Organic waste drying, Low-temperature drying of strongly sticky and adhesive, difficult-to-dry organic waste / Test cases / Organic waste dryer, Upcycling drying

■ Organic waste drying, Low-temperature drying of strongly sticky and adhesive, difficult-to-dry organic waste / KENKI DRYER / Organic waste dryer, Upcycling drying

 

SUMMARY

Organic Waste Drying Challenges
If organic waste is left moist, it decomposes due to microbial activity, producing gases, odors, and pathogens. Drying is an effective solution to these problems.
Many organic wastes are sticky, adhesive, and difficult to dry, often causing clogging in traditional dryers.

KENKI DRYER Features
KENKI DRYER uses a unique, patented mechanism to dry sticky and adhesive organic waste smoothly without clogging, even with high water content.
It employs indirect steam heating for low-temperature drying, preserving the composition of the organic waste and allowing for effective upcycling and recycling.

Environmental and Economic Benefits
The low-temperature drying process minimizes changes in the waste’s composition, making it suitable for various applications such as fertilizer, compost, soil conditioner, livestock feed, and bioplastics production.
Dryers do not emit CO2 during operation, and because they can use steam from electric or hydrogen fuel boilers as a heat source without emitting excess steam or CO2, they contribute to decarbonization and environmental protection.

Operational Efficiency
KENKI DRYER is a continuous drying system, allowing for 24-hour unattended operation, easy maintenance, and low operating costs. The slow rotation speed of the main body blades reduces wear and tear on parts.

Resource Conservation
Drying reduces the weight and volume of sludge, lowering disposal costs and carbon emissions from transportation.
The dryer helps in the reuse and recycling of minerals like phosphorus from sludge, contributing to resource conservation and environmental protection.

Additional Uses
Dried organic sludge can be used as fuel, biochar, or bio-coke, which can replace traditional wood or coke in various industries, such as steel and foundry.

Patents and Recognition
The KENKI DRYER has 11 patents in 8 countries (Japan, USA, Taiwan, France, Germany, UK, Switzerland, Canada) and is recognized for its improved productivity, high performance, and durability.

 


 

If organic waste is left in a moist state, it will begin to decompose due to the activity of the micro-organisms (particularly bacteria and molds) it contains. These micro-organisms use the moisture and nutrients in the organic waste to multiply, producing gases and odors which cause the waste to rot and become a source of bad odors and pathogens. Drying is an effective way to solve these problems.

However, many organic wastes have strong adhesive qualities and are difficult to dry, and depending on the type of dryer, there are cases where the dryer becomes clogged during the drying process and the organic waste cannot be discharged. With the KENKI DRYER, even if the adhesive qualities are strong and the processing is difficult, and even if the product to be dried has a high water content and is difficult to process, it can be dried easily and smoothly. The KENKI DRYER uses a unique mechanism, which is patented worldwide, and can dry even organic waste with a high water content that has a strong adhesive quality smoothly without clogging the inside of the dryer.

The up-cycling and recycling of organic waste generated during the production of goods in factories is becoming increasingly important from the perspective of environmental protection and decarbonization, and the demand for this will only increase.
KENKI DRYER The heat source is steam from a boiler and it is an indirect low temperature drying process. As it is a low-temperature drying process, there is little change in the composition of organic waste, so it can be effectively used for upcycling, and it is possible to achieve zero-emission drying.

Depending on its composition, dried organic waste can be used as fertilizer, compost or soil conditioner on fields, or as feed for livestock such as cows and pigs. It is also possible to produce bioplastics from plant-based organic waste, which can be used as alternatives to petroleum-based plastics and as raw materials for biodegradable plastics.

KENKI DRYER, which has 11 patents in 8 countries, is a steam indirect dryer, but it is a completely unique product with a different structure from other steam indirect dryers. Direct-fire dryers, such as those that use burners, emit carbon dioxide, which is bad for the environment and goes against the trend of decarbonization. Because they dry at high temperatures, they use a lot of fuel and their parts wear out quickly, making them expensive to maintain.

