Hi A Dark Side of Solar Power!!!

Hi A Dark Side of Solar Power!!!

The harshest criticism for fossil fuels has always been the horrible effect they have on the environment. Not only does retrieving the resource (coal, petroleum, natural gas) do irreparable damage to landscapes and ecosystems, but transporting it can be quite dangerous. And once the fuel has been spent, harmful byproducts clog the atmosphere and have far-reaching effects that scientists have only recently begun to quantify.

You know this, and I know this. And I know that you know that we all know this. This isn't going to be a recital of facts we know, ya know? But what about the negative environmental impacts our cultural shift to renewable energies, namely solar power, produce? There is a side to solar (PV) power that's rarely considered and not well understood.

Energy Payback Time (EPBT):

EPBT is the amount of time it takes a solar panel to collect the same value of energy that was expended in the panel's creation. It used to be that panels virtually never recaptured the amount of energy which was needed to create them, but that belief faded in the 1990s as the technology improved.

A significant amount of energy is spent producing, processing, and purifying materials for PV panels, as well as for the manufacture, transportation, and installation of the panel. The mathematical formula (.pdf) for determining the EPBT looks like this:

Rather than break down figures for areas with my limited text space, I'll just spoil the conclusion: the effectiveness of solar panels is severely affected by material efficiency and the location of the panel. In most of the United States, it takes almost two years before the panels begin to reduce emissions. At what latitude do solar panels stop making sense?

Environmental Waste:

Not surprisingly, China has been the leading manufacturer of PV panels worldwide by nearly fourfold. Despite this robust production rate, they're only second in PV power production (18,400 mW compared to Germany's 36k mW). What gives?

Frankly, China doesn't care about its environment and has little oversight on how companies dispose of industrial waste. And in consideration of the profit the industry is making, what regulations do exist are overlooked. U.S.-based PV panel manufacturers have a hard time disposing of toxic materials used in the production process. Chinese companies don't have the same difficulty, choosing to bury chemicals or flush them in public waterways. The result is a panel which was cheaper to produce and ship abroad.

Really, we're just burying the problem someplace else, hoping that a super-solution from future geniuses materializes in the meantime.

Wildlife Impacts:

The Ivanpah solar plant in utilizes 174,000 heliostats to reflect sunlight onto a centralized solar tower. The tower collects the sunlight, transfers it to heat, and boils water to begin the electricity production process. The plant is located in the Mojave Desert, away from population centers.

Human population centers, at least. While the imagery of a desert solar plant probably conjures images of dust and tumbleweeds, the area where the plant lives is much more lush than you might expect. When the plant was first announced, it incited considerable backlash because it was building on habitat that belonged to the endangered desert tortoise. The plant's construction was ultimately changed to help curtail its effects.

Now that the plant is up and running, an unforeseen consequence has occurred: an excessive number of bird deaths. Birds are lured to the area by insects or migration patterns, but once in the vicinity of the plant they're almost assured a hellish death. Estimates of up to 28,000 bird deaths a year have been attributed to the concentrated solar arrays, which blind and even ignite birds midflight. Officials are considering how to proceed with a megawatt and mega-money facility that may drive the extinction of entire species on its own.

The point isn't that solar power is harming our environment. Without a doubt, nearly any energy harvest strategy will conclude with negative environmental effects. But it shows that a long, long road of development must be traveled before our technology creates the sustainable utopia we envision. For now, we should probably maximize the efficiencies of the energy sources we have.

(Hi) Cross flow HEMF from IPS provides clean process water and reduces downtime!.

(Hi) Cross flow HEMF from IPS provides clean process water and reduces downtime!.

According to Industrial Purification Systems, process water users can achieve effective water filtration by installing Cross flow HEMF and at the same time save on operating costs by reducing downtime.

The technology filters water down to levels below 1.0 micron, reliably producing a supply of clean water not only free of solids contamination such as sand, grit and iron but also with reduced bacteria, phages and spores such as cryptosporidium.

By reducing the total biological and organic loading from water, chemical dosing is more effective as there is less of a challenge.

 This in turn often results in significant chemical use reduction, which is better for the water user, better for the environment and reduces operational costs.

The company said that industries that have installed this technology have reported a return on investment in less than six months, with some achieving payback in three.

Click on the following link here to download the Cross flow technical information sheet.

Key benefits;

• Filtration of process water down to 0.45 micron with efficiencies up to 99 per cent.
• Filtration of up to five times more water than a conventional filter achieving only 20-micron filtration.
• Longer ‘on line’ filtration time.
• Acceptance of solid challenges in excess of 200ppm.
• Short backwash times.
• More effective chemical treatment with fewer chemicals.
• Maintaining heat-transfer efficiencies for life of a system.
• Cleaning up older, already contaminated systems and improving performance.
• Reducing backwash loss by up to 95 per cent.
• Reducing costs by reducing loss of chiller and or heater kW input during backwash.
• Inlet pressure of only 1.0barg to operate.
• Minimum energy losses for pumping and processing through high flow, low pressure.

