American Power Consultants

The enormous increase in the quantum and diversity of waste materials generated by human activity and their potentially harmful effects on the general environment and public health, have led to an increasing awareness, world-wide, about an urgent need to adopt scientific methods for safe disposal of wastes. While there is an obvious need to minimize the generation of wastes and to reuse and recycle them, the technologies for recovery of energy from wastes can play a vital role in mitigating the problems. Besides recovery of substantial energy, these technologies can lead to a substantial reduction in the overall waste quantities requiring final disposal, which can be better managed for safe disposal in a controlled manner while meeting the pollution control standards.

Waste generation rates are affected by socioeconomic development, degree of industrialization, and climate. Generally, the greater the economic prosperity and the higher percentage of urban population, the greater the amount of solid waste produced. Reduction in the volume and mass of solid waste is a crucial issue especially in the light of limited availability of final disposal sites in many parts of the world. Although numerous waste and byproduct recovery processes have been introduced, anaerobic digestion has unique and integrative potential, simultaneously acting as a waste treatment and recovery process.


There are three main pathways for conversion of organic waste material to energy – thermochemical, biochemical and physicochemical. Thermochemical conversion, characterized by higher temperature and conversion rates, is best suited for lower moisture feedstock and is generally less selective for products. Thermochemical conversion includes incineration, pyrolysis and gasification. The incineration technology is the controlled combustion of waste with the recovery of heat to produce steam which in turn produces power through steam turbines. Pyrolysis and gasification represent refined thermal treatment methods as alternatives to incineration and are characterized by the transformation of the waste into product gas as energy carrier for later combustion in, for example, a boiler or a gas engine.

The bio-chemical conversion processes, which include anaerobic digestion and fermentation, are preferred for wastes having high percentage of organic biodegradable (putrescible) matter and high moisture content. Anaerobic digestion can be used to recover both nutrients and energy contained in organic wastes such as animal manure. The process generates gases with a high content of methane (55–70 %) as well as biofertilizer. Alcohol fermentation is the transformation of organic fraction of waste to ethanol by a series of biochemical reactions using specialized microorganisms.

The physico-chemical technology involves various processes to improve physical and chemical properties of solid waste. The combustible fraction of the waste is converted into high-energy fuel pellets which may be used in steam generation. Fuel pellets have several distinct advantages over coal and wood because it is cleaner, free from incombustibles, has lower ash and moisture contents, is of uniform size, cost-effective, and eco-friendly.

Factors affecting Energy Recovery

The two main factors which determine the potential of recovery of energy from wastes are the quantity and quality (physico-chemical characteristics) of the waste. Some of the important physico-chemical parameters requiring consideration include:

  • Size of constituents
  • Density
  • Moisture content
  • Volatile solids / Organic matter
  • Fixed carbon
  • Total inerts
  • Calorific value

Often, an analysis of waste to determine the proportion of carbon, hydrogen, oxygen, nitrogen and sulfur (ultimate analysis) is done to make mass balance calculations, for both thermochemical and biochemical processes. In case of anaerobic digestion, the parameters C/N ratio (a measure of nutrient concentration available for bacterial growth) and toxicity (representing the presence of hazardous materials which inhibit bacterial growth), also require consideration.

Significance of Waste-to- Energy (WTE) Plants

While some still confuse modern waste-to-energy plants with incinerators of the past, the environmental performance of the industry is beyond reproach. Studies have shown that communities that employ waste-to-energy technology have higher recycling rates than communities that do not utilize waste-to-energy. The recovery of ferrous and non-ferrous metals from waste-to-energy plants for recycling is strong and growing each year. In addition, numerous studies have determined that waste-to-energy plants actually reduce the amount of greenhouse gases that enter the atmosphere.

Nowadays, waste-to-energy plants based on combustion technologies are highly efficient power plants that utilize municipal solid waste as their fuel rather than coal, oil or natural gas. Far better than expending energy to explore, recover, process and transport the fuel from some distant source, waste-to-energy plants find value in what others consider garbage. Waste-to-energy plants recover the thermal energy contained in the trash in highly efficient boilers that generate steam that can then be sold directly to industrial customers, or used on-site to drive turbines for electricity production. WTE plants are highly efficient in harnessing the untapped energy potential of organic waste by converting the biodegradable fraction of the waste into high calorific value gases like methane. The digested portion of the waste is highly rich in nutrients and is widely used as biofertilizer in many parts of the world.

