipitation does not occur. Cloud seeding artificially adds condensation nuclei to the atmosphere, significantly improving the ability of a cloud to produce rain or snow. With the added condensation nuclei, cloud seeding provides a base for snowflakes or raindrops to form. After cloud seeding, precipitation in the form of rain or snow will fall from the clouds back to earth. The intent or goal of cloud seeding is to increase the rain or snow precipitation, suppress hail, reduce lightning, or even dissipate the fog.

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Cloud Seeding

How Does Cloud Seeding Work?

Rinkesh

The weather has been, for Millenia, a natural phenomenon that could not be altered by human activity.

For instance, no one could manipulate the atmosphere so that it rains. However, in the last several years, human intelligence and technology have changed that.

Humans can now control the weather, including ‘making it rain’ literally – through a process called cloud seeding.

It basically is the enhancement of natural precipitation.

The process makes water vapor into clouds, turning into precipitation and into rain that would otherwise not fall on earth.

It is the most widely used technique in the modification of weather.

The following is an in-depth analysis of cloud seeding, how it works, and its potential negative effects.

What is Cloud Seeding?

Cloud seeding, rainmaking, or man-made precipitation enhancement is a way to artificially modify the weather by spreading clouds with small particles, to make it snow or rain.

In other words, cloud seeding is all about manipulating the clouds so that it rains. Clouds consist of water droplets or ice crystals.

They form when water vapor in the atmosphere cools and later condenses around a particle of dust or salt.

These dust or ice particles, also known as condensation nuclei, facilitate the formation of raindrops or snowflakes.

Without the condensation nuclei, rainfall cannot form and, therefore, precipitation does not occur.

Cloud seeding artificially adds condensation nuclei to the atmosphere, significantly improving the ability of a cloud to produce rain or snow.

With the added condensation nuclei, cloud seeding provides a base for snowflakes or raindrops to form.

It, therefore, follows that after cloud seeding, precipitation in the form of rain or snow will fall from the clouds back to earth.

The intent or goal of cloud seeding is to increase the rain or snow precipitation, suppress hail, reduce lightning, or even dissipate the fog.

It is an efficient tool, especially in arid areas of the world, where rainfall is minimal under ordinary circumstances.

Cloud seeding has been practiced by a number of countries including India, the United Arab Emirates, the United States, China, and the United Kingdom.

China has used the technology dependently in dry areas of the country.

The UAE has used the technology since the 1990s, including in 2015 when they pumped about $5 million into their Research Program for Rain Enhancement Science.

The US has employed the technology since the 1950s, especially in the Rocky Mountains, Sierra Nevada, and other mountainous and dry areas.

During the 2008 Beijing Summer Olympics and during the wedding of the Duke and Duchess of Cambridge, the technology was used to prevent rain.

How Does Cloud Seeding Work?

The enhancement of rainmaking or precipitation was first done in 1946 when Vincent Schaefer and Bernard Vonnegu, American scientists at General Electric, were successful in seeding a cloud with dry ice.

They climbed onto a small plane and seeded a cloud with dry ice floating above Schenectady, New York. They then watched as the snow fell from the base of the ice.

After that experiment, Schaefer became referred to as the ‘Snow Man’. According to Guo (2018), three methods can make cloud seeding work:

1.    Spraying water into warm clouds

2.    Dropping ice into cold clouds

3.    Spraying silver iodide or similar crystals into a cold cloud, either from the ground or over the cloud from an airplane

Regardless, the types of clouds play a vital role in ensuring the process is successful.

Large droplets are required if rain is expected to form, meaning maritime clouds are a better source of rain than continental clouds.

The temperature of the cloud is also important.

For instance, cumulus and stratiform clouds, whose temperature is below -7°C, would be accompanied by precipitation within 25 minutes.

Types of Cloud Seeding

1. Static Cloud seeding

This first of three methods work when a chemical compound is spread onto the clouds.