KENKI DRYER uses steam as a heat source, but because of its high drying heat efficiency, it only needs a small amount of steam, so you can use the steam you’re currently using, and if you use excess or surplus steam, you don’t have to pay for fuel. The dryer doesn’t emit carbon dioxide when it dries, so you can dry without carbon dioxide. Alternatively, by installing an electric or hydrogen fuel boiler, there is no emission of global warming gases or carbon dioxide CO2 during the drying process.
In addition, there are no problems after start-up, and the rotation speed of the dryer’s main body blades is very slow at less than 5 rpm, so there is little wear and tear on parts, and maintenance is easy and inexpensive. KENKI DRYER is a continuous drying system, in which the drying material to be dried is stored, rather than a batch system. Therefore, operation is simple and unmanned operation is possible 24 hours a day.

By reducing the weight of the sludge through drying, the amount of industrial waste produced can be reduced, which in turn helps to reduce the cost of industrial waste, which has increased in recent years due to the 2024 trucking issue and other factors, and also helps to reduce carbon dioxide emissions by reducing the number of trucks used, thereby contributing to environmental protection and decarbonization.

Japan is almost 100% dependent on imports for its mineral resources. In the future, precious metals and rare metals in particular will continue to be important resources, and securing these resources is essential to maintaining and strengthening international competitiveness. One of the measures to secure mineral resources is the reuse and recycling of minerals contained in sludge, which will contribute to environmental protection and reduce greenhouse gas emissions. Phosphorus, which is currently imported from China, is also an indispensable mineral. Therefore, the extraction of phosphorus from sewage sludge is being promoted as a national project. The recycling of sludge, which is a necessary part of wastewater treatment plants, is important for environmental protection, decarbonization, and securing resources that are currently dependent on imports and demand is only increasing.

Wood is currently in short supply in Japan. The use of dried organic sludge as a fuel instead of wood or the use of dried organic sludge as biochar or bio-coke by carbonization is attracting much attention. For example, bio-coke can be used as a reductant or deoxidizer to replace coke in the steel and foundry industries. Biochar and bio-coke are carbonized materials made from biological resources that are effective in revitalizing organisms and improving the environment. For carbonization, please contact us about Biogreen, our pyrolysis equipment that does not use fossil fuels and does not emit CO2, a greenhouse gas.

If you have any questions or concerns, please let us know. We will be happy to suggest the best dryer for your company’s needs.
Our dryer, ‘KENKI DRYER’, has received 11 patents in 8 countries and is particularly effective at drying sticky materials that others cannot handle. It has no installation problems, is easy to maintain, and has low operating costs. The KENKI DRYER has been well received by companies that have installed it due to its uniform drying, improved productivity with less manpower, high performance and durability.

KENKI DRYER can dry sticky and adhesive materials that others cannot dry. KENKI DRYER is a breakthrough drying device with a total of 11 patents (2 in Japan and 9 in 7 overseas countries). Please consider KENKI DRYER for your high moisture organic waste dryer, sludge dryer, slurry dryer, methane fermentation digestate dryer, and waste upcycling or recycling dryer.

KENKI DRYER has been granted 11 patents in 8 countries (Japan, Taiwan, USA, France, Germany, UK, Switzerland, Canada).

 

 

 

 

organic waste upcycling drying kenki dryer waste dryer 17.6.2024

 

 

kenki dryer front KENKI DRYER

 

 

■ The reasons why KENKI DRYER is chosen for organic waste dryers

 

KENKI DRYER is a specialized low-temperature dryer designed to efficiently dry and recycle difficult-to-dry, high-moisture organic waste. It uses indirect steam heating to ensure minimal changes to the waste’s composition, making it suitable for various applications.