Waste-to-Energy around the World

To an even greater extent than in the United States, waste-to-energy has thrived in Europe and Asia as the preeminent method of waste disposal. Lauding waste-to-energy for its ability to reduce the volume of waste in an environmentally-friendly manner, generate valuable energy, and reduce greenhouse gas emissions, European nations rely on waste-to-energy as the preferred method of waste disposal. In fact, the European Union has issued a legally binding requirement for its member States to limit the landfilling of biodegradable waste.

The Confederation of European Waste-to-Energy Plants (CEWEP) notes that Europe currently treats 50 million ton of wastes at waste-to-energy plants each year, generating an amount of energy that can supply electricity for 27 million people or heat for 13 million people. Upcoming changes to EU legislation will have a profound impact on how much further the technology will help achieve environmental protection goals. Describing the advances of waste-to-energy, the German Ministry for the Environment cites drastic reductions in emissions of dioxin, dust and mercury. Twenty years ago, 18 Swedish waste-to-energy plants emitted a total of about 100 grams of dioxins every year. Today, the collective dioxin emissions from all 29 Swedish waste-to-energy plants amount to 0.7 of a gram. It is clear that Europe has made similar strides as the United States with respect to emissions reductions.


Agricultural Residues

Large quantities of crop residues are produced annually worldwide, and are vastly underutilised. The most common agricultural residue is the rice husk, which makes up 25% of rice by mass. Other residues include sugar cane fibre (known as bagasse), coconut husks and shells, groundnut shells, cereal straw etc. Current farming practice is usually to plough these residues back into the soil, or they are burnt, left to decompose, or grazed by cattle. A number of agricultural and biomass studies, however, have concluded that it may be appropriate to remove and utilise a portion of crop residue for energy production, providing large volumes of low cost material. These residues could be processed into liquid fuels or combusted/gasified to produce electricity and heat.

Animal Waste

There are a wide range of animal wastes that can be used as sources of biomass energy. The most common sources are animal and poultry manures. In the past this waste was recovered and sold as a fertilizer or simply spread onto agricultural land, but the introduction of tighter environmental controls on odour and water pollution means that some form of waste management is now required, which provides further incentives for waste-to-energy conversion. The most attractive method of converting these waste materials to useful form is anaerobic digestion which gives biogas that can be used as a fuel for internal combustion engines, to generate electricity from small gas turbines, burnt directly for cooking, or for space and water heating. Food processing and abattoir wastes are also a potential anaerobic digestion feedstock.

Sugar Industry Wastes

The sugar cane industry produces large volumes of bagasse each year. Bagasse is potentially a major source of biomass energy as it can be used as boiler feedstock to generate steam for process heat and electricity production. Most sugar cane mills utilise bagasse to produce electricity for their own needs but some sugar mills are able to export substantial amount of electricity to the grid.

Forestry Residues

Forestry residues are generated by operations such as thinning of plantations, clearing for logging roads, extracting stem-wood for pulp and timber, and natural attrition. Wood processing also generates significant volumes of residues usually in the form of sawdust, off-cuts, bark and woodchip rejects. This waste material is often not utilised and often left to rot on site. However it can be collected and used in a biomass gasifier to produce hot gases for generating steam.

Industrial Wastes

The food industry produces a large number of residues and by-products that can be used as biomass energy sources. These waste materials are generated from all sectors of the food industry with everything from meat production to confectionery producing waste that can be utilised as an energy source. Solid wastes include peelings and scraps from fruit and vegetables, food that does not meet quality control standards, pulp and fibre from sugar and starch extraction, filter sludges and coffee grounds. These wastes are usually disposed of in landfill dumps.

Liquid wastes are generated by washing meat, fruit and vegetables, blanching fruit and vegetables, pre-cooking meats, poultry and fish, cleaning and processing operations as well as wine making. These waste waters contain sugars, starches and other dissolved and solid organic matter. The potential exists for these industrial wastes to be anaerobically digested to produce biogas, or fermented to produce ethanol, and several commercial examples of waste-to-energy conversion already exist.