It is the most commonly used method and involves the spraying of particles of salt, like silver iodide and chloride onto clouds.

Silver iodide (AgI) exists in the environment naturally and is not harmful to humans or wildlife.

To do so, a special aircraft, rocket, or other dispersion device is used.

The salt particles act as a condensation nucleus, drawing water vapor within the cloud towards them.

Moisture will then latch onto them, condensing into water droplets. Subsequently, raindrops form, leading to rainfall.

2. Dynamic Cloud Seeding

This second type of seeding works by boosting the vertical air currents, encouraging more water to pass through the clouds.

It, therefore, translates to more rain.

For it to work, about 100 times more ice crystals are required as compared to the static cloud seeding method.

It is a more complex method as it relies on a sequence of events working properly.

Scientists within the atmospheric science departments as well as other researchers have broken the dynamic cloud seeding method into eleven separate stages.

If one of the stages fails or its outcome is unexpected, the entire process is ruined.

It also makes the technique less dependent as compared to the static cloud seeding method.

3. Hygroscopic Cloud Seeding

This last type utilizes the dispersal of salts through flares or explosives onto the lower parts of a cloud.

The salt will become bigger and water will join it.

It is a relatively new method that has been described as ‘promising.’ It, however, requires more research.

Negative Effects of Cloud Seeding

1. The process is not 100% effective

Despite the process being touted as highly successful in creating rain, it has raised concerns as to its actual effectiveness.

The main question that arises is, would rain have come in a certain place even without the need for the seeding?

Cloud seeding becomes irrelevant if it would have rained regardless of it being used.

It becomes difficult to ascertain if fluctuations in the level of rainfall, occurring during cloud seeding times, are produced by seeding or could have occurred naturally.

2. The process is very expensive

It is an innovative way of creating rainfall, especially in arid areas. However, it is an expensive process.

In China, for instance, the country uses between $60 and $90 million every year on such weather modification projects.

Between 1995 and 2003, the country used $266 million for the same causes.

As already mentioned, the UAE spent about $5 million in 2015 for its Research Program for Rain Enhancement Science.

Such monies could be used to fund other projects, given that it will inevitably rain.

Also, if the aim is to bring rain to areas severely affected by climate change, wouldn’t it be easier to tackle global warming and climate change, as it would bring a long-lasting solution?

3. The truth about silver iodide is that it may potentially contain dangerous substances

Despite silver iodide being termed as safe for the environment, there remain concerns about exposure to the same, especially with regards to soil contamination.

Silver iodide has been known to result in incapacitation and possible residual injuries to humans and other animals, especially after chronic exposure.

The toxicity of silver and its compounds in the environment might be low, but they are negative effects nonetheless.

4. Cloud seeding is not the end solution; it may actually worsen global warming and climate change

It has been argued that cloud seeding is just a way of sweeping the effects of pollution and climate change under the rug.

Using cloud seeding to bring rainfall does not negate the fact that climate change exists and the process does nothing to fix the initial problem, which is global warming and climate change.

Since the process is expensive, it would be easier to fix the bigger problem and enjoy the long-term benefits of a better climate.

5. The results might be damaging – more or less rain!

The end results of cloud seeding are either having no rain, like during the 2008 Beijing Olympics or having more rain, especially in dry areas.

However, sometimes, the results have been damaging.

In 1974, a hurricane on the US East Coast was seeded using dry ice.

The hurricane did not hit the area but moved to the west in Georgia. It caused severe damage, leading to General Electric Corporation being sued.

Operation Cumulus was as well an alleged to be series of secret scientific experiments being conducted in the UK between August 4^th and 15^th What followed were flash floods in Devon village in Lynmouth, England, killing 35 people.

6. Cloud seeding can be used for destructive purposes

According to Brown (2018), only 56 countries practiced cloud seeding activities in 2016.

This means the possibility of more powerful countries using the process to attack other countries.