Industries and applications that benefit;

• Plastic moulding shops.
• Oil and gas exploration.
• Power generation.
• Paper manufacturing.
• Automotive manufacture.
• District heating/cooling.
• Pollution control.
• Data centres, banks, hotels, universities.
• UPVC extruders for pipes and windows.
• Potable water production.
• High-performance heating cooling loops.
• Brick, marble stone cutting.
• Brewing and distilling.
• Manufacturing.
• Nuclear power and processing.

Case study: Sheffield Homes uses Cross flow HEMF from IPS for efficient water filtration:

- 'Efficient water filtration is a hot topic for Sheffield homes’

Sheffield Homes manages the continual improvement of council homes across Sheffield. 

The company has a network of boilers and district heating pipework running throughout the city, which supplies heating and hot water to council properties. 

It is crucial that the water flowing through the pipework is kept as clean as possible to maintain flow rates and in so doing achieve maximum energy efficiency. 

Some sections of the pipe network are more than 35 years old. Over time, the pipes have collected debris and particles in the water, which have caused restrictions in the flow rates to some properties and led to problems maintaining an efficient district heating system.

Expensive pump and boiler parts and replacements are often required due to these issues. 

It was therefore felt there was a strong business case to introduce a filtration system to help clean and prolong the life of the heating systems as well as reducing maintenance costs.

Sheffield Homes chose the Cross flow HEMF advanced media filter from Industrial Purification Systems.

Click the following link here to download case study Or view & save below; 

*Click the following link here for further supplier information and company manufacturer brochure download or visit the company homepage by clicking the following link here. 

Watch Below, Introduction Video Clip:

Hi Sustainable Development in Industrial Ventilation

Sustainable Development in Industrial Ventilation

The best route to sustainable development in industrial ventilation, dust extraction and waste extraction is through the design of the system. Moving air requires energy. Heating air requires energy. In both cases the potential to save energy over a prolonged period through good design exceeds that from other current efficiency developments. Key points of design include:

• The air volume
• Fan efficiency and motor control
• Heat recovery and air make-up
• Training and maintenance

Air volume:

The broad spectrum of industrial ventilation and process extraction requirements means that a simple solution to sustainable development is not possible as, for the most part, each system is a bespoke design for the specific application. However, optimizing the air volume in each design is without doubt one of the best. Why?

• Air volume is directly proportional to power
• 10% less air means 10% less energy

How is this achieved? Often through the design of the hood, the position relative to the emission source and how much that source is enclosed.

The hood designs in the diagram above represent concepts as there will often be limitations on how far this design philosophy can be followed. However, it is clear to see that the position of the hood relative to the emission source and changing to an enclosure hood design, where practicable, could reduce the required extraction air volume significantly.

Fan efficiency:

The range of fans used across the application of ventilation and process extraction systems being typically considered could have efficiency from 50% to 80%. The fan efficiency compares the input energy to the work done and has a significant impact on energy consumption, for example,

• 40,000 hours operation broadly equates to 5-years @ 24/7 or 10-years @ 16 hours 5 days per week.

Based on 25kW aerodynamic energy requirement and an energy cost of 10p/kWh

• A 50% efficiency fan would consume 50kW/h, at a cost of £200,000.00
• A 75% efficiency fan would consume 33.3kW/h, at a cost of £133,200.00

If this is compared to the stated difference in efficiency between IE3, IE2 and IE1 motors of around 1.5-2%, at these motor ratings, then notwithstanding the possibly increased capital cost of selecting a higher efficiency fan, the energy savings through the 40,000 hour life cycle are vastly more significant than the initial costs. For more information on these motor standards, look up "Premium efficiency" on Wikipedia.

Motor control:

A related aspect to consider is the motor control where further energy saving possibilities exists although often not through the widely promoted speed or frequency inverter control.

In the first instance it is necessary to appreciate the laws of physics which apply to fans once installed in a system, assuming there are no changes to the ducting design.

• A 10% increase in the fan speed increases the volumetric airflow by 10%; however it requires a 33% increase in electrical power.
• Conversely, a 10% reduction in the fan speed reduces the airflow by 10% and reduces the electrical power by 27%. Just 5% speed reduction reduces the power by 14% so the savings through speed optimization can be significant.

However, a fan only absorbs the power required to do the work so, reducing the speed by 10% through a change in the drive belts may provide the saving at a modest investment. And as the power and motor size increase the savings become disproportionately greater.