Municipal Solid Waste (MSW)

Millions of tonnes of household waste are collected each year with the vast majority disposed of in landfill dumps. The biomass resource in MSW comprises the putrescibles, paper and plastic and averages 80% of the total MSW collected. Municipal solid waste can be converted into energy by direct combustion, or by natural anaerobic digestion in the landfill. At the landfill sites the gas produced by the natural decomposition of MSW (approximately 50% methane and 50% carbon dioxide) is collected from the stored material and scrubbed and cleaned before feeding into internal combustion engines or gas turbines to generate heat and power. The organic fraction of MSW can be anaerobically stabilized in a high-rate digester to obtain biogas for electricity or steam generation.


Sewage is a source of biomass energy that is very similar to the other animal wastes. Energy can be extracted from sewage using anaerobic digestion to produce biogas. The sewage sludge that remains can be incinerated or undergo pyrolysis to produce more biogas

Black Liquor

Pulp and Paper Industry is considered to be one of the highly polluting industries and consumes large amount of energy and water in various unit operations. The wastewater discharged by this industry is highly heterogeneous as it contains compounds from wood or other raw materials, processed chemicals as well as compound formed during processing. Black liquor can be judiciously utilized for production of biogas using UASB technology.

Summary of Successful Waste-to-Energy Plants in India based on Anaerobic Digestion

Leather & Abattoir Industry Waste
Location Capacity Feed type Type of reactor used Biogas utilization
Rudraram, Andhra Pradesh 60 tpd Abattoir waste BIMA Boiler fuel
Melvisharam, Tamil Nadu 5 tpd Fleshing & primary sludge CSTR Aerator operation
Melvisharam, Tamil Nadu 2 tpd Tannery fleshing & sludge UASB Boiler fuel
Dewas, Madhya Pradesh 1.2 -1.5 tpd Chromed leather dust UASB UASB
Vegetable Market Yard Waste
Rudraram, Andhra Pradesh 60 tpd Abattoir waste BIMA Boiler fuel
Melvisharam, Tamil Nadu 5 tpd Fleshing & primary sludge CSTR Aerator operation
Melvisharam, Tamil Nadu 2 tpd Tannery fleshing & sludge UASB Boiler fuel
Dewas, Madhya Pradesh 1.2 -1.5 tpd Chromed leather dust UASB UASB
Vijayawda, Andhra Pradesh 20 tpd Vegetable market and slaughterhouse waste UASB Power generation
Koyambedu, Tamil Nadu 30 tpd Vegetable waste BIMA Power generation
Municipal Wastewater/ Sewage
Bhubaneshwar, Orissa 400 m3/d Domestic Sewage Fixed film Heating and illumination
Surat, Gujarat 0.5 MWe Domestic Sewage Anaerobic sludge Power generation
Animal Agro Residue
Karur, Tamil Nadu 12000 m3/d Bagasse wash water UASB Lime kiln
Ludhiana, Punjab 235 tpd Cattle manure BIMA Power generation
Fruit and Food Processing Waste
Dharmapuri, Tamil Nadu 12000 tpd Tapioca wastewater HUSMAR Power generation

Waste Energy Systems

CCIC energy systems is accompanied by our team of professional whom are more than suppliers. Our Sales, Marketing and Construction Team have over 20 years of experience in the energy industry and contract procurements. We are skilled in the development of the Energy business; we build Energy Plants that turn Garbage into Power. This renewable energy technology reduces wastes by 93% and eliminates methane and other polluting gas emissions while producing electricity. The energy waste systems Process does not create pollution through burning or paralysis, but rather gasifies these materials into a synthetic gas which is then fed into fuel cells to produce clean electricity. These plants have a near-zero carbon footprint and because it uses waste as its fuel source, qualifies as a carbon free energy producer. Operating and maintaining a renewable energy systems can be challenging for commercial, industrial and municipal organizations with constraints. CCIC comprehensive energy services assist businesses and municipalities from the ongoing expense of renewable energy systems while allowing them to reap the benefits of lower energy costs.

Operations and Maintenance (O&M) expenses can vary greatly from one energy solution to another. While a solar array or geothermal system may need very little ongoing maintenance, wind turbines and landfill-gas-to-energy systems require skilled technicians to keep them operating efficiently. Simply finding the right personnel to operate and maintain advanced energy systems can be a challenge, as technologies are changing rapidly.

CCIC can provide complete O&M solutions or integrated solutions with training for existing staff. Our customers can choose best-in-class energy equipment solutions and gain control over the costs to operate and maintain them.