Here are some key reasons why KENKI DRYER is chosen for organic waste dryers:

Unique Mechanism:

  • Self-cleaning twin screw conveyors: This patented technology guarantees effective movement of the feedstock, even for sticky and adhesive objects to be dried.
  • Low-temperature drying: Minimal changes to the waste composition, preserving its value for upcycling and recycling.
  • Indirect steam heating: Safe and efficient drying process that use low-pressure steam.

Advantages:

  • Handles difficult-to-dry objects to be dried: Effectively dries sticky, adhesive, and high-moisture organic waste.
  • Preserves objects to be dried quality: Low-temperature drying minimizes changes in composition.
  • Environmentally friendly: Zero-emission drying reduces environmental impact.
  • Efficient and cost-effective: Low running costs and easy maintenance.
  • Continuous operation: 24-hour unattended operation is possible.
  • Versatile applications: Dried organic waste can be used for various purposes, such as fertilizer, compost, feed, fuel, soil conditioner, and bioplastic.

If you are looking for a reliable and efficient solution for drying organic waste, KENKI DRYER is an excellent choice. It offers a unique combination of features and benefits that make it stand out from other drying technologies.

 

■ The reasons why KENKI DRYER is chosen for upcycling dryers

 

KENKI DRYER is an ideal choice for upcycling dryers due to its unique design and capabilities:

Preservation of Material Quality:

  • Low-temperature drying: Minimal changes to the waste’s composition, preserving its original properties for various upcycling applications.
  • Indirect steam heating: Safe and efficient drying process that use low-pressure steam.

Efficient Handling of Difficult Materials:

  • Self-cleaning twin screw conveyors: Effectively handle sticky and adhesive materials, ensuring smooth and continuous drying.
  • Crushing function: Breaks down lumps and agglomerates, promoting uniform drying and maximizing upcycling potential.

Environmental Benefits:

  • Zero-emission drying: Reduces environmental impact and contributes to sustainable practices.
  • Energy efficiency: Low energy consumption and minimal maintenance requirements.
  • Resource conservation: Enables the recovery of valuable materials from waste streams.

Versatility and Flexibility:

  • Handles a wide range of materials: Suitable for various organic waste types, including beverage lees, raw material lees, sludge and food waste
  • Customizable configurations: Adaptable to specific upcycling needs and production scales.

By choosing KENKI DRYER, you can significantly enhance your upcycling operations and contribute to a more sustainable future.

 

What is upcycling drying?

 

Upcycling drying refers to the process of removing moisture from waste materials to prepare them for conversion into higher-value products or materials. This is a crucial step in the upcycling process, where discarded or low-value materials are transformed into new, more valuable items rather than simply being recycled or disposed of.
The drying phase ensures that organic or other moist waste is suitable for further processing, such as mechanical, chemical, or thermal treatments. By thoroughly drying the waste, it becomes easier to handle, process, and incorporate into new products, contributing to sustainable practices and supporting a circular economy.
For instance, drying can be applied to food waste, agricultural by-products, or sludge to convert them into biofuels, compost, animal feed, or other reusable materials. The goal of upcycling drying is not just to reduce the volume and weight of the waste but to enhance its value and prepare it for productive reuse.

Source:ChatGPT

 

■ What is organic waste?

 

Organic waste is any material that comes from plants or animals and can decompose naturally. This means that it can be broken down by microorganisms, such as bacteria and fungi, into simpler organic matter. Organic waste is a major component of municipal solid waste, and it can be a valuable resource if it is composted or recycled.

Here are some examples of organic waste:

  • Food scraps, such as fruit peels, vegetable trimmings, and coffee grounds
  • Yard trimmings, such as leaves, grass clippings, and branches
  • Manure from animals
  • Paper products, such as cardboard and newspapers
  • Wood scraps

Organic waste can be composted to create a nutrient-rich soil amendment that can be used to improve plant growth. It can also be anaerobically digested to produce biogas, which can be used as a renewable energy source.

Source:Gemini

 

■ Reasons for drying organic waste

 

Prevents Decomposition and Odors: Drying inhibits the activity of bacteria and molds, which stops decomposition, unpleasant odors, and the spread of pathogens.