% fan speed	80%	90%	100%	110%
% motor load kW	51%	73%	100%	133%

Table of motor power change with fan speed change

Example

• 37kW motor installed
• 32kW absorbed by the fan
• Energy cost per annum, 24/7 operation, is £27,955 @ 10p/kWh.
• Energy cost per annum, 16/5 operation, is £13,312
• 10% speed reduction means absorbed power becomes 24kW
• Assuming new drive belts and labour costs £500 (renewed annually anyway)
• Then first year net saving at 24/7 operation is circa £7,000, then £7,500
• And first year saving at 16/5 operation is circa £3,000, then £3,500.

Of course this is only applicable to a fan with a drive belt system fitted. An inverter controller will do the same, although the installation would cost more and an older motor may not be suitable for frequency variation control.

It should be noted there are certain advantages in using an inverter over the simple drive belt option including:

• Applicable to all fans; direct drive or belt drive
• Further speed change adjustments are easily made
• Little loss in motor efficiency at reduced speeds, whereas reduced power at unchanged motor speeds may reduce the motor efficiency
• Fan speed reduction is limited to reducing the rated motor power by 50%, when other factors may come into play
• Applications with frequent start/stop cycles

In designing an extraction system, it is prudent and not untypical to err on the side of caution and allow for a modest increase in airflow and hence fan speed on completion of the installation, which would have an impact on the power required, and to select a motor one size above the bare minimum required. However, once installed and commissioned at the correct speed, the load on the motor may be some way below the motor duty, although only drawing the proportionate electrical current. Often a case is made for inverters based on the installed power rather than absorbed power of the fan motor. It is fairly simple for an electrical engineer to measure the running current of the motor compared to the motor rated full load current (FLC) to provide an indication of the energy being used.

Air input:

Exhausted air must be replenished either uncontrolled through egress into the building or controlled through an air make-up supply. Whenever the external temperature is below the required internal level, heat energy will also be required. Whether or not the air entering is controlled or not is often dependant on the building size and relative amount of extracted air. As an example, 70kW of heat energy would be required for a 20OC temperature rise in 10,000m3/h and with a 5p/kWh heat energy, could cost around £10,000 per annum on a 24/7 operation.

More sustainable approaches to air make-up include controlled introduction which reduces draughts and may, in some instances, lessen the heat load required. Re-using exhausted and filtered air will have an operational cost however often shows a payback within two to three years. Although less efficient than returning filtered air, heat exchangers may also enable the re-use of exhausted heat energy when filtering in impracticable. Sources of "free" heat should also be considered, compressors and hot process areas being valuable sources on occasion.

Once into operation the levels of training and maintenance can have an impact on wasted energy, environmental emissions or waste materials requiring landfill disposal.

The main objective under these headings is achieving optimum performance. By definition energy, emissions and waste are then controlled. It is a difficult position to reach and maintain. As ventilation and process extraction, (dust or waste), provide secondary or support roles to the principle production process all too often they get a lesser level of training and maintenance. Performance may decline gradually over time and often goes unnoticed with some examples including:

• Incorrect low compressed air pressure or cleaning control settings resulting in lower filter cleaning efficiency. This increases pressure drop and hence the absorbed motor power, and may reduce extraction efficiency.
• Incorrect high compressed air pressure resulting in "puffing"- dust passing through the filter bags due to over-cleaning which increases the carry-over emissions and reduces the life of the filter bags through fatigue during the cleaning process.
• Incorrect fan belt drive adjustment leading to a loss of fan speed which could lead to lost production through a build-up in the ducting or lower efficiency in the extraction and a reduction in the control measure. Complying with COSHH/LEV guidelines may help to identify this, however with 14 month intervals there is a risk of long term deficiency.
• Operators using equipment in an unintended manner is all too frequent and often goes unrecognised. When this situation occurs, performance as a control measure, emissions to atmosphere and an increase in energy consumption may easily result.

In conclusion, sustainable developments in industrial ventilation and process extraction applications are not only achievable but may be quite significant because they are based on good system understanding, design and use. Interestingly many recent developments in energy efficiency are over shadowed by the improvements which may be possible through design, equipment selection and an on-going user training and maintenance programme. It is clear that any low cost installation advantage may be far from the lowest overall cost and soon offset as running and service costs are included over a modest period of time. Also, when using and maintaining the system as intended, the safety and protection provided will be optimised.

Hi Noise Reduction Innovation For Power Stations

Hi Aerodynamic noise control innovation technology;

New technology deployed at the largest US biomass power plant prevents creation of noise from fans while reducing power consumption.

The solution developed by the Industrial Noise and Vibration Center (INVC) from Berkshire, UK, relies on active noise reduction instead of suppressing the noise by silencers and acoustic enclosures.

“We have developed a way to prevent the noise being generated in the first place instead by designing aerodynamic inserts that fit inside the fan casing. You can think of these as akin to the aerodynamic features used on Formula 1 cars to control airflow,” said Peter Wilson, the INVC technical director.