Solar Energy Systems Roof Designs

CCIC are experienced in the design and distribution of commercial solar systems for condominiums, town-houses, home-owners associations, apartment complexes, senior development communities, and multi-metered dwellings. Let our team assist with determining what the best commercial solar solution is for your solar project at a low solar system cost.

CCIC knowledge about Renewable & Alternative Power, CREST, PG&E, SDG&E, SCE, LADWP, Excel, LIPA and many other solar incentive programs such as Solar Feed in Tariffs and RAM program; Renewable Automated Auction programs has proven to be beneficial for our clients. Many states have solar rebate and or solar SREC programs. Buy CCIC can save you hundreds of thousands of dollars on your commercial solar project and solar farm.

Solar System Investment Example

Total Project Size 50 Kilowatts AC
Total Installed Cost ($7*/watt AC) $350,000
State Rebate ($1.9/Watt AC)** - $95,000
Initial Cost $255,000
30% Federal Tax Credit - $76,500
Final Out-of Pocket Cost $178,500
*Cost of SES grid tie system plus $1.50/watt for installation, taxes, permit fees, etc. **Varies state by state.

Let our team assist with Designs and integrates Utility: Scale Solar Systems, Solar Farms, Solar Tracking Systems, Municipal Systems, and Industrial Solar Systems, determining what’s the best commercial solar location and solution for your solar project at a low solar system cost.

Cost Effectiveness:

Factors that affect cost effectiveness for your business, including:

  • System Size
  • Larger systems can cost less per watt than small systems because of economies of scale.

  • Installation Complexity
  • More complex installations, including mounting systems on racks, working around obstructions, such as pipes and HVAC equipment, and building-integrated custom installations can be more expensive.

  • System Production
  • Installing your system at the optimal orientation and tilt will maximize system production. The more energy your system produces over time, the faster you will recoup your investment.

  • Operation and Maintenance (O&M)
  • Compared to other distributed energy technologies, operation and maintenance costs of PV systems are relatively low. Costs may include occasional cleaning of PV modules, regular visual inspections and repair, and possible replacement of inverter and/or components.

  • Expectations
  • Creating some of your own electricity will lower your monthly power bill. One major advantage of a solar power system is that it produces power during peak demand times, offsetting expensive power. It is almost impossible to give you an accurate estimate of financial savings, because it depends on the future price of electricity and your patterns of use.

CCIC use Commercial solar systems are custom solar panel grid-tie power systems for commercial buildings using Kyocera, Sharp, Trina, Shuco, Suntech, Sunpower, Sanyo Yingli, and Upsolar solar panels. Grid-tie inverters include: PV Powered, Satcon, SMA, and GE. CCIC offer below factory direct pricing with factory technical support available and can assist with the solar system design, return on investment calculation, and solar system financing. Solar system rebate application assistance is also available.


The waste-to-energy plants offer two important benefits of environmentally safe waste management and disposal, as well as the generation of clean electric power. Waste-to-energy facilities produce clean, renewable energy through thermochemical, biochemical and physicochemical methods. The growing use of waste-to-energy as a method to dispose of solid and liquid wastes and generate power has greatly reduced environmental impacts of municipal solid waste management, including emissions of greenhouse gases. Waste-to-energy conversion reduces greenhouse gas emissions in two ways. Electricity is generated which reduces the dependence on electrical production from power plants based on fossil fuels. The greenhouse gas emissions are significantly reduced by preventing methane emissions from landfills. Moreover, waste-to-energy plants are highly efficient in harnessing the untapped sources of energy from a variety of wastes.


1. Gunasegarane, G.S., Energy from Dairy Waste, Bio Energy News, 6, 2002, pp 26.
2. Sirviö, A., and Rintala, J. A., Renewable Energy Production in Farm Scale: Biogas from Energy Crops, Bio Energy News, 6, 2002, pp 16.
3. Rao, R.P., Energy from Agro Waste – A Case Study, Bio Energy News, 3, 1999, pp 21.
4. Mapuskar, S.V., Biogas from Vegetable Market Waste at APMC Pune, Bio Energy News. 1, 1997, pp 16.
5. Dhussa A.K., and Varshney, A.K., Energy Recovery from Municipal Solid Waste – Potential and Possibilities, Bio Energy News, 4, 2000, pp 7.

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