Reduces Weight and Volume: Lowering moisture content significantly reduces the weight and volume of waste, leading to decreased transportation and disposal costs.

Facilitates Recycling and Upcycling: Dried organic waste can be repurposed as fertilizer, compost, animal feed, or as raw materials for bioplastics, supporting circular economy initiatives.

Contributes to Environmental Protection: Drying reduces greenhouse gas emissions by minimizing waste transport needs and promoting the use of organic byproducts.

Supports Zero-Emission Processes: When dried using low-emission technologies, such as steam-based or electric drying, organic waste processing aligns with decarbonization efforts.

Enables Resource Recovery: Dried organic waste can be processed into biochar or bio-coke, which can replace fossil fuels in various industrial applications, contributing to resource efficiency.

Improves Storage and Handling: Dried waste is easier to store and handle, reducing issues related to moisture retention, such as mold and material degradation.

Source:ChatGPT

 

■ Organic waste drying, Low-temperature drying of strongly sticky and adhesive, difficult-to-dry organic waste / KENKI DRYER / Test cases

 

 

 

■ Organic waste drying, Low-temperature drying of strongly sticky and adhesive, difficult-to-dry organic waste / KENKI DRYER / Test result

 

  • Material to be dry: Strongly sticky and adhesive Organic waste
  • Purpose of drying: Upcycling, Reducing industrial waste cost and amount
  • Moisture content: 56.7%W.B. before drying, 3.2%W.B. after drying
  • Requirements for dryer: To prevent clogging inside the dryer caused by the stickiness and adhesiveness. Automated continuous operation with no operator attended.
    Machine cost can be recovered in short term.
  • Test result: OK

organic waste drying before and after kenki dryer organic waste dryer 17.07.2024

 

Waste drying

Competitive comparison

 

KENKI DRYER kenki dryer back 13.06.2024

 

 

Woman illustration organic waste drying kenki dryer organic waste dryer 08.11.2024

 

 

Fuel

 

fuel is any material that can be made to react with other substances so that it releases energy as thermal energy or to be used for work. The concept was originally applied solely to those materials capable of releasing chemical energy but has since also been applied to other sources of heat energy, such as nuclear energy (via nuclear fission and nuclear fusion).
The heat energy released by reactions of fuels can be converted into mechanical energy via a heat engine. Other times, the heat itself is valued for warmth, cooking, or industrial processes, as well as the illumination that accompanies combustion. Fuels are also used in the cells of organisms in a process known as cellular respiration, where organic molecules are oxidized to release usable energy. Hydrocarbons and related organic molecules are by far the most common source of fuel used by humans, but other substances, including radioactive metals, are also utilized.
Fuels are contrasted with other substances or devices storing potential energy, such as those that directly release electrical energy (such as batteries and capacitors) or mechanical energy (such as flywheels, springs, compressed air, or water in a reservoir).

Source:Wiki Fuel

 

 Compost

 

Compost is a mixture of ingredients used as plant fertilizer and to improve soil’s physical, chemical, and biological properties. It is commonly prepared by decomposing plant and food waste, recycling organic materials, and manure. The resulting mixture is rich in plant nutrients and beneficial organisms, such as bacteria, protozoa, nematodes, and fungi. Compost improves soil fertility in gardens, landscaping, horticulture, urban agriculture, and organic farming, reducing dependency on commercial chemical fertilizers. The benefits of compost include providing nutrients to crops as fertilizer, acting as a soil conditioner, increasing the humus or humic acid contents of the soil, and introducing beneficial microbes that help to suppress pathogens in the soil and reduce soil-borne diseases.

Source:Wiki Compost

 

 Fertilizer

 

fertilizer (American English) or fertiliser (British English) is any material of natural or synthetic origin that is applied to soil or to plant tissues to supply plant nutrients. Fertilizers may be distinct from liming materials or other non-nutrient soil amendments. Many sources of fertilizer exist, both natural and industrially produced. For most modern agricultural practices, fertilization focuses on three main macro nutrients: nitrogen (N), phosphorus (P), and potassium (K) with occasional addition of supplements like rock flour for micronutrients. Farmers apply these fertilizers in a variety of ways: through dry or pelletized or liquid application processes, using large agricultural equipment or hand-tool methods.