The technology was installed at the 50 MW Schiller biomass power plant in New Hampshire - the largest biomass power plant in the US. The site had had problems due to the noise produced by the station’s ID fan. The installation itself only required 12 hours. According to a technical review evaluating the solution, not only noise reduction has been achieved but the plant  has also been consuming considerably less energy.

"We recorded a 10dB drop in noise, which is huge. We also recorded a reduction in the power used by the ID fan after Quiet Fan technology had been installed." said Jim Granger, the Senior Engineer at Schiller.

Conventional silencing technology to suppress the drone of large ID fans is rather costly and increases down-time of the installation. According to the evaluation data, the Quit Fan technology managed to achieve similar level of noise reduction costing about 80 per cent less.

How does the fan noise attenuating technology work?

A similar approach to that of the way that Formula 1 teams invest in the design of aerodynamic aids to control the airflow round their cars. As fan noise is the sum of the turbulence generated pressure fluctuations in the air shed by the blades, we have developed a range of aerodynamic inserts that are fitted inside the fan casing to smooth the flow. This reduces the pressure fluctuations – and hence the noise – at source without introducing the back-pressure often associated with silencers. This not only reduces the noise travelling down the intake and exhaust duct-work  but also that passing through the fan casing which may not only eliminate the need for silencers, but also the need for acoustic enclosures.

HVAC – Chiller – Condenser – Cooling Tower Noise Reduction:

Innovative new techniques developed to control the noise from HVAC and chiller / condenser systems without compromising efficiency. These typically provide around 10dB of additional attenuation compared with conventional noise reduction packages and silencers – and at a fraction of the cost.

Visit INVC Website for further information and to view case studies on noise reduction innovations.

Hi Industrial Dust, Air Pollution and related Occupational Diseases:

Industrial Dust, Air Pollution and related Occupational Diseases – Nuisance to be controlled for improvement of general environment, safety and health standard:

1.0. Introduction - Air pollution is the presence of high concentration of contamination, dust, smokes etc., in the general body of air man breaths. Dust is defined as particulate matter as “any airborne finely divided solid or liquid material with a diameter smaller than 100 micrometers.” Dust and smoke are the two major components of particulate matter. Car emissions, chemicals from factories, dust, pollen and mold spores may be suspended as particles. Ozone, a gas, is a major part of air pollution in cities. When ozone forms air pollution, it’s also called smog. These materials come from various sources, such as, various industrial processes, paved and unpaved roadways, construction and demolition sites, parking lots, storage piles, handling and transfer of materials, and open areas. Some air pollutants are poisonous. Inhaling them can increase the chances of health problems. In fact, dust when inhaled can increase breathing problems, damage lung tissue, and aggravate existing health problems. In addition to health concerns, dust generated from various activities can reduce visibility, resulting in accidents. Therefore, every federal Govt. has stringent regulations which require prevention, reduction and/or mitigation of dust emissions.

Thus, prime sources of air pollution are the industrial activities or processes releasing large quantity of pollutants in the atmosphere. These pollutants are mainly:

(a) Smoke comes out from various industries like, power plants, chemical plants, other manufacturing facilities, motor vehicles, etc.;

(b) Burning of wood, coal in furnaces and incinerators;

(c) Gaseous pollutants from Oil refining industries;

(d) Dust generated and thrown to general atmosphere by various industries such as cement plants, ore / stone crushing units, mining industries due to rock drilling & movements of mining machineries & blasting etc.;

(e) Waste deposition for landfills which generate methane;

(f) Toxic / germ / noxious gasses and fumes generated from military activities and explosives blasting in mines.

2.0. Mechanism of Adverse Impact of Smoke Pollutant – The main sources of smoke pollutants in urban areas are Petrol / Diesel driven motor vehicles, Fuel combustion in stationary sources including residential, commercial and industrial heating / cooling system and coal-burning power plants etc.

Petrol / Diesel driven motor vehicles produce high levels of Carbon Dioxide (CO2) / Carbon Monoxide (CO), major source of Hydrocarbon (HC) and Nitrogen oxides (NOx). Fuel combustion in stationary sources is the dominant source of Carbon Dioxide (CO2) and Sulfur Dioxide (SO2).

Carbon Dioxide (CO2) – This is one of the major gas pollutants in the atmosphere. Major sources of CO2 are due to burning of fossil fuels and deforestation. Industrially developed countries like USA, Russia etc., account for more than 65% of CO2 emission. Less developed countries with 80% of world’s population responsible for about 35% of CO2 emission. Due to high growth reported from less developed countries in last decade, it is estimated that, the Carbon dioxide emissions may rise from these areas and by 2020 their contribution may become 50%. It has also been seen that, Carbon dioxide emissions are rising by 4% annually.