For instance, the US used cloud seeding to cause a monsoon in Ho Chi Minh, Vietnam, during the Vietnam War, as a tactic against the Vietnamese soldiers.

Rinkesh. A true environmentalist by heart ❤️. Founded Conserve Energy Future with the sole motto of providing helpful information related to our rapidly depleting environment. Unless you strongly believe in Elon Musk‘s idea of making Mars as another habitable planet, do remember that there really is no 'Planet B' in this whole universe.

https://www.conserve-energy-future.com/types-effects-cloud-seeding.php

TYPICAL ROAD STRUCTURE DETAILS - Composition of Road Structure: Road Structure Cross Section is composed of the following components: Surface/Wearing Course. Base Course. Sub Base. Sub Grade. Surface/Wearing Course in pavement cross section: The top layers of pavement which is in direct contact with the wheel of the vehicle. Usually constructed of material in which bitumen is used as binder materials. Bituminous Pavement: Consists of combination of mineral aggregate with bituminous binder ranging from inexpensive surface treatment ¼ in or less thick to asphaltic concrete. For good service throughout the full life bituminous pavement must retain following qualities. Freedom from cracking or raveling. Resistance to weather including the effect of surface water heat and cold.Resistance to internal moisture, particularly to water vapors. Tight impermeable surface or porous surface (if either is needed for contained stability of underlying base or subgrade). Smooth riding and non-skidding surface. The design should be done so that to meet the above requirements for considerable number of years (need proper design and construction supervision). Pavement meeting all the requirements above have been product if six distinctly different construction processes as follows: Heat a viscous bituminous binder to make it fluid, then in a plant mix it with heated aggregate place and compact the mixture while it is hot.

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Typical Road Structure Details

By: Haseeb Jamal 

Composition of Road Structure:

Road Structure Cross Section is composed of the following components:

1.        Surface/Wearing Course

2.        Base Course

3.        Sub Base

4.        Sub Grade

1. Surface/Wearing Course in pavement cross section:

The top layers of pavement which is in direct contact with the wheel of the vehicle. Usually constructed of material in which bitumen is used as binder materials.

a. Bituminous Pavement:

Consists of combination of mineral aggregate with bituminous binder ranging from inexpensive surface treatment ¼ in or less thick to asphaltic concrete.

For good service throughout the full life bituminous pavement must retain following qualities.

·      Freedom from cracking or raveling.

·      Resistance to weather including the effect of surface water heat and cold.

·      Resistance to internal moisture, particularly to water vapors.

·      Tight impermeable surface or porous surface (if either is needed for contained stability of underlying base or subgrade).

·      Smooth riding and non-skidding surface.

The design should be done so that to meet the above requirements for considerable number of years (need proper design and construction supervision).

Pavement meeting all the requirements above have been product if six distinctly different construction processes as follows:

·      Heat a viscous bituminous binder to make it fluid, then in a plant mix it with heated aggregate place and compact the mixture while it is hot.

·      Use fluid bituminous binder, mix it with aggregate at normal temperature. Mixing may be done at a plant (plant mix) or on the prepared roadway base (road mix). Spread and compact the mixture at normal temperature.

·      Add solvent such as naphtha or kerosene to a viscous bituminous binder to make it fluid with aggregate at normal temperature by either plant or road mix methods. Spread and compact at normal temperature before solvent evaporates.

·      Use fluid emulsion of viscose bituminous binder in water, mix it with aggregate at normal temperature by either plant or road mix method. Spread and compact at normal temperature before the emulsion breaks down with its components.

·      Spread and compact clean crushed aggregate as for water bound macadam. Over it spray heated dissolved or emulsified bituminous binder which penetrates open areas of the rock and binds the aggregate together. Thus is commonly called “Penetration Method”.

·      Spread bituminous binder over the roadway surface then cover it with properly selected aggregate. This is commonly called the “Inverted Penetration Method”.