Source:Wiki Fertilizer

 

The three primary elements of fertilizer

 

The three primary elements of fertilizer, essential for plant growth and commonly referred to as macronutrients in the context of plant nutrition, are:

Nitrogen (N):
Function: Promotes leaf and stem growth, as it is a crucial component of chlorophyll, the compound that plants use in photosynthesis to convert sunlight into energy. Nitrogen is also a key part of amino acids, the building blocks of proteins.
Deficiency Symptoms: Yellowing of leaves (chlorosis), stunted growth, and poor yield.

Phosphorus (P):
Function: Essential for energy transfer and storage in plants, as it is a component of ATP (adenosine triphosphate). Phosphorus also plays a vital role in root development, flowering, and seed production.
Deficiency Symptoms: Dark green or purplish leaves, delayed maturity, and poor root development.

Potassium (K):
Function: Regulates various metabolic activities in plants, including photosynthesis, protein synthesis, and water regulation. Potassium is also important for improving disease resistance and overall plant health.
Deficiency Symptoms: Leaf edges may turn yellow or brown (scorching), weak stems, and reduced resistance to drought and diseases.
Fertilizers are often labeled with an N-P-K ratio, which indicates the relative proportions of these three essential nutrients. For example, a fertilizer labeled as 10-20-10 contains 10% nitrogen, 20% phosphorus, and 10% potassium.

Source:ChatGPT

 

■ What is Bioplastics?

 

Bioplastics are a type of plastic derived from renewable biological sources, such as vegetable fats and oils, corn starch, straw, woodchips, sawdust, and recycled food waste. Unlike conventional plastics, which are made from petroleum-based raw materials, bioplastics are made from biomass. There are several types of bioplastics, each with different properties and applications.

Types of Bioplastics

  1. Bio-based plastics: Made partially or wholly from biological sources. Examples include:

    • Polylactic Acid (PLA): Derived from corn starch or sugarcane, used in packaging, disposable cutlery, and medical implants.
    • Polyhydroxyalkanoates (PHA): Produced by bacterial fermentation of sugars or lipids, used in medical devices and packaging.
  2. Biodegradable plastics: These can be broken down by microorganisms into water, carbon dioxide, and biomass under certain conditions.

    • Starch Blends: Composed of starch mixed with other biodegradable polymers.
    • Polybutylene Succinate (PBS): Biodegradable plastic made from succinic acid and 1,4-butanediol.
  3. Compostable plastics: These biodegrade under composting conditions within a specific timeframe.

    • Polylactic Acid (PLA): When used in compostable products, it can break down in industrial composting facilities.

Advantages of Bioplastics

  • Reduced Carbon Footprint: Production often generates fewer greenhouse gas emissions compared to conventional plastics.
  • Biodegradability: Some bioplastics can decompose in natural environments, reducing litter and pollution.
  • Renewable Resources: Made from plant-based materials, which can be sustainably grown and harvested.

Challenges and Considerations

  • Cost: Often more expensive to produce than conventional plastics.
  • Performance: May not always match the durability and versatility of petroleum-based plastics.
  • Recycling and Composting Infrastructure: Limited facilities available for processing bioplastics.
  • Environmental Impact: Not all bioplastics are biodegradable, and improper disposal can still contribute to pollution.

Bioplastics are part of a broader effort to create more sustainable materials and reduce reliance on fossil fuels. However, their development and adoption involve balancing environmental benefits with practical and economic considerations.

Source:ChatGPT

 

What is Biodegradable Plastic?