As ocean water contain about 60 times more CO2 than atmosphere; CO2 released by the industry leads to disturbance of equilibrium of concentration of CO2 in the system. In such a scenario, the oceans would absorb more and more CO2 and atmosphere would also remain excess of CO2. As water warms, ocean’s ability to absorb CO2 is reduced. CO2 is a good transmitter of sunlight, but partially restricts infrared radiation going back from the earth into space. This produces the so-called “Greenhouse Effect” that prevents a drastic cooling of the Earth during the night. This so-called “Greenhouse Effect” is responsible for GLOBAL WARMING. Currently Carbon Dioxide is responsible for major portion of the global warming trend.

Nitrogen oxides (NOx) – They come mainly from nitrogen based fertilizers, deforestation, and biomass burning. Nitrogen oxides contribute mostly as atmospheric contaminants. These gases are responsible in the formation of both acid precipitation and photochemical smog and causes nitrogen loading. These gases have a role in reducing stratospheric ozone.

Sulfur Dioxide (SO2) – Sulfur dioxide is produced by combustion of sulfur-containing fuels, such as coal and fuel oils. SO2 also produced in the process of producing Sulfuric Acid and in metallurgical process involving ores that contain sulfur. Sulfur oxides can injure man, plants and materials. As emissions of sulfur dioxide and nitric oxide from stationary sources are transported long distances by winds, they form secondary pollutants such as nitrogen dioxide, nitric acid vapor, and droplets containing solutions of sulfuric acid, sulfate, and nitrate salts. These chemicals descend to the earth’s surface in wet form as rain or snow and in dry form as a gases fog, dew, or solid particles. This is known as acid deposition or acid rain.

Choloroflurocarbons (CFCs) – Chlorofluorocarbons, also known as Freons, are greenhouse gases that contribute to global warming. CFCs are responsible for lowering the average concentration of ozone in the stratosphere.

Smog – Smog is the result from the irradiation by sunlight of hydrocarbons caused primarily by unburned gasoline emitted by automobiles and other combustion sources. Smog is created by burning coal and heavy oil that contain mostly sulfur impurities.

3.0. Mechanism of air pollution by particulate matters (Fine and Coarse Dust particles) – ‘Fine particles’ are less than 2.5 micron in size and require electron microscope for detection, however, they are much larger than the molecules of Ozone etc., and other gaseous pollutants, which are thousands times smaller and cannot be seen through even electron microscope.

Fine particles are formed by the condensation of molecules into solid or liquid droplets, whereas larger particles are mostly formed by mechanical breakdown of material or crushing of minerals. ‘Coarse particles’ are between 2.5 to 10 micron size, and cannot penetrate as readily as of Fine particle; however, it has been seen these are responsible for serious health hazards. The severity of the health hazards vary with the chemical nature of the particles.

The inhalation of particles has been linked with illness and deaths from heart and lung disease as a result of both short- and long-term exposures. People with heart and lung disease may experience chest pain, shortness of breath, fatigue etc., when exposed to particulate-matter pollutants. Inhalation of particulate matter can increase susceptibility to respiratory infections such as Asthma, Chronic Bronchitis. The general medical term given for such lung diseases is ‘Pneumoconiosis’.

Emissions from diesel-fuel combustion in vehicles / engines / equipments; Dusts from cement plants, power plants, chemical plants, mines are a special problem, specially for those individuals breathing in close proximity to such atmosphere. Cars, trucks and off-road engines emit more than half a million tones of diesel particulate matter per year.

3.1. Controlling Airborne Particulate Matters – Airborne particulate matters (PM) emissions can be minimized by pollution prevention and emission control measures. Prevention, which is frequently more cost-effective than control, should be emphasized. Special attention should be given to mitigate the effects, where toxics associated with particulate emissions may pose a significant environmental risk.

Measures such as improved process design, operation, maintenance, housekeeping, and other management practices can reduce emissions. By improving combustion efficiency in Diesel engines, generation of particulate matters can be significantly reduced. Proper fuel-firing practices and combustion zone configuration, along with an adequate amount of excess air, can achieve lower PICs (products of incomplete combustion). Few following steps should be adhered to control PM:

a. Choosing cleaner fuels – Natural gas used as fuel emits negligible amounts of particulate matter.

b. Low-ash fossil fuels contain less noncombustible, ash-forming mineral matter and thus generate lower levels of particulate emissions.

c. Reduction of ash by coal cleaning reduces the generation of ash and Particulate Matter (PM) emissions by up to 40%.

d. The use of more efficient technologies or process changes can reduce PIC emissions.

e. Advanced coal combustion technologies such as coal gasification and fluidized-bed combustion are examples of cleaner processes that may lower PICs by approximately 10%.

f. A variety of particulate removal technologies, are available – these are (a) Inertial or impingement separators, (b) Electrostatic precipitators (ESPs) , (c) Filters and dust collectors (baghouses), (d) Wet scrubbers that rely on a liquid spray to remove dust particles from a gas stream.