Selections based on the requirements and economy, large volume of heavy vehicles, low traffic volume etc.

2. Base course

It is the layer immediately under the wearing surface (Applies whether the wearing surface is bituminous or cement concrete and or more inch thick or is but a thin bituminous layer).

As base course lies close under the pavement surface it is subjected to severe loading.

The material in a base course must be of extremely high quality and its construction must be done carefully.

Types of Base Course

1.    Granular Base Course

2.    Macadam Base

3.    In-water bound Macadam

4.    Treated Bases

3. Sub Base:

It is layer of granular material provided above subgrade generally natural gravel. It is usually not provided on subgrade of good quality. It is also called granular subbase.

a. Function of Sub base in Road Cross Section

·      It enables traffic stresses to be reduced to acceptable levels in sub-grade in the Road Cross Section so that excessive deformation is prevented.

·      It acts as a working plate form for the construction of upper pavement layers.

·      Acts as a drainage layer, by protecting the sub grade from wetting up.

·      It intercept upward movement of water by capillary action.

·      It acts as a separating layer b/w subgrade and road base. By this it prevent the two layers from mixing up.

b. Characteristics of materials used in Sub Base:

The subgrade material should be clean and free from organic matter and should be able to be compacted by roller, to form stable sub-base. The material should have following characteristic.

·      Well graded uniformity coefficient (D60/D10) should not be less than 3.

·      Fraction passing sieve #200 shall not be greater than 2/3rd of the fraction passing sieve #40.

·      Should have a L.L not greater than 25%.

·      P.I not greater than 6

·      CBR should not be less than 25. See also: CBR Test Procedure

·      In coarse grain, aggregate retained by #10 sieve, %age of wear shall not be greater than 5%.

·      The max dia of any particle shall not be greater than 2/3ed of the layer thickness of sub-base.

• Typical particle size distribution for the sub-base (granular) when will meet strength requirement are:

B.S Sieve Size	% By mass of total Aggr. passing test sieve
50	100
37.5	80 - 100
20	60 - 100
5	30 - 100
1.15	170 - 75
0.3	9 - 50
0075	5 - 25

* To avoid intrusion of silt and clay material in sub-base from subgrade

D15 (sub base) < 5 D15 (sub grade)

• Recommended plasticity characteristic for granular Sub Base (Road Note 31) are;

Climate	Liquid Limit (L.L)	Plasticity Index (P.I)
Moist or wet tropical	< 35	< 6
Seasonal wet tropical	< 45	< 12
Arid & Semi Arid	< 55	< 20

4. Sub Grade:

Consists of the naturally occurring material on which the road is built, or the imported fill material used to create an embankment on which the road pavement is constructed.

Subgrades are also considered layers in the pavement design, with their thickness assumed to be infinite and their material characteristics assumed to be unchanged or unmodified.

Prepared subgrade is typically the top 12 inches of subgrade.

Haseeb Jamal. I am a Civil Engineer, graduated from University of Engineering and Technology, Peshawar, Pakistan in 2010. I also have a PG-Diploma in Disaster Management and MS in Urban Infrastructure Engineering (In Progress). My expertise include civil related softwares like AutoCAD, SAP2000, MS Project, Primavera, MS Office and GIS. My technical skills include project management, monitoring and evaluation, structural assessment, disaster risk management, Quantity survey, land survey, material testing, site management and technical writing. I am trained in writing project progress reports as well as proposals and concept papers. I have also received advanced training on surveying, proposal writing, Monitoring and Evaluation of projects as well as organizations.

I have worked as Project Engineer at National Research and Development Foundation, Peshawar and CENCON Associates. I also worked with Spectra Engineering Solutions as Senior Civil Engineer in monitoring of World Bank and UNDP funded projects all over Khyber Pakhtunkhwa and FATA. Currently, I am working as Deputy Manager Development at NayaTel, Peshawar.

https://www.aboutcivil.org/road-structure-cross-section.html