 

Bioplastics are a type of plastic derived from renewable biological sources, such as vegetable fats and oils, corn starch, straw, woodchips, sawdust, and recycled food waste. Unlike conventional plastics, which are made from petroleum-based raw materials, bioplastics are made from biomass. There are several types of bioplastics, each with different properties and applications.

Biodegradable plastic is a type of plastic that can be broken down by living organisms, typically microbes, into simpler substances like water, carbon dioxide, and biomass. It’s one kind of bioplastic, but the terms aren’t exactly interchangeable.

Here’s the key difference:

  • Bioplastic: This refers to the origin of the plastic. It’s made from renewable sources like plants or microorganisms (bio-based). Not all bioplastics are biodegradable.
  • Biodegradable Plastic: This describes the end-of-life of the plastic. It can be broken down by living things under certain conditions (e.g., composting facilities).

So, all biodegradable plastics are bioplastics, but not all bioplastics are biodegradable.

Here are some additional details about biodegradable plastics:

  • Materials: They can be derived from various renewable sources like corn starch, cellulose, or even be made with the help of microorganisms.
  • Benefits: Biodegradable plastics offer an advantage over traditional plastics by decomposing in a reasonable timeframe, potentially reducing plastic pollution in landfills.
  • Considerations: Biodegradable plastics often require specific conditions for breakdown, such as industrial composting facilities. Improper disposal might not lead to biodegradation and could still cause environmental issues.

Overall, biodegradable plastics are a promising development for reducing plastic waste, but it’s important to understand their proper use and limitations.

Source:Gemini

 

Why there is not enough lumber in Japan as of 2024?

 

The shortage of lumber in Japan as of 2024 can be attributed to several factors:

  1. Increased Demand: The global demand for lumber has surged due to a post-pandemic construction boom. As economies recover, the need for housing, infrastructure, and renovations has significantly increased, putting pressure on lumber supplies.

  2. Supply Chain Disruptions: Ongoing disruptions in global supply chains, including transportation delays, port congestions, and logistical challenges, have made it difficult to import lumber into Japan efficiently.

  3. Reduced Domestic Production: Japan’s domestic lumber production has been declining due to factors such as aging forestry workers, a lack of investment in modern forestry practices, and environmental regulations that limit logging activities.

  4. Natural Disasters: Japan is prone to natural disasters such as earthquakes, typhoons, and floods, which can disrupt lumber production and supply chains, further exacerbating shortages.

  5. Environmental Regulations: Stricter environmental regulations and sustainability practices have led to reduced logging activities in Japan and other countries, limiting the availability of lumber.

  6. Geopolitical Tensions: Trade tensions and geopolitical issues with major lumber-producing countries can impact the availability and cost of imported lumber. Restrictions or tariffs on lumber exports from key suppliers can lead to shortages.

  7. Economic Factors: Fluctuations in currency exchange rates, inflation, and the overall economic climate can affect the affordability and accessibility of imported lumber.

  8. COVID-19 Impact: The lingering effects of the COVID-19 pandemic, including labor shortages and health-related restrictions, continue to impact production and transportation sectors globally, affecting lumber supply.

  9. Forest Management Issues: Poor forest management practices and insufficient reforestation efforts in Japan have led to a depletion of local timber resources, contributing to the shortage.

These factors combined create a challenging environment for ensuring a steady supply of lumber in Japan, impacting various sectors that rely on this essential resource.

Source:ChatGPT

 

What is Biochar?

 

Biochar is a form of charcoal that is produced by heating organic material (biomass) such as wood, crop residues, or manure in a controlled environment with little or no oxygen through a process called pyrolysis. Here are some key aspects of biochar:

  1. Production Process: Biochar is created through pyrolysis, which involves heating biomass in the absence of oxygen. This process thermally decomposes the organic material, producing a stable, carbon-rich product.

  2. Soil Amendment: One of the primary uses of biochar is as a soil amendment. When added to soil, it can enhance soil fertility, improve water retention, increase microbial activity, and reduce the need for chemical fertilizers.

  3. Carbon Sequestration: Biochar is highly stable and can remain in the soil for hundreds to thousands of years, effectively sequestering carbon and reducing greenhouse gas emissions. This makes it a valuable tool in mitigating climate change.

  4. Environmental Benefits: Biochar can help reduce soil erosion, improve soil structure, and increase agricultural productivity. It also has the potential to filter and remove contaminants from soil and water, contributing to environmental remediation.

  5. Energy Production: The pyrolysis process that produces biochar also generates syngas (a mixture of hydrogen, carbon monoxide, and other gases) and bio-oil, which can be used as renewable energy sources.

  6. Waste Management: By converting agricultural and forestry residues, animal manure, and other organic waste into biochar, it provides a sustainable method of managing waste materials.

  7. Livestock and Composting: Biochar can be used in animal husbandry to improve feed efficiency and reduce methane emissions from livestock. It is also used in composting to enhance the composting process and reduce odors.

  8. Water Purification: Due to its porous structure and high surface area, biochar can be used as a filtration medium to remove pollutants from water, including heavy metals, organic contaminants, and nutrients.

Overall, biochar represents a versatile and sustainable solution with multiple applications in agriculture, environmental management, and energy production, contributing to both soil health and climate change mitigation.

Source:ChatGPT

 

What is Bio-coke?

 

Bio-coke is an eco-friendly fuel source produced from biomass, which are organic materials like plants and animals. Unlike traditional coke, which is derived from coal, bio-coke is made from renewable resources and offers a more sustainable alternative.

Here’s a breakdown of bio-coke:

  • Raw Materials: Bio-coke can be created from various forms of biomass, including:

    • Waste materials like used tea leaves, coffee grounds, fruit peels, and sawdust
    • Energy crops specifically grown for bio-fuel purposes
  • Production Process: Biomass goes through a process called pyrolysis, which involves heating the material in the absence of oxygen. This process removes moisture and volatile compounds, leaving behind a solid carbonaceous material – bio-coke.

  • Applications: Bio-coke is primarily used as a substitute for coal coke in industrial processes, particularly steelmaking. Steelmaking traditionally relies on coal coke as a source of carbon and heat. Bio-coke offers a more sustainable alternative by reducing dependence on fossil fuels and potentially lowering greenhouse gas emissions.

Benefits of Bio-Coke:

  • Renewable Source: Bio-coke is derived from renewable biomass, unlike coal coke which is a finite resource.
  • Reduced Emissions: Bio-coke production can potentially lower greenhouse gas emissions compared to traditional coke production.
  • Waste Management: Bio-coke can utilize waste materials like used coffee grounds and sawdust, promoting waste management and diverting them from landfills.

Challenges of Bio-Coke:

  • Production Scale: Bio-coke production is still under development, and large-scale production facilities are not yet widespread.
  • Properties: Bio-coke may have slightly different properties compared to coal coke, potentially requiring adjustments in industrial processes.
  • Cost: Currently, bio-coke production can be more expensive than traditional coke production.

Overall, bio-coke is a promising development in the pursuit of more sustainable industrial practices. As research and development progress, bio-coke has the potential to become a more viable and widely used alternative to coal coke.

Source:Gemini

 

Difference between Biochar and Bio-coke

 

Both biochar and bio-coke are products derived from organic materials, but they have some key differences:

Processing Temperature:

  • Biochar: Produced at lower temperatures (typically around 300-700°C) through a process called pyrolysis. Limited oxygen is present during pyrolysis.
  • Bio-coke: Produced at higher temperatures (around 700-1000°C) in an almost complete absence of oxygen. This higher temperature process is more similar to coal coking.

End Product:

  • Biochar: A porous and lightweight material with a high surface area. It’s rich in carbon but can also retain some nutrients from the original biomass.
  • Bio-coke: Denser and has a higher carbon content compared to biochar. It shares some similarities with traditional coke in terms of physical properties.