4.0. Dust in cement industry – Its prevention and collection enhances environment standard : The manufacturing of cement involves mining; crushing and grinding of raw materials (mostly limestone and clay); calcinating the material in rotary kiln; cooling the resulting clinker; mixing the clinker with Gypsum; and milling, storing and bagging the finished cement. The cement manufacturing process generates lot of dust, which is captured and recycled to the process. Gasses from clinker cooler are used as secondary combustion air. The process, using pre-heaters and pre-calciners, is both economically and environmentally preferable to wet process because of techno-economic advantages of the energy saving dry system over wet. Certain other solids such as pulverized fly ash from power plants, slag, roasted pyrite residue and foundry sand can be used as additives to prepare blended cement.

a. Dust generation:Generation of fine particulates and dust are inherent in the process; but most are recovered and recycled. The sources of dust emission include clinker cooler, crushers, grinders and material-handling equipment's. Material-handling operations such as conveyors result in fugitive dust emission.

b. Prevention and control of dust: The priority in the cement industry is to minimize the increase in ambient particulate levels by reducing the mass load emitted from the stacks, from fugitive emissions, and from other sources. Collection and recycling of dust in the kiln gases in required to improve the efficiency of the operation and to reduce atmospheric emissions. Units that are well designed, well operated, and well maintained can normally achieve generation of less than 0.2 kilograms of dust per metric tonne (kg /t) of clinker, using dust recovery systems. For control of fugitive dust (a) ventilation systems should be used in conjunction with hoods and enclosures covering transfer points and conveyors; (b) Drop distances should be minimized by the use of adjustable conveyors; (c) Dusty areas such as roads should be wetted down to reduce dust generation; (d) Appropriate stormwater and runoff control systems should be provided to minimize the quantities of suspended material carried off site.

c. Mechanical systems for controlling dust: Several mechanical equipments are used in cement manufacturing plant to control / collect dust. These are:

(i) Dust collector - A dust collector (bag house) is a typically low strength enclosure that separates dust from a gas stream by passing the gas through a media filter. The dust is collected on either the inside or the outside of the filter. A pulse of air or mechanical vibration removes the layer of dust from the filter. This type of filter is typically efficient when particle sizes are in the 0.01 to 20 micron range.

(ii) Cyclone - Dust laden gas enters the chamber from a tangential direction at the outer wall of the device, forming a vortex as it swirls within the chamber. The larger articulates, because of their greater inertia, move outward and are forced against the chamber wall. Slowed by friction with the wall surface, they then slide down the wall into a conical dust hopper at the bottom of the cyclone. The cleaned air swirls upward in a narrower spiral through an inner cylinder and emerges from an outlet at the top. Accumulated particulate dust is deposited into a hopper, dust bin or screw conveyor at the base of the collector. Cyclones are typically used as pre-cleaners and are followed by more efficient air-cleaning equipment such as electrostatic precipitators and bag houses.

(iii) Electrostatic Precipitator - In an electrostatic precipitator, particles suspended in the air stream are given an electric charge as they enter the unit and are then removed by the influence of an electric field. A high DC voltage (as much as 100,000 volts) is applied to the discharge electrodes to charge the particles, which then are attracted to oppositely charged collection electrodes, on which they become trapped. An electrostatic precipitator can remove particulates as small as 1 μm (0.00004 inch) with an efficiency exceeding 99 percent.

5.0. Dust in Coal Handling Plant (CHP) and its control systems:Thermal power plants (coal-fired power plants) use coal as their fuel. To handle the coal, each power station is equipped with a coal handling plant. The coal has to be sized, processed, and handled which should be done effectively and efficiently. The major factor which reduces the staff efficiency in operation of coal handling plant is the working environment i.e. a dusty atmosphere and condition. Lots of care is always needed to reduce dust emission. In developing countries, all most all systems used in power station coal handling plants are wet dust suppression systems.

5.1. After dust is formed, control systems are used to reduce dust emissions. Although installing a dust control system does not assure total prevention of dust emissions, a well-designed dust control system can protect workers and often provide other benefits, such as (a) Preventing or reducing risk of dust explosion or fire; (b) Increasing visibility and reducing probability of accidents; (c) Preventing unpleasant odors; (d) Reducing cleanup and maintenance costs; (e) Reducing equipment wear, especially for components such as bearings and pulleys on which fine dust can cause a “grinding” effect and increase wear or abrasion rates; (f) Increasing worker morale and productivity; (f) Assuring continuous compliance with existing health regulations. In addition, proper planning, design, installation, operation, and maintenance are essential for an efficient, cost-effective, and reliable dust control system.

5.2. There are two basic types of dust control systems currently used in minerals processing operations are:

(a) Dust collection system - Dust collection systems use ventilation principles to capture the dust-filled air-stream and carry it away from the source through ductwork to the collector. A typical dust collection system consists of four major components, such as (1) An exhaust hood to capture dust emissions at the source; (2) Ductwork to transport the captured dust to a dust collector; (3) A dust collector to remove the dust from the air; (4) A fan and motor to provide the necessary exhaust volume and energy.

(b) Wet dust suppression system - Wet dust suppression techniques use water sprays to wet the material so that it generates less dust. There are two different types of wet dust suppression:

(i) wets the dust before it is airborne (surface wetting) and

(ii) wets the dust after it becomes airborne. In many cases surfactants or chemical foams are often added to the water into these systems in order to improve performance.

A water spray with surfactant means that a surfactant has been added to the water in order to lower the surface tension of the water droplets and allow these droplets to spread further over the material and also to allow deeper penetration into the material.

i. Surface wetting system: The principle behind surface wetting is the idea that dust will not even be given a chance to form and become airborne. With this method, effective wetting of the material can take place by static spreading (wetting material while it is stationary) and dynamic spreading (wetting material while it is moving). For static wetting, more effective dust suppression arises by increasing the surface coverage by either reducing the droplet diameter or its contact angle. For dynamic spreading, more factors come into play such as the surface tension of the liquid, the droplet diameter, the size of the material being suppressed, and the droplet impact velocity.

ii. Airborne dust capture system -Airborne dust capture systems may also use a water-spray technique; however, airborne dust particles are sprayed with atomized water. When the dust particles collide with the water droplets, agglomerates are formed.  These agglomerates become too heavy to remain airborne and settle. Airborne dust wet suppression systems work on the principle of spraying very small water droplets into airborne dust. When the small droplets collide with the airborne dust particles, they stick to each other and fall out of the air to the ground. Research showed that, if a sufficient number of water droplets of approximately the same size as the dust particles could be produced, the possibility of collision between the two would be extremely high. It was also determined that if the droplet exceeded the size of the dust particle, there was little probability of impact and the desired precipitation. Instead, the dust particle would move around the droplet.

5.3. System Efficiency: 

Over the years, water sprays has established the following facts:

(a) For a given spray nozzle, the collection efficiency for small dust particles increases as the pressure increases;

(b) At a given pressure, the efficiency increases as the nozzle design is changed so as to produce smaller droplets. The efficiency of spray dust capture increases by increasing the number of smaller sized spray droplets per unit volume of water utilized and by optimizing the energy transfer of spray droplets with the dust-laden air.

5.4. Sophisticated system like ‘Ultrasonic Dust Suppression’ systems uses water and compressed air to produce micron sized droplets that are able to suppress respirable dust without adding any detectable moisture to the process. Ideal for spray curtains to contain dust within hoppers. The advantages of using Ultrasonic Atomizing Systems for dust suppression can therefore be summarized as: (a) reduced health hazards; (b) decrease in atmospheric pollution; (c) improved working conditions; (d) efficient operation with minimum use of water.

6.0. Air pollution control devices / equipments for industries, in general 

The commonly used equipment's / process for control of dust in various industries are (a) Mechanical dust collectors in the form of dust cyclones; (b) Electrostatic precipitators – both dry and wet system; (c) particulate scrubbers; (d) Water sprayer at dust generation points; (e) proper ventilation system and (f) various monitoring devices to know the concentration of dust in general body of air.

The common equipment's / process used for control of toxic / flue gases are the (a) process of desulphurisation; (b) process of denitrification; (c) Gas conditioning etc. and (d) various monitoring devices to know the efficacy of the systems used.

7.0. Occupational Hazards / diseases due to expose in dusty and polluted air: 

There are certain diseases which are related to one’s occupation. These are caused by constant use of certain substances that sneak into air and then enter our body.

(i) Silicosis 

(Silico-tuberculosis) occurs due to inhalation of free silica, or SiO2 (Silicon dioxide), while mining or working in industries related to pottery, ceramic, glass, building and construction work. The workers get chronic cough and pain in the chest. Silicosis treatment is extremely limited considering a lack of cure for the disease. However, like all occupational respiratory ailments, it is 100% preventable if exposure is minimized.

(ii) Asbestosis is caused by asbestos, which is used in making ceilings. It is also considered as cancer causing agent. Pathogenesis of the disease is characterized as progressive and irreversible, leading to subsequent respiratory disability. In severe cases, asbestosis results in death from pulmonary hypertension and cardiac failure.

(iii) Byssinosis, also referred to as brown lung disease, is an occupational respiratory disorder characterized by the narrowing of pulmonary airways. It is a disabling lung disease, which is marked by chronic cough and chronic bronchitis due to inhalation of cotton fibers over a long period of time.

(iv) Coal worker’s Pneumoconiosis 

occurs due to inhalation of coal dust from coal mining industry. Also referred to as black lung disease. The workers suffer from lung problems. Apart from asbestosis, black lung disease is the most frequently occurring type of pneumoconiosis . In terms of disease pathogenesis, a time delay of nearly a decade or more occurs between exposure and disease onset.