Applications:

  • Biochar: Primarily used for soil amendment. Its porous structure helps retain water and nutrients, improving soil health. It can also be used for filtration, as a source of renewable energy, and for capturing pollutants.
  • Bio-coke: Intended as a sustainable substitute for coal coke in industrial processes, particularly steelmaking. It provides carbon and heat, similar to coal coke, but with potentially lower greenhouse gas emissions.

Here’s a table summarizing the key differences:

FeatureBiocharBio-coke
Processing TemperatureLower (300-700°C)Higher (700-1000°C)
Oxygen PresenceLimitedAlmost absent
End ProductPorous, lightweightDense, high carbon
ApplicationsSoil amendment, filtrationIndustrial fuel (steel)

Source:Gemini

 


 

■ Self-cleaning screw / Steam Heated Twin Screw Technology
( SHTS technology )

 

One of the International Patented Technology that KENKI DRYER has is a self-cleaning structure called Steam Heated Twin Screw technology (SHTS technology). No matter how materials are sticky, adhesive and viscous is, they can be dried without clogging inside of the dryer because of this unique structure that no other products has.
For example, even materials stuck to the blades of one screw, blades of the other screw in the dryer’s body forcibly peels the materials off as they rotate. Since the blades rotate by peeling the material off each other, any sticky, adhesive and viscous material does not adhere to the blade, and the blades continue rotating, peeling, agitating and heating material without stopping while they carries material further. Also, since surface of blades are always renewed and kept clean, heat near the blades is not blocked and it is conducted directly into the materials.

Self-cleaning screw

 

■ Product characteristics


KENKI DRYER has three main characteristics. They are 1) Any materials can be dried as expected including sticky, adhesive and viscous materials and raw material slurry that no other company can deal with, 2) dried material can by recycled or utilized as raw materials because of its low-temperature drying method, and 3) there is no need to assign operator since its continuous operating system makes 24 hours unattended operation possible.

Products

 

■ Drying process

 

The unique and original drying mechanism of KENKI DRYER is also International Patented Technology. Because 4 drying mechanisms which are crashing drying, agitation drying, circulation drying and indirect drying work simultaneously and add heat to material being dried repeatedly and continuously, inner part of the material is dried thoroughly and quality of discharged material after drying is stable. This series of drying mechanisms prevents agglomeration which causes insufficient drying from feeding process of the material into the dryer until discharging process after drying completed. Various ingenuities to conduct heat surely into inner part of the materials are exercised and stable heating and drying are proceeded continuously.

Methods

 

■ Heat source, Saturated steam

 

Even KENKI DRYER uses only saturated steam as its heat source, it is outstanding in safety and hygiene point of view with its unique drying mechanism based on combined use of conductive heat transfer method and heated air method. Since steam is a stable heat source, quality of discharged material after drying is also stable and equable. Maximum allowed steam pressure is 0.7Mpa and adjustment of steam pressure, adjustment of drying temperature in other words, can be easily done. Saturated steam is commonly used in many factories so that it can be said as a familiar and handy heat source. In comparison with drying methods using burner or hot blasts, saturated steam method is an indirect drying applying heat exchange via pipes that steam is passing through, therefore, it hardly burns the materials and is outstanding in safety and hygiene point of view.

Heat source, Steam

 

Please consider KENKI DRYER for drying of sticky materials, adhesive materials and materials in liquid state that no other dryer can deal with.
Initial, running and maintenance costs are low because of its simple structure based on internationally patented technology.
For sludge drying, costs of our dryers are estimated to be retrieved within 2, 3 years by reducing industrial waste disposal cost.
For raw material slurry drying, laborious works of manual operation will be decreased significantly by replacing box shaped compartment tray dryer with our dryer
In case of organic wastes drying, the waste can be recycled as fuel, fertilizer, soil conditioner and feedstuff after being dried.

 

Company site
No more trouble. Conveyor, Industrial environmental equipment and apparatus
http://kenki-corporation.com
Pyrolyzer Biogreen
A pyrolyser with internationally patented technology which use no fire
http://www.biogreen-energy.com