7.1. Preventive Measures 

The most successful tool of prevention of respiratory diseases from industrial dust is to minimize exposure. However, this is not a practical approach from the perspective of industries such as mining, construction/demolition, refining/manufacturing/processing, where industrial dust is an unavoidable byproduct. In such cases, industries must implement a stringent safety protocol that effectively curtails exposure to potentially hazardous dust sources. National Institute for Occupational Safety and Health (NIOSH) recommended precautionary measures to reduce exposure to a variety of industrial dust types.

1.    Recognize when industrial dust may be generated and plan ahead to eliminate or control the dust at the source. Awareness and planning are keys to prevention of silicosis.

2.    Do not use silica sand or other substances containing more than 1% crystalline silica as abrasive blasting materials. Substitute less hazardous materials.

3.    Use engineering controls and containment methods such as blast-cleaning machines and cabinets, wet drilling, or wet sawing of silica-containing materials to control the hazard and protect adjacent workers from exposure.

4.    Routinely maintain dust control systems to keep them in good working order.

5.    Practice good personal hygiene to avoid unnecessary exposure to other worksite contaminants such as lead.

6.    Wear disposable or washable protective clothes at the worksite.

7.    Shower (if possible) and change into clean clothes before leaving the worksite to prevent contamination of cars, homes, and other work areas.

8.    Conduct air monitoring to measure worker exposures and ensure that controls are providing adequate protection for workers.

9.    Use adequate respiratory protection when source controls cannot keep silica exposures below the designated limit.

10.    Provide periodic medical examinations for all workers who may be exposed to respirable crystalline silica.

11.    Post warning signs to mark the boundaries of work areas contaminated with respirable crystalline silica.

12    Provide workers with training that includes information about health effects, work practices, and protective equipment for respirable crystalline silica.

13.    Report all cases of silicosis to Federal / State health departments.

8.0. Preventing damaging effects of air and dust pollution 

The prevention of air pollution is world wide concern. There have been many investigations into what causes air pollution and the exact methods that work best in the prevention of air pollution. Through the use of many different methods air pollution is becoming easier to control. It is only through various measures, though, that the prevention of air pollution is possible. The government plays a very important role in prevention of air pollution. It is through government regulations that industries are forced to reduce their air pollution and new developments in technology are created to help everyone do their part in the prevention of air pollution. The government also helps by continuously making regulations stricter and enforcing new regulations that help to combat any new found source of air pollution.

In many countries in the world, steps are being taken to stop the damage to our environment from air pollution. Scientific groups study the damaging effects on plant, animal and human life. Legislative bodies write laws to control emissions. Educators in schools and universities teach students, beginning at very young ages, about the effects of air pollution. The first step to solving air pollution is assessment. Researchers have investigated outdoor air pollution and have developed standards for measuring the type and amount of some serious air pollutants.

Scientists must then determine how much exposure to pollutants is harmful. Once exposure levels have been set, steps can be undertaken to reduce exposure to air pollution. These can be accomplished by regulation of man-made pollution through legislation. Many countries have set controls on pollution emissions for transportation vehicles and industry. This is usually done to through a variety of coordinating agencies which monitor the air and the environment.

In the prevention of air pollution it is important to understand about indoor air pollution. Indoor air pollution may seem like an individual concern, but it actually is not just something to worry about in your own home. Indoor air pollution contributes to outdoor air pollution. Prevention is another key to controlling air pollution. The regulatory agencies mentioned above play an essential role in reducing and preventing air pollution in the environment. In addition, it is possible to prevent many types of air pollution that are not regulated through personal, careful attention to our interactions with the environment. One of the most dangerous indoor air pollutants is cigarette smoke. Restricting smoking is an important key to a healthier environment. Legislation to control smoking is in effect in some locations, but personal exposure should be monitored and limited wherever possible.

9.0. Conclusion 

Air pollution prevention efforts of companies have generally focused on both source and waste reduction, and on reuse and recycling. Preventing air pollution within a company’s manufacturing processes remains the key approach. Cleaning and processing, switch to non-polluting technologies and materials, reduced generation of waste water, converting hazardous by-products to non-threatening forms, etc. have been attempted in this regard. Indirect air pollution prevention measures by companies also cover transportation. Examples of such measures include: providing company transportation to employees; offering commuting information and selling public transit passes; and encouraging employees to carpool and use public transportation. Companies have also initiated successful programmes such as the use of bicycles to commute to work, telecomuting, and work-at-home etc. to reduce pollution due to commuting.

It should be noted that, only through the efforts of scientists, business leaders, legislators, and individuals can we reduce the amount of air pollution on the planet. This challenge must be met by all of us in order to assure that a healthy environment exist for ourselves and